transformation of 'galia
TRANSCRIPT
TRANSFORMATION OF ‘GALIA’ MELON TO IMPROVE FRUIT QUALITY
By
HECTOR GORDON NUÑEZ-PALENIUS
A DISSERTATION PRESENTED TO THE GRADUATE SCHOOL OF THE UNIVERSITY OF FLORIDA IN PARTIAL FULFILLMENT
OF THE REQUIREMENTS FOR THE DEGREE OF DOCTOR OF PHILOSOPHY
UNIVERSITY OF FLORIDA
2005
Copyright 2005
by
Hector Gordon Nuñez-Palenius
This document is dedicated to the seven reasons in my life, who make me wake up early all mornings, work hard in order to achieve my objectives, dream on new horizons and
goals, feel the beaty of the wind, rain and sunset, but mostly because they make me believe in God: my Dads Jose Nuñez Vargas and Salvador Federico Nuñez Palenius, my Moms Janette Ann Palenius Alberi and Consuelo Nuñez Solís, my wife Nélida Contreras
Sánchez, my son Hector Manuel Nuñez Contreras and my daughter Consuelo Janette Nuñez Contreras.
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ACKNOWLEDGMENTS
This dissertation could not have been completed without the support and help of
many people who are gratefully acknowledged here.
My greatest debt is to Dr. Daniel James Cantliffe, who has been a dedicated advisor
and mentor, but mostly an excellent friend. He provided constant and efficient guidance
to my academic work and research projects. This dissertation goal would not be possible
without his insightful, invariable and constructive criticism. I thank Dr. Daniel J.
Cantliffe for his exceptional course on Advanced Vegetable Production Techniques
(HOS-5565) and the economic support for living expenses during my graduate education
in UF.
I extend my appreciation to my supervisory committee, Dr. Donald J. Huber, Dr.
Harry J. Klee, and Dr. Donald Hopkins, for their academic guidance. I am very thankful
to Dr. Donald J. Huber for his excellent advice on postharvest guidance, and also for his
excellent lectures in Postharvest Physiology (HOS-6331). I am very grateful to Dr. Harry
J. Klee for his constant supervision and help on plant molecular issues, as well as for his
outstanding teaching in Molecular Biology of Plant Hormones (HOS-5306). I express my
gratitude to Dr. Donald Hopkins for his welcoming assistance.
I would like to express my deepest appreciation to Dr. Richard Lee and Dr. Charles
Niblett for being part of my committee, although they had to leave before this dissertation
was completed. I would like to extend an special thank to Dr. Charles Niblett for all his
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help when I arrived at UF, and for being an excellent mentor, but mostly for his
exceptional friendship.
I extend my appreciation to Dr. Mark Settles for allowing me to use his lab to
accomplish some of the plant molecular issues, as well as to Diego Fajardo for his
technical advice and untied camaraderie.
I would like to make a special acknowledgement to my friends in the Seed
Physiology Lab for their help and support during these years: Reggie Salazar, Dr. Do
Kim, Dr. Javier Castellanos, Nicole Shaw, Dr. Ivanka Kozareva, Ashwin Paranjpe,
Yousef Al-Dlaigan, Juan Carlos Rodriguez, Elio Jovicich, Jennifer Bonina, JeanMarie
Mitchell, Teddy McAvoy, Jimmy Webb, Ji-Young and Cecil Shine III.
I would like to thank my friends in the Plant Molecular Lab: Dr. Mark G. Taylor,
Dr. Joseph A. Ciardi, Dawn Bies, Stephanie Maruhni, Michele Auldridge, Michele
Zeigler, Anna Block, Patricia Moussatche, and especially Dr. Denise M. Tieman and
Bryan Kevany for their outstanding technical advice and friendship to accomplish this
dissertation.
I would like to show appreciation to my friends in the Postharvest Lab: Dr. Steve
A. Sargent, James Lee, Muharem Ergun, Yasart Karakurt, Kim Cordasco, Adrian Berry,
Brandon Hurr and Daniel Stanley.
I would like to express my deepest appreciation to the National Council for Science
and Technology (CONACYT-México) and EDUCAFIN (Guanajuato-México) which
have supported my scholastic and living expenses during my graduate education in UF.
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TABLE OF CONTENTS page
ACKNOWLEDGMENTS ................................................................................................. iv
LIST OF TABLES............................................................................................................. ix
LIST OF FIGURES ........................................................................................................... xi
ABSTRACT..................................................................................................................... xiv
CHAPTER
1 INTRODUCTION ........................................................................................................1
2 LITERATURE REVIEW .............................................................................................4
2.1. Importance of Melon .............................................................................................4 2.1.1 Introduction ..................................................................................................4 2.1.2 Botany and Origin of Cucumis melo ............................................................5 2.1.3 Classification and Cultivars..........................................................................7
2.1.3.1 Naudin’s categories for Cucumis melo L. are listed below:...............9 2.1.3.2 Guis’s categories: ...............................................................................9
2.1.4 Climateric and Non-climateric Fruits .........................................................11 2.2 Postharvest Physiology of Melon .........................................................................11
2.2.1 Physiological Changes During Ripening....................................................11 2.2.2 Ethylene Production ...................................................................................14 2.2.3 Biochemical Changes During Ripening .....................................................15
2.2.3.1 Introduction ......................................................................................15 2.2.3.2 Carbohydrate Metabolism ................................................................16 2.2.3.3 Organic Acids...................................................................................19 2.2.3.4 Volatiles ...........................................................................................20 2.2.3.5 Cell Wall Degradation......................................................................23 2.2.3.6 Pigments ...........................................................................................26
2.2.4 Ethylene and Molecular Changes During Ripening...................................28 2.2.4.1 Introduction ......................................................................................28 2.2.4.2 Biosynthesis, Perception and Effects of Ethylene............................28
2.3 Melon Biotechnology ...........................................................................................36 2.3.1 Genetic Improvement .................................................................................36
2.3.1.1 Traditional Breeding ........................................................................36 2.3.1.2 Improvement Through Genetic Engineering....................................37
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2.3.1.3 Melon Biotechnology.......................................................................42 2.3.2 In vitro Regeneration..................................................................................43
2.3.2.1 Genetic Control ................................................................................44 2.3.2.2 Polyploidization and Somaclonal Variation.....................................46 2.3.2.3 Vitrification ......................................................................................51
2.3.3 Regeneration by Organogenesis .................................................................53 2.3.3.1 Medium Composition.......................................................................54 2.3.3.2 Environmental Factors .....................................................................60
2.3.4 Regeneration by Somatic Embryogenesis ..................................................61 2.3.4.1 Medium Composition.......................................................................65 2.3.4.2 Environmental Factors .....................................................................66
2.3.5 Haploid Plants and Embryo Culture...........................................................67 2.3.6 Genetic Transformation..............................................................................70
2.3.6.1 Improvement of Disease Resistance ................................................76 2.3.6.2 Improvement of Tolerance to Physical Factors................................78 2.3.6.3 Improvement of Postharvest Characteristics....................................78
2.4 ‘Galia’ melon ........................................................................................................82 2.4.1 Introduction ................................................................................................82 2.4.2 Botany and Origin ......................................................................................83 2.4.3 Postharvest Physiology...............................................................................86 2.4.4 Genetic Improvement by Conventional Methods and Biotechnology .......89
3 EFFECT OF EXPLANT SOURCE ON REGENERATION AND TRANSFORMATION EFFICIENCY IN ‘GALIA’ MELON (Cucumis melo L.) MALE AND FEMALE PARENTAL LINES ............................................................95
3.1 Introduction...........................................................................................................95 3.2 Materials and Methods .........................................................................................97
3.2.1 Plant Material .............................................................................................97 3.2.2 Agrobacterium Inoculation and Plant Transformation...............................97 3.2.3 Histochemical Staining for GUS Activity and GFP Detection ..................99 3.2.4 PCR Assay................................................................................................100 3.2.5 Experimental Design and Statistical Analysis..........................................100
3.3 Results and Discussion .......................................................................................101 3.3.1 Effect of Explant Origin on Regeneration Efficiencies............................101 3.3.2 Plant Transformation ................................................................................102 3.3.3 Summary...................................................................................................110
4 TRANSFORMATION OF A MUSKMELON ‘GALIA’ HYBRID PARENTAL LINE (Cucumis melo L. var. reticulatus Ser.) WITH AN ANTISENSE ACC OXIDASE GENE .....................................................................................................111
4.1 Introduction.........................................................................................................111 4.2 Materials and Methods .......................................................................................113
4.2.1 Plant Material ...........................................................................................113 4.2.2 Plant Regeneration....................................................................................113 4.2.3 Agrobacterium Inoculation and Plant Transformation.............................114
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4.2.4 Flow Cytometry Analysis.........................................................................115 4.2.5 Detection of Transgenes ...........................................................................116 4.2.6 Southern Blot Analysis.............................................................................117 4.2.7 Segregation Analysis of Transgenes in Primary Transformants ..............118
4.3 Results and Discussion .......................................................................................118 4.3.1 Transformation Efficiency........................................................................118 4.3.2 Ploidy Level of Primary Regenerants.......................................................120 4.3.3 Southen Blot Analysis ..............................................................................123 4.3.4 Transgene Inheritance in the T1 Progenies of Primary Transformants ....123 4.4.1 Conclusion................................................................................................124 4.5.1 Summary...................................................................................................127
5 EMBRYO-RESCUE CULTURE IN ‘GALIA’ MALE PARENTAL LINE MELON (Cucumis melo L. var. reticulatus Ser.)....................................................129
5.1 Introduction.........................................................................................................129 5.2 Materials and Methods .......................................................................................130
5.2.1 Plant Material ...........................................................................................130 5.2.2 Embryo Culture ........................................................................................131 5.2.3 Experimental Design and Statistical Analysis..........................................134
5.3 Results and Discussion .......................................................................................134 5.3.1 Embryo Development...............................................................................134 5.3.2 Regeneration Efficiency ...........................................................................136
5.4 Summary.............................................................................................................146
6 FRUIT RIPENING CHARACTERISTICS IN A TRANSGENIC ‘GALIA’ MALE PARENTAL LINE MUSKMELON (Cucumis melo L. var. reticulatus Ser.)...........................................................................................................................148
6.1 Introduction.........................................................................................................148 6.2 Materials and Methods .......................................................................................149
6.2.1 Plant Material ...........................................................................................149 6.2.2 Determination of Fruit Size ......................................................................151 6.2.3 Determination of Physical and Biochemical Characteristics ...................151 6.2.4 Experimental Design and Statistical Analysis..........................................154
6.3 Results.................................................................................................................155 6.3.1 ACC Oxidase Activity In Vivo ................................................................155 6.3.2 Ethylene Production .................................................................................155 6.3.3 Firmness, Rind Color and TSS.................................................................157 6.3.4 Mesocarpic Titratable Acidity, pH and Ripening Index ..........................159 6.3.5 Determination of Fruit Size and Seed Number ........................................161
6.4 Discussion...........................................................................................................164 6.5 Summary.............................................................................................................175
LIST OF REFERENCES.................................................................................................177
BIOGRAPHICAL SKETCH ...........................................................................................215
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LIST OF TABLES
Table page 2.1 Production of various cucurbits on different countries in 2004 (1,000 metric
tons). ...........................................................................................................................5
2.2 Similarities between conventional and biotechnological methods for melon plant improvement.............................................................................................................38
2.3 Melon regeneration (shoots, roots and/or complete plants) through direct organogenesis. ..........................................................................................................55
2.4 Melon regeneration through indirect organogenesis. ...............................................58
2.5 Melon regeneration through somatic embryogenesis...............................................63
2.6 Genes transferred to melon by plant genetic transformation. ..................................73
2.7 ‘Galia’ Type Muskmelon Imports to U.S.................................................................84
2.8 ‘Galia’ Type Muskmelon Unit Value Imports to U.S. .............................................85
3.1 Regeneration efficiency in ‘Galia’ muskmelon parental lines depending on explant source.........................................................................................................103
4.1 Transformation efficiency of ‘Galia’ male parental line with CMACO-1 antisense construct..................................................................................................120
5.1 Components of E-20A nutrient medium. ...............................................................133
5.2 Regeneration efficiency of ‘Galia’ male parental line immature embryos that underwent development to form normal plants......................................................141
5.3 Regeneration efficiency of ‘Galia’ male parental embryos cultured on two different media. ......................................................................................................145
5.4 Regeneration efficiency of ‘Galia’ male parental embryos depending on harvesting dates. .....................................................................................................145
5.5 Regeneration efficiency of ‘Galia’ male parental embryos depending on inoculation system (IS)...........................................................................................145
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6.1 Postharvest fruit characteristics of ‘Galia’ male parental line. ..............................163
6.2 Postharvest fruit characteristics of ‘Galia’ male parental line. ..............................165
6.3 Postharvest fruit characteristics of ‘Galia’ male parental line. ..............................166
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LIST OF FIGURES
Figure page 2.1 Global land area of cultivated transgenic crops.. .....................................................40
2.2 Yearly increase in global land area of transgenic crops...........................................41
2.3 Top Ten Countries growing GMOs in the World in 2004. From James, C. (2004). ......................................................................................................................42
3-1 Map of the T-DNA in pMON17204 and pCAMBIA 2202-sGFPS65T...................99
3.2 Organogenetic response of ‘Galia’ muskmelon parental lines depending on explant source.........................................................................................................101
3.3 Time schedule for de novo shoot regeneration in hypocotyl, cotyledon and true-leaf explants of ‘Galia’ muskmelon parental lines.................................................104
3.4 Stable expression of GFP and GUS genes in T0 shoots and roots of ‘Galia’ muskmelon parental lines.......................................................................................106
3.5 Transformation efficiency on ‘Galia’ muskmelon parental lines. GUS reporter gene was used to transform different explant sources............................................107
3.6 Transformation efficiency on ‘Galia’ muskmelon parental lines. GFP reporter gene was used to transform different explant sources............................................107
3.7 PCR assay for transgenic GUS ‘Galia’ melon male and female line plants. .........108
3.8 Time schedule for cotyledon and hypocotyl transformation systems in ‘Galia’ melon parental lines ...............................................................................................109
4.1 T-DNA region of binary vector pCmACO1-AS. ...................................................116
4.2 PCR assay for putative transgenic ‘Galia’ muskmelon male line plants. ..............119
4.3 Stable expression of β-D-Glucuronidase (GUS) gene in T0 shoots (A and B) and roots (C and D) of ‘Galia’ muskmelon male parental line. ....................................121
4.4 Transgenic (left) and non-transgenic (right) in vitro ‘Galia’ male line explants. ..122
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4.5 Flow cytometry analysis of propidium iodide-stained nuclei from wild type leaf tissue of ‘Galia’ male parental line. .......................................................................125
4.6 Flow cytometry analysis of propidium iodide-stained nuclei from transgenic leaf tissue of ‘Galia’ male parental line. .......................................................................126
4.7 Southern blot hybridization assay of male muskmelon transgenic plants. ............127
5.1 ‘Galia’ male parental line fruit at 4 DAP stage (a and b). (c) in vitro embryo development from 4 DAP stage. ............................................................................136
5.2 ‘Galia’ male parental line fruit at 10 DAP stage (a)...............................................137
5.3 ‘Galia’ male parental line fruit at 17 DAP stage (a)...............................................138
5.4 ‘Galia’ male parental line fruit (a and b) and embryo (c) at 24 DAP stage. ‘Galia’ male parental line fruit (d and e) and embryo (f) at 30 DAP stage............139
5.5 Normal ‘Galia’ male parental line seedlings obtained from embryo rescue, having well-developed cotyledonary (red arrows) and true leaves (blue arrows). 140
5.6 Percentage of ‘Galia’ male parental line immature embryos that developed to form normal plants. ................................................................................................143
5.7 Percentage of ‘Galia’ male parental line immature embryos that developed to form normal plants. ................................................................................................144
6.1 Wild type and TGM-AS ‘Galia’ male parental line fruit at 50 DAP. ....................152
6.2 Flesh size and seed cavity size determination in ‘Galia’ male parental line fruit.. .......................................................................................................................154
6.3 ACC oxidase activity in vivo in WT (∗), TGM-AS-1 ()), TGM-AS-2 (→), azygous-AS (=) and T-GUS (■) fruits....................................................................156
6.4 Ethylene production from WT (∗), TGM-AS-1 ()), TGM-AS-2 (→), azygous-AS (=) and T-GUS (■) fruits. .................................................................................157
6.5 Regression analysis between ACC oxidase activity and ethylene production in ‘Galia’ male parental fruits. ...................................................................................158
6.6 Ethylene production from WT (∗) and TGM-AS ()) fruits compared to firmness of WT (■) and TGM-AS (□) intact fruits...............................................................160
6.7 Ethylene production from WT (∗) and TGM-AS ()) fruits compared to rind color of WT (■) and TGM-AS (□) intact fruits......................................................161
6.8 Rind color in WT (A) and TGM-AS (B) ‘Galia’ male muskmelon fruit. ..............162
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6.9 Ethylene production from WT (∗) and TGM-AS ()) fruits compared to TSS content of WT (■) and TGM-AS (□) intact fruits. .................................................162
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Abstract of Dissertation Presented to the Graduate School of the University of Florida in Partial Fulfillment of the Requirements for the Degree of Doctor of Philosophy
TRANSFORMATION OF ‘GALIA’ MELON TO IMPROVE FRUIT QUALITY
By
Hector Gordon Nuñez-Palenius
December 2005 Chair: Daniel J. Cantliffe Major Department: Horticultural Science
Stable genetic transformation in ‘Galia’ muskmelon has not been achieved to date.
The objectives of this study were to obtain an efficient and reliable in vitro regeneration
system for ‘Galia’ muskmelon (Cucumis melo L. var. reticulatus Ser.) parental lines, and
to attain a dependable transformation protocol as depicted through reporter genes such as
β-glucuronidase (GUS) and green fluorescent protein (GFP). Once this was accomplished
the ACC oxidase gene (CMACO-1) in antisense orientation was inserted into both
‘Galia’ parental lines using an Agrobacterium-mediated transformation system. By
reducing ACC oxidase, it was hoped that ripening would be delayed thus allowing a
longer time-frame to ship fruit in a firm condition. Three protocols using different melon
explants, i.e. cotyledon, hypocotyl and true-leaf, and several plant hormonal balances
were used on ‘Galia’ male and female parental lines with the aim to induce de novo shoot
in vitro regeneration. The best explant to induce in vitro regeneration was cotyledon
using 1 mg.L-1 benzyladenine (BA) and 0.001 mg.L-1 α-Naphthaleneacetic acid (NAA) as
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plant hormones. Efficient transformation rates as high as 13% were achieved when
hypocotyl and the GFP reporter gene were used, however, more than 27 weeks were
needed to attain seedlings. Using cotyledon as explants and either the GUS or GFP gene,
transformation rates of 8-10% were observed, and transgenic seedlings were obtained in
fewer than 11 weeks. The ACC oxidase gene from melon (CMACO-1) in antisense
orientation was used to transform ‘Galia’ male and female parental lines. Two (TGM-
AS-1 and TGM-AS-2) independent ‘Galia’ male transgenic diploid plants were obtained
using the ACC oxidase gene. A postharvest evaluation was carried out on ACC oxidase
transgenic and wild type fruits. Antisense fruits had reduced ACC oxidase enzyme
activity, as well as lower ethylene production compared to wild type fruits. Moreover,
fruit softening was delayed in CMACO-1. The results of this research indicated that the
insertion of an ACC oxidase gene in antisense orientation in the ‘Galia’ male parental
inbred reduced ethylene synthesis in transgenic (TGM-AS) T0 fruits. As a result of low
ethylene production by TGM-AS fruits, several parameters such as yellowing of the rind,
ripening index, and fruit softening were delayed by as much as 10 days. Other non-
ethylene dependent traits, such as fruit size, seed development, and mesocarpic total
soluble solids, titratable acidity and pH were not affected by the transgene presence.
TGM-AS-1 and TGM-AS-2 T1 seeds, obtained from these T0 evaluated fruits, will be
used to obtain and select future improved lines with extended shelf-life.
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CHAPTER 1 INTRODUCTION
Melon (Cucumis melo L.) belongs to the Cucurbitaceae family, and is an important
worldwide commodity (Food and Agriculture Organization [FAO], 2005). Within
Cucumis melo species several important horticultural groups can be identified:
cantalupensis, inodorus, flexuosus, conomon, dudaim, and momordica (Robinson and
Decker-Walters 1999). Melons belonging to these horticultural groups vary in their field
performance and postharvest characteristics.
Developed from a breeding program initiated in the mid-1960s ‘Galia’ muskmelon
was the first Israeli melon hybrid. This commodity was released in 1973, and has
exceptional characteristics such as fruit quality with 13-15% total soluble solids (TSS),
bold flavor and a distinct musky aroma. Galia’s high-quality characteristics increased
local market popularity within a short time. In fewer than 10 years, ‘Galia’ melons were
distributed almost all over Western Europe, and became a unique and special market
category of muskmelon (Karchi, 2000). The main disadvantage of ‘Galia’ is its short
storage life, since it is harvested near peak maturity for optimum flavor. Storage is
limited to two or three weeks, even when it is maintained in low temperature (6-8oC).
Different strategies have been used in order to delay fruit softening in ‘Galia’ including
the use of controlled atmospheres plus adding an ethylene absorbent (Aharoni et al.,
1993a), reducing the storage time during transportation by using airfreight systems,
instead of seafreight shipping (Bigalke and Huyskens-Keil, 2000), and applying
inhibitors of ethylene action, such as 1-methylcyclopropene (Ergun et al. 2005).
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Using traditional breeding methods and long-shelf life melon cultivars, breeders
have been able to develop a strategy to insert gene(s) which have increased ‘Galia’
muskmelon shelf-life. However, this approach has resulted in a loss of favorable fruit
quality characteristics (Karchi, personal communication). Using a plant biotechnology
approach by means of plant transformation is a feasible alternative to introduce novel or
native genes, which likely will increase ‘Galia’ muskmelon shelf life, without affecting
its unique characteristics. This approach was used to delay fruit ripening in Cantaloupe
melon (cv. Védrantais), by inserting the ACC oxidase gene in antisense orientation with
promising results (Ayub et al. 1996; Guis et al. 1997b; Silva et al. 2004). However, in
order to attain a consistent plant transformation protocol, it is imperative to have a
reliable and efficient in vitro plant regeneration system. Nevertheless, ‘Galia’ muskmelon
has not been easily in vitro cultivated and full regenerated plants are especially difficult
or are impossible to obtain (Leshem, 1989; Leshem et al. 1994a; 1994b; Gaba et al. 1994;
Gaba et al. 1996; Edriss et al. 1996; Kintzios and Taravira, 1997; Galperin et al. 2003a).
Moreover, Gaba et al. (1999) reported ‘Galia’ muskmelon to be recalcitrant to
transformation by Agrobacterium tumefaciens.Therefore, the research on plant in vitro
parameters to induce de novo shoot regeneration in ‘Galia’ muskmelon will provide
valuable information to attain a consistent and practical in vitro protocol, in order to
obtain fully regenerated ‘Galia’ muskmelon plants. Moreover, the research to find
favorable conditions for successful Agrobacterium-mediated transformation will enable
us to insert any gene of interest into this recalcitrant muskmelon cultivar, specifically
with the final aim to increase its shelf-life.
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The objective of this research was to obtain an efficient and reliable in vitro
protocol to induce de novo plant regeneration in ‘Galia’ muskmelon parental lines, as
well as to attain a consistent and practical transformation methodology aimed to insert the
ACC oxidase gene in antisense orientation, and delay the fruit ripening process. In order
to achieve the objective of this research, several experimental approaches were taken.
These were to 1) examine the effect of several plant hormones and their balances, as well
as different melon explant sources on de novo shoot and root regeneration in ‘Galia’ male
and female parental lines; 2) establish the favorable conditions for Agrobacterium
tumefaciens-mediated transformation using two reporter genes, i.e., GUS and GFP in
‘Galia’ male and female parental lines; 3) transform ‘Galia’ male parental line with the
ACC oxidase gene in antisense orientation (CMACO-1); and 4) evaluate transgenic
CMACO-1 ‘Galia’ male fruit since a postharvest approach.
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CHAPTER 2 LITERATURE REVIEW
2.1. Importance of Melon
2.1.1 Introduction
The Cucurbitaceae family consists of mostly frost sensitive, principally tendril-
bearing vine plants which are found in sub-tropical and tropical regions around the world
(Robinson and Decker-Walters, 1999). Nevertheless, some species within this family are
well adapted to low temperatures and xerophytic conditions (Wien, 1997). Plants
belonging to the Cucurbitaceae family are commonly well known as Cucurbits, and,
according to their geographic origin they can be classified as new world and old world
species. Two well-defined subfamilies, eight tribes, about 120 genera and more than 800
species are found in this family (Jeffrey, 1990). They are largely cultivated as vegetables
and several parts of the plants are utilized for foodstuff. Fruits are the most commonly
eaten part of the plant, but seeds, flowers, tendrils, very young shoots and roots are also
used for food. In addition, Cucurbits are exploited as medicines, such as Cucurbita
andreana, which has chemical compounds (cucurbitacins) with anticancer and
antiinflamatory activities (Jayaprakasam et al. 2003). In addition, in China, fruits and
roots of Cucumis melo are taken as emetic, leaves and seeds for hematoma, and stems to
reduce hypertension. Cucurbits are utilized for unusual purposes as well, such as to store
food (Gourd) or to be used as a sponge (Loofah) (Robinson and Decker-Walters, 1999).
The most important cultivated cucurbits –based on total production and harvestable
area– around the globe are watermelon (Citrullus lanatus Thunb.), cucumber (Cucumis
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sativus L.), melon (Cantaloupe and other melons) (Cucumis melo L.), pumpkin
(Cucurbita spp.), and squash (Cucurbita spp.) (Table 2.1) (FAO, 2005).
Table 2.1 Production of various cucurbits on different countries in 2004. Region Watermelon Cucumber Melon Pumpkin & squash Asia 81,157 33,038 19,537 12,122 Europe 3,955 3,923 3,160 2,177 N&C America 3,135 2,059 2,440 1,942 Africa 3,800 1,074 1,601 1,782 South America 1,315 77 565 722 World 93,481 40,190 27,371 19,016
(1,000 metric tons). (FAO, 2005).
Among the major cucurbit vegetables, Cucumis melo has one of the highest
polymorphic fruit types and botanical varieties. This is as a consequence of genetic
diversity in this species (Mliki et al. 2001). Therefore, some melon fruits can have
excellent aroma, variety of flesh colors, deeper flavor and more juice compared to other
cucurbits (Goldman, 2002).
2.1.2 Botany and Origin of Cucumis melo
Most melons are trailing indeterminate length vines and up to 15 m long;
nevertheless some modern cultivars with shortened internodes, bushy appearance and
concentrated-yield have been bred (Paris et al. 1982, Paris et al. 1985, McCollum et al.
1987, Paris et al. 1988). All melons are frost-sensitive, but many differ in their ability to
survive cold and hot environments (Wien, 1997).
The main stem is almost round in shape. Stems may have some pubescence or not,
but when present it is not so pronounced as in other cucurbits (Zitter et al. 1996). Leaves
are simple, either three- or five-lobed, and borne singly at the nodes and commonly they
may have a great variation in size, color, and shape (Kirkbride, 1993). Tendrils are borne
in leaf axis and are simple (unbranched).
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Sex expression in Cucumis melo is controlled by genetic factors, as well as by
environment (Wien, 1997; Robinson and Decker-Walters, 1999). According to Wien
(1997), at least four environmental factors, such as light energy, photoperiod, water
supply, and temperature, have a strong influence on sex expression. Normally,
physiological conditions which favor the increase of carbohydrates within the plant, such
as low temperature, low nitrogen availability, short photoperiod and high moisture
accessibility, promote female sex expression (Robinson and Decker-Walters, 1999).
These environmental factors affect plant hormonal balance, which in turn determines sex
expression. In general, gibberellins promote male flower development, whereas auxins
and ethylene induce female flower production (Karchi, 1970). Melon plants bear perfect
or imperfect flowers in several combinations: perfect (hermaphroditic) flowers are
capable of self-pollination, and imperfect flowers are either pistillate (female) or
staminate (male) (Zitter et al. 1996). Most melon cultivars are andromonoecious
(hermaphroditic and staminate flowers present at the same plant), although monoecious
(pistillate and staminate flowers) forms are found as well (Seshadri and More, 2002).
Melon fruits are generally classified as an indehiscent ‘pepo’, with three ovary
sections or locules. According to Robinson and Decker-Walters (1999), a ‘pepo’ is a
fleshy fruit with a leathery, non-septate rind derived from an inferior ovary. The edible
flesh is derived from the placentae or mesocarpic tissue (Seymour and McGlasson, 1993).
Among the different parts of a melon plant, fruit has the highest diversity in size, form,
external ornamentation, and internal and external color (Kirkbride, 1993). For instance,
Périn et al. (2002b) reported that fruits as short as 4 cm long (Cucumis melo L. var.
agrestis) and as long as 200 cm (Cucumis melo L. var. flexuosus), attaining weights of
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between 50 g and more than 15 kg (a 300-fold variation size), are known (Naudin, 1859).
Variation is also expressed in flesh color (orange, orange light or pink, green, white or
even mixture of these colors), rind color (green, yellow, white, orange, red, gray or blend
of these colors), rind texture (smooth, warty, striped, netted, rough or combination of
these textures), form (round, flatten or elongated), and size (from 4 up to 200 cm)
(Kirkbride, 1993; Goldman, 2002). Some melon fruits (depending of the cultivar) when
ripe have an abscission layer at the attachment zone between the fruit and stem, whereas
others remain attached to the stem even after they are ripe (Kirkbride, 1993).
Africa and Asia have been suggested as possible sites of origin (Robinson and
Decker-Walters, 1999). Nevertheless, Kerje and Grum (2000) reported, based on genetic
studies, crossing attempts with other Cucumis species, and world distribution of melon
varieties, that the origin of melon appears to be Africa. The domestication process of
melon started in Egypt over 3,000 years ago (Pangalo, 1929). From this area, melon
species dispersed throughout the Middle East and Asia, where a secondary domestication
and diversification development may have ocurred (Kerje and Grum, 2000).
2.1.3 Classification and Cultivars
According to Jeffrey (1990), melon classification may be listed as follows:
Class: Dycotyledoneae
Subclass: Dilleniidae
Superorder: Violanae
Order: Cucurbitales
Family: Cucurbitaceae
Tribe: Melothrieae
Subtribe: Cucumerinae
8
Genus: Cucumis
Subgenus: Melo
Species: Cucumis melo
The high polymorphism of fruits in cultivated melons has lent botanists to propose
different infraspecific classifications. An excellent, updated and complete study on
Cucumis genus was undertaken by Dr. Joseph H. Kirkbride, Jr. (1993) from USDA. His
book titled “Biosystematic Monograph of the Genus Cucumis (Cucurbitaceae)” is a
cornerstone in melon classification.
In 1859 the french botanist Charles Naudin, using mostly living plants grown in the
gardens of the Natural History Museum of Paris, proposed the first useful system of
infraspecific categorization for Cucumis melo L. Naudin (1859) subdivided this species
into ten groups, which were later revised by Munger and Robinson (1991), proposing
trinomial names. However, several classifications have been reported (Alefeld, 1866;
Cogniaux and Harms, 1924; Whitaker and Davis, 1962; Pangalo, 1958; Filov, 1960;
Grebenščikov, 1986; Kirkbride, 1993; Pyzhenkov and Malinina, 1994; Robinson and
Decker-Walters, 1999). Recently, Pitrat et al. (2000) proposed a complete synthesis of
infraspecific classification of melon. They identified the synonymous epithets used in
several publications in order to propose their classification. These authors recognized 16
groups and denominated them as varietas or variety.
On the other hand, Smith and Welch (1964) and Robinson and Decker-Walters
(1999) considered that Naudin's categories are horticultural groups and not botanical
varieties based in phylogeny.
9
2.1.3.1 Naudin’s categories for Cucumis melo L. are listed below:
1. Cantalupensis group. Cantalupe and muskmelon. Medium size fruits with netted, warty or scaly surface, flesh usually orange but sometimes green, flavor aromatic or musky. Fruits with abscission layer at maturity. Usually andromonoecious plants.
2. Inodorus group. winter melons: honeydew, canary, casaba and crenshaw. Fruits usually larger, later in maturity and longer keeping than those of the Cantalupensis group. Rind surface smooth or wrinkled, but not netted, flesh typically white or green and lacking amusky odor. Fruits do not detach from the peduncle when mature. Typically andromonoecious plants.
3. Flexuosus group. Snake melon or Armenian cucumber. Fruits are very long, slender and often ribbed. They are used when inmmature as an alternative to cucumber. Monoecious plants.
4. Conomon group. Makura uri and Tsuke uri (pickling melons). Small fruits with smooth, tender skin, white flesh, early maturity and usually with little sweetness or odor. They are used as a pickling, but also eaten fresh or cooked. Andromonoecious plants.
5. Dudaim group. Pomegranate melon, chito melon, Queen Anne’s pocket melon and mango melon. Small, round to oval fruits with white flesh and thin rind.
6. Momordica group. phoot and snap melon. Small fruits with oval to cylindrical shape. Flesh is white or pale orange, low in sugar content. Smooth surface. Most of the cultivars are monoecious.
Alternatively, Guis et al. (1998) reported a new categorization of horticultural
important melons. These authors based their classification on a previous biosystematic
monograph of the genus Cucumis (Cucurbitaceae) reported by Kirkbride in 1993, who
used morphological, cytological and macro-distributional data to systematize that genus.
2.1.3.2 Guis’s categories:
7. C. melo var. cantaloupensis Naud. Medium size fruits, rounded in shape, smooth surface or warty, and often have prominent ribs and sutures, if there is netting, is sparse. Orange flesh, aromatic flavor and high in sugars.
8. C. melo var. reticulatus Ser. Medium size fruits, and netted surface. If ribs are present, they are not-well marked, flesh color from green, white to red orange. Most are sweet and have a musky odor.
9. C. melo var. saccharinus Naud. Medium size fruits, round or oblong shape, smooth with grey tone sometimes with green spots, very sweet flesh.
10
10. C. melo var. inodorus Naud. Smooth or netted surface, flesh commonly white or green, lacking the tipical musky flavor. These fruits are usually later in maturity and longer keeping than cantaloupensis or reticulatus.
11. C. melo var. flexuosus Naud. Long and slender fruit, green rind and finely wrinkled or ribbed. Green flesh and usually eaten as an alternative to cucumber. Low level of sugars.
12. C. melo var. conomon Mak. Small fruits, smooth surface, crisp white flesh. These melons ripe very rapidly, develop high sugar content but little aroma.
13. C. melo var. dudaim Naud. Small fruits, yellow rind with red streak, white to pink flesh.
On the other hand, Stepansky et al. (1999) proposed an intraspecific classification
of melons based on phenotypic and molecular variation. They studied a collection of 54
accessions representing diverse melon genotypes (cantaloupensis, inodorus, conomom,
chito, dudaim, momordica, flexuosus, agrestis and some non-defined varieties) from
more than 20 countries, building with their data a “botanical-morphological” dendogram.
Likewise, DNA polymorphism among the accessions was assessed using inter-SSR-PCR
and RAPD techniques. They concluded that the molecular phylogeny agreed, broadly,
with the classification of melon into two subspecies, and it did not contradict the division
into “horticultural varieties.”
Recently, Liu et al. (2004) concluded after an extensive evaluation of 72 melon
accessions belonging to six melon varieties -cantaloupensis, reticulatus, inodorus,
acidulus and saccharinus- that accessions which were previously classified in the same
variety by traditional taxonomy were also located closely to each other using Principal
Component Analysis (PCA) approach in 35 different morphological and physiological
plant characters.
In general, both Naudin’s and Guis’ categorizations have more common features
than contrasting ones; therefore both are well accepted among scientists.
11
2.1.4 Climateric and Non-climateric Fruits
Fruit in general can be classified as either climacteric or non-climacteric on the
basis of their respiration pattern and autocatalytic ethylene production peak during
ripening (Tucker, 1993, Hadfield et al. 1995). Climateric fruits, such as tomato, peach,
avocado, apple and pear, have a respiratory burst and a pronounced autocatalytic ethylene
production while the ripening process is proceeding. Non-climateric fruits, such as bell
pepper, watermelon, strawberry, grape, and citrus, do not show evidence of an increased
ethylene evolution or respiratory rise coincident with ripening (Seymour and McGlasson,
1993). This fruit categorization might not be completely strict for all species. Within a
species there could be both climateric and non-climateric fruits. As a general rule, melon
fruits have been considered as a climateric type; usually reticulatus and cantaloupensis
melon varieties belong to this group. However, non-climateric melon fruits are available
as well, most of them fitting in inodorus variety (Seymour and McGlasson, 1993; Zheng
and Wolf, 2000; Périn et al. 2002a).
Therefore, it is not easy to define a set of criteria that may be used to predict the
ripening-related respiratory and ethylene evolution performance of specific fruit and then
extrapolate that behavior for another fruit related-cultivar or species.
2.2 Postharvest Physiology of Melon
2.2.1 Physiological Changes During Ripening
In order to achieve a typical melon fruit growth pattern, pollination, satisfactory
double fertilization and a normal development of the ovules have to take place (Wien,
1997). Fruit growth patterns among melon cultivars can be similar or quite diverse. In
1971 Pratt reported that both the ‘Honey Dew’ and ‘cantaloupe’ types reached half of
their total fruit growth almost at the same time (15 and 20 days after anthesis); however,
12
the ‘Honey Dew’ melon attained four times as much as size fruit than ‘cantaloupe’.
Likewise, McCollum et al. (1987) described a comparable fruit growth in two melon
genotypes (NY and D26) for the first 14 days after anthesis, but from 21 days after
anthesis to full slip, NY had greater fresh weight than did D26 fruits. McCollum et al.
(1988) measured fruit growth in ‘Galia’ and ‘Noy Yizre’el’ muskmelon cultivars, and
reported that both fruits had sigmoidal growth curves. However, differences between the
cultivars were apparent; i.e. ‘Galia’ fruits were larger than ‘Noy Yizre’el’ fruits at each
stage of development and continued to grow until the time of abscission.
Due to genetic diversity, melon fruits have a wide variation in ripening behavior.
Fruits belonging to the reticulatus and cantaloupensis varieties have a quick climacteric
at, or close to, the time of fruit maturity and abscission, although the abscission process is
absent in some muskmelon (reticulatus) varieties (Sakata and Sugiyama, 2002). On the
other hand, inodorus and saccharinus type fruits may have the climacteric process
extended up to several days or it may be absent (Miccolis and Saltveit, 1991; Aggelis, et
al. 1997a; Liu et al. 2004).
The moment of fruit maturation as well as the beginning of fruit ripening depends
upon the melon variety (Liu et al. 2004). In reticulatus and cantaloupensis varieties the
abscission characteristic is one of the most practical standards to estimate the harvest
maturity (Pratt et al. 1977; Larrigaudiere et al. 1995). Other indexes of muskmelon
harvest maturity include fruit color and appearance of the netted pattern. A muskmelon
fruit color chart has been prepared for ‘Galia’, which categorized six different levels of
maturity: 1, very dark green; 2, green; 3, light yellow with some green areas; 4, light
yellow; 5, yellow; and 6, dark yellow to orange peel (Fallik et al. 2001). On the other
13
hand, in those melon varieties, such as inodorus, flexuosus and saccharinus, where an
abscission layer is not formed, other characteristics are used to assess harvest maturity.
For example according to Portela and Cantwell (1998), at commercial melon production
level a variety of subtle changes in external color (green to white), peel texture (hairy to
smooth), aroma at the blossom end (none to detectable), and fruit density (low to high)
are used in order to assess the harvest maturity point.
Fruit ripening is a genetically determined event that involves a series of changes in
color, texture, and flavor (Hashinaga et al. 1984, Keren-Keiserman et al. 2004). Flavor is
a multifaceted human perception, which involves taste and aroma (Shewfelt, 1993).
According to Tucker (1993), fruit flavor depends on the complex interaction of sugars,
organic acids, phenolics and a wide variety of volatile compounds. In general, the quality
of melon fruit is mostly associated to both elevated sugar level and excellent flavor in
mesocarpic tissue (McCollum et al. 1988; Shewfelt 1993; Wyllie et al. 1995). In netted
melons, final fruit quality is also influenced by shading of the melon plant (Nishizawa et
al. 2000). It was reported by Pratt et al. (1977) that in the State of California, for ‘Honey
Dew’ melon a minimum of 10% soluble solids is legally required for market, but high
quality melons can even reach soluble solids content as high as 17% (Pratt et al. 1977;
Bianco and Pratt, 1977). Regarding the melon fruit volatile compounds, a comprehensive
study on the key aroma compounds in melon as well as their development and cultivar
dependence has been described previously (Wyllie et al. 1995).
Fruit storage shelf life is dissimilar among melon varieties. Cantaloupensis and
reticulatus fruits have a shorter shelf life compared to fruits belonging to inodorus and
saccharinus varieties (Liu et al. 2004). Muskmelon and netted melons have a storage life
14
of approximately 10-14 days at cool temperatures (6-9oC) and proper humidity (90-95%)
conditions (Gull, 1988). Muskmelon and netted melons can be kept at storage conditions
of 2-5o C and a relative humidity of the air of 90-95%. Netted melon fruits are more
prone to lose moisture. This may be a result of the presence of fissured epidermal tissue
(netted), which is an elaborated system of lenticels, therefore allowing a more rapidly
water loss as a result of evaporation (Webster and Craig, 1976). ‘Honey Dew’ type
melons should be stored at 7 to 10o C and 85-90% relative humidity up to three or four
weeks, but lower temperatures of 6o C can cause chilling injury (Gull, 1988; Suslow et al.
2001, Lester et al. 2001).
2.2.2 Ethylene Production
Ethylene is a plant gas hormone, which is involved in the melon fruit ripening
process (Giovannoni, 2001). A burst of ethylene production coincides with ripening in
climateric melon fruits (Pratt et al. 1977). Kendall and Ng (1988) measured ethylene
from two netted (reticulatus variety) and three non-netted (Casaba type-inodorus variety)
muskmelon cultigens and their hybrids immediately after harvest and found that the
netted muskmelon fruits synthesized considerable quantities of ethylene at or close
harvest. Conversely, the non-netted fruits did not produce ethylene until as late as 20 days
after harvest. Hybrids were generally intermediate to the parental lines in rate and time of
ethylene production. These results suggested that ethylene production in Cucumis melo
fruit is regulated by both genetic and developmental factors.
Because netted fruit melons produce ethylene during ripening, they do not require
exogenous ethylene application after harvest (Pratt, 1971). However, inodorus fruit types
may require exogenous ethylene application after harvest, in order to obtain a more
uniform and rapid ripening, as well as better development of color, wax, and aroma (Gull,
15
1988, Suslow et al. 2001). Likewise, inodorus fruit types must be harvested when they
have already acceptable soluble solids content, because melon fruit generally do not
increase their sugar content after harvest (Bianco and Pratt, 1977).
In general, orange- or green-fleshed and netted rind fruit melons produce higher
amounts of ethylene than green- or white-fleshed and smooth rind fruits (Zheng and
Wolff, 2000; Liu et al. 2004). However, exceptions to this generalization may be found in
netted melons. Shiomi et al. (1999) measured the ethylene biosynthetic capacity in two
netted cultivars, ‘Earl’s Favourite’ and ‘Andes’, and found that ehylene production in
‘Earl’s Favourite’ fruit remained low even at their commercial harvest maturity stage,
whereas ‘Andes’ fruit exhibited a typical climacteric pattern with a high ethylene
production. They concluded that the ‘Earl’s Favourite’ fruit used in that experiment
behaved like a non-climacteric fruit.
2.2.3 Biochemical Changes During Ripening
2.2.3.1 Introduction
Major biochemical changes take place in fruit during maturation and ripening
(Jiang and Fu, 2000; Giovannoni, 2001, Lelievre et al. 2000, Pech et al. 2002). The melon
fruit ripening process requires a high metabolic activity, i.e. synthesis and/or degradation
of new structural, soluble and enzymatic proteins, novel mRNAs, changes in plant
hormones levels, and DNA transcription, as well as accumulation of original pigments,
organic acids and sugars, and the release of volatile compounds (Bianco and Pratt 1977;
Miccolis and Saltveit 1995; Larrigaudiere et al. 1995; Dunlap et al. 1996; Guillén et al.
1998; Aggelis et al. 1997a; Sato-Nara et al. 1999; Flores et al. 2001a; 2001b; Villanueva
et al. 2004). All these anabolic and catabolic events need both energy and a carbon-
nitrogen-framework for building blocks, which are supplied via respiration. The two most
16
important respiratory substrates found in melon fruit are sugars and organic acids
(Seymour and McGlasson, 1993). Likewise, ethylene is the major plant hormone
involved in the melon fruit ripening process (Bianco and Pratt, 1977; Leliévre et al. 1997;
Sato-Nara, 1999).
2.2.3.2 Carbohydrate Metabolism
Sweetness is the most important edible quality attribute of ripe melon fruits
(Yamaguchi, et al. 1977; Lester and Shellie, 1992; Artes et al. 1993). Sucrose, glucose
and fructose are the major sugars found in the mesocarp of ripe melon fruits. High levels
of sucrose attribute fruit sweetness in melon (McCollum et al. 1988; Hubbard et al. 1990;
Burger et al. 2003; Villanueva et al. 2004).
Muskmelon fruit do not store starch as some other fruits do (i.e. apple, and banana),
therefore the fruit requires a constant supply of translocated photoassimilate from the leaf
canopy for sugar use and accumulation during development and ripening (Pratt, 1971;
Hubbard et al. 1989; Hubbard et al. 1990). Consequently, any factor which has an effect
on photoassimilate translocation during fruit development will reduce sucrose content
(Hubbard et al. 1990). For example, presence of viral infections, such as cucumber
mosaic virus, in melon plants causes an alteration in carbon metabolism in source leaves,
and in resource partitioning among the various plant organs because there is an increased
in respiration, and a decrease in net photosynthetic rate in infected leaves (Shalitin and
Wolf, 2000; Shalitin et al. 2002).
In Cucumis melo, sucrose is not the only translocated photoassimilate carbohydrate,
since galactosyl-sucrose oligosaccharides raffinose and stachyose can be found in the
phloem (Mitchell et al. 1992; Gao and Schaffer, 1999; Gao et al. 1999; Volk, et al. 2003).
17
Mitchell et al (1992) reported maximal amounts of sucrose (60 mM), stachyose (50 mM),
and raffinose (10 mM) in sap phloem measurements.
Sugar continues to accumulate during fruit development (Pratt, 1971; Pratt et al.
1977). Beginning at early fruit enlargement and reaching its maximum at full maturity
(McCollum et al. 1988; Seymour and McGlasson, 1993; Burger et al. 2002; Burger et al.
2003). The trait for sugar accumulation is controlled by a single recessive gene, called
suc (Burger et al. 2002). Therefore, sucrose accumulation is controlled through several
hormones and enzymes, as well as compartmentation processes (McCollum et al. 1988;
Hubbard et al. 1989; Ofosu-Anim and Yamaki, 1994; Lee et al. 1997; Ofosu-Anim et al.
1998; Gao et al. 1999; Gao and Schaffer, 1999; Feusi et al. 1999; Carmi et al. 2003; Volk
et al. 2003). Likewise, sugar accumulation is affected quantitatively by environmental
and physiological factors as well, such as salinity, nutrient availability, shading, cellular
size in the fruit, and available foliar area (Hubbard et al. 1990; del Amor et al. 1999;
Nishizawa et al. 2000; Nishizawa et al. 2002; Kano, 2002; Kano, 2004).
Netted, muskmelon, and Honeydew fruits have similar, but not identical, patterns
of sugar accumulation (Seymour and McGlasson, 1993). For instance, Bianco and Pratt
(1977) reported that both ‘Honey Dew’ and ‘PMR-45’ fruits have a parallel pattern for
sugar accumulation including total sugars, sucrose, glucose and fructose. Likewise,
McCollum et al. (1988) reported that ‘Galia’ and ‘Noy yizre’el’ fruits accumulated
glucose and fructose, in nearly equal amounts, during the first 24 days after anthesis.
Sucrose accumulation built up 24 days after anthesis and it was the predominant sugar at
the ripe stage. Similar results were obtained one year later by Hubbard et al. (1989), who
measured the concentrations of sucrose, raffinose saccharides, glucose, fructose, and
18
starch in one orange-fleshed netted melon and three green-fleshed muskmelons, two of
them categorized as sweet melons and one as a non-sweet type (‘Birds Nest’).
In an extensive study, Stepansky et al. (1999) found considerable variation in sugar
content and composition in mature flesh of melon fruits from 56 different genotypes
belonging to cantaloupensis, inodorus, conomom, chito, dudaim, momordica, flexuosus,
agrestis, and some non-defined varieties. Among the 14 genotypes classified as
cantaloupensis, total sugars ranged between 40-100 mg/gfw, and sucrose was 50-70% of
the total sugar, although a few accessions had lower levels. Within the inodorus group,
both low and high sucrose-accumulating genotypes were observed. Some genotypes
reached only ∼30mg/gfw total sugar, mostly glucose and fructose, whereas others had a
high sucrose accumulation (∼50 mg/gfw). Among the six conomon genotypes analyzed,
there were fruits with almost no sucrose (line 85-893) accumulation as well as genotypes
with intermediate and high sucrose levels. In the chito and dudaim varieties five
genotypes were evaluated, four out of five genotypes accumulated less than 10 mg/gfw
sucrose, but interestingly, the last one (PI 164320) had an unusual sugar pattern profile as
it accumulated high levels of total sugar, due mostly to elevated glucose and fructose
levels. Most members of the agrestis group accumulated extremely low levels of sugars,
however, two accessions (PI 164493 and PI 436532) had high total sugars (41 and 58
mg/gfw respectively). The momordica and flexuosus genotypes did not accumulate
significant amounts of sucrose or hexose. These authors also indicated that in the sweeter
melon varieties, sucrose was generally the most significant component that contributed to
variation in total sugars.
19
The physiological and biochemical aspects of sucrose accumulation in melon fruit
has been investigated extensively (McCollum et al. 1988; Hubbard et al. 1989; Hubbard
et al. 1990; Gao et al. 1999; Gao and Schaffer, 1999; Feusi et al. 1999; Carmi et al. 2003;
Volk et al. 2003; Burger et al. 2003; Villanueva et al. 2004). As previously mentionated,
melon plants translocate sucrose, stachyose and raffinose as main soluble sugars, which
are used as the carbon supply for sucrose synthesis in the fruit. Two enzymes, acid
invertase (EC 3.2.1.26) and sucrose phosphate synthase (SPS) (EC 2.4.1.14) have been
implicated as the determinants of sucrose accumulation in melon fruit (Hubbard et al.
1989; Stepansky et al. 1999). Both enzymes are inversely related in melon sink tissues,
such as fruits (Hubbard et al. 1989; Hubbard et al. 1990; Gao et al. 1999). During sucrose
accumulation, acid invertase activity decreases, as a result less sucrose degradation. At
the same time, SPS activity begins to increase significantly (Hubbard et al. 1989;
Hubbard et al. 1990; Gao et al. 1999). In addition, SPS activity is higher in sweet melon
fruit compared with non-sweet genotype fruits, suggesting its function in sucrose
accumulation (Hubbard et al. 1990).
Stepansky et al. (1999) stated “the final content of sucrose in the fruit mesocarp of
sweet melon is a function of two factors: the rate of sucrose accumulation, coupled with
the duration of the accumulation period until abscission or harvest.”
2.2.3.3 Organic Acids
Organic acids are compounds regularly found at low amounts in sweet ripe melon
fruit types, such as inodorus, cantaloupensis and reticulatus varieties (Yamaguchi et al.
1977; Seymour and McGlasson, 1993). On the other hand, non-sweet ripe melon fruits,
(flexuosus variety) are able to accumulate higher amounts of organic acids (Stepansky et
al. 1999; Pitrat et al. 1999). For instance, Burger et al. (2003) reported that the high-
20
organic acid fruit content characteristic is conferred by a single dominant gene, called So,
which is found only in melon varieties that do not accumulate high levels of sugars and
which are used for non-dessert purposes. In the recessive condition (so), melon fruits
have a low-organic acid attribute. Furthermore, these authors stated that the evolution of
horticultural sweet melon varieties required the sequential selection of three recessive
mutations: first a recessive mutation that allowed for non-bitter fruit (bif), then a
recessive mutation for low-acid fruit (so), followed by a recessive mutation for high
sucrose fruit (suc) (Burger et al. 2003). Despite the fact that low-organic acid level is a
genetically regulated feature, several envionmental factors, such as salinity can affect
quantitatively, the organic acid level in melon fruit (del Amor et al. 1999).
Citric and malic acids are the most important organic acids found in the flesh of
different melon varieties (Leach et al. 1989; Flores et al. 2001b; Burger et al. 2003). In
1989, Leach et al. studied the organic acid fractions from 12 melon cultivars, and
reported that citric acid was the major component in all melon cultivars that they
analized. Similarly, Flores et al. (2001b) found that the major organic acids found in wild
type and transgenic cantaloupe melon fruit were citric and malic acids. Artes et al. (1993)
found that titratable acidity in four melon varieties varied from 0.14% in ‘Tendral’ up to
0.50% in ‘Galia’ melon fruits.
2.2.3.4 Volatiles
The aroma or fragance of melon fruits are essential quality factors, for consumer
quality (Yamaguchi, 1977), and they are strongly linked to the ripening process (Wang et
al. 1996; Beaulieu and Grim, 2001). Unlike sugar accumulation in the ripe fruit, the
aroma fruit caused by volatile production continues after harvest (Wyllie et al. 1995). The
volatile profile, as well the identification of the main ‘melon odor’ substances in melon
21
fruits have been the subject of a considerable amount of research (Kemp et al. 1972;
Yabumoto et al. 1977; Yabumoto et al. 1978; Buttery et al. 1982; Horvart and Senter,
1987; Leach et al. 1989; Wyllie and Leach, 1990; Homatidou et al. 1992; Wang et al.
1996; Ueda et al. 1997; Bauchot et al. 1998; Yahyaoui et al. 2002; Aubert and Bourger,
2004).
Early studies reported that the volatile ester pattern of ripe muskmelon (reticulatus
varieties) and Honey Dew (inodorus varieties) type fruit were extremely similar, except
for ethyl butyrate, which was more abundant in muskmelon (Kemp et al. 1972;
Yabumoto et al. 1977; Yabumoto et al. 1978). The volatile profile of melon fruit was
made of around 35-50 volatile compounds (Kemp et al. 1972; Yabumoto et al. 1977;
Yabumoto et al. 1978; Buttery et al. 1982). With the advance and improvement of
extraction methods (Beaulieu and Grimm, 2001), such as Solid Phase Microextraction
(SPME), as well as the analytical and detection techniques (Aubert and Bourger, 2004),
such as sniffing port analysis, have shown that the volatile compound content responsible
for ‘melon aroma’ is diverse and cultivar dependent. Indeed, Aubert and Bourger (2004)
were able to differentiate statistically long-shelf life cultivars from wild and mid-shelf life
melon cultivars, based merely upon volatile compound profiles. Moreover, Beaulieu and
Grimm (2001) affirmed that roughly 240 volatile compounds have been reported from
muskmelon fruit.
In the particular case of ‘Arava’ melon, which is a ‘Galia’-type melon, various
volatile acetates were identified in the ripening fruit, including nine aliphatic, four
aromatic, and one compound containing a sulfur moiety (Shalit et al. 2000). Benzyl
acetate was the most abundant volatile compound in the headspace of this cultivar,
22
however, hexyl acetate and 2-methyl butyl acetate were also found in considerable
amounts.
The aroma and taste of most melon fruits are influenced considerably by ester
compounds, as well as to a certain extent by sulphur compounds (Yabumoto et al. 1977;
Wyllie and Leach, 1990; Homatidou et al. 1992). Even though, Kemp et al. (1972)
suggested that four unsaturated esters found in muskmelon fruit did not contribute
significantly to the ‘melon aroma’. Yabumoto et al. (1977) using three different
extraction methods for melon fruit volatiles stated that it was probable that the large
quantities of volatile esters also play a critical role in the integrated flavor of melons, and
that they are necessary for the strong and characteristic fruity aroma. According to
Yabumoto et al. (1978), the volatile ester profile of ripe reticulatus variety (‘PMR-45’
and ‘Top Mark’) and inodorus variety (‘Honey Dew’ and ‘Crenshaw’) fruit were similar,
and they fit into two groups, depending on the pattern exhibited by the production of that
compound. One group had a continuously accelerating rate of production (ethyl esters)
and another increased rapidly and then plateaued (acetate esters).
The major compounds responsible for ‘Honey Dew’ melon aroma are ethyl 2-
methylbutyrate, ethyl butyrate, ethyl hexanoate, hexyl acetate, 3-methylbutyl acetate,
benzyl acetate, (Z)-6-nonenyl acetate, and possibly (E)-6-nonenol and (Z,Z)-3,6-
nonadienol (Buttery et al. 1982). Horvat and Senter (1987) identified eight novel volatile
compounds from ‘Saticoy’ melon (reticulatus). In ‘Galia’-type melon cultivars C8 and
5080, six important aroma volatiles during ripening were found: ethyl acetate, isobutyl
acetate, butyl acetate, 2-methylbutyl acetate, hexyl acetate, and 3-hexenyl acetate (Fallik
et al. 2001).
23
The biochemical connection between the development of aroma volatiles and free
amino acid content in melon ripening fruit is well established (Yabumoto et al. 1977;
Wyllie and Leach, 1992; Wyllie et al. 1995). Wang et al. (1996) proposed that several
amino acids, such as valine, isoleucine, methionine, and alanine may be the precursors of
the mayority of the esters found in melon fruit, providing the branched alkyl chain
moiety, which is present in a significant proportion of volatile ester compounds.
The aroma volatile profile in each type of melon is a genetically controlled
characteristic (Ueda et al. 1997; Yahyaoui et al. 2002). The presence or absense of seeds
in the fruit cavity can modify the final aroma volatile profile (Li et al. 2002). Likewise,
the developmental fruit stage may have a strong influence on aroma characteristics
(Beaulieu and Grimm, 2001).
In summary, similar to other fruits the melon fragance is made of complex mixtures
of volatiles compounds. Both their production and profile in melon fruits is a genetically
controlled attribute, which is associated with the ripening process (Wang et al. 1996), and
which is regulated by ethylene (Bauchot et al. 1998; 1999). Therefore, the volatile
compound profile is a cultivar-dependent characteristic (Aubert and Bourger, 2004).
2.2.3.5 Cell Wall Degradation
The plant cell wall is a dynamic structure, which determines cell shape and
contributes to the functional specialization of cell types (Carpita and McCann, 2000).
The plant cell wall is a highly organized structure composed of several polysaccharides,
proteins, and aromatic compounds. Likewise, the new primary cell wall comes from the
cell plate during cell division, and after differentiation many cells are able to develop
within the primary wall, a secondary cell wall (Carpita and McCann, 2000). According to
Bennett (2002), a simplest form of the structural model of the plant cell wall can be
24
pictured as a core structure of cellulose microfibrils embedded in two coextensive
networks of pectin and hemicellulose.
Fruit softening observed during ripening is associated with textural changes that are
believed to result from modification and disassembly of the primary cell wall (Fischer
and Bennett, 1991). Fruit softening and the underlying cell wall structural changes are
complex. Softening or loss of firmness of the edible mesocarp of melon fruit starts in the
middle (around 30-45 days after anthesis, depending on cultivar) of the development
cycle, along with other typical changes connected with the ripening process (Lester and
Dunlap, 1985). Some general events during melon fruit softening are (Lester and Dunlap,
1985; Lester and Bruton, 1986; McCollum et al. 1989; Ranwala et al. 1992; Fils-Lycaon
and Buret, 1991; Simandjuntak et al. 1996; Rose et al. 1998; Hadfiled et al. 1998; Rojas
et al. 2001; Bennett, 2002):
1. There is no a significant change in total pectins (measured as total polyuronides) as a percentage of cell wall material, rather a substancial change in the relative solubility and depolimerazation of pectin levels is observed as fruit softening proceed, as well as a decrease in pectin molecular size. Quoting McCollum et al. (1989) “Quantitative changes in pectin content are apparently less important than are qualitative changes in the softening process.”
2. It seems likely that polygalacturonase (PG) enzyme(s) might not be involved in that solubilization process during the early ripening stages, however some PG-dependent developments may contribute to overall pectin disassembly at later stages.
3. Other enzymes could be involved in that early pectin solubilization process, for instance β-galactosidases and / or β-galactanases.
4. Hemicellulose polymers undergo important modifications, such as changes in the degree of solubility and modifications from large molecular size to smaller size, and loss of specific sugars.
5. Most of the non-cellulosic neutral sugars decrease significantly in the mesocarp of ripening fruits, regularly Galactose, Mannose and Arabinose, whereas other neutral sugars such as Xylose might or not increase during fruit softening.
25
6. Other enzymatic activities, such as pectin methylesterase, which have been associated with pectin metabolism in other fruits (Harriman et al. 1991; Tieman et al. 1992), and/or other proteins, such as expansins, which have been proposed to disrupt hydrogen bonds within the plant cell wall polymer matrix (Rose et al. 1997; Civello et al. 1999), could also be involved in melon fruit softening. More evidence has appeared regarding the expansins’ role in early fruit softening. Brummell et al. (1999) obtained two types of transgenic tomato plants, some were suppressed and anothers were overexpressed in the LeExp1 protein. Tomato fruit in which Exp1 protein accumulation was inhibited by 3% were firmer than control fruit throughout the ripening process. Conversely, fruit overexpressing high amounts of LeExp1 protein were much softer than control fruit, even in mature green stage before the ripening event had commenced.
Rose et al. (1998) and Bennett (2002) proposed a complete model of the temporal
sequence of cell wall changes, pectinase activity, and PG-mRNA expression in ripening
‘Charentais’ melon fruit at defined developmental stages, unfortunately they did not
include the role of expansins in cell wall degradation in their model.
Among the different plant hormones which are involved in fruit development,
ethylene has the main role during melon fruit softening (Rose et al. 1998). Internal
ethylene concentrations inside ‘Charentais’ melon fruit cavity increases, concomitant
with a loss of flesh firmness during ripening. Furthermore, Guis et al. (1999) using
antisense ACC-oxidase transgenic melon plants to reduce ethylene production, reported
that plants did not have substancial changes in pectin molecular mass observed in the
wild type fruit. Moreover, exogenous ethylene application to those transgenic fruits
resumed both accelerated fruit softening and a downshift in the size of cell wall
polymers. Additionally, transgenic melon plants (antisense ACC oxidase) were also used
to study the role of ethylene in regulating cell wall-degrading enzyme activities (Botondi
et al. 2000). In transgenic ‘Charentais’ melon, cell-wall degradation process is regulated
by both ethylene-dependent and ethylene-independent mechanisms. In support of a fruit
softening-ethylene involvement, it was established that ripening-regulated expansin
26
gene(s) in tomato were influenced directly by ethylene, and the expression of that gene
parallels the pattern of xyloglucan disassembly, and early fruit softening (Rose et al.
1997).
The exact hormonal, molecular and enzymatic mechanisms by which all these
processes take place in melon ripening fruit, and finally develop to the fruit softening
event are not well understood. Maybe by using updated molecular and genetic
techniques, such as cDNA microarrays (Fonseca et al. 2004), in order to monitor the gene
expression during fruit development and ripening, there will be more evidence to
understand and manipulate the melon fruit softening process. What's more, as Bennett
(2002) proposed: ‘future research should focus on using genetic strategies to assess the
potential for synergistic interactions by suppression of both hemicelluloses and pectin
disassembly in ripening fruit.’
2.2.3.6 Pigments
Flesh color of melons is another important quality attributes for a consumer appeal
(Yamaguchi, 1977). In general, four basic and distinctive flesh colors can be observed in
melon fruits: orange, light-orange or pink, green, and white (Watanabe et al. 1991;
Goldman, 2002).
According to Seymour and McGlasson (1993) the principal pigments in orange-
fleshed melons are: β-carotene (84.7%), δ-carotene (6.8%), α-carotene (1.2%),
phytofluene (2.4%), phytoene (1.5%), lutein (1.0%), violaxanthin (0.9%) and traces of
other carotenoids. Likewise, Watanabe et al. (1991) evaluated nine different melon
cultivars belonging to the four basic and distinctive flesh colors. They found that the
orange-fleshed colored melon cultivars 'Iroquois', 'Blenheim Orange', 'Birdie Red',
27
'Quincy' and 'Tiffany' contained about 9.2 to 18.0-µg/g β-carotene as the major pigment,
as well as a small amount of phytofluene, α-carotene, ζ-carotene and xanthophylls. They
also measured pigments in light-orange-fleshed ‘Hale’s Best’ melon, which contained
about 4.0-µg/g β-carotene, and phytofluene; α-carotene, ζ-carotene and xanthophylls
were also present but in small amounts. Finally, in the green-fleshed melon 'Earl's
Favourite' and 'Fukunoka', and white-fleshed colored melon 'Barharman', their main
components were β-carotene and xanthophylls.
Chlorophyll and carotenoid changes in developing fruit muskmelon were studied
earlier by Reid et al. (1970). They evaluated three melon cultivars: ‘Crenshaw’, ‘Persian’,
and ‘PMR 45’. In all the fruits, cholorophyll content decreased to an intermediate level
five weeks after anthesis, and they suggested that chlorophyll loss was probably due to
dilution through growth, because there were no more chlorophyll synthesis, but an
enlargement of the fruit occurred. In ‘PMR 45’ and ‘Chenshaw’ fruits, however, there
was a successive rapid decrease, which was concurrent with the ripening process.
Carotenoids content increase steadily three weeks after anthesis to high levels at full
maturity. The development of orange pigmentation was a gradual event, starting at the
placentae and progressing outward through the mesocarp, until the flesh was uniformly
orange at full maturity.
Forbus et al. (1992) used Delayed Light Emission (DLE), a nondestructive method,
to study physical and chemical properties related to fruit maturity in Canary melons.
They found that cholorophyll and yellow pigments decreased with fruit development,
having a high correlation with maturity index (IM). Flügel and Gross (1982) studied
pigment and plastid changes during ripening of the green-fleshed ‘Galia’ muskmelon
28
fruit. They observed that the carotenoid profile in the exocarp and mesocarp did not
change during development. Also, relatively low levels of chlorophyll and carotenoids
were found in the flesh. Yellowing of the exocarp was due to increased chlorophyll
degradation during ripening, as well as a partial decrease in total carotenoids took place.
In conclusion, it seems that pigment profile accumulation and degradation in melon
fruit is a cultivar-dependent characteristic, which is expressed during fruit maturity.
2.2.4 Ethylene and Molecular Changes During Ripening
2.2.4.1 Introduction
There are ethylene-dependent and ethylene-independent biochemical and
physiological pathways throughout melon fruit ripening (Pech et al. 1999; Hadfield et al.
2000; Srivastava, 2002; Silva et al. 2004), which both coexist at the same time in the
climacteric fruit. Likewise, besides ethylene several plant hormones, such as indole-3-
acetic acid (IAA) and abscisic acid (ABA), are involved in melon fruit ripening
(Larrigaudiere et al. 1995; Dunlap et al. 1996; Guillén et al. 1998; Martínez-Madrid et al.
1999).
2.2.4.2 Biosynthesis, Perception and Effects of Ethylene
Ethylene biosynthesis goes from methionine, through S-adenosylmethionine
(SAM), then to 1-aminocyclopropane-1-carboxylic acid (ACC), and finally to ethylene
(Yang and Baur, 1969; Adams and Yang, 1979; Yang, 1980; Yang, 1982; Yang and
Hoffman, 1984). Two regulatory enzymes in this pathway are ACC synthase (ACS) (EC
4.4.1.14) and ACC oxidase (ACO) (EC 1.14.17.4). The latter enzyme was formely
known as ethylene-forming enzyme (EFE) by Adams and Yang (1979) because the
reaction mechanism was not known at that time. ACC synthase is generally considered as
the rate-limiting step in ethylene biosynthesis (Yang and Hoffman, 1984).
29
Both ACS and ACO melon enzymes are coded by a multigene family (Miki et al.
1995; Yamamoto et al. 1995; Lasserre et al. 1996; Lasserre et al. 1997), therefore several
isoenzymes are recognized in melon tissues. For instance, Miki et al. (1995) and Ishiki et
al. (2000) isolated three cDNAs for ACC synthase from wounded mesocarp tissue of
melon fruits. Lasserre et al. (1996) reported the isolation and categorization of three
genomic clones, identified by screening a melon genomic DNA library with the cDNA
pMEL1, corresponding to three putative members of the ACC oxidase gene family in
cantaloupensis melon. These authors in addition determined the entire sequence of these
genes and found that they were all transcriptionally active. One genomic clone, named
CM-ACO1, presented a coding region with four exons and interrumted by three introns.
The other two genes, CM-ACO2 and CM-ACO3, were only interrupted by two introns, at
same positions as CM-ACO1. The degree of DNA homology in the coding regions of
CM-ACO3 relative to CM-ACO1 was 75%. In contrast, the degree of DNA homology of
CM-ACO2 relative to both CM-ACO1 and CM-ACO3 were 59% in their coding region.
ACS and ACO melon multigenes are differentially activated and expressed by
several environmental and developmental factors (Yamamoto et al. 1995; Lasserre et al.
1996; Shiomi et al. 1999; Zheng et al. 2002). Yamamoto et al. (1995) using tissue
printing and immunoblot analysis with antibodies specific for ACO, were able to identify
in which part of the fruit the ethylene synthesis started at the early stages of ripening.
They reported that the rate of ethylene production (accumulation of ACO protein) in
melon fruits increased initially in the placental tissue, then in mesocarp tissue and finally
at the rind. They also concluded that levels of ACO mRNA and protein were low in
unripe fruit stage, but became detectable in placental tissue at the pre-climacteric period,
30
and their levels increased in the mesocarp at the climacteric stage. All these results
suggested that the central region of melon fruit (placental tissue and seeds) plays a major
role in the production of ethylene during the early stage of fruit ripening.
A RT-PCR assay was used by Lasserre et al. (1996) to detect the differential
expression of ACO melon genes (CM-ACO1, CM-ACO2, and CM-ACO3). They found
that these three genes were differentially expressed during development, ethylene
treatment and wounding. CM-ACO1 was induced during fruit ripening, and also in
response to wounding and ethylene treatment in leaves. CM-ACO2 was detectable at low
levels in etiolated hypocotyls, whereas CM-ACO3 was expressed in flowers and it was
not induced by any treatment tested.
Lasserre et al. (1997) found that the regulation of the CM-ACO1 gene was
connected preferentially to stress responses, while the CM-ACO3 gene seemed to be
associated with developmental routes. Moreover, Bouquin et al. (1997) using the 5’-
untranslated region of the CM-ACO1 gene fused to the β-glucuronidase (GUS) reporter
gene were capable of measuring the transcriptional activation in leaves of the CM-ACO1
gene after wounding and ethylene stimulation. Their results suggested that induction of
CM-ACO1 gene expression occurs via two direct and independent signal transduction
pathways in response to both stimuli. Zheng et al. (2002) studied some genetic aspects of
ethylene production and its relationship to the RFLPs of the ACC oxidase and ACC
synthase genes in two melon cultivars. One cultivar had high ethylene production during
fruit ripening (‘TAM Uvalde’) and another had low levels of ethylene production (‘TAM
Yellow Canary’). Their results of single-copy-reconstruction assays suggested that the
31
CMACO-1 gene was present as a single copy, whereas the CMACS-1 gene was a
component of a multigene family in both melon cultivars.
It has been suggested that differences in ethylene production among melon fruits
might be the result of transcriptional changes in ACS and ACO genes (Shiomi et al.
1999). These authors measured the ACS-1, ACO-1 and ACO-2 mRNA expression pattern
in exocarp, mesocarp and placental tissues of ‘Earl’s Favorit’ (recognized as non-
climacteric) and ‘Andes’ (known as climacteric) fruit cultivars at different stages of
maturity, finding that mRNA CMACS-1 transcripts accumulated only in the mesocarp
and placentae of ‘Andes’ fruit at 50 DAP (commercial harvest maturity stage). This
accumulation was coincident with increases in ACS activity, ACC content and maximum
ethylene production. In contrast, CMACO-1 mRNA accumulated in elevated levels in the
mesocarp and placentae of both cultivars at 50 DAP, but in ‘Andes’ cultivar those
transcripts were more abundant than in ‘Earl’s Favorit’ fruit. In the exocarp, the
CMACO-1 mRNA level was low for both cultivars. CMACO-2 mRNA was constitutively
expressed in placentae and mesocarp at low levels, and non-detectable in the exocarp.
These results suggested that the difference in ethylene-forming ability between these two
cultivars may result from the expression of CMACS-1 mRNA and CMACO-1 mRNA
during the fruit ripening process.
Ethylene perception is mediated by specific receptors, which have been cloned and
completely described for several plants, such as Arabidopsis (Fluhr and Mattoo, 1996;
Johnson and Ecker, 1998), tomato (Tieman et al. 1999; Tieman et al. 2000), tobacco
(Terajima et al. 2001), and carnation (Reid and Wu, 1992; Shibuya et al. 2002). In
Cucumis melo, ethylene-receptor-like homolog genes have been reported as well (Sato-
32
Nara et al. 1999, Takahashi et al. 2002; Nukui et al. 2004; Cui et al. 2004). Sato-Nara et
al. (1999) isolated and characterized two cDNAs, which were described as putative
ethylene receptors, from muskmelon using the Arabidopsis ethylene receptor genes ETR1
and ERS1 sequences. These authors measured the expression pattern of these cDNAs
during fruit enlargement and ripening by means of Northen blot assay, finding that both
clones were expressed in a stage- and tissue-specific manner. They named their cDNAs
as Cm-ETR1 (Accession No. AF054806) and Cm-ERS1 (Accession No. AF037368).
Three years later (Takahashi et al. 2002), polyclonal antibodies against melon receptor,
Cm-ERS1, were prepared in order to determine the temporal and spatial expression
pattern of Cm-ERS1 protein during melon fruit development. They reported that Cm-
ERS1 protein formed a disulphide-linked homodimer and it was present in microsomal
membranes but not in soluble fractions. In addition, their results revealed that a post-
transcriptional regulation of Cm-ERS1 expression affects stage- and tissue-specific
accumulation of this protein. That transition pattern was not cultivar-dependent because it
was observed in two different melon cultivars, i.e. ‘Fuyu A’ and ‘Natsu 4’.
The cloning and characterization of two melon ethylene receptor genes has allowed
their use as molecular genetic tools in heterologous systems with promising results
(Nukui et al. 2004; Cui et al. 2004). The overexpression of a missense mutated melon
ethylene receptor gene, Cm-ETR1/H69A, in a heterologous plant, Nemesia strumosa,
confered reduced ethylene sensitivity (Cui et al. 2004), making transgenic plants that had
a significantly extended flower longevity compared with the wild type counterpart. On
the other hand, because ethylene inhibits the establishment of symbiosis between rhizobia
and legumes, a point mutated Cm-ERS1/H70A gene was used to transform Lotus
33
japonicus plants in order to examine how and when endogenous ethylene inhibits that
rhizobial infection and nodulation (Nukui et al. 2004). Endogenous ethylene in L.
japonicus roots inhibits rhizobial infection at the early stages (primary nodulation), and
suggested that ethylene perception also assists negative feedback regulation of secondary
nodule initiation.
Ethylene has a profound influence on climacteric fruit ripening, and in some cases
it induces biochemical and physiological changes in non-climacteric fruit (Leliévre et al.
1997; Giovannoni, 2001; Périn et al. 2002a). In research with 63 different cultivars from
eight market types of melon, belonging to Cantaloupensis and Inodorus varieties, Zheng
and Wolff (2000) were able to demonstrate a significant correlation between RFLP
polymorphisms and ethylene production in the fruit. These RFLPs were associated with
flesh color, rind texture and postharvest decay characteristics in the melon genotypes
examined. Low ethylene production and green- and white-flesh color were associated
with the presence of a putative RFLP-MEL1 allele Ao (15kb), whereas high ethylene
production and orange-flesh color were associated with allele Bo (8.5 kb) in the
homozygous condition. Some melon cultivars, such as ‘Honeybrew’ and ‘HD Green
flesh’, did not accumulate any detectable ethylene. Likewise, Périn et al. (2002a) reported
that in the non-abscission melon fruit PI 161375, exogenous ethylene failed to stimulate
abscission, loss of firmness, ethylene production and expression of ethylene-inducible
genes. These authors obtained a recombinant population of Charentais X PI 161375
inbred lines segregating for fruit abscission and ethylene production. Genetic analysis
showed that both characters are controlled by two independent loci. They concluded that
34
the non-climacteric phenotype in fruit tissues was attributable to ethylene insensitivity
conferred by the recesive allelic forms from PI 161375.
As it was previously pointed out, ethylene-dependent and ethylene-independent
biochemical and physiological pathways take place and coexist during melon fruit
ripening. Hadfield et al. (2000) made a differential screening of a ripe melon fruit cDNA
library and identified 16 unique cDNAs corresponding to mRNAs whose accumulation
was estimulated by ripening. Expression of fifteen, out of sixteen cDNAs, was ripening
regulated, and twelve of them were fruit specific. Three patterns of gene expression were
observed when the expression of cDNA clones was examined in transgenic ACC oxidase
melon fruit. One group of cDNAs corresponded to mRNAs whose abundance was
reduced in transgenic fruit but still inducible by ethylene treatment. The second group of
mRNAs was not significantly altered in the transgenic fruit and it was not affected by
ethylene treatment, indicating that these genes are regulated by ethylene-independent
factors. The third group of cDNAs had an unexpected pattern of expression, low levels of
mRNA in transgenic fruit and even remaining low after ethylene treatment. Obviously,
the regulation of this third group of genes appears to be ethylene-independent.
Pech et al. (1999) described some ethylene-dependent events in cantaloupe
Charentais melon fruits and divided them into two main groups. One group was
considered as general metabolism, such as yellowing of the rind, fruit softening, volatile
production, presence of climacteric respiration, abscission of the fruit, and susceptibility
to chilling injury. The other group included enzyme activities, such as galactanase, α-
arabinosidase, β-galactosidase, endo-polygalacturonase, ACC synthase (negative
feedback) and ACC N-malonyltransferase. Likewise, these authors categorized ethylene-
35
independent characteristics into the same two groups, one group included in general
metabolism, such as coloration of the flesh, accumulation of sugars and organic acids,
accumulation of ACC, and loss of acidity. Within enzyme activities non-induced by
ethylene were pectin methyl esterase, exo-polygalacturonase and ACC synthase
(induction at onset of ripening). This classification of ethylene-dependent and ethylene-
independent events provides valuable basic information, which might be used to design
biochemical and/or molecular strategies with the aim to control melon fruit ripening.
Ethylene regulates fruit ripening by coordinating the expression of several genes
(Leliévre et al. 1997; Aggelis et al. 1997a; Aggelis et al. 1997b; Yang and Oetiker, 1998;
Jiang and Fu, 2000; Périn et al. 2002a). The most common genes which are frequently
regulated by ethylene during fruit ripening embrace some members of the ACS and ACO
multigene family, phytoene synthase, endo-polygalacturonase, galactanase, one
homologue of S-adenosyl-L-homocysteine hydrolase (SAHH) and even a mRNA, which
is ripening-specific, named MEL2 of unidentified function (Karvouni et al. 1995; Aggelis
et al. 1997a; Aggelis et al. 1997b; Hadfield et al. 1998; Pech et al. 1999; Guis et al. 1999;
Périn et al. 2002a).
New insight knowledge will be available on ethylene role(s) in melon fruit
development and ripening, when the molecular techniques which have produced
information from model systems, such as Arabidopsis and tomato, might some day be
applied to different melon genotypes. Moreover, that information could also be retrieved
from wild and landraces melons, in order to find ripening genes to be transferred to
commercial varieties.
36
2.3 Melon Biotechnology
2.3.1 Genetic Improvement
2.3.1.1 Traditional Breeding
For several thousands of years, human beigns have altered the genetic background
of plants, which have been used as crops (Fehr et al. 1987; Snustad et al. 1997). This
genetic alteration was achieved by first selecting one type of plant or seed in preference
to another, instead of randomly taking what nature provided (Fehr et al. 1987; Snustad et
al. 1997). Subsequently, human selection for specific traits such as faster plant growth,
larger and more nutritious seeds or sweeter fruits dramatically changed the domesticated
plant species compared to their wild type counterparts (Fehr et al. 1987). The improved
plant characteristics selected by those early agriculturalists were transmited genetically to
the succeeding plant generations, and later on, plant breeding methods as an art and
science discipline was born (Suslow et al. 2002).
Cucumis melo plants were not the exception to that human selection and plant
breeding effort. Traditional breeding methods in melon have led to a considerable varietal
improvement. Strong sexual incompatibility barriers at the interspecific and intergeneric
levels have restricted the use of that genetic potential to develop new and enhanced
melon cultivars (Niemirowicz-Szcztt and Kubicki 1979; Robinson and Decker-Walters,
1999). Melon plant improvement by traditional hybridization is slow and limited to a
restricted gene pool (Pitrat et al. 1999). It is possible to produce viable intraspecific
melon hybrids between wild type melons and commercial melon varieties, with the aim
to transfer some particular melon genetic traits, such as disease resistance to fungi,
bacteria, virus and insects, or tolerance to environmental factors, such as salinity,
flooding, drought, and high or low temperature, to commercial melon varieties (Dane,
37
1991). Commercial melon varieties, with sweet, non-bitter and low-acidic fruits, carry
three genes (suc/suc, so/so, bif/bif), which control high-quality-fruit traits, in recessive
form (Burger et al. 2003). Therefore, any intraspecific crosses, using traditional breeding
methods, between melon land races (Seshadri and More, 2002) and commercial melon
cultivars will produce hybrid fruit with low quality characteristics, because of the effect
of dominant genes controlling low-sweetness, high-acid, and high-bitterness level in the
melon land race fruit.
In conclusion, it is highly desirable to have other genetic breeding tools, besides
traditional hand crossing, in order to obtain improved melon cultivars. The same results
obtained from conventional breeding methods can be developed using biotechnology
strategies (Table 2.2). It is well documented that using genetic engineering strategies it is
feasible to overcome most of the genetic barriers among plants, which are unsurpassable
by traditional breeding techniques (Vasil, 1990; 1996; 1998; 2003).
2.3.1.2 Improvement Through Genetic Engineering
According to the ‘FAO statement on biotechnology’, The Convention on Biological
Diversity (CBD) defines biotechnology as: “any technological application that uses
biological systems, living organisms, or derivatives thereof, to make or modify products
or processes for specific use” (FAO, 2004). This scientific discipline in its broad sense
covers many of the tools and techniques that are commonplace in agriculture and food
production, whereas in its narrow or molecular sense it considers only the new DNA
techniques, molecular biology and reproductive technological applications, including
differente technologies such as gene manipulation, gene transfer, DNA typing and
cloning of genes, plants and animals (FAO, 2004).
38
Table 2.2 Similarities between conventional and biotechnological methods for melon plant improvement.
Steps in Breeding Conventional Methods Biotechnological Methods
1. Collection and evaluation of genetic resources
Genetic analysis of valuable traits
Cloning of valuable gene
2. Generation of variation Intraspecific crosses Genetic transformation, embryo culture, somatic cell fusion, polyploidy, anther culture, and somaclonal variation
3. Selection of desirable variants
Growth and evaluation PCR, selectable markers, DNA markers, etc.
4. Production of fixed lines
Self-pollination Self-pollination and haploid production by gynogenesis
5. Seed production Growth in controlled conditions
DNA markers to test seed purity and growth in controlled conditions
Modified from Ezura (1999).
During the 1970s, molecular biology and genetic engineering research laid the
foundation for the development of transgenic plants in 1983 using the Ti plasmid from
the soil bacterium Agrobacterium tumefaciens (Herrera-Estrella et al. 1983). This
bacterium transfers a specific fragment of the Ti plasmid (T-DNA) which can be
engineered to contain a selectable marker and /or genes of interest, into the plant nuclear
genome under in vitro conditions. Once inserted, nontransformed plants can be killed in
culture by the toxic substance the marker gene codes resistance to. Within the plant
biotechnology discipline, plant tissue culture methods has had an essential role, allowing
the development of transgenic plants with a number of desirable agronomic, pest
resistance and food traits. It is commonly accepted that the term “plant tissue culture”
refers to in vitro cultivation on nutrient media of any plant part, a single cell, tissue or an
39
organ under a sterile environment, leading to a whole de novo regenerated plant (Nunez-
Palenius et al. 2005a).
After the milestone plant tranformation achievement by Herrera-Estrella et al.
(1983), a number of technological difficulties were surpassed, allowing the cloning and
insertion of different genes and engineering of transgenic plants with: a) resistance to
plant viruses, fungi and insects, tolerance to herbicides, salinity, drought, heavy metals
and low/high temperatures, b) improved nutritional quality (proteins, oils, vitamins, and
minerals among others), shelf life of fruits and vegetables, flavor and fragance, c) novel
production of vaccines, pharmaceuticals, and therapeutic and prophylactic proteins, d)
reduced production of allergens, and e) phytoremediation activity (James and Krattiger,
1996; Vasil, 2002; 2003; Nuñez-Palenius et al. 2005). The first transgenic commercial
plant variety in the USA was released in May 1994, when Calgene marketed its Flavr-
Savr™ delayed ripening tomato (James and Krattiger, 1996). At the present time, more
than 50 transgenic crops have been approved for commercial planting, and at least 100
more are under field trials and/or regulatory review (Vasil, 2003).
The influence of plant genetic engineering on commercial crop production is
evident by the global increase of cultivated land with transgenic crops, also known as
Genetically Modified Organisms (GMOs). All this increase has happened in a relatively
short time span, i.e. less than a decade. According to James (2003), the global land area
of transgenic crops continued to grow for the seventh consecutive year in 2003, 15%, 9
million hectares, compared with 12% in 2002. In 2003, 25% of the aggregate area of four
main crops, i.e. soybean, maize, cotton and canola, totaling over one quarter billion
hectares was GMOs. The market value of transgenic crops is expected to increase from
40
$450 million in 1995 to over $7 billion by 2005 (James and Krattiger, 1996; James,
2003), for instance, the total market for transgenic seed now exceeds $3 billion (Vasil,
2003).
Throughout an eight-year period, from 1996-2003, the land area of transgenic crops
in the world increased 40 times, from 1.7 million hectares in 1996 up to 67.7 million
hectares in 2003 (Figure 2.1). Plants containing herbicide (Roundup) tolerance was the
dominant trait used, followed by insect resistance conferred by Bacillus thuringiensis
(Bt) toxin.
Global Land Area of Transgenic Crops
0102030405060708090
1995 1996 1997 1998 1999 2000 2001 2002 2003 2004
M h
ecta
res
TotalIndustrial CountriesDeveloping Countries
Figure 2.1 Global land area of cultivated transgenic crops. From James and Krattiger,
(1996), James (1997; 1998; 1999; 2000; 2001; 2002; 2003; 2004).
The highest yearly increase of global land area cultivated with transgenic crops was
observed during the period 1997-1999 (Figure 2.2). Afterward, in 2000, a substancial
decline in the rate of yearly increase took place. Nevertheless, it seems from most recent
data (2001 to 2003) that global land area cultivated with GMOs will be increased and it
might be able to attain again similar levels as previous years (James, 2001; 2002; 2003).
41
13.3
96.1
8.44.3
12.1
1.79.3
16.8
0
10
20
30
40
50
60
70
80
90
1996 1997 1998 1999 2000 2001 2002 2003 2004
M h
ecta
res
IncreaseoverPreviousYearPreviousYear
Figure 2.2 Yearly increase in global land area of transgenic crops. Numbers above bars
indicate the increased amount in Mhectares for that year. From James and Krattiger, (1996), James (1997; 1998; 1999; 2000; 2001; 2002; 2003; 2004).
USA cultivated more land area (42.8 million hectares) of transgenic crops than any
other nation (Figure 2.3). In the same year a growth rate of 10% in planted area of
transgenic crops was reflected a strong increase in both Bt toxin maize and herbicide
tolerant maize, and continued growth in herbicide tolerant soybean (James, 2003). These
transgenic plants, for the period of 2003, were grown by 7 million farms in 18 different
countries, two million more of farms and two more countries than in 2002. Globally in
2003, the most common and commercialized transgenic crops were: soybean (41.4
million hectares), maize (15.5 million hectares), cotton (7.2 million hectares), and canola
(3.5 million hectares). Similarly in 2003, herbicide tolerance installed in soybean, maize,
canola and cotton occupied 49.7 million hectares (73%) of the global 67.7 million
hectares.
42
Figure 2.3 Top Ten Countries growing GMOs in the World in 2004. From James, C.
(2004).
Thus, world land area planted with GMOs is increasing substancially every year.
According to FAO (2004), global population reached 6 billion on October 12, 1999, and
in view of the current human population growth rates (1.5%), it is expected that human
beings in this world will be approximately 11 billion for the year 2050 (Swaminathan,
1995). Doubling or tripling of the world food and fiber production by 2050 cannot be
achieved using existing crop technology (James and Krattiger, 1996). Therefore, more
research with plant molecular tools and transgenic crops must be accomplished in order
to reach the needs to maintain such high human populations.
2.3.1.3 Melon Biotechnology
Since the first report of successful transformation of melon (Cucumis melo) (Fang
and Grumet, 1990), several valuable plant features, such as virus resistance (Fang and
2 ARGENTINA 16.2 Million Has. Soybean, Maize,
Cotton
3 CANADA 5.4 Million Has. Canola, Maize,
Soybean
1 USA 47.6 Million Has. Soybean, Maize,
Cotton, Canola
10 AUSTRALIA 0.2 Million Has.
Soybean
7 INDIA 0.5 Million Has.
Cotton
5 CHINA 3.7 Million Has.
Cotton
9 URUGUAY 0.3 Million Has. Soybean, Maize
8 SOUTH AFRICA
0.5 Million Has. Maize, Soybean,
Cotton
6 PARAGUAY 1.2 Million Has. Soybean, Maize
4 BRAZIL 5.0 Million Has.
Soybean
43
Grumet 1993; Yoshioka et al. 1993; Gonsalves et al. 1994; Huttner et al. 2001), tolerance
to salinity (Bordas et al. 1997) and fruit quality improvement (Ayub et al. 1996; Ezura et
al. 1997; Shellie, 2001; Silva et al. 2004; Nuñez-Palenius et al. 2003; 2004) have been
incorporated to wild type germplasm. The first US trial of field-tested virus resistance in
a commercial transgenic melon crop was done in 1993 and 1994 (Clough and Hamm,
1995). Although, a transgenic melon application was first registered in 1998 by the
USDA-APHIS service (2004), there is still no commercial transgenic melon cultivars
approved, despite of more than 140 transgenic melon field trials in the United States
during the period 1987-2001 (Grumet and Gifford, 1998; Grumet, 2002; Gaba et al. 2004;
Grumet, 2005. Personal communication). The lack of a commercial GMO melon is due to
unstable expression or partial loss of the transgene of interest (due somaclonal variation
and/or chromosomal rearrengements), and because the transgenic melon plant did not
have any commercial advantage compared to the wild type counter part.
2.3.2 In vitro Regeneration
In order to achieve a successful commercial application from biotechnology in
melon a competent de novo regeneration system from in vitro cultures is requiered (Guis
et al. 1998). In the last 25 years, more than 40 in vitro melon regeneration protocols have
been described, some using either organogenesis, somatic embryogenesis or both
regeneration pathways (Table 3.2, 3.3 and 3.4). Melon plant regeneration has been
reported from adventitious buds, somatic embryos, shoot primordia, protoplasts, and
axillary buds. Several biological and physical factors influence in vitro regeneration
efficiency rate, and all have to be considered in order to develop a reproducible and
reliable melon regeneration protocol.
44
2.3.2.1 Genetic Control
Because genetic variability in melon is highly diverse (Monforte et al. 2003),
genotype is the most important factor, determining regeneration potential. Melon
varieties (reticulatus, cantaloupensis, inodorus, flexuosus, etc.) and commercial cultivars
have differences on their regeneration ability under the same in vitro protocol and
environmental conditions (Orts et al. 1987; Oridate et al. 1992; Gray et al. 1993;
Ficcadenti and Rotino, 1995; Molina and Nuez, 1995a; Kintzios and Taravira, 1997;
Galperin et al. 2003a; 2003b). Likewise, organogenesis and somatic embryogenesis
responses in melon cultures are also genotype-dependent. For instance, Oridate et al.
(1992) and Gray et al. (1993) reported that reticulatus varieties were more prone to
produce in vitro somatic embryos than inodorus varieties.
Oridate et al. (1992) found significant differences in somatic embryogenic response
from melon seeds among 18 commercial cultivars. They made reciprocal crosses between
those cultivars, in order to obtain the F1 seeds and evaluate their embryogeny response.
Some lines produced a large number of somatic embryos whereas others did not produce
any somatic embryos or the response was very low. Moreover, these authors were able to
transfer, by sexual crosses, the embryogenic regeneration response from superior to
inferior responding cultivars, demonstrating that the capacity to de novo regenerate
through somatic embryogenesis by diferent melon cultivars was under genetic control.
These researchers were unable to determine the specific mode of inheritance of the
somatic embryogenic capacity due to variation in the range of somatic embryogenesis
from F2 seeds.
Gray et al. (1993) developed an improved protocol for high-frequency somatic
embryogenesis from melon seeds. Using the cultivar ‘Male Sterile A 147’, the authors
45
tested several factors, such as, changes in plant hormone levels and combinations, type of
culture media, and incubation time of explants in those media. This protocol was tested
on 51 commercial melon cultivars, where all underwent somatic embryogenesis, but
exhibited from 5% to 100% explant response and 0.1 to 20.2 embryos per explant,
indicating again a genetic factor in melon embryogenesis response.
Melon regeneration through organogenesis is also affected by melon genotype
(Orts et al. 1987; Ficcadenti and Rotino, 1995; Molina and Nuez, 1995a; Kintzios and
Taravira, 1997; Galperin et al. 2003a; 2003b). Orts et al. (1987) found significant
differences in the morphogenetic response of a diverse group of melon cultivars. The
percentage of calli with developed shoots ranged from 0 to 44.3 among cultivars.
Variability in morphogenetic responses was found between seed lots of the same cultivar.
Comparable results were obtained by Ficcadenti and Rotino (1995), who evaluated the
morphogenetic response of 11 melon cultivars belonging to the reticulatus and inodorus
genotypes. These authors found that melon morphogenetic response was affected by
genetic background, i.e. C. melo var. inodorus genotypes exhibited high narrow shoot
regeneration rates whereas wide differences were noted among the reticulatus types. The
number of shoots per explant ranged from 6.0 to 17.3 for reticulatus varieties and from
12.2 to 14.2 for inodorus genotypes.
A complete statistical approach was used by Molina and Nuez (1995a) to detect
genotypic variability of the in vitro organogenetic response (shoot regeneration) among
individual melon seeds. Their results clearly evidenced the presence of highly significant
differences for organogenetic response, among plants from a specific seed population.
These authors used data from stochastic simulation to study the accuracy of different
46
analysis to detect the presence of genotypic heterogeneity within a population. These
analyses, together with their experimental results, allowed the separation of seed
genotypes differing up to 5% in their regeneration ability. Afterward, Molina and Nuez
(1996) reported the inheritance of organogenesis response in melon cv. ‘Charentais’, by
studying the distribution of the shoot regeneration frequency in F1 and F2 generations
from parents representing extreme values for that in vitro organogenesis response. Their
results suggested a genetic model with two genes, partial dominance, independent
segregation and similar effects for both genes. Recently, Galperin et al. (2003b) claimed
that the high competence for adventitious regeneration in the BU-21/3 melon genotype
was controlled by a single dominant locus, without cytoplasmic interactions.
On the other hand, Kintzios and Taravira (1997) evaluated 14 commercial melon
cultivars for plant regeneration capability. Only six cultivars responded positively to a
shoot induction treatment. Similarly, Galperin et al. (2003a) screened 30 different
commercial melon cultivars for shoot de novo regeneration. In 24 out of 30 melon
genotypes, no detectable normal shoot growth was observed. Five of those which were
able to regenerate, exhibited very low regeneration efficiency. Only the genotype BU-21,
an inbred line, had profuse regeneration of multiple shoots.
In summary, melon in vitro response is under genetic control, however, other
factors should be taken into account for melon regeneration as well. Among them, plant
hormones have a paramount importance upon the melon in vitro response.
2.3.2.2 Polyploidization and Somaclonal Variation
Diploid melon plants have 24 chromosomes (haploid stage n=x=12), and a genome
size of 0.94 pg (454 Mbp/1C) (Arumuganathan and Earle, 1991). A natural and
spontaneous increase in the ploidy level has been observed in field-growing melon plants
47
(Nugent and Ray, 1992), nevertheless, this ploidy increase can also been induced in
muskmelon plants using chemical compounds, such as colchicine (Batra, 1952; Kubicki,
1962). In fact, polyploidy as a method of plant breeding received an increase amount of
attention in the late 1930s, when it was discovered that polyploidy could be induced with
colchicine treatment and the earlier demonstration that heat treatment in early
embryogeny stages could also induce a chromosome doubling (Batra, 1952).
Numerous tetraploid and triploid muskmelon plants have been obtained since the
1930s (Batra, 1952; Kubicki, 1962; Nugent and Ray, 1992; Fassuliotis and Nelson, 1992;
Ezura, et al. 1992a; Adelberg, 1993; Nugent, 1994a; Nugent, 1994b; Adelberg et al.
1995; Adelberg et al. 1999). According to Ezura et al. (1992b), Fassuliotis and Nelson
(1992) and Nugent (1994b), tetraploid melon plants are characterized by having large
male and hermaphrodite flowers, protrudent stigmas, low fertility, thickened and leathery
leaves, rounded cotyledons, highly hairy leaves and stems, short internodes, flat fruits,
large fruit blossom-end scar, increased number of vein tracts on the fruit, and round
seeds. Nonetheless, Shifriss (1941) had previously been reported that tetraploid melon
plants were highly fertile and no later in maturity than the ordinary diploids. Moreover,
Batra (1952) reported that the quality of melon tetraploids was superior to diploids in
certain varieties and that tetraploids were sufficiently fertile to be propagated readily
from seeds.
Regarding the fruit quality of tetraploid melon plants, Batra (1952) and Nugent
(1994a, 1994b) reported that tetraploid fruits were superior in sugar level, firmness, and
had better color than diploid fruits. However, tetraploid melon plants were less
productive, because they had smaller and flatter fruits than diploids, most cultivars had
48
low fertility, and the fruits had an increased tendency to suffer of easy cracking, therefore
reducing considerably their marketable properties.
As it was mentionated before, triploid melon plants have also been produced (Ezura
et al. 1993; Adelberg et al. 1995; Adelberg et al. 1999). Despite triploids plants grew
more vigorously than diploids, and their fruits were not as flat as tetraploids. These
triploids melon plants did not have any marketable advantage over diploids ones, because
still the percentage of cracking in those triploid fruits was greater than diploid fruits, and
their sugar content was lower. In addition, triploid plants required adjacent diploid
pollinators as a result that they did not set fruit when self-pollinated (Ezura et al. 1993;
Adelberg et al. 1995).
When modern biotechnology, specifically plant tissue culture, was applied to
Cucumis melo in order to obtain reliable regeneration protocols, somaclonal variation was
a common observable fact, therefore tetraploid, octaploid, mixoploid, and aneuploid
melon plants were easily recovered from in vitro cultures (Bouabdallah and Branchard,
1986; Fassuliotis and Nelson, 1992; Ezura et al. 1992a; 1992b; Debeaujon and
Branchard, 1992; Kathal et al. 1992; Ezura and Oosawa, 1994a; 1994b; Ezura et al.
1994). According to Ezura et al. (1995), somaclonal variation could be used to obtain
variants lines with low-temperature germinability in melon. Changes in fatty acid patterns
have been found in melon callus tissue (Halder and Gadgil, 1984), as well changes in a
repetitive DNA sequences during callus culture have been detected (Grisvard et al. 1990).
However, somaclonal variation has to be avoided in research, where genetic
transformation is involved because genomic stability in transgenic plants has to be
maintained in order to express the inserted transgene. In addition, regeneration of melon
49
plants has never been obtained from long-term calli tissue cultures of Cucumis melo
(Grisvard et al. 1990).
The production of tetraploid regenerated melon plants has been observed from
somatic embryogenesis (Ezura et al. 1992a; 1992b), organogenesis (Bouabdallah and
Branchard, 1986; Fassuliotis and Nelson, 1992; Ezura et al. 1992a), and protoplast
regeneration (Debeaujon and Branchard, 1992). Nevertheless, each morphogenetic
pathway has a diffferent effect on the frequency of recovered tetraploid plants, i.e.
somatic embryogenesis (31%), adventitious shoots (30%), shoot primordia (4%), and
axillary buds (0%) (Ezura et al. 1992a). Therefore, when a callus stage is involved in the
regeneration process the likelihood to augment the ploidy level in the regenerated plant is
increased as well. In addition, explant origin affects the frequency of tetraploid plants
from melon tissue cultures (Adelberg et al. 1994). Immature cotyledons produced more
tetraploid regenerants than mature cotyledons, while explants from apical meristems
produced fewer or no tetraploid plants (Adelberg et al. 1994).
Ezura and Oosawa (1994a; 1994b) reported that the capacity of diploid melon cells
to generate in vitro shoots was greater than tetraploid cells. The ability of tetraploid cells
to differentiate into somatic embryos was greater than diploid cells. These same authors
reported that the ability of somatic embryos to develop into plantlets decreased in the
following order: diploid>tetraploid>octaploid. Ezura and Oosawa (1994a) and Kathal et
al. (1992) reported the longer melon cells are kept under in vitro conditions, the greater
the possibility to increase the ploidy levels in those cells. The frequency of chromosomal
variation leading to aneuploid (hyperploid and hypoploid) plants at diploid, tetraploid and
octaploid levels also increases.
50
Melon plant ploidy levels can be determined by cytological methods, such as
counting the chromosome number using root squash tips (Ezura et al. 1992a; 1992b;
Kathal et al. 1992; Ezura et al. 1993; Ezura et al. 1994; Adelberg et al. 1995) or young
tendrils (Yadav and Grumet, 1994). These methods are very laborious and time
consuming, and are not completely reliable because melon chromosomes are smaller in
comparison with other plants, which complicated the easy chromosome observation.
Unconventional and indirect techniques have been developed in order to determine the
ploidy level of regenerated melon plants (Fassuliotis and Nelson, 1992; Adelberg et al.
1994; Adelberg et al. 1995). Among them, pollen grain shape and stomate length, as well
as the chloroplast number in guard cells from stomata have been commonly used. Diploid
plants have pollen grains with typical triangular-appearing shape and are tripolar,
whereas tetraploid plants produce many square tetraporous, round-monoporous or oval
biporous pollen grains (Fassuliotis and Nelson, 1992; Adelberg et al. 1994; Adelberg et
al. 1995). Likewise, Fassuliotis and Nelson (1992) reported that in diploid plants the
average stomate length was 22.1 ± 2.15 µm and the average number of chloroplast inside
the guard cell was 9.4 ± 1.5, while in tetraploid plants the average stomate length was
29.1 ± 2.15 µm and the average number of chloroplast inside the guard cell was twice the
diploid plant. All these data were measured in the epidermal layer from the third or fourth
expanded leaf from the apex.
Flow cytometry is the only absolute, reliable and precise technique to determine the
exact level of ploidy, and even it is useful to detect any chromosomal change or
polysomaty state in melon tissues (Brown, 1984; Delaat et al. 1987; Dolezel et al. 1998;
51
Gilissen et al. 1993; Dolezel et al. 2004). Neverthelesss, the economic constraint to
purchase and operate this equipment restricts its wide usage.
In order to avoid somaclonal variation and regenerate mostly diploid plants from
melon in vitro cultures, several strategies have been proposed. Among them, the
induction of shoot primordium aggregates from shoot-tips then cultivating them in liquid
medium shaken at low speed (Ezura et al. 1997b) was reported. Using this protocol, the
frequency of tetraploids and mixoploids regenerated plants was less than 8% after 4 years
of culture. The cryopreservation of shoot primordia cultures at low temperatures (liquid
nitrogen) using a slow prefreezing procedure has given excellent results as well (Niwata
et al. 1991; Ogawa et al. 1997). A reliable system for transformation of a cantaloupe
Charentais type melon leading to a majority of diploid regenerants was developed (Guis
et al. 2000). Unfortunatly, this regeneration system did not generate completely
developed transgenic shoots for other commercial melon cultivars (Nuñez-Palenius et al.
2002; Gaba, 2002, personal communication), again, a genetic factor is involved at some
stage in melon culture in vitro response.
In summary, it is particularly important to avoid in vitro-conditions which produce
polyploid melon plants or other induced somaclonal variation, in order to maintain
commercial value of the new genotype.
2.3.2.3 Vitrification
Woody and herbaceous explants are proned to suffer anatomical, morphological
and physiological abnormalities when they are cultivated in vitro. Several terms have
been used to describe those abnormalities, such as vitrification, translucency,
hyperhydration, succulency and glassiness (Paques and Boxus, 1987; Ziv, 1991).
52
Vitrification term is the most often used term to describe physical changes in leaves and
roots of cultured explants (Paques et al. 1987).
Melon in vitro cultures are very sensitive to undergo spontaneous vitrification, even
if explants are cultured on non-inductive media or conditions (Leshem et al. 1988a;
1988b). Different factors have been proposed to induce and maintain an explant in a
vitrificated state, such as, high relative humidity inside the in vitro container, high water
potential of the media, low agar level, deficiency in Ca2+ level, high NH4 concentration,
presence of ethylene within the flask, and high a level of cytokinins (mostly BA)
(Leshem et al. 1988a; 1988b; Paques and Boxus, 1987; Paques et al. 1987; Ziv, 1991).
Leshem et al. (1988a) studied the development of vitrification in melon shoot tips
cultured in solid and liquid media. These authors found that on solid medium the
vitrification process gradually increased with time, whereas on liquid medium it was an
‘all-or nothing’ effect. Cytokinins had the major effect on vitrification induction on
melon buds as well (Leshem et al. 1988b). Paques et al. (1987) and Kathal et al. (1994)
reported that vitrification process was an inducible and reversable physiological event. If
the tissues are frequently subcultured, vitrification may be avoided, however this may
induces somaclonal variation.
The following modifications in the culture media have been suggested to avoid
vitrification: increasing the agar concentration, diminishing chloride ions, reducing
potassium, increasing calcium, adding cobalt, modifying the plant hormone balance by
reducing the amount or type of cytokinins, suppressing the use of casein hydrolysate and
adenine sulphate, and adding pectin, phoroglucinol, or phloridzine (Paques and Boxus,
1987; Paques et al. 1987; Ziv, 1991). In vitro environmental conditions can also be
53
altered including: several treatments have been proposed: a cold treatment to the plants
before in vitro culture, reducing culture room temperature, increasing the daily dark
period, increasing the container-environment gas exchange, and reducing the relative
humidity within the flask (Paques and Boxus, 1987; Paques et al. 1987; Ziv, 1991).
2.3.3 Regeneration by Organogenesis
In addition to genotype, explant source or type has a main role on melon in vitro
regeneration (Adelberg et al. 1994; Ficcadenti and Rotino, 1995; Molina and Nuez,
1995b; Curuk et al. 2002b). Shoots, roots, and complete melon plants have been de novo
regenerated through organogenesis using diverse explants, among them: cotyledons (from
immature and quiescent seeds, and/or seedlings), hypocotyls, roots, leaves, protoplasts,
and shoot meristems have been reported (Table 3.2. and Table 3.3). This in vitro
organogenetic pathway may produce plants by direct regeneration (non-callus growth
between explant culture and de novo shoot induction) (Table 3.2) or indirect regeneration
(involving callus growth before de novo shoot induction) (Table 3.3).
Cotyledons and true leaves have commonly a higher regeneration frequency (above
80%) of de novo shoots using direct organogenesis compared to other melon explants
(Moreno et al. 1985a; 1985b; Kathal et al. 1986; Orts et al. 1987; Tabei et al. 1991;
Ficcadenti and Rotino, 1995; Yadav et al. 1996; Nuñez-Palenius et al. 2002, Galperin et
al. 2003a; 2003b). Likewise, Molina and Nuez (1995b) studied the variation in
regeneration ability among and within several populations of leaf, cotyledon and
hypocotyl melon explants. These authors reported that in vitro clonal selection to
improve the regeneration frequency from leaf explants also raises the organogenetic
response in other explant types. These results suggest the presence of a partial common
genetic system controlling the regeneration frequency of all type of explants.
54
In addition to explant type, other non-genotype in vitro culture components may
have some influence upon the efficiency of melon regeneration through organogenesis,
among them, environmental factors and media composition.
2.3.3.1 Medium Composition
It is generally accepted that medium composition has a greater effect upon
organogenic regeneration than environmental factors. This is due to the fact that plant
growth regulators have an enormous effect on in vitro cell development. In general, a
cytokinin/auxin ratio greater than 1 is used in order to induce de novo bud formation,
however, auxins are not always a prerequisite to achieve that goal (Table 2.3 and Table
2.4), and cytokinins alone are able to induce bud formation. Among cytokinins, 6-
benzylaminopurine (N6-benzyladenine, BA) is the most frequently used in high levels (1
mg/l or higher) to induce bud formation. BA concentration is lowered (0.5 mg/l or lower)
to allow shoot elongation. Elongated shoots are then transferred to a plant growth
regulator-free medium or with low-auxin level (NAA or IAA) to induce the rooting
process. If indirect regeneration is used, two- or even a three-step method has to be
utilized. First, an induction callus growth is stimulated on the explant by applying strong
cytokinins (TDZ) and auxins (2,4-D) to the medium culture. Second, those calli, which
have green nodules are transferred to a low-level plant hormone-medium to induce shoot
differentiation, and third, differentiated shoots are cultured in a low-cytokinin medium to
induce shoot elongation (Table 2.3). In general, indirect regeneration is longer in time
than direct regeneration to recover a whole regenerated plant. This is due to the several
subcultures are required for shoot elongation and two or three months are needed for
rooting using the indirect method (Moreno et al. 1985a; 1985b; Kathal et al. 1986; 1994).
55
Table 2.3 Melon regeneration (shoots, roots and/or complete plants) through direct organogenesis. Explant Source Cultivar Induction Medium
(Plant Growth Regulators) Reference
Cotyledon and primary leaf ‘Bananna’, ‘Dixie Jumbo’, Planters Jumbo’, ‘Morgan’, ‘Cavaillon Red Flesh’, and ‘Saticoy Hybrid’
BR-1 medium: 0.1mg/l NOA, 20 mg/l 2iP, and 0.1 mg/l CCC HC medium: 0.05 mg/l NOA, 10 mg/l 2iP, and 0.1 mg/l CCC
1
Hypocotyl from 11 to 13-day-old seedlings
‘Amarillo Oro’ 4.5 mg/l IAA 2
Leaf (0.3-0.5 cm) from 14-day-old seedlings
‘Pusa Sharbati’ 0.22 mg/l BA and 0.2 mg/l 2iP 3
Cotyledons ‘Halest Best’, ‘Iroquois’, and ‘Perlita’
NAA and BA 4
Cotyledons from mature seeds, and cotyledons and leaves from 5 to 7-day-old seedlings
‘Accent’, ‘Galia’, ‘4215’, ‘Preco’, and ‘Viva’
1 mg/l BA 5
Cotyledons from 4-day-old seedlings ‘Superstart’, ‘Hearts of Gold’, ‘Hale’s Best Jumbo’ and ‘Goldstart’
0.88 mg/l IAA and 1.13 mg/l BA 6
Cotyledons from 4-day-old seedlings
Not reported 0.2 mg/l BA 7
Cotyledons from 9 to 10-day-old seedlings
‘Topmark’ 1 mg/l 8
56
Table 2.3 Continued Explant Source Cultivar Induction Medium
(Plant Growth Regulators) Reference
Cotyledons from mature seed, cotyledons and hypocotyl from 10-day-old seedlings, and leaf segment and petioles from 3-weeks-old seedlings
‘Earl’s Favorite Harukei No.3’ 0.01 mg/l 2,4-D or 1 mg/l IAA and 0.1 mg/l BA 9
Cotyledons from 8-day-old seedlings ‘Charentais’ and ‘Gulfstream’ 1.12 mg/l BA for ‘Charentais’ and 1.12 mg/l BA and 1.75 mg/l IAA for ‘Gulfstream’
10
Cotyledons from 2-day-old seedlings ‘Sunday Aki’ 1 mg/l BA, 50-200 µM salycilic acid and 10 mM proline
11
Cotyledons from 7-day-old seedlings
Five Inbred lines from Teziers 0.1 mg/l NAA and 0.5 mg/l BA 12
Cotyledons from immature seeds ‘Miniloup’, ‘L-14’, and ‘B-Line’
2.25 mg/l BA 13
Cotyledons from mature seeds
‘Prince’and ‘Andes’ 1 mg/l BA 14
Cotyledons from 4-day-old seedlings
11 genotypes 0.63 mg/l BA and 0.26 mg/l ABA 15
3-4 cm diam expanded leaves ‘Hale’s Best Jumbo’ and ‘Ananas El Dokki’
0.87 mg/l IAA, 1.13 mg/l BA and 0.026 ABA 16
Cotyledons from 7-day-old seedlings
‘Pusa Madhuras’ 0.22 mg/l BA 17
57
Table 2.3 Continued Explant Source Cultivar Induction Medium
(Plant Growth Regulators) Reference
Cotyledons from 2-week-old seedlings 14 cultivars Embryogenesis: 1.98 mg/l 2,4-D and 4.99 mg/l Organogenesis: 0.01 mg/l 2,4-D and 0.059 mg/l BA
18
Leaves from 10 day-old seedlings ‘Védrantais’ 0.22 mg/l BA and 0.33 mg/l 2iP 19
Cotyledons from 2-day-old seedlings
‘Galia’ male and female parental lines
0.001 mg/l NAA and 1 mg/l BA 20
Cotyledons from mature seeds ‘Yellow Queen’, ‘Yellow King’, and ‘Hybrid AF-222’
1 mg/l BA 21
Proximal zone of the Hypocotyl from 4-day-old seedlings
‘Revigal’ 1 mg/l BA 22
Cotyledons from 4 to 5-day-old-seedlings
Some Turkish cultivars: ‘Hasanbey’ I, ‘Yuva’, ‘Kirkagac 637’, ‘Topatan’, ‘Kuscular’ and ‘Ananas’
Medium and plant growth regulators from reference 6 23
Cotyledons from mature seeds Thirty melon genotypes 1 mg/l BA 24 1. Blackmon et al. (1981a; 1982), 2. Moreno et al. (1985b), 3. Kathal et al. (1988), 4. Mackay et al. (1988), 5. Dirks and Van Buggenum, (1989), 6. Niedz et al. (1989), 7. Leshem et al. (1989), 8. Chee, (1991), 9. Tabei et al. (1991), 10. Fassuliotis and Nelson, (1992), 11. Shetty et al. (1992), 12. Roustan et al. (1992), 13. Adelberg et al. (1994), 14. Ezura and Oosawa, (1994a), 15. Ficcadenti and Rotino, (1995), 16. Yadav et al. (1996), 17. Singh et al. (1996), 18. Kintzios and Taravira, (1997), 19. Guis et al. (2000), 20. Nuñez-Palenius et al. (2002), 21. Stipp et al. (2001), 22. Curuk et al. (2002a), 23. Curuk et al. (2002b), 24. Galperin et al. (2003a).
58
Table 2.4 Melon regeneration through indirect organogenesis. Explant Source Cultivar Callus Induction Medium (CIM) and Shoot
Induction Medium (SIM) (Plant Growth Regulators)
Reference
Cotyledon-callus culture from 11 to 13-day-old seedlings
‘Amarillo Oro’ CIM: 1.5 mg/l IAA and 6.0 mg/l KIN SIM: 0.01mg/l NAA and 0.1 mg/l BA
1
Hypocotyl-callus culture from 7-day-old seedlings
‘Pusa Sharbati’ CIM: 1.0 mg/l IAA and 0.5 mg/l KIN SIM: 0.5 mg/l BA and 0.5 mg/l 2ip
2
Cotyledon-callus from 7 to 9-day-old seedlings
‘Charentais T’, ‘Doublon’, ‘CM 17 187’, and ‘Piboule’
CIM: 2 mg/l IAA and 2 mg/l KIN SIM: no plant growth regulators
3
Cotyledon-callus from 11 to 13-day-old seedlings
15 cultivars belonging to cantaloupensis, inodorus and reticulatus varieties
CIM: 6.0 mg/l KIN and 1.5 mg/l IAA SIM: Same as CIM
4
Cotyledon-protoplasts from 2-week-old seedlings
‘Hong-Xin-cui’ Protoplast Culture Medium and CIM: 0.5 mg/l 2,4-D, 0.5 mg/l Zeatin and 0.5 mg/l BA SIM: 0.3 mg/l 2,4-D, 1.0 mg/l Zeatin and 0.5 mg/l BA
5
Leaf segment (1.0 X 0.5 cm) from 8 to 10-day-old seedlings and petiole segment (0.4-0.8 cm) from 3 to 4-week-old seedlings
‘Cantaloupe PMR’ CIM: 5.0 mg/l NAA and 2.5 mg/l BA SIM: no plant growth regulators
6
Cotyledon-protoplasts from 2-week-old seedlings
‘Charentais’ Protoplast Culture Medium and CIM: 0.05 mg/l 2,4-D and 0.5 mg/l BA. SIM: 2 mg/l BA
7
59
Table 2.4 Continued Explant Source Cultivar Callus Induction Medium (CIM) and Shoot
Induction Medium (SIM) (Plant Growth Regulators)
Reference
Cotyledon-protoplasts from 12-day-old seedlings and fully expanded leaves-protoplasts from 3-week-old seedlings
‘Charentais T’ and F1 hybrid cv. ‘Preco’
Protoplast Culture Medium and CIM: 0.75 mg/l BA SIM: 1.0 mg/l 2,4-D and 0.1 mg/l BA
8
Root-callus culture from 21-day-old seedlings
‘Pusa Sharbati’ CIM: 0.61 mg/l 2iP and 0.68 mg/l BA SIM: 0.22 mg/l BA
9
Cotyledon and Hypocotyl from 11-13 day-old-seedlings
‘Charentais’ CIM: 2.5 mg/l NAA and 1 mg/l BA SIM: 0.01 mg/l NAA and 6 mg/l Kin
10
1. Moreno et al. (1985b), 2. Kathal et al. (1986), 3. Bouabdallah and Branchard, (1986), 4. Orts et al. (1987), 5. Li et al. (1990), 6. Punja et al. (1990), 7. Tabei et al. (1992), 8. Debeaujon and Branchard, (1992), 9. Kathal et al. (1994), 10. Molina and Nuez, (1995b).
60
Other plant hormones, such as gibberellins, and ABA (Kathal et al. 1986; Niedz et
al. 1989; Ficcadenti and Rotino, 1995), and/or plant additives, such as proline, proline
analogues, ornithine, salicylic acid, aspirin, and fish protein hydrolysates (Shetty et al.
1992; Milazzo et al. 1998; et al. 1999), Calcium antagonists (Leshem and Lurie, 1995),
silver nitrate (Niedz et al. 1989; Roustan et al. 1992; Yadav et al. 1996), have been used
to increase in vitro shoot regeneration frequency, nevertheless, the obtained results using
both types of components (plant hormones and plant additives) are either melon
genotype-dependent or are not consistent among reported results.
2.3.3.2 Environmental Factors
Environmental factors, such as light, temperature, nature of media gelling agent,
and relative humidity within flask, influence the efficiency of regeneration method
(Niedz et al. 1989; Ficcadenti and Rotino, 1995; Yadav et al. 1996; Kintzios and
Taravira, 1997; Curuk et al. 2003). For instance, Niedz et al. (1989) studied the effect of
temperature (22, 25 and 29oC) and light (0, 5, 10, 30, 60 and 3,000 µmol.m-2s-1) on the
percentage of bud initiation in cotyledonary explants of ‘Hale’s Best Jumbo’ melon. The
greatest bud initiation was obtained when explants were cultured at 29oC under a range of
light intensity of 5 to 30 µmol.m-2s-1. Conversely, lower temperatures (22 and 25oC),
darkness, and higher light intensities (60 and 3,000 µmol.m.2s-1) reduced bud initiation.
Similarly, Kintzios and Taravira (1997) tested two levels of light intensity, 50 and 250
µmol.m.2s-1 on shoot and root induction in 14 different melon cultivars. As expected,
lower light intensities induced a greater root induction in many melon cultivars. Also,
higher PPFD (250 µmol.m.2s-1) values adversely affected shoot induction from
cotyledonary explants. Interestingly, Curuk et al. (2003) recently described that
61
regeneration from hypocotyls (proximal part to the cotyledons) of Cucumis species does
not requiere light.
High relative humidity within the flask culture might induce ethylene
accumulation, which affects shoot regeneration in melon cotyledons (Roustan et al.
1992). These authors added several levels of silver nitrate (60-120 µM AgNO3) into
culture media to inhibit ethylene action. They were able to obtain a two-fold increase in
shoot regeneration by using silver. Furthermore, a transgenic antisense ACC oxidase line,
which had little ethylene production, displayed a 3.5-fold increase in regeneration
frequency compared to wild type line (Amor et al. 1998).
As it was pointed out previously, the nature of medium gelling agent also has an
important role in melon regeneration (Ficcadenti and Rotino, 1995; Yadav et al. 1996).
Ficcadenti and Rotino, (1995) described that using agar, instead of ‘gelrite’, they were
able to attain a better cotyledon organogenetic response. Likewise, Yadav et al. (1996)
preferred ‘phytagel’, as a substitute of agar for leaf organogenesis.
2.3.4 Regeneration by Somatic Embryogenesis
In addition to organogenesis, somatic embryogenesis is an alternative de novo
morphological pathway that it can be induced in explants to form and recover whole
dicots plants (Liu and Cantliffe, 1983). Somatic embryogenesis was described in melon
explants before organogenesis and used to recover complete melon plants (Table 2.5)
(Blackmond et al. 1981b). In general, cotyledonary tissue has been the most efficient
explant for the induction of melon somatic embryogenesis (Table 2.5).
An embryogenic response in melon is affected by the nature of explant and
genotype. Gray et al. (1993) reported significant differences in the frequency of
62
embryogenic muskmelon explants when they compared two commercial sources of the
same melon cultivar. High regeneration frequency, up to 100%, may be attained from
cotyledon explants with an average number of 20.2 embryos per explant (Gray et al.
1993). However, not all melon cultivars achieve that such a high regeneration frequency,
some as low as 5% with 0.1 embryos per explant (Gray et al. 1993). The conversion rate
of somatic embryos to plantlets might be a limiting step in some melon genotypes, for
example, Trulson and Shahin (1986) were able to recover only 5 melon plants from
hundreds of somatic embryos, Branchard and Chateau (1988) reported a 12% conversion
rate, and Homma et al. (1991) reported a conversion rate from 7% up to 61%, depending
on explant type.
Tabei et al. (1991) concluded that cotyledons were the best explant to induce
somatic embryogenesis in the melon cultivar ‘Earl’s Favorite Harukei No.3’ using high
concentrations of 2,4-D. Homma et al. (1991) tested the effects of explant shape on the
production of melon somatic embryos, finding that the most reproducible result was
obtained with explants consisted of radicle, hypocotyl and a proximal part of cotyledon.
Oridate et al. (1992) found significant differences in somatic embryogenesis capability
from 18 different melon cultivars from four genotypes. These authors concluded that
genetic differences in somatic embryogenic formation capacity existed among cultivars
rather than among genotypes.
Debeaujon and Branchard (1993) published a complete and extensive review on
somatic embryogenesis in Cucurbitaceae, including Cucumis melo, where they
concluded that even though somatic embryogenesis and plant recovery have been
obtained from numerous plant sources including protoplasts,
63
Table 2.5 Melon regeneration through somatic embryogenesis. Explant Source Cultivar Induction Medium (IM) and Development
Medium (DM) (Plant Growth Regulators)
Reference
Cotyledons from 5-day-old seedlings
‘Hale’s Best No.36’ and ‘Rocky Ford’
IM: 1.0 mg/l 2,4-D and 0.5 mg/l BA DM: 0.5 mg/l 2,4-D and 0.25 mg/l BA
1
Expanded cotyledons ‘Charentais T’ IM: 4.52 mg/l 2,4-D and 0.44 mg/l BA DM: no hormones
2
Cotyledons from mature seeds and cotyledons and hypocotyls from 10-day-old seedlings, leaves and petioles from 3-week-old plantlets
‘Earl’s Favorite Harukei No. 3’
IM: 2.0 mg/l 2,4,-D or 25 mg/l IAA DM: no hormones
3
Cotyledons and hypocotyls from mature seeds
‘Green Pearl’ and ‘Earl’s Favourite’
IM: 4 mg/l 2,4-D, 2 mg/l NAA, and 0.1 mg/l BA DM: no hormones
4
Hypocotyls from mature seeds ‘Earl’s Favourite’ IM: 1 mg/l 2,4-D, 1 to 4 mg/l NAA, and 0.1 mg/l BA DM: no hormones
5
Cotyledons from 1-day-old seedlings
‘Earl’s Favourite Haru 1’ IM: 1 mg/l 2,4-D, 1 mg/l NAA, and 0.1 mg/l BA DM: no hormones
6
Protoplasts from 12-day-old cotyledons
‘Charentais T’ and F1 hybrid ‘Preco’
IM: 1 mg/l 2,4-D and 0.1 mg/l BA DM: no hormones
7
64
Table 2.5 Continued
Explant Source Cultivar Induction Medium (IM) and Development Medium (DM)
(Plant Growth Regulators)
Reference
Cotyledons and hypocotyls from mature seeds
18 cultivars belonging to reticulatus, inodorus, makuwa and intermediated type between reticulatus and cantaloupensis varieties
IM: 3.0 mg/l 2,4-D and 0.1 mg/l BA DM: no hormones
8
Cotyledons from mature seeds 52 cultivars IM: 5 mg/l 2,4-D and 0.1 mg/l TDZ DM: no hormones
9
Mature seeds ‘Earl’s Favourite’ IM: 4 µg/l 2,4-D and 0.1 µg/l BA DM: no hormones
10
Hypocotyls from imbibed seeds ‘Prince’ and ‘Sunday Aki’ IM: 1 mg/l 2,4-D, 2 mg/l NAA and 0.1 mg/l BA DM: no hormones
11
Cotyledons from mature seeds ‘Védrantais’ IM: 2.2 mg/l 2,4-D and 0.11 mg/l BA DM: no hormones
12
Cotyledons from mature seeds ‘Yellow Queen’ and ‘Yellow King’
IM: 5.0 mg/l 2,4-D and 0.075 mg/l TDZ DM: no hormones
13
Mature seeds ‘Védrantais’ and ‘Earl’s Favoutire Fuyu A’
IM: 2.0 mg/l 2,4-D and 0.1 mg/l BA DM: no hormones
14
1. Trulson and Shahin, (1986), 2. Branchard and Chateau, (1988), 3. Tabei et al. (1991), 4. Homma et al. (1991), 5. Shimonishi et al. (1991), 6. Kageyama et al. (1991), 7. Debeaujon and Branchard, (1992), 8. Oridate et al. (1992), 9. Gray et al. (1993), 10. Hosoi et al. (1994) 11. Ezura and Oosawa (1994a), 12. Guis et al. (1997a), 13. Stipp et al. (2001), 14. Akasa-Kennedy et al. (2004).
65
the best results were observed with explants coming from seedling parts, especially
cotyledons and hypocotyls. These authors also reported that the genetic constitution of
donor plants seems to play a key role in the success of somatic embryogenesis.
2.3.4.1 Medium Composition
Media composition (mostly plant growth regulators) has a great effect on melon
somatic embryogenesis. The embryogenic pathway involves a two-stage methodology
process: first, explants are cultured onto an ‘induction’ medium, to which auxins have
been added, and second, ‘induced’ explants are transferred to development media, where
full and complete normal embryo development takes place in the absence of the induction
hormone. Auxins are prerequisite for induction of somatic embryogenesis (Tabei et al.
1991; Oridate et al. 1992; Debeaujon and Branchard, 1993; Gray et al. 1993; Guis et al.
1997a; Nakagawa et al. 2001).
In general, the most common and efficient auxin to induce somatic embryogenesis
in melon explants is 2,4-D (Oridate and Oosawa, 1986; Debeaujon and Branchard, 1993).
However, other auxins can be used, such as IAA and NAA, although NAA at high
concentrations can induce abnormal embryo growth (Tabei et al. 1991). Likewise, Tabei
et al. (1991) reported that IAA was the most efficient auxin to induce somatic
embryogenesis in ‘Earl’s Favorite Harukei No.3’ melon. Auxins can be used in
combination with cytokinins, such as BA and TDZ, and/or other hormones, such as ABA
(Trulson and Shahin, 1986; Tabei et al. 1991; Homma et al. 1991; Debeaujon and
Branchard, 1992; Gray et al. 1993; Guis et al. 1997a; Nakagawa et al. 2001). Hormones
are removed to mature the embryos (Table 3.4), nevertheless gibberellins can be added to
the culture medium (Tabei et al. 1991). ABA (10 mg.L-1) was supplemented into the
66
culture medium in order to control the desiccation process and to increase the survival
rate before cryopreservation (Shimonishi et al. 1991).
The type and concentration of carbohydrate in the media plays a role in somatic
embryogenesis in melon (Oridate and Yasawa, 1990; Debeaujon and Branchard, 1992;
Gray et al. 1993, Guis et al. 1997a). Oridate and Yasawa, (1990) reported that a complex
combination of different sugars, such as sucrose, glucose, fructose, and galactose, led to
the highest rate of somatic embryogenesis. Similarly, Gray et al. (1993) concluded that
the sucrose concentration in embryo induction and development media had a profound
effect on somatic embryogenesis, i.e. 3 % sucrose produced a greater explant response
than lower or higher levels of the carbohydrate. These authors found that sucrose
concentration also exerted an effect on the relative percentage of somatic embryo stages
recovered and on abnormal embryo development and precocious germination. Guis et al.
(1997a) tested the effects of several levels of sucrose, glucose and maltose, on inducing
melon somatic embryogenesis. Glucose enhanced the embryogenic response by almost
two-fold, whereas maltose at any level totally somatic embryogenesis. Nakagawa et al.
(2001) reported that the addition of mannitol to the initial media increased the frequency
of somatic embryogenesis in ‘Prince’ melon.
2.3.4.2 Environmental Factors
Several physical factors can affect melon embryogenesis, among them, presence
and quality of light, and physical state of media culture are the most important. In order
to induce somatic embryogenesis, melon explants are cultured in light (Trulson and
Shahin 1986; Branchard and Chateau 1988; Tabei et al. 1991; Homma et al. 1991;
Shimonishi et al. 1991; Ezura et al. 1992a; Debeaujon and Branchard, 1992; Oridate et al.
1992, Debeaujon and Branchard, 1993; Hosoi et al. 1994; and Nakagawa et al. 2001).
67
Somatic embryo formation has been augmented by pretreatment in a dark period, usually
one or two weeks before placing in light (Gray et al. 1993, Guis et al. 1997a). Culturing
on solid medium (Branchard and Chateau, 1988) is better than using liquid medium.
Different gelling agents have been used for this purpose, obtaining improved developed
embryos by using ‘gelrite’ and/or ‘phytagel’ as a substitute for agar (Branchard and
Chateau, 1988). Nevertheless, recently Akasaka-Kennedy et al. (2004) reported that
somatic embryos from ‘Vedrantais’ and ‘Earl’s Favourite Fuyu A’ melon cultivars
underwent development without vitrification, if agar was used instead of ‘gelrite’. Thus
different melon cultivars give diverse responses under similar in vitro conditions.
Kageyama et al. (1991) and Moreno et al. (1985a) reported that the vitrification state of
regenerated plants is increased if liquid cultures are used during the initial steps of
somatic embryogenesis. Kageyama et al. (1991) reported that consecutive washing of
somatic embryos with hormone-free MS medium with 0.5% activated charcoal increased
the number of somatic embryos two-fold.
2.3.5 Haploid Plants and Embryo Culture
Hybrid cultivars represent the F1 progeny of crosses that may involve inbred lines,
clones, or populations (Fehr et al. 1987). The most common type of hybrid cultivar is
produced by crossing two or more inbred lines, which have to be homozygous for certain
important traits (Fehr et al. 1987). The production of inbred lines in Cucumis melo
requires several generations, taking more than seven years of inbreeding in order to
obtain homozygosity (Yashiro et al. 2002). Through using a plant biotechnology
approach, such as production of haploid melon plants, is possible to reduce the amount of
time to obtain melon inbred lines. Diploids can be induced by chromosome doubling
agents, such as colchicine or oryzalin (Yetisir and Sari, 2003; Lotfi et al. 2003). This
68
approach has been used to obtain plants tolerant to diseases, such as virus or powdery
mildew (Kuzuya et al. 2000; 2002; 2003; Lotfi et al. 2003).
According to Guis et al. (1998), using androgenesis and gynogenesis have not been
successful to produce haploid melon plants. Using either gamma or soft X-ray irradiated
pollen will induce in situ gynogenetic haploid parthenogenesis in melon (Sauton and
Dumax de Vaulx 1987; Cuny et al. 1992; 1993; Yanmaz et al. 1999; Kuzuya et al. 2000).
Sauton and Dumax de Vaulx (1987) developed an in vitro technique (commonly named
embryo rescue or embryo culture) to recover muskmelon haploid plants. These authors
obtained haploid plants after pollination of hermaphrodite flowers with irradiated (Co60 γ-
rays) pollen and in vitro culture of ovules or immature embryos. They also developed a
new culture medium to allow further development of these embryos into plants, resulting
with an average number of 2.5 haploid embryos per 100 seeds. Sauton and Dumax de
Vaulx’s embryo culture technique has been applied not only to induce and rescue haploid
melon plants, but also to culture diploid embryos as well in numerous melon cultivars
with excellent results (Sauton, 1988; Kuzuya et al. 2000; Oliver et al. 2000; Kuzuya et al.
2002; Lotfi et al. 2003; Kuzuya et al. 2003; Yetisir et al. 2003).
The rate of melon haploid production is afected by genotypic factors and
environmental growth conditions of donor plants (Sauton, 1988; Cuny et al. 1992; 1993;
Yanmaz et al. 1999). Sauton (1988) studied haploid embryo production on seven melon
cultivars, belonging to five melon types, i.e. reticulatus, cantaloupensis, inodorus,
conomon and acidulus. Gynogenetic haploid embryo production among those melon
genotypes ranged from 0 to 1.7%. Cuny et al. (1993) reported significant differences in
haploid embryo production between two melon cultivars, ‘Vedrantais’ which produced
69
an average number of haploid embryos of 3.5%, whereas ‘F1.G1’ formed 1.7%. Sauton
(1988) found that ‘Arizona’ muskmelon produced the highest number of haploid embryos
(3%) if melon plants were grown during the summer season. Cuny et al. (1992) reported
the effect of season planting on haploid embryo induction. These authors found that
haploid embryo induction was greater in ‘Vedrantais’ melon fruits obtained from plants
grown in summer than those harvested in autumn.
Unlike other plant systems, such as carrot and tobacco, melon pollen is able to
tolerate high γ-irradiation doses (up to 3,600 Grays) and still germinate –in vitro as well
as in vivo- and inducing parthenocarpic haploid plant production (Cuny et al. 1992; 1993;
Yanmaz et al. 1999). However, a significant reduction in pollen tube length has been
observed using high radiation doses. This reduction was proportional to the amount of γ-
radiation used (Cuny et al. 1992; 1993; Yanmaz et al. 1999). High γ-irradiation doses can
induce an increase in the percentage of necrotic haploid embryos. The most common
gamma irradiation doses are between 250 and 350 Grays (Sauton and Dumax de Vaulx
1987; Cuny et al. 1992; 1993; Beharav and Cohen, 1995a; Yanmaz et al. 1999; Lotfi et
al. 2003; Yetisir and Sari, 2003), and for soft-X-rays the doses are between 65 and 130
kR (Kuzuya et al. 2000; 2002; 2003).
Niemirowicz-Szcztt and Kubicki (1979) demostrated that strong incompatibility
events occurred in the intergeneric and intraspecific crosses within the Cucurbitaceae
family, avoiding sexual hybridization among Cucumis melo. Thus, in vitro embryo
culture technique has been utilized to recover melon haploid plants, and to save valuable
diploid plant material through zygotic embryo culture and somatic embryogenesis.
Different diploid plant material has been recovered, such as hybrid plants obtained after
70
interspecific cross of Cucumis melo (PI140471) x C. metuliferus (PI 29190) (Norton,
1981), Cucumis metuliferus (PI 292190, PI 202681, 3503, and 701A) x C. anguria (PI
233646) (Fassuliotis and Nelson, 1988), Cucumis melo (‘Gylan’ gynoecious E6/10) x C.
metuliferus (‘Italia’) (Beharav and Cohen, 1995a), Cucumis melo (‘Cantaloup
Charentais’) x Cucumis anguria L. var. longipes (Dabauza et al. 1998), and Cucumis
melo (‘Cantaloup Charentais albino mutant’) x Cucumis myriocarpus (Bordas et al.
1998).
In summary, the potential of in vitro embryo culture has lead to reduced time to
obtain inbred melon lines. In addition, the improvement of this technique as well as the
cointegration to marker-assisted selection (MAS) (Fukino et al. 2004) may eventually
allow the transfer of disease resistance and/or other important horticultural traits from
other cucurbits into Cucumis melo species.
2.3.6 Genetic Transformation
Two main natural and artificial genetic transformation processes have been used to
obtain melon transgenic plants; Agrobacterium tumefaciens and particle gun
bombardment (Table 2.6). Succesful transformation of melon with Agrobacterium
rhizogenes has not been reported. Gaba et al. (1992) and Gonsalves et al. (1994) used
particle gun bombardment to transform melon explants and recover transgenic plants
through organogenesis. Gray et al. (1995) used the same transformation protocol and
recovered plants from embryogenic materials. Gonsalves et al. (1994) and Gray et al.
(1995) reported both that A. tumefaciens and microprojectile gene transfer produced
almost the same percentage of transgenic plants. Gray et al. (1995) produced stable
normal plants via particle bombardment while embryos from Agrobacterium-mediated
71
transformation were abnormal. Mefoxine, was used to stop Agrobacterium growth may
have caused this.
Transformation success via Agrobacterium or particle gun bombardement is
genotype-, explant source-, and in vitro culture conditions-dependent (Fang and Grumet,
1990; Dong et al. 1991; Yoshioka et al. 1992; Valles and Lasa, 1994; Gonsalves et al.
1994; Gray et al. 1995; Bordas et al. 1997; Clendennen et al. 1999; Ezura et al. 2000;
Nuñez-Palenius et al. 2002; Akasaka-Kennedy et al. 2004). The Agrobacterium strain,
vector structure, and co-cultivation with acetosyringone, have an influence on melon
transformation efficiency (Dong et al. 1991; Yoshioka et al. 1992; Valles and Lasa, 1994;
Bordas et al. 1997).
Fang and Grumet (1990) tested several factors, such as kanamycin concentration,
Agrobacterium inoculum level, length of inoculation, period of co-cultivation, and the
use of tobacco nurse cultures, on melon transformation efficiency rate. These authors
found that 75 mg.L-1 kanamycin, fresh overnight grown bacteria at a concentration of 107
– 108 bacteria.ml-1 (OD600= 0.8), 10 min of inoculation, three days of co-cultivation, and
not using tobacco nurse culture were the best conditions to attain an efficient
transformation rate. Unfortunatly, these transformation conditions were only tested in one
melon cultivar, ‘Hale’s Best Jumbo’. A similar approach was described by Dong et al.
(1991). These authors tested the sensitivity of melon cotyledons to kanamycin and
methotrexate concentrations, co-cultivation time, and different selection schemes -1. no
selection pressure, 2. explants were placed in selection medium inmediately after co-
cultivation, and 3. explants were placed under selection two weeks after co-cultivation-.
The highest transformation frequency was obtained when 75 µg.L-1 methotrexate and 100
72
mg.L-1 kanamycin, 5-6 days of co-cultivation period, and immediate selection pressure
was routinely used.
These experiments were carried out on ‘Orient Sweet, F1 Hybrid’ melon cultivar.
Vallés and Lasa (1994) reported that two days of co-cultivation with Agrobacterium
tumefaciens with cotyledons of ‘Amarillo Oro’ melon were necessary to reach an
efficient transformation process. If they used a longer period of co-cultivation, no
transgenic shoots were recovered.
Different bacterial and plant genes, which provide tolerance or resistance to several
selectable chemical agents, have been used to delay or completely inhibit the growth of
non-transformed buds and shoots of melon during the selection process. Among them,
nptII, which provides tolerance to aminoglycoside antibiotics (Fang and Grumet, 1990;
Dong et al. 1991; Yoshioka et al. 1992; Gonsalves et al. 1994; Vallés and Lasa, 1994;
Gray et al. 1995; Ayub et al. 1996; Bordas et al. 1997; Clendennen et al. 1999; Akasaka-
Kennedy et al. 2004), dhfr, which gives resistance to methotrexate (Dong et al. 1991),
and CP4syn, which offers tolerance to Glyphosate herbicide (Nuñez-Palenius et al. 2002;
2003) have been used. When typical concentrations (75-150 mg.l-1) of kanamycin are not
able to inhibit the non-transgenic bud or shoot growth (Guis et al. 1998; Dong et al.
1991), other antibiotics, which are also detoxified by the neomycin phosphotransferase
protein (NPTII), may be added to melon in vitro cultures in order to improve the selection
efficiency. Gentamycin, hygromycin, and paromomycin have been used in melon
cultures as alternative to kanamycin with excellent results (Guis et al. 1998; Nuñez-
Palenius et al. unpublished results, Ezura et al. personal communication).
73
Table 2.6 Genes transferred to melon by plant genetic transformation. Transgene Phenotypic Trait Explant used and
morphogenetic pathway
Cultivar Transformation
Method
Reference
npt-II gene Selectable marker 4 to 5-day-old cotyledons
Organogenesis
‘Hale’s Best Jumbo’ A. tumefaciens
LBA4404 strain
1
npt-II ,
Dihydrofolate
reductase, and
luciferase gene
Selectable markers
and reporter gene
Mature cotyledons
Organogenesis
‘Orient Sweet, F1
Hybrid’
A. tumefaciens
GV3111SE strain
2
CMV-coat protein
gene
Virus resistance Mature cotyledons
Organogenesis
‘ Prince’ and ‘EG360’ A. tumefaciens
LBA4404 strain
3
uidA gene GUS Reporter gene 3-day-old cotyledons
Organogenesis
‘Galia’ Particle
bombardment
4
ZYMV-coat
protein gene
Potyvirus resistance 4 to 5-day-old cotyledons
Organogenesis
‘Hale’s Best Jumbo’ A. tumefaciens
LBA4404 strain
5
uidA gene GUS Reporter gene 5-day-old cotyledons
Organogenesis
‘Amarillo Oro’ A. tumefaciens
LBA4404 strain
6
CMV-white leaf
coat protein gene
Virus resistance 3-day-old cotyledons
Organogenesis
‘Burpee Hybrid’, ‘Hale’s
Best Jumbo’, ‘Harvest
Queen’, ‘Hearts of
Gold’, and ‘Topmark’
A. tumefaciens
C58Z707 strain
7
74
Table 2.6 Continued.
Transgene Phenotypic Trait Explant used and
morphogenetic pathway
Cultivar Transformation
Method
Reference
ZYMV, WMV, and
CMV coat protein
genes
Virus resistance Leaves
Organogenesis
‘Don Luis’, ‘Galleon’,
‘Hiline’, ‘Mission’, and
‘Parental inbred’
A. tumefaciens 8
npt-II gene Selectable marker Cotyledons
Organogenesis
‘Eden Gem’ A. tumefaciens
and Particle
bombardment
9
ACC oxidase
antisense gene from
melon
Improved fruit quality 5-day-old cotyledons
Organogenesis
‘Védrantais’ A. tumefaciens
LBA4404 strain
10
HAL 1 gene Halotolerance 7-day-old cotyledons and
2-week-old leaves
Organogenesis
‘Pharo’ and ‘Amarillo
Canario’
A. tumefaciens
LBA4404 strain
11
ACC synthase
antisense gene
Improved fruit quality NRz NR A. tumefaciens 12
SAM hydrolase gene Improved fruit quality NR NR A. tumefaciens 13
ACO anti-sense gene
from melon
Improved fruit quality 10-day-old true laves
Organogenesis
‘Védrantais’ A. tumefaciens
LBA4404 strain
14
75
Table 2.6 Continued. Transgene Phenotypic Trait Explant used and
morphogenetic pathway
Cultivar Transformation
Method
Reference
SAM hydrolase
gene
Improved fruit quality NR NR A. tumefaciens 15
Ribozyme genes Potyvirus resistance 0 to 4-day-old cotyledons
Organogenesis
US Patent 5,422,259 A. tumefaciens 16
uidA and gfp genes GUS and GFP
Reporter genes
2-day-old cotyledons
Organogenesis
‘Galia’ male and female
parental lines
A. tumefaciens
ABI strain
17
ACC oxidase
antisense gene from
melon
Improved fruit quality 2-day-old cotyledons
Organogenesis
‘Galia’ male parental
line
A. tumefaciens
ABI strain
18
ACC oxidase
antisense gene from
apple
Improved fruit quality NR ‘Védrantais’ A. tumefaciens
LBA4404 strain
19
uidA and hpt genes GUS Reporter and
Selectable marker
genes
Mature seeds
Somatic embryogenesis
‘Védrantais’ and ‘Earl’s
Favourite Fuyu A’
A. tumefaciens
C58C1Rif® strain
20
1. Fang and Grumet (1990), 2. Dong et al. (1991), 3. Yoshioka et al. (1992), 4. Gaba et al. (1992), 5. Fang and Grumet (1993), 6. Vallés and Lasa (1994), 7. Gonsalves et al. (1994), 8. Clough and Hamm, (1995), 9. Gray et al. (1995), 10. Ayub et al. (1996), 11. Bordas et al. (1997), 12. Ezura et al. (1997), 13. Clendennen et al. (1999), 14. Guis et al. (2000), 15. Shellie, (2001), 16. Huttner et al. (2001), 17. Nuñez-Palenius et al. (2002), 18. Nuñez-Palenius et al. (2003), 19. Silva et al. (2004), 20. Akasa-Kennedy et al. (2004). Znot-reported.
76
Genetic transformation efficiency rate in most melon systems is normally lower
than other plant species (Fang and Grumet, 1990; Dong et al. 1991; Gaba et al. 1992;
Gonsalves et al. 1994; Bordas et al. 1997; Akasaka-Kennedy et al. 2004). Several
transformation rate efficiency values have been reported according to transformation
protocol and melon cultivar used, among them, average efficiencies such as 3-7% (Fang
and Grumet, 1990), 4-6% (Dong et al. 1991), 1% (Gaba et al. 1992), 0.0%, 0.9%, and 1%
(Gonsalves et al. 1994), 0.7-3% (Bordas et al. 1997), 2.4% (Guis et al. 2000), 10%
(Nuñez-Palenius et al, 2003), and 2.3% (Akasaka-Kennedy et al. 2004) has been
depicted. Unfortunatly, in many cases most of the recovered transgenic plants had
somaclonal variation especially ploidy changes [tetraploids (75%, Ayub et al. 1996),
octaploids, mixoploids] or had morphogenetic altered characteristics, which were
expressed in the T0 and T1 generation (Gonsalves et al. 1994).
2.3.6.1 Improvement of Disease Resistance
Cucumis melo is attacked by numerous viral, bacterial, mycoplasmal and fungal
organisms, which cause severe diseases (Zitter et al. 1998). These diseases can affect
melons at any plant developmental stage, causing enormous economic losses. According
to Zitter et al. (1998), definitive disease control is reached by using genetically resistance
melon cultivars. More than 30 viruses are able to induce disease symptoms in melon
plants. Cucumber mosaic virus (CMV), zucchini yellow mosaic virus (ZYMV) and
watermelon mosaic virus (WMV) are the most prevalent (Zitter et al. 1998; Gaba et al.
2004).
The first virus–resistant transgenic melon plants were obtained by Yoshioka et al.
(1992). These authors transferred and over-expressed the gene for CMV coat protein via
Agrobacterium tumefaciens using ‘Prince’, ‘EG360’ and ‘Sunday Aki’ melon cotyledons.
77
Those transgenic melon plants which over-expressed the CMV-CP gene, grown under
greenhouse conditions, were found to be resistant to infection after inoculation with a
low-dose of CMV (Yoshioka et al. 1993). Transgenic plants did not develop any
symptoms of disease during 46-day observation period, while control plants had mosaic
symptoms three days after inoculation. When the virus-dose was increased by ten fold,
only a delayed appearance of symptoms was observed in transgenic plants (Yoshioka et
al. 1993). After Yoshioka’s achievement, different authors were able to obtain transgenic
melon plants over-expressing the CMV-CP for other melon cultivars, such as ‘Burpee
Hybrid’, ‘Halest Best Jumbo’, and ‘Topmark’ (Gonsalves et al. 1994), and ‘Don Luis’,
‘Galleon’, ‘Hiline’, ‘Mission’, and a distinct ‘inbred line’ (Clough and Hamm, 1995). In
addition, transgenic plants over-expressing either CMV-CP for specific viral strains -
White Leaf strain- (Gonsalves et al. 1994) or multi-virus resistance –CMV, WMV, and
ZYMV- (Clough and Hamm, 1995; Fuchs et al. 1997) were described. Gonsalves et al.
(1994) found strong resistance to CMV-White Leaf strain in 5 out of 45 transgenic melon
plants. Gaba et al. (2004) stressed that CP-protection gave effective field resistance, but
not 100% protection.
Field trials were conducted to determine if transgenic plants would retard the
spread of the aphid non-transmissible strain C of CMV (Tabei et al. 1994; Clough and
Hamm, 1995; Fuchs et al. 1997; Fuchs et al. 1998). Clough and Hamm (1995) tested the
level of resistance of five melon transgenic varieties to WMV and ZYMV. Transgenic
melon plants had little or no virus infection, while more than 60% of the control plants
developed virus-symptoms. Similar results were achieved by Fuchs et al. (1997), who
evaluated transgenic melon resistance under high disease pressure, achieved by
78
mechanical inoculations, and/or natural challenge inoculations by indigenous aphid
vectors. After five different trials, more than 90% of the homozygous and 75% of the
hemizygous plants were not infected by two or three viruses whereas 99% of the wild
type melon plants had mixed virus infections. Moreover, control plants were severely
stunted (44% reduction in shoot length) and had poor fruit yield (62% loss), and most of
their fruits were unmarketable (60%) compared to transgenic melon plants.
2.3.6.2 Improvement of Tolerance to Physical Factors
Several environmental factors, such as high or low temperature, salt accumulation,
low-sun irradiance, drought, and flooding, seriously affect melon field cultivation and
production (Robinson and Decker-Walters, 1999). Only one report on transgenic melon
providing tolerance to one environmental factor has been published (Bordas et al. 1997).
The HAL1 gene, which encodes a water soluble protein and provides halotolerance in
yeast, was inserted using Agrobacterium tumefaciens-transformation protocol to ‘Pharo’
and ‘Amarillo Canario’ melon cultivars. In vitro shoots from transgenic and control
plants were evaluated for salt tolerance after 16 days of incubation on medium containing
10 g.L-1 sodium. The frequency and intensity of root formation were higher in HAL1-
positive plant populations compared to wild type plants. However, no differences in
vegetative fresh weight and number of leaves between transgenic and control plants were
scored. Moreover, greenhouse and field evaluation of transgenic plants was not reported.
2.3.6.3 Improvement of Postharvest Characteristics
According to Perishables Group Research, price, firmness and appearance are
among the top criteria for consumers when deciding to purchase melons. Appearance,
which includes color, texture, and look of any sign of damage or disease are the top
criteria for consumers to purchase melons. Customers are interested in knowing
79
nutritional and ripening information in store displays (Anonymous, 2002). Extended shelf
life in melon fruit is an important quality attribute because increase the opportunity to
commercialize melon commodities.
The first transgenic melon plants carrying genes involved in fruit ripening process
were obtained by Ayub et al. (1996). Using the Agrobacterium-mediated transformation
system and cotyledons of the Charentais type Cantaloupe melon cv. ‘Védrantais’, these
authors were able to transfer the 1-aminocyclopropane-1-carboxilic-acid oxidase gene
(ACC oxidase from melon under the control of a constitutive promoter) in antisense
orientation to reduce the level of ethylene (Ayub et al. 1996). Different ripening
parameters were evaluated in transgenic ripening improved melon fruits, such as internal
and gas space ethylene production, total soluble solids, titratable acidity, flesh pigment
content, flesh firmness, rind and flesh color, harvest maturity (timing from anthesis to full
slip), and reversion to wild type behavior by exogenous ethylene treatment (Ayub et al.
1996; Guis et al. 1997b).
Ayub et al. (1996) and Guis et al. (1997b) found that in wild type fruit attached to
the vine, the internal ethylene concentration rose at 39 days after pollination and reached
maximum (120 ppm) production at 42 days. In antisense fruit the internal ethylene
concentration on the vine remained at low levels (0.6 ppm), even at late fruit
development stages (60 days after pollination). When wild type fruits were detached from
the plant there was a significant increase in the internal ethylene concentration, producing
180 ppm 48 hours later. Detached transgenic fruit also had an increase in ethylene
production, but reached only 10 ppm 12 days after harvest. Compared to wild-type,
antisense fruit did not undergo significant rind yellowing and flesh softening at maturity
80
period. Transgenic fruit remained attached to the vine for a longer period of time (65 days
after pollination) compared to control plants (38 days after pollination). Only exogenous
ethylene treatment (50 ppm) of transgenic fruits allowed the recovery of the wild type
behavior and phenotype. There were no significant differences in carotenoid content
(flesh color) and total soluble solids (°Brix) content in wild type and transgenic fruit at
any stage of ripening.
Clendennen et al., (1999) utilized the product of the S-adenosylmethionine
hydrolase (SAMase) gene (from T3 bacteriophage) to catalyze the degradation of SAM,
the initial precursor of ethylene. Unlike the T-DNA construct used by Ayub et al. (1996),
Clendennen et al. (1999) used a fruit specific promoter (chimeric ethylene-responsive
E8/E4 promoter) aimed to overexpress the SAMase gene in two ‘American Cantalope’
lines, which were proprietary inbred lines from Harris Moran Seed Company, Inc. These
authors evaluated several postharvest fruit quality parameters, such as fruit size and
weight, firmness, mold susceptibility, external and internal color, soluble solids, harvest
maturity (timing from anthesis to full slip, measured as Heat Units), and ethylene
production, in wild type and transgenic melon fruits from plants grown under field
conditions. These authors reported that transgenic melon fruit from both lines ‘A’ and
‘B’ did not differ in horticultural traits from wild type fruits, except for the intended goal
of SAMase expression on ethylene biosynthesis and related events. In lab experiments,
transgenic fruits produced half of the ethylene amount accumulated by wild type fruits.
However, in field trials, the onset of maturity, measured on four different dates, was not
significantly delayed in transgenic fruit compared to wild type, but transgenic fruits ripe
more uniformly in the field. Firmness was also measured on transgenic and wild type
81
fruits from three different field trial locations. Significant differences were found in fruit
internal firmness between transgenic and wild type melons, but only from one location.
Clendennen et al. (1999) claimed that by expressing SAMase in a regulated manner by a
fruit-specific promoter, transgenic fruits produced less ethylene than non-transgenic fruit
resulting in a modified ripening and postharvest phenotype.
Silva et al. (2004) obtained transgenic Cantaloupe melon plants cv. Védrantais by
inserting and overexpressing ACC oxidase from apple and not from melon as Ayub et al.
(1996) protocol. These authors reported the characterization of ripening melon fruits, and
their experimental comparison between transgenic and control fruit provided very similar
results in almost all the evaluated parameters, such as harvest maturity, total soluble
solids content, rind color, and internal ethylene production, to those previously reported
by Ayub et al. (1996) and Guis et al. (1997b).
In Charentais type Cantaloupe melon (cv. Védrantais) climateric respiration,
yellowing and carotenoid content of the rind, chilling injury, and formation of the
peduncular abscission zone are events totally ethylene-dependent (Pech et al. 1999;
Flores et al. 2001a; 2001b), whereas fruit softening, volatiles synthesis, and membrane
deterioration are ethylene-partially dependent processes and display some ethylene-
independent components (Bauchot et al. 1998; Bauchot et al. 1999; Guis et al. 1999;
Flores et al. 2001a; 2001b; Flores et al. 2002). According to Guis et al. (1997b), Pech et
al. (1999), Silva et al. (2004) sugar accumulation and the increase in carotenoid content
in the flesh are ethylene-independent events. There is still some controversy about
organic acid metabolism and loss of acidity during fruit melon ripening, i.e. Guis et al.
(1997b) and Pech et al. (1999) suggested that the organic acid metabolism was ethylene-
82
independent, whereas Silva et al. (2004) recently implied that organic acid metabolism is
an ethylene-dependent regulated process. It is likely that these differences in conclusions
might be related to a different ethylene concentration reached by each transgenic fruit. In
Silva’s report transgenic fruit attained a lower internal ethylene-level (<0.09 µl.L-1) than
Guis’s results (<0.5 µl.L-1). This subtle difference in ethylene concentration could have
obvious outcomes such as at the specific levels (Srivastava, 2002; Silva et al. 2004)
All fruit quality oriented transgenic melon plants have been obtained using just
three melon cultivars, such as Védrantais and lines ‘A’ and ‘B’, belonging to one single
variety, i.e. cantaloupensis (Ayub et al. 1996; Clendennen et al. 1999; Silva et al. 2004).
Considering that there are seven commercial and horticultural important melon varieties
(cantaloupensis, reticulatus, saccharinus, inodorus, flexuosus, conomon and dudaim)
(Guis et al. 1998; Kirkbride, 1993), and hundreds of melon cultivars, much more work
could be accomplished. There still remains a need to improve in vitro regeneration and
transformation protocols (Guis et al. 1997a; Gaba et al. 2004; Akasa-Kennedy et al.
2004).
2.4 ‘Galia’ melon
2.4.1 Introduction
‘Galia’ melon is an exotic, green-fleshed, and yellow skinned -finely-netted rind
specialty hybrid muskmelon bred in Israel. ‘Galia’ is also easily recognized by the
volatile-musky aroma that the fruit is able to release (Shalit et al. 2000; Fallik et al.
2001). This muskmelon was developed for semi-arid, dry-land, and open-field and
summer season cultivation in Mediterranean areas. Turkey, Morocco and Spain are major
producers of ‘Galia’ (Karchi, Personal communication). Due its high demand within
83
European market ‘Galia’ muskmelons have recently started been cultivated in Central
American countries such as Guatemala, Honduras, Costa Rica, and Panama, and exported
to the U.S. and Europe (Table 2.7). Open-field, ‘Galia’ muskmelon yields between 35-50
t/ha of excellent-quality fruit (Karchi, 2000). Using passive ventilated greenhouses and
soilless culture in North Florida yields as high as 165 t/ha have been reported (Shaw et al.
2004). The ‘Galia’ type muskmelon world production is around 300,000-500,000 tons per
year (Reho, 2004).
‘Galia’ muskmelon is a commodity reaching dissimilar prices, from $ 1.97 to $
2.17 per fruit, mostly depending on quality characteristics and origin country (Table 2.8)
(Produce1, INC. 2005, United States Department of Agriculture [USDA] Department of
Commerce, U.S. Census Bureau, Foreign Trade Statistics, 2005). However, according to
the USDA, ‘Galia’ high-quality muskmelons can reach prices in a range from $3.0 up to
$5.0 per fruit (USDA, Department of Commerce, U.S. Census Bureau, Foreign Trade
Statistics, 2005).
2.4.2 Botany and Origin
According to Karchi (2000), ‘Galia’ muskmelon was the first Israeli melon hybrid
produced and was obtained through an extensive breeding program at the Newe Ya’ar
Research Center of the Agricultural Research Organization (A.R.O – Israel) during the
mid-1960s. ‘Galia’ has green-fleshed characteristics of ‘Ha’ Ogen’ type, which is a
smooth-skinned, sutured melon and was introduced from Hungary to Israel during the
1950’s, and used as the female parental line. ‘Galia’ has also a golden-yellow netted rind
from ‘Krymka’, Russian melon cultivar,
84
Table 2.7 ‘Galia’ Type Muskmelon Imports to U.S. 1999 2000 2001 2002 2003 TOTAL
ORIGIN (Mt) ($1,000) (Mt) ($1,000) (Mt) ($1,000) (Mt) ($1,000) (Mt) ($1,000) (Mt) ($1,000)
Brasil 363 147 0 0 0 0 0 0 7 4 370 151
Chile 2 3 16 11 0 0 0 0 1 2 19 16
Costa Rica 0 0 0 0 0 0 121 181 0 0 121 181
Dominican
Rep.
49 94 38 66 24 44 28 41 13 20 152 265
Ecuador 141 71 0 0 2 3 0 0 0 0 143 74
France 7 23 11 36 6 19 1 4 0 0 25 82
Guatemala 136 49 0 0 0 0 0 0 7 8 143 57
Honduras 0 0 0 0 0 0 272 109 142 58 414 167
Israel 905 438 95 148 169 161 53 90 11 22 1,233 859
Jamaica 0 0 0 0 0 0 4 8 0 0 4 8
Mexico 75 83 95 137 72 67 87 116 108 112 437 515
Minor Antilles 0 0 0 0 0 0 8 19 28 52 36 71
Netherlands 0 0 0 0 0 0 0 0 1 4 1 4
Panama 6 4 0 0 123 198 69 42 10 10 208 254
Spain 45 40 54 86 63 87 18 25 22 40 202 278
TOTAL 1,729 952 309 484 459 579 661 635 350 332 3,508 2,982
Source: USDA, Department of Commerce, U.S. Census Bureau, Foreign Trade Statistics (2005).
85
Table 2.8 ‘Galia’ Type Muskmelon Unit Value Imports to U.S 1999 2000 2001 2002 2003 AVERAGE
ORIGIN $/Kg $/Kg $/Kg $/Kg $/Kg $/Kg
12/1-
5/31
6/1-
11/30
12/1-
5/31
6/1-
11/30
12/1-5/31 6/1-
11/30
12/1-5/31 6/1-11/30 12/1-5/31 6/1-
11/30
12/1-
5/31
6/1-
11/30
Brasil 0.405 0 0 0 0 0 0 0 0.634 0 0.520 0
Chile 1.091 0 0.700 0 0 0 0 0 2.125 0 1.305 0
Costa Rica 0 0 0 0 0 0 1.488 0 0 0 1.488 0
Dominican Rep. 1.923 1.712 1.733 0 1.848 2.111 1.472 0 1.461 0 1.687 1.911
Ecuador 0.501 0 0 0 1.822 0 0 0 0 0 1.162 0
France 3.097 3.571 3.445 2.313 0 3.078 0 3.112 0 0 3.271 3.019
Guatemala 0.361 0 0 0 0 0 0 0 1.169 0 0.765 0
Honduras 0 0 0 0 0 0 0.401 0 0.412 0 0.407 0
Israel 1.834 0.393 1.961 1.250 2.000 0.759 2.540 1.626 1.963 2.052 2.060 1.216
Jamaica 0 0 0 0 0 0 1.750 0 0 0 1.750 0
Mexico 1.100 1.195 1.334 1.686 0.813 0.985 1.107 1.435 1.178 0.661 1.106 1.192
Minor Antilles 0 0 0 0 0 0 2.393 0 1.887 0 2.140 0
Netherlands 0 0 0 0 0 0 0 0 4.490 0 4.490 0
Panama 0.737 0 0 0 1.603 0 0.610 0 1.000 0 0.988 0
Spain 1.024 0.754 1.619 1.541 1.768 0.837 1.305 1.785 1.824 1.976 1.508 1.379
Minimum Price Guatem. Israel Chile Israel Mexico Israel Honduras Mexico Honduras Mexico
Maximum Price France France France France Israel France Israel France Netherlan
.
Israel
Source: USDA, Department of Commerce, U.S. Census Bureau, Foreign Trade Statistics (2005).
86
which was used as the male parental line (Karchi, personal communication, 2004).
‘Galia’ was named after Dr. Karchi’s daughter and released as a Hybrid F1 for
production in 1973-74 (Karchi, 2000).
‘Ha’ Ogen’ type melons are considered as members of cantaloupensis variety,
whereas ‘Krymka’ cultivar belongs to the reticulatus variety (Kirkbride, 1993; Goldman,
2002). Since ‘Galia’ is a F1 Hybrid muskmelon obtained from crossing ‘Ha’ Ogen’ and
‘Krimka’, disagreement to whether ‘Galia’ F1 is a cantaloupensis variety (Zheng and
Wolff, 2000; Staub et al. 2000; Lopez-Sese et al. 2003) or a reticulatus variety (Aharoni
et al. 1992; Aharoni et al. 1993a; 1993b; Garcia et al. 1998; Fallik et al. 2000) has
emerged.
2.4.3 Postharvest Physiology
‘Galia’ muskmelon has exceptional characteristics such as fruit quality with 13-
15% total soluble solids (TSS), bold flavor and a distinct musky aroma. The main
disadvantage of ‘Galia’ is its short storage life, since it is harvested near peak maturity for
optimum flavor. Storage is limited to two or three weeks, even when it is maintained in
low- temperature (6oC). Several pathogenic agents, such as Alternaria alternata (Fr.)
Keissler and Fusarium spp. can severely reduce the ‘Galia’ fruit storage life, causing a
rapid decay (Barkai-Golan et al. 1981; Aharoni et al. 1992; Aharoni et al. 1993a).
However, using specific fungicides, such as imazalil (2,000 µl.L-1), combined with wax
coating, ‘Galia’ fruits can be protected from decay (Aharoni et al. 1992; 1993a).
Unfortunatly, the residue level of imazalil in Israeli ‘Galia’ wax coated fruits is 3-5 µl.L-1,
more than the maximum tolerance limit (0.5 ml.L-1) imposed by most of European
87
countries (Anonymous, 1990). Therefore, new fungicides and postharvest strategies were
sought to reduce the fruit decay in ‘Galia’ muskmelon.
Other treatments including use of Sanosil-25, which is a 48% hydrogen peroxide
solution and silver salts (Aharoni et al. 1994), applying Hinokitiol (beta-thujaplicin), a
volatile oil extracted from the Japanese Hiba tree (Thujopsis dolabrata) at a concentration
of 750 ppm in the wax (Aharoni et al. 1993b), other fungicides, such as prochloraz and
orthophenylphenol (Aharoni et al. 1992), coating ‘Galia’ fruits with wax containing 2%
sodium bicarbonate (Aharoni et al. 1997), and combined treatments, such as hot water
(52oC) dipping and γ-irradiation (Barkai-Golan et al. 1994), short hot water (59oC) rinse
and rotating brushes (Fallik et al. 2000), and hot water (55oC) treatment and packing in
polyethylene bags (Halloran et al. 1999a; 1999b) The optimal treatment to reduce decay
and fulfill European import requirements, while maintaining high fruit quality after
prolongated storage and marketing simulation in ‘Galia’ type muskmelon is to place the
fruits on rotating brushes, and rinse them with ambient water followed by a hot water
rinse (HWRB) at 59oC ± 1oC for 15 s (Fallik et al. 2000).
Different strategies have been used in order to delay fruit softening in ‘Galia’
including the use of controlled atmospheres plus adding an ethylene absorbent (Aharoni
et al. 1993a), reducing the storage time during transportation by using airfreight systems,
instead of seafreight shipping (Bigalke and Huyskens-Keil, 2000), and applying
inhibitors of ethylene action, such as 1-methylcyclopropene (Ergun et al. 2005) have been
reported.
Aharoni et al. (1993a) carried out a study aimed to determine if ‘Galia’ melons
could be stored under controlled atmosphere (CA) (10% CO2 and 10% O2) plus an
88
ethylene absorbent on semi-commercial scale, in order to maintain fruit quality. Fruit
were evaluated after 14 days in CA at 6°C and additional 6 days at 20°C. These authors
found that ‘Galia’ melons stored in controlled atmosphere plus ethylene absorbent were
significantly firmer and had less decay than control treatments.
Bigalke and Huyskens-Keil (2000) studied the influence of different treatments,
such as low temperatures (5 and 8°C) and individual fruit plastic packaging, as well as
two controlled atmosphere conditions, i.e. 4% and 12% at 80% RH and 8°C for 14 days,
on postharvest characteristics of airfreight ‘Galia’ melon. External and internal fruit
quality attributes, such as color, firmness, soluble solids content, titratable acidity, and
flavor assessment by a consumer panel were evaluated. These authors did not find
statistical differences between quality attributes of bagged and non-bagged melon fruits.
Also, ‘Galia’ melons stored at 5°C maintained the highest external and internal quality
during the storage period, regarding firmness, soluble solids content, titratable acidity and
flavor assessment. Controlled atmosphere conditions tested in this study were
unfavorable to maintain excellent ‘Galia’ fruit quality characteristics.
Ergun et al. (2005) characterized the physiological responses of ‘Galia’ fruit
harvested at green (preripe) and yellow (advanced ripening) stages after treatment with 1-
methylcyclopropene (1-MCP) and further storage at 20°C. These authors found that
treatment with 1.5 µL.L-1 1-MCP delayed the climacteric peaks of respiration and
ethylene production of green fruit by 11 and 6 days, respectively, and also significantly
suppressed respiration and ethylene production maxima. Fruit softening of both
developmental stages, green and yellow, was significantly delayed after 1-MCP
treatment.
89
By delaying fruit ripening via reduction in ethylene production ‘Galia’ F1 hybrid
shelf-life might be improved.
2.4.4 Genetic Improvement by Conventional Methods and Biotechnology
‘Galia’ F1 hybrid has high tolerance to some diseases, such as vine decline and
powdery mildew race 1 (Wolff and Miller, 1998, Karchi, 2000) and elevated fruit quality
characteristics. ‘Galia’ inbred parental lines have been used in breeding programs to
develop improved hybrid with firmer fruit, and also to inbreed other melon accessions
lines for multiple virus resistance (Garcia et al. 1998; Lofti et al. 2003). Crossing
‘Ha’Ogen’ x ‘Inodorus’ type has improved shelf-life but favorable fruit quality
characteristics, such as flavor, volatiles and sugar levels, were lost (Dr. Karchi, personal
communication, 2002).
A reliable and efficient regeneration and transformation system for ‘Galia’
muskmelon has been a desired goal for more than a decade (Gaba et al. 1992). ‘Galia’
muskmelon efficient in vitro regeneration and transformation protocols are lacking (Gaba
et al. 1992; 1995; 1996; 1999; Edriss et al. 1996; Kintzios and Taravira, 1997; Galperin et
al. 2003a).
Dirks and van Buggenum (1989) described an efficient method for shoot
regeneration from leaf and cotyledon explants in ‘Accent’, ‘Galia’, ‘4215’, ‘Preco’, and
‘Viva’ melon cultivars. The best combination of plant growth regulators for shoot
induction in cotyledon explants was 1 mg/l BA, without adding IAA. For leaf explants,
there were no clear differences on shoot induction among the cultivars tested. A range of
20 to 50 shoots per explant were recorded. These authors also claimed that over 100
shoots were formed in cotyledon explants. The best results on shoot induction were
90
obtained with ‘Galia’, ‘Accent’, and ‘Preco’. Elongated shoots were rooted on hormone-
free MS, and then successfully transferred into the greenhouse.
Leshem (1989), working in the Volcani Center in Israel, reported a plant tissue
culture approach in order to study the responsive zone for organogenesis and the time for
organ induction in ‘Galia’ melon cotyledons. Calli proliferation as well as root and shoot
primordia formation was only confined to the basal side (attachment point to the stem) of
the cotyledon or its segments and never appeared on the distal cut edge. The basal
segments were always the most regenerative explants than the distal ones. The organ
induction period to develop roots required at least one day but no more than three,
whereas three days but not more than five were needed to produce shoots. According to
Leshem (1989), melon cotyledon responsiveness was apparently achieved by the
transverse cut and possibly due to accumulation of a polarly transported endogenous
growth factor (maybe IAA). Exogenous plant hormones, such as 0.2 mg.L-1 BA and 2
mg.L-1 IAA, had a fundamental role for the induction of organ formation. Leshem’s
research team, published three more articles (Leshem et al. 1990a; 1990b; 1991), where
they studied the role of exogenous cytokinins, some reserve cotyledon polypeptides and
polyamines on in vitro melon regeneration. Leshem’s team shifted from using ‘Galia’
melon cultivar to ‘Sweet’n Early’ hybrid in those published articles (Leshem et al. 1990a;
1990b; 1991). Perhaps this decision was taken because fully complete well developed
shoots were not obtained in Leshem (1989).
Leshem et al. (1994a; 1994b) used thidiazuron (TDZ), benzyladenine (BA) and
paclobutrazol (PC), and the plant hormone IAA in order to examine changes in
cotyledonary organogenetic response in ‘Galia’ F1 hybrid. They studied the effect of
91
those bioregulators on temporal changes in protein profiles (mostly some reserve
cotyledonary polypeptides with molecular weights of 20-25 kDa -P20-P25-) in cultured
melon cotyledons. These authors found that TDZ exerted a cytokinin-like influence by
inducing de novo shoot proliferation and inhibition of root initiation, while PC was a
potent root-inducer, due to its ability to overcome the inhibitory effect of BA on melon
rooting. However, PC was not able to induce roots at the basal edge of the cotyledon
when TIBA (inhibitor of auxin transport) was incorporated into culture medium.
Exogenous cytokinin (2.25 mg.L-1 BA) enhanced mobilization of reserve proteins (P20-
P25) and also induced shoot regeneration in cultured cotyledons. These polypeptides
disappeared from cotyledonary tissue on day four if the media culture contained BA,
whereas a constant level of those polypeptides was maintained through the culture period
if 1.75 mg.L-1 IAA was present. Regeneration correlated well with the P20-P25
disappearance, and shoots were only induced on medium containing 2.25 mg.L-1 BA. A
delayed organogenetic regeneration and P20-P25 breakdown was observed when IAA
was present in the media. The incorporation to the medium of an inhibitor of
carboxypeptidase (PMSF) inhibited both P20-P25 disappearance and root regeneration,
but not shoot initiation.
Gaba et al. (1996) reported that ancymidol, an anti-gibberellin compound,
improved in vitro bud development in cotyledonary explants of ‘Galia’ melon. This anti-
gibberellin substance had a synergistic effect when BA was incorporated to the media.
The presence of 5 mg/l GA3 reverted that rate of regeneration induced by BA alone or
BA plus ancymidol.
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It has been suggested that cytokinin and white light operate together to enhance
polypeptide metabolism and induce shoot regeneration in ‘Galia’ cultured cotyledons
(Leshem et al. 1995; Kintzios and Taravira, 1997). Leshem et al. (1995) studied the effect
of different light intensities (PPFD 0, 3, 7, 14, 30 and 50) on shoot regeneration incidence
on medium containing 2.25 mg.L-1 BA and disappearance of P20-P25 polypeptides in
melon cotyledons. They found that BA enhanced the polypeptide loss under light
conditions (50 µmol.m2.s-1), but it failed when cotyledons were cultured in total darkness.
A reduction in white light fluency to 14 µmol.m2.s-1 was enough to observe the
polypeptide pattern as in darkness culture. The incidence of shoot regeneration was
reduced about half when cotyledons were cultivated at 14 µmol.m2.s-1 white light fluency,
and only 5% of cotyledons were responsive to shoot induction under total darkness.
These authors suggested that BA loses its shoot induction capacity in the absence of
white light, therefore, it is not able to support any growth response, even if BA
concentration is increased (2.25 mg.L-1).
Kintzios and Taravira (1997) studied several morphogenetic pathways, such as calli
induction, somatic embryogenesis and plant regeneration response, of 14 commercial
melon cultivars to two levels of photosynthetic photon flux densities (PPFD), i.e. 50 or
250 µmol.m2.s-1. ‘Galia’ was able to undergo shoot induction only when PPFD was 250
µmol.m2.s-1.
Micropropagation of ‘Galia’ F1 melon explants, using either shoot tips or axillary
buds, has been reported as well (Spetsidis et al. 1996; Edriss et al. 1996). Elevated levels
of BA (2 mg/l) were needed to reach the greatest shoot production, and the presence of
0.5 mg/l IAA did not affect that number.
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The first report on ‘Galia’ melon genetic transformation through plant
biotechnology was described by Gaba et al. (1992; 1995). They used particle gun
bombardment to transform cotyledon explants and detect transient GUS expression.
Permanent GUS transformation was observed only after a strong selection procedure
(350 mg/l kanamycin). They were able to detect the presence of that transgene by PCR
methods, but only 1% of the explants produced transformed shoots. Gaba et al. (1999)
claimed that despite abundant shoot induction ‘Galia’ melon cotyledons (Dirks and van
Buggenum, 1989), the cultivar was recalcitrant to transformation by Agrobacterium
tumefaciens (Gaba et al. 1995; 1996).
An innovative regeneration system using the proximal zone of the hypocotyl of
‘Galia’ type melon cultivar, i.e. ‘Revigal’ has been reported (Curuk et al. 2002). This
protocol was later applied to three melon cultivars, ‘Revigal’, ‘Topmark’ and ‘Kirkagac’,
and to one cucumber cultivar, i.e. ‘Taoz’ (Curuk et al. 2003). Regeneration from
hypocotyl explants resulted in almost 100% diploid shoots, therefore, this is the first
report of regeneration from Cucumis genus producing a fully diploid plant population.
Unfortunatly, these authors did not try to regenerate the original ‘Galia’ F1 hybrid
through their system nor to transform it by means of Agrobacterium tumefaciens or
particle gun bombarment.
Galperin et al. (2003a) screened, through in vitro regeneration, 30 melon genotypes
to measure their regeneration capabilities. Those melon genotypes embraced wild
landraces, breeding lines and commercial cultivars. According to their results, 24 out of
30 genotypes did not produce any normal shoots. Only five out of six genotypes
displayed low regeneration efficiency, because a few explants developed normal shoots.
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Only ‘BU-21’ had exceptional regeneration ability. Five melon genotypes, among them
‘Galia’, were selected from the original 30 genotypes to determine the organogenetic
response on three different regeneration media, i.e. MR, HC and IK (Fang and Grumet,
1990; Blackmon and Reynolds, 1982; Moreno et al. 1985a). The regeneration efficiency
reported for ‘Galia’ melon was 0% on those three different media.
So far, there is no any report in the literature on stable genetic transformation in
‘Galia’ F1 hybrid or in any of its parental lines.
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CHAPTER 3 EFFECT OF EXPLANT SOURCE ON REGENERATION AND TRANSFORMATION
EFFICIENCY IN ‘GALIA’ MELON (CUCUMIS MELO L.) MALE AND FEMALE PARENTAL LINES
3.1 Introduction
The Cucurbitaceae family consists of mostly frost sensitive, principally tendril-
bearing vine plants which are found in sub-tropical and tropical regions around the world
(Robinson and Decker-Walters, 1999). Melon (Cucumis melo L.) belongs to this family
and is an important horticultural produce. World melon production (Cantaloupe & others)
in 2004 was over 27 million metric tons (FAO, 2005). Traditional breeding methods in
melon have led to a considerable varietal improvement. However, strong sexual
incompatibility barriers at the interspecific and intergeneric levels have restricted
potential to readily develop new and enhanced melon cultivars (Niemirowicz-Szcztt and
Kubicki, 1979; Robinson and Decker-Walters, 1999). Using genetic engineering
strategies is feasible to overcome most of the genetic barriers among plants, which are
unsurpassable by traditional breeding techniques (Vasil, 1990; 1996; 1998; 2003).
Likewise, in order to achieve a successful commercial application from biotechnology in
melon a competent de novo regeneration system from in vitro cultures is required (Guis et
al. 1998).
In the last 25 years, more than 40 in vitro melon regeneration protocols have been
described, some using either organogenesis, somatic embryogenesis or both regeneration
pathways (Blackmon et al. 1981a; Blackmon et al. 1982; Moreno et al. 1985a; Mackay et
al. 1988; Punja et al. 1990; Chee, 1991; Shetty et al. 1992; Hosoi et al. 1994; Singh et al.
96
1996; Kintzios and Taravira, 1997; Guis et al. 1998; Guis et al. 2000; Nuñez-Palenius et
al. 2005; Stipp et al. 2001; Curuk et al. 2002a; 2002b; 2003; Galperin et al. 2003a; 2003b;
Akasa-Kennedy et al.; 2004). Several biological and physical factors influence in vitro
regeneration efficiency rate, and all have to be considered in order to develop a
reproducible and reliable melon regeneration protocol. All the systems had diverse
regeneration rates depending on genotype, culture conditions and explant source. Melon
plant regeneration has been reported from roots (Kathal et al. 1994), calli (Moreno et al.
1985b), petioles (Punja et al. 1990), hypocotyls (Moreno et al. 1985b), leaves (Yadav et
al. 1996), protoplasts (Moreno et al. 1985a), somatic embryos (Gray et al. 1993), shoot
primordia (Adelberg et al. 1999), and cotyledons (Guis et al. 1997a).
‘Galia’ muskmelon is an Israeli melon F1 hybrid with exceptional fruit quality
characteristics such as 13-15% total soluble solids (TSS), bold flavor and a distinct aroma
(Karchi, 2000). Unlike other melon types, such as Cantaloupe Charentais (Ayub et al.
1996; Akasa-Kennedy et al. 2004; Silva et al. 2004), ‘Galia’ muskmelon is not easily
cultivated in vitro and full regenerated wild type plants are especially difficult to obtain
(Leshem 1989; Leshem et al. 1994a; 1994b; Gaba et al. 1994; Gaba et al. 1996; Edriss et
al. 1996; Kintzios and Taravira 1997; Galperin et al. 2003a). Additionally, Gaba et al.
(1999) reported ‘Galia’ muskmelon to be recalcitrant to transformation by Agrobacterium
tumefaciens. Therefore, a reliable and efficient in vitro protocol for regeneration and
transformation in ‘Galia’ muskmelon has been a desired objective for more than a decade
(Gaba et al. 1992). Because different melon explants have diverse in vitro regeneration
responses, it is important to accurately assess that parameter in ‘Galia’ parental lines. The
goal of this research was to measure the source of the explant on regeneration and
97
transformation efficiency using two reporter genes (GUS and GFP) in ‘Galia’ melon male
and female parental lines.
3.2 Materials and Methods
3.2.1 Plant Material
Mature seeds of ‘Galia’ male (Cucumis melo L. var. reticulatus Ser. cv. ‘Krimka’)
and female (Cucumis melo L. var. cantaloupensis Naud. cv. ‘Noy yizre’el’) parental lines
were surface sterilized and germinated on hormone-free half-strength Murashige and
Skoog (MS) medium (Murashige and Skoog, 1962) according to Nuñez-Palenius et al.
(2005a) protocol. In vitro regeneration of both parental lines was carried out on explants
from cotyledons, hypocotyls, and non-expanded true leaves following the procedures and
plant-hormone balances reported by Nuñez-Palenius et al. (2005a), Ramirez-Malagon
and Ochoa-Alejo (1996), and Guis et al. (2000), respectively. De novo shoot regeneration
response was measured as bud forming capacity index [BFC index= (average number of
shoots per explant) X (% explants forming shoots) / 100] (Martinez-Pulido et al. 1992).
Seedling growth and plant regeneration were conducted in a growth chamber (Lab-Line
Instruments, Inc. Melrose Park, IL) under 100 µmol . m-2 . s-1 light and a 16 h photoperiod
provided by cool-white fluorescent lamps and constant 25 ± 1°C temperature.
3.2.2 Agrobacterium Inoculation and Plant Transformation
Agrobacterium tumefaciens strain ABI containing a binary vector, pMON17204,
harboring a selectable glyphosate resistance marker [CP4 syn gene encoding for 5-
enolpyruvylshikimate-3-phosphate synthase (EPSPS)], and the uidA gene encoding for β-
glucuronidase (GUS) was used (Figure 3.1a). CP4 syn gene was under control of the
Figwort Mosaic Virus (FMV) promoter (Richins et al. 1987), whereas uidA gene was
under control of the CaMV 35S promoter (35S). Agrobacterium tumefaciens strain LBA-
98
4404 containing a binary vector, pCAMBIA 2202-sGFPS65T, harboring a selectable
kanamycin-resistance marker, NPT-II gene encoding for neomycin phosphotransferase,
and a fully functional green fluorescent protein (GFP) gene was used (Figure 3.1b). Both
Agrobacterium tumefaciens strains, ABI and LBA4404, were transferred to 5 ml of
Luria-Bertani Broth (LB) medium (pH 7.5). The former was supplemented with 25 mg .
L-1 chloramphenicol, 50 mg . L-1 kanamycin, and 100 mg . L-1 spectinomycin, whereas
the second strain was supplemented with 50 mg . L-1 carbenicillin and 100 mg . L-1
chloramphenicol. Both strains were then incubated on an orbital shaker (200 rpm) for 12
hours at 25oC. Afterward, the cultures (5 ml aliquot) were transferred to 250 ml baffled
culture flask containing 50 ml liquid LB medium with the same antibiotics and
concentrations previously used, and incubated at 25oC on an orbital shaker (150 rpm) for
an additional 14-20 hours until an A600= 0.7-1.0 was reached.
Cotyledon and non-expanded leaf explants from both ‘Galia’ melon parental lines
were immersed in Agrobacterium suspension for 20-30 min with orbital shaking (50
rpm), and then were blotted three times onto sterile filter paper (Whatman No. 1) to
remove the excess bacterial suspension. Cotyledon and true leaf explants were then
cultured and de novo shoots were obtained as previously described by Nuñez-Palenius et
al. (2005) and Guis et al. (2000), respectively. Hypocotyls were inoculated with a
Agrobacterium tumefaciens suspension using a sterile syringe needle (0.72 mm gauge
and 32 mm length) following the protocol described by Ramirez-Malagon and Ochoa-
Alejo (1996).
99
Figure 3-1 Map of the T-DNA in pMON17204 and pCAMBIA 2202-sGFPS65T. (A) T-
DNA region of binary vector pMON17204. RB: right border of T-DNA, 35S: promoter for 35S RNA from Cauliflower mosaic virus, CP4syn: 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) gene, rbcSE9: 3’end of pea rbcSE9 terminator, 35S: promoter for 35S RNA from Cauliflower mosaic virus, GUS: uidA gene, rbcSE9: 3’end of pea rbcSE9 terminator, LB: left border of T-DNA. (B) T-DNA region of binary vector pCAMBIA 2202-sGFPS65T. RB: right border of T-DNA, 35S: promoter for 35S RNA from cauliflower mosaic virus, NPT-II: neomicyn phosphotransferase gene, 35S: terminator for 35S RNA from cauliflower mosaic virus, 35S: promoter for 35S RNA from cauliflower mosaic virus, GFP: sGFPS65T (humanized, for high expression level and solubility in eukaryote cells) gene, NOS: nopaline synthase terminator, LB: left border of T-DNA.
3.2.3 Histochemical Staining for GUS Activity and GFP Detection
Histochemical localization for β-D-glucuronidase (GUS) activity in putative T0
transformant tissues was performed as described by Gama et al. (1996). Plant organ and
tissues were incubated in GUS-staining solution [50 mM sodium phosphate (pH 7.0), 0.5
mM potassium ferricyanide, 0.5 mM potassium ferrocyanide, 10 mM EDTA (pH 8.0),
0.06% (v/v) Triton X-100, 0.35 mg . mL-1 5-bromo-4-chloro-3-indolyl-β-D-
glucuronidase (X-Gluc)] at 37°C for 12-36 h. After incubation, the samples were then
CP4syn 35S
RB
GU
LB
rbcSE9 rbcSE9
NPT-II 35S
RB
GF
LB
NO35S 35S
A
B
100
transferred to 70% (v/v) ethanol to remove chlorophyll. GUS-positive tissues were
photographed with a Zeiss MC63 photomicrographic camera coupled to a DRC
stereomicroscope.
Putative GFP-positive plant tissues were examined directly to detect fluorescence
using a Zeiss Stemi SU11 fluorescence stereomicroscope having a mercury lamp and a
FITC 535 filter.
3.2.4 PCR Assay
Total DNA isolation from wild type and transgenic GUS T1 melon leaflets (0.25-
0.5 g) was performed using a modified CTAB protocol (Doyle and Doyle 1987; 1990).
The forward and reverse primers for uidA gene (GUS) were 5’-CAACGAACTGAACTG
GCAG-3’ and 5’-CATCACCACGCTTGGGTG-3’, respectively, amplifying a fragment
of 750 bp. The GUS fragments in total DNA were amplified under the following
conditions: a pre-incubation period at 94 oC for 2 minutes followed by 30 cycles of 94 oC
for 30 sec for denaturation, 55 oC for 30 sec for primer annealing, and 72 oC for 45 sec
for extension, and a final extension period at 72 oC for 5 min. The amplified PCR
products (10 µl) were subjected to electrophoresis on a 0.8% agarose gel and visualized
by UV light.
3.2.5 Experimental Design and Statistical Analysis
The experiment to measure the BFC index on three different melon explants was
carried out under a factorial design (2 x 3) with six replicates, having two levels for
genotype, and three levels for explant type. The experimental design for transformation
experiment was a factorial (2 x 3 x 2) with three replicates, having two levels for
genotype, three levels for explant type, and two levels for reporter gene used. Original
data from transformation experiment was transformed by the arcsine square root in order
101
to be analyzed for analysis of variance (ANOVA). Means were separated by Tukey’s
Studentized Range Test at P≤ 0.05 (SAS Institute, Cary, N.C.).
3.3 Results and Discussion
3.3.1 Effect of Explant Origin on Regeneration Efficiencies
Cotyledonary explants from ‘Galia’ muskmelon male and female parental line
attained the greatest BFC index compared to hypocotyl and true-leaf explants (Figure
3.2). The BFC value for cotyledons was almost 4 times greater than hypocotyls and true-
leaves. When the same explant type was used, no significant differences between male
and female BFC response were found, except for cotyledons.
Figure 3.2 Organogenetic response of ‘Galia’ muskmelon parental lines depending on
explant source. Bars with the same letter are not significantly different by Tukey’s Studentized Range Test at P≤ 0.05. BFC= bud forming capacity index (Martinez-Pulido et al. 1992).
Cotyledonary explants have been the most common plant organ used to induce de
novo regeneration through either organogenesis or somatic embryogenesis in Cucumis
melo (Blackmon et al. 1981a; 1982; Trulson and Shahin, 1986; Mackay et al. 1988;
0
1
2
3
4
5
6
7
8
Cotyledon Hypocotyl True-leaf
BFC
Male
Female
a
c c c
c
b
102
Branchard and Chateau, 1988; Dirks and Van Buggenum, 1989; Niedz et al. 1989;
Leshem et al. 1989; Chee, 1991; Tabei et al. 1991; Kageyama et al. 1991; Homma et al.
1991; Fassuliotis and Nelson, 1992; Shetty et al. 1992; Debeaujon and Branchard, 1992;
Roustan et al. 1992; Oridate et al. 1992; Gray et al. 1993; Adelberg et al. 1994; Ezura and
Oosawa, 1994b; Hosoi et al. 1994; Ficcadenti and Rotino, 1995; Yadav et al. 1996; Singh
et al. 1996; Kintzios and Taravira, 1997; Guis et al. 1997a; Stipp et al. 2001; Curuk et al.
2002a; Galperin et al. 2003a; 2003b; Akasa-Kennedy et al. 2004).The use of cotyledon as
explants for melon in vitro culture has several advantages over other plant tissues, i.e. a)
cotyledons have a quick morphogenetic response producing high number of shoots or
somatic embryos, b) cotyledons are ready to be used as explants in a short period of time
(0-5 days), and c) several cotyledonary explants (8-12) are effortlessly acquired from a
single seed (Table 3.1). Moreover, de novo shoots from cotyledon are ready to be
‘hardened’ as early as 9 weeks after the initiation of in vitro culture, whereas hypocotyl
and true-leaf systems require 23 and 17 weeks, respectively (Figure 3.3).
Overall, the cotyledon was the best explant to regenerate complete plants for both
‘Galia’ muskmelon male and female parental lines compared to hypocotyl and true-leaf
explants.
3.3.2 Plant Transformation
In order to assess the effect of source explant on transformation efficiency in
‘Galia’ male and female parental lines, two Agrobacterium tumefaciens strains, ABI and
LBA4404, harboring GUS and GFP reporter genes, respectively, were tested on
cotyledon, hypocotyl and true-leaf explants. GUS-positive tissues were detected by a
histological GUS assay (Gama et al. 1996), while GFP-positive tissues were identified by
fluorescence microscopy.
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Table 3.1 Regeneration efficiency in ‘Galia’ muskmelon parental lines depending on explant source.
Explant source Number of explants
per seed
zBFC yPeriod (weeks)
Cotyledon 12 6.31 4-5
Hypocotyl 1 1.51 19-20
True-leaf 10 1.11 11-13
zBFC= bud forming capacity index (average number of shoots per explant) X (% explants forming shoots) / 100. (Martinez-Pulido et al. 1992). yPeriod needed to achieve complete developed shoots. Data are the average for male and female ‘Galia’ parental lines results.
Transformed cotyledon and hypocotyl explants from both ‘Galia’ male and female
parental lines produced de novo shoots and roots, which were positive for GUS and GFP
expression (Figure 3.4). Although de novo shoots were obtained, only ‘escapes’ (non
GUS- or GFP-positive shoots and roots) were observed when true-leaf explants were
used (Figures 4-5 and 4-6). It has been reported that different plant explants have diverse
susceptibility to be transformed by Agrobacterium tumefaciens (Febres et al. 2003). This
differential susceptibility has been described in melon (Bordas et al. 1997; Guis et al.
1998) cucumber (Rajagopalan and Perl-Treves, 2005), and other plant species (Tu et al.
2005). Also, the production of ‘escapes’ after Agrobacterium- or biolistic-mediated
transformation in Cucumis melo is a commonly observable result (Guis et al. 1998).
Indeed, Akasaka-Kennedy et al. (2004) have claimed that in order to reduce the problem
of high production of ‘escapes’ by melon in vitro cultures, alternative regeneration and
transformation systems have still to be obtained.
104
Figure 3.3 Time schedule for de novo shoot regeneration in hypocotyl, cotyledon and true-leaf explants of ‘Galia’ muskmelon parental lines. The numbers between the top and bottom photographs represent the number of weeks to attain from mature seeds the in vitro rooted seedlings. Hypocotyl: (a) seedlings, (b) hypocotyl injury (arrow), (c) decapitation, (d) decapitated seedlings, (e) de novo shoots, (f) in vitro seedling. Cotyledon: (a) cotyledons from 2-day-old seedlings, (b) de novo shoots, (c) in vitro seedling. True-leaf: (a) seedlings, (b) true-leaves, (c) de novo shoots, (d) in vitro seedlings.
HYPOCOTYL COTYLEDON TRUE-LEAF
b
a
c
b
c
a
d
0 0
17
9
a
b
f
e
c
d
0
23
105
A greater number of T0 GUS-positive seedlings for both ‘Galia’ male and female
parental lines was obtained when cotyledons were used as explants compared to
hypocotyls (Figure 3.5). Moreover, significant differences were observed between both
explants. Conversely, when the Agrobacterium tumefaciens strain LBA4404, containing a
binary vector pCAMBIA 2202-sGFPS65T, was used to transform both ‘Galia’ parental
lines, only female-hypocotyl explants produced a higher amount of GFP-positive
seedlings than cotyledons (Figure 3.6). It was found that 13% of hypocotyl-explants
produced transgenic shoots. ‘Galia’ male parental-hypocotyl explants had a
transformation efficiency value similar to ‘Galia’ male- and female-cotyledon explants.
The results obtained on Cucumis melo transformation efficiency in this work exceed what
it has been previously reported. In general, the genetic transformation rate efficiency in
most of melon systems is normally lower than other plant organisms (Fang and Grumet,
1990; Dong et al. 1991; Gaba et al. 1992; Gonsalves et al. 1994; Bordas et al. 1997;
Akasaka-Kennedy et al. 2004). Several transformation rate efficiency values have been
described according to transformation protocol and melon cultivar used, among them,
average efficiencies such as 3-7% (Fang and Grumet, 1990), 4-6% (Dong et al. 1991),
1% (Gaba et al. 1992), 0.0%, 0.9%, and 1% (Gonsalves et al. 1994), 0.7-3% (Bordas et
al. 1997), 2.4% (Guis et al. 2000), 10% (Nuñez-Palenius et al. 2005a), and 2.3%
(Akasaka-Kennedy et al. 2004) has been depicted.
A PCR assay was performed on total DNA isolated from T1 GUS positive plants in
order to detect the presence of uidA gene and corroborate their transgenic status. We were
able to detect the presence of a GUS-specific 750 bp fragment which belongs to the GUS
106
reporter gene, in male and female ‘Galia’ muskmelon transgenic lines but not in non-
transgenic lines (Figure 3.7).
In summary, it is possible to obtain transgenic ‘Galia’ male and female parental
plants using either cotyledon or hypocotyl explants. Moreover, cotyledonary explants
have the advantage to attain those transgenic plants in a shorter period (Figure 3.8).
Figure 3.4 Stable expression of GFP and GUS genes in T0 shoots and roots of ‘Galia’
muskmelon parental lines. A) GUS non-positive tissue, B) and C) GUS positive tissue. D) GFP non-positive tissue, E) and F) GFP positive tissue.
A
B
C
D
E
F
107
Figure 3.5 Transformation efficiency on ‘Galia’ muskmelon parental lines. GUS reporter
gene was used to transform different explant sources. Bars with the same letter are not significantly different by Tukey’s Studentized Range Test at P≤ 0.05.
Figure 3.6 Transformation efficiency on ‘Galia’ muskmelon parental lines. GFP reporter
gene was used to transform different explant sources. Bars with the same letter are not significantly different by Tukey’s Studentized Range Test at P≤ 0.05.
0.0
2.0
4.0
6.0
8.0
10.0
12.0
Cotyledon Hypocotyl True-leaf
% o
f tra
nsfo
rmat
ion
Male
Female
a
a
b
b
c c
0.0
2.0
4.0
6.0
8.0
10.0
12.0
14.0
Cotyledon Hypocotyl True-leaf
% o
f tra
nsfo
rmat
ion
Male
Female
a
b b
b
c c
108
Figure 3.7 PCR assay for transgenic GUS ‘Galia’ melon male and female line plants. The
amplification product for GUS gene was 750 bp. M: 100 bp Ladder, 1: negative control (DNA from wild type melon plant), 2 and 3: DNA from ‘Galia’ male GUS positive plant, 4 and 5: DNA from ‘Galia’ female GUS positive plant, 6: positive control (DNA from GUS plasmid).
M 1 2 3 4 5 6
109
Figure 3.8 Time schedule for cotyledon and hypocotyl transformation systems in ‘Galia’
melon parental lines. A. Explant transformation B. Regeneration of transgenic shoots. C. Elongation of transgenic shoots D. Rooting E. ‘Hardening’ of seedlings.
WEEKS
Hypocotyl
B
E
C
D
A
Cotyledon
A
D
E
B
0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26
C
110
3.3.3 Summary
The goal of this work was to measure the source of the explant on regeneration and
transformation efficiency in ‘Galia’ melon parental lines. Cotyledon, hypocotyl and true-
leaves of both female and male ‘Galia’ parental lines were used for transformation. The
ABI strain of Agrobacterium tumefaciens, containing a construct harboring the GUS gene
under the constitutive 35S promoter, and a glyphosate tolerance gene under the
constitutive FMV promoter as selectable marker were used. The LBA4404 strain of
Agrobacterium tumefaciens carrying a plasmid vector harboring the GFP and NPTII
genes both under the constitutive 35S promoter was also used. Regeneration of ‘Galia’
melon parental line shoots was achieved from hypocotyls, true-leaves and cotyledons.
Hypocotyls were transformed according the protocol described in Ramirez-Malagon &
Ochoa-Alejo (1996). Cotyledons were transformed with a protocol previously developed
in our lab (Nuñez-Palenius et al. 2005a) and true-leaf explants were transformed using
the methodology of Guis et al. (2000). The greatest numbers of shoots were regenerated
from cotyledons. These explants also produced the highest number of GUS positive
shoots and roots. Using hypocotyls as explants gave the greatest number of GFP positive
roots and shoots. We were not able to obtain any transgenic shoots using either the GUS
or GFP constructs when true-leaves were used as explants. According to our results,
‘Galia’ melon parental lines are readily transformable with Agrobacterium tumefaciens
using the hypocotyl or cotyledon-protocol. It is possible to have full regenerated
transgenic plants in 3-4 months using the cotyledon-protocol, whereas at least 6-7 months
are needed when the hypocotyl-protocol is used.
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CHAPTER 4 TRANSFORMATION OF A MUSKMELON ‘GALIA’ HYBRID PARENTAL LINE
(CUCUMIS MELO L. VAR. RETICULATUS SER.) WITH AN ANTISENSE ACC OXIDASE GENE
4.1 Introduction
‘Galia’ muskmelon (Cucumis melo L.) is an Israeli melon F1 hybrid bred by Dr. Zvi
Karchi at the Newe Ya’ar research center of the Agricultural Research Organization
(A.R.O. - Israel) and released in 1973 (Karchi 2000). This cultivar has green-flesh
characteristics of the ‘Ha’Ogen’ melon cultivar, which was used as the female parent, and
netted rind from ‘Krymka’, which was used as the male parental line. It has exceptional
fruit quality with 13-15% total soluble solids (TSS), bold flavor and a distinct aroma,
leading to rapid adoption in both local and export markets. ‘Galia’ type melons have been
the mainstay in muskmelon sales in the European market for more than 30 years (Karchi,
2000). One disadvantage of ‘Galia’ is its storage life, which is limited to two to three
weeks. Timing of harvest is critical for ‘Galia’ fruit because in order to develop peak
flavor and aroma, the melon should be picked at maturity (Karchi, 2000). ‘Galia’ F1
hybrid tends to be extremely soft at and past peak fruit maturity. Traditional breeding
methods have helped breeders develop a strategy to obtain ‘Galia’ muskmelons with a
long shelf life; however, this approach can result in a loss of favorable fruit quality
characteristics.
Plant biotechnology has the potential to genetically transform plants and transfer
novel characteristics. In order for plant transformation to be successful a reliable plant in
vitro regeneration system must first be developed (Guis et al. 1998). Using
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Agrobacterium and particle-gun bombardment methods, several transgenes, which
provide different phenotypic characteristics, have been transferred into Cucumis melo
explants. These have included selectable marker and reporter genes (Fang and Grumet,
1990; Dong et al. 1991; Gaba et al. 1992; Vallés and Lasa, 1994; Gray et al. 1995;
Akasa-Kennedy et al. 2004), virus-resistance genes (Yoshioka et al. 1992; 1993; Fang
and Grumet, 1993; Gonsalves et al. 1994; Clough and Hamm, 1995), halotolerance-genes
(Bordas et al. 1997), and genes to improve fruit quality (Ayub et al. 1996; Ezura et al.
1997a; Clendennen et al. 1999; Guis et al. 2000; Shellie 2001; Silva et al. 2004).
Improved quality of Charentais type muskmelon has been achieved by inserting ACC
oxidase genes in antisense orientation in order to reduce fruit ethylene biosynthesis
(Ayub et al. 1996; Guis et al. 1997b; Silva et al. 2004).
Increasing the shelf life of ‘Galia’ F1 muskmelon by transformation of parental
lines is a feasible alternative. Unlike other melon types, such as Cantaloupe Charentais
(Ayub et al. 1996; Akasa-Kennedy et al. 2004; Silva et al. 2004), ‘Galia’ muskmelon is
not easily cultivated in vitro and complete regenerated wild type plants are especially
difficult to obtain (Leshem 1989; Leshem et al. 1994a; 1994b; Gaba et al. 1994; Gaba et
al. 1996; Edriss et al. 1996; Kintzios and Taravira 1997; Galperin et al. 2003a).
Moreover, Gaba et al. (1999) reported ‘Galia’ muskmelon to be recalcitrant to
transformation by Agrobacterium tumefaciens.
The goal of this research was to transform the male parental line (cv. ‘Krymka’) of
‘Galia’ muskmelon with the ACC oxidase (CMACO-1) antisense gene in an attempt to
delay fruit ripening.
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4.2 Materials and Methods
4.2.1 Plant Material
Coats of 50 male parental line ‘Galia’ (Cucumis melo L. var. reticulatus Ser.) cv.
‘Krymka’ seeds were removed, and the embryos surface sterilized in 1.2% sodium
hypochlorite (20% commercial bleach solution containing two drops of Tween 20™ per
100 ml) for 15 min in a sterile Erlenmeyer flask (50 ml), and washed three times with
sterilized distilled water. Embryos were then cultivated for 2 days in regeneration
medium (RM), which consisted of Murashige and Skoog salts (MS) (Murashige and
Skoog, 1962), supplemented with 30 g.L-1 sucrose, 0.1 g.L-1 myo-inositol, 0.001 g.L-1
thiamine-HCl, 0.05 mg.L-1 pyridoxine-HCl, 0.05 mg.L-1 nicotinic acid, 2 mg.L-1 glycine,
1 mg.L-1 benzyladenine (BA), 0.001 mg.L-1 α-Naphthaleneacetic acid (NAA), and 0.7
g.L-1 phytagar. Seedling growth and plant regeneration were conducted in a growth
chamber (Lab-Line Instruments, Inc. Melrose Park, IL) under 100 µmol . m-2 . s-1 light and
a 16 h photoperiod provided by cool-white fluorescent lamps and constant 25°C
temperature.
4.2.2 Plant Regeneration
Cotyledons from 2-day-old seedlings, grown aseptically in RM, were dissected and
cut transversely into four equal pieces, then placed with their abaxial side on the surface
of RM. Each cotyledon slice constituted an explant. Complete shoots were obtained de
novo from these cotyledon explants after four weeks of culture. Regeneration efficiency
was calculated as BFC index, BFC index= (average number of shoots per explant) X (%
explants forming shoots) / 100 (Martinez-Pulido et al., 1992). Shoots were excised from
cotyledon explants and incubated on elongation medium (EM), which consisted of MS
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salts, supplemented with 30 g.L-1 sucrose, 0.1 g.L-1 myo-inositol, 0.001 g.L-1 thiamine-
HCl, 0.05 mg.L-1 pyridoxine-HCl, 0.05 mg.L-1 nicotinic acid, 2 mg.L-1 glycine, 0.025
mg.L-1 BA and 0.8 g.L-1 phytagar, for three more weeks. Elongated shoots were then
transferred to rooting media consisting of ½ strength MS medium supplemented with 1
mg.L-1 indole-3-acetic acid (IAA). After three weeks of culture, shoots developed a
complete and normal root system. Rooted shoots were hardened using common practices
and then transferred to glasshouse. Plants were grown in an evaporative-cooled fan and
pad glasshouse, which maintained temperatures of 28oC day and 20oC night, in plastic
pots (11.3 L) filled with soil-less media and following common growing practices
recommended by Rodriguez and Cantliffe (2001). A complementary light regime was
supplied by MetalarcR lamps with a light intensity of 350 – 530 µmol . m-2 . s-1. The light
period was set to 18 hours per day.
4.2.3 Agrobacterium Inoculation and Plant Transformation
Agrobacterium tumefaciens strain ABI containing a binary vector, pCmACO1-AS,
harboring a selectable glyphosate resistance marker [CP4 syn gene encoding for 5-
enolpyruvylshikimate-3-phosphate synthase (EPSPS)], and the ACC oxidase (CMACO-
1) gene in antisense orientation was used (Figure 4.1). Both genes were under control of
the Figwort Mosaic Virus promoter (Richins et al. 1987) (Figure 4.1). Agrobacterium
was transferred to 5 ml of Luria-Bertani Broth (LB) medium (pH 7.5) supplemented with
25 mg . L-1 chloramphenicol, 50 mg . L-1 kanamycin, and 100 mg . L-1 spectinomycin,
and then incubated on an orbital shaker (200 rpm) for 12 hours at 25oC. Afterward, the
culture (5 ml aliquot) was then transferred to 250 ml baffled culture flask containing 50
ml liquid LB medium with the same antibiotics and concentrations previously used, and
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incubated at 25oC on an orbital shaker (150 rpm) for an additional 14-20 hours until an
A600= 0.7-1.0 was reached.
Cotyledonary explants were immersed in Agrobacterium suspension for 20-30 min
with orbital shaking (50 rpm), and then were blotted three times onto sterile filter paper
(Whatman No. 1) to remove the excess bacterial suspension. Explants were then cultured
and de novo shoots were obtained as previously described in Plant Regeneration section,
except that RM was supplemented with 50 µM Glyphosate and 150 mg.L-1 Timentin
(GlaxoSmithKline, Research Triangle Park, NC). Glyphosate selection was carried out
only on RM.
4.2.4 Flow Cytometry Analysis
Plant nuclei were freshly isolated from the 3rd leaf below the shoot apex of
acclimatized plants grown in a greenhouse. Briefly, plant material (4 cm2) was chopped
for three minutes (at 4oC) with a razor blade in a Petri dish containing 5 ml of
Quesenberry (1995) extraction buffer. The nuclei suspension was filtered through
Spectra/Mesh® nylon filter (60-�m mesh size) to remove cell debris. The nuclei-filtered
suspension was stained with propidium iodide by adding 1 ml of a propidium iodide
stock solution (1 mg.ml-1) to 2 ml of nuclei suspension. After gently stirring, the nuclei
mixture was incubated for 5 min and then analyzed by flow cytometry. DNA content of
the isolated plant nuclei was analyzed with a flow cytometry apparatus (FACScan. BD-
Biosciences, San Jose, Cal). It was calibrated using the 2C peak from nuclei of young
leaves of diploid plants derived from seed. A minimum of 10,000 nuclei were measured
for each sample.
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Figure 4.1 T-DNA region of binary vector pCmACO1-AS. The underlined fragment of CP4syn gene was used as a probe for Southern blot hybridization assay. RB: right border of T-DNA, FMV: figwort mosaic virus promoter, CP4syn: 5-enolpyruvylshikimate-3-phosphate synthase (EPSPS) gene, E9: 3’end of pea rbcSE9 terminator, CMACO-1: melon ACC oxidase gene in antisense orientation, NOS: nopaline synthase terminator, LB: left border of T-DNA.
4.2.5 Detection of Transgenes
Total DNA isolation from wild type and putative transgenic melon leaflets (0.25-
0.5 g) was performed using a modified CTAB protocol (Doyle and Doyle 1987; 1990).
The forward and reverse primers for CP4 syn gene were 5’-
CGGTGCAAGCAGCCGTCCAGC-3’ and 5’-CCTTAGTGTCGGAGAGTTCG-3’,
respectively, amplifying a fragment of 1,400 bp (1.4 Kb). The forward and reverse
primers for ACC oxidase gene were 5’-GCAATTATCCGCCGTGTC-3’ and 5’-
TCTTCAAACACAAACTTGGGG-3’, respectively. These primers will produce a 503 bp
fragment from the native (genomic) ACC oxidase gene and a 378 bp product from the
transgene. The ACC oxidase and CP4 syn fragments in total DNA were amplified under
the following conditions: a pre-incubation period at 94 oC for 7 minutes followed by 40
cycles of 94 oC for 1 min for denaturation, 60 oC for 1 min for annealing, and 72 oC for 1
min for extension, and a final extension period at 72 oC for 10 min. The amplified PCR
products (25 µl) were subjected to electrophoresis on a 1% agarose gel and visualized by
UV light.
CP4syn FMFM ERB
BamH
Probe 1.4
CMACO-1 ANTISENSE NOLB
BamH
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4.2.6 Southern Blot Analysis
Total melon DNA was isolated from young leaves of wild type and transgenic T1,
TGM-AS-1 and TGM-AS-2 lines (TGM-AS stands for Transgenic Galia Male AntiSense
line), using a modified CTAB protocol from Doyle and Doyle (1987; 1990). Twenty
micrograms of this DNA were digested overnight at 37o C with BamHI and separated by
electrophoresis in a 1.3% agarose gel. Because BamHI has one cut-site within T-DNA, a
fragment bigger than 0.398 Kb is expected for each insertion event. DNA was then
denatured and transferred to N+ Hybond membrane. The nylon membrane was
prehybridized 4 h at 42o C with constant shaking at 60 rpm, in a solution containing 50%
(v/v) formamide, 5X Denhardt’s, 1% sodium dodecyl sulfate (SDS), 5X SSPE (1X SSPE
is 15 mM NaCl, 10 mM NaH2PO4.H2O and 1 mM EDTA), and 100 µg . mL-1 denatured
salmon sperm DNA. Hybridization was carried through overnight at 42oC with constant
shaking at 60 rpm, in a solution containing 50% (v/v) formamide, 5X Denhardt’s, 1%
sodium dodecyl sulfate (SDS), 5X SSPE, and 100 µg . mL-1 denatured salmon sperm
DNA plus 1 X 106 cpm.ml-1 denatured 32P-labeled 1.4 Kb PCR-product from CP4 syn
gene. All further washes were performed with constant shaking at 60 rpm. Membranes
were first washed in a solution containing 2X SSPE, 0.05% sarkosyl and 0.01% sodium
pyrophosphate at 42oC during 20 min. The second wash was performed in a solution
containing 2X SSPE, 0.05% sarkosyl and 0.01% sodium pyrophosphate at 65oC for 20
min. The third and last (fourth) washes were carried out in a solution containing 0.1 X
SSPE, 0.05% sarkosyl and 0.01% sodium pyrophosphate for 20 min at 65oC. Membranes
were exposed to Kodak BIOMAX MR Film at -80oC for 3-5 days.
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4.2.7 Segregation Analysis of Transgenes in Primary Transformants
In order to analyze the segregation pattern of transgenes, 62 randomly selected T1
seedlings of TGM-AS-1 and TGM-AS-2 transgenic lines of ‘Galia’ male parental line
were evaluated. DNA was extracted at least three times from each individual seedling
according to the modified CTAB protocol (Doyle and Doyle 1987; 1990). A PCR assay
with specific primers for CMACO-1 and CP4 syn genes was performed for each DNA
sample as described above for transgene detection.
4.3 Results and Discussion
4.3.1 Transformation Efficiency
A total of six experiments of transformation were completed, under a CR design,
using the vector pCmACO1-AS. Glyphosate selection was not completely efficient,
because several “escapes” were detected by PCR assays. In addition, these PCR assays
aided in detecting the presence of CP4 syn and CMACO-1 antisense genes (Figure 4.2).
We were able to observe the presence of 1.4, 0.5, and 0.3 kb fragments that belong to the
CP4 syn, the native ACC oxidase and the engineered ACC oxidase genes, respectively.
Using the cotyledon-protocol and the CMACO-1 construct, the individual
transformation efficiency for each experiment, assessed by PCR, ranged between 7.5%
and 12.5% (Table 4.1). Similar transformation efficiency rates (9.5%) were obtained for
muskmelon cv. ‘Krymka’ using another independent transformation system, such as the
GUS reporter gene (Figure 4.4). This transformation efficiency obtained for ‘Galia’ male
parental line is one of the highest reported for any Cucumis melo transformation protocol
(Fang and Grumet, 1990; Dong et al. 1991; Gaba et al. 1992; Gonsalves et al. 1994;
Bordas et al. 1997; Guis et al. 2000; Akasaka-Kennedy et al. 2004). This high
transformation efficiency could be the result of a combination of factors such as
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Agrobacterium tumefaciens strain, selectable marker, and construct used (Hellens and
Mullineaux 2000; Febres et al. 2003), which may have provided the right conditions to
accomplish these positive results.
Figure 4.2 PCR assay for putative transgenic ‘Galia’ muskmelon male line plants. The
amplification product for CP4syn, native ACO-1, and engineered ACO-1 genes were 1.4 Kb, 0.5 Kb, and 0.3 Kb, respectively. M: HyperLadder (Bioline), 1 through 6: putative transgenic plants, 7: DNA from positive plant, 8: DNA from negative plant, 9: PCR reaction mixture.
Transgenic explants had an epinastic response while they were growing in vitro on
Glyphosate selection (Figure 4.5). However, this abnormality was not observed once
transgenic shoots were rooted and transferred to ex vitro conditions. Glyphosate is a
strong herbicide. It is able to induce ‘stress’ responses even in Glyphosate-tolerant
M 1 2 3 4 5 6 7 8 9 M
1.4 Kb
0.5 Kb
0.3 Kb
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Table 4.1 Transformation efficiency of ‘Galia’ male parental line with CMACO-1 antisense construct.
Number of explants zBFC yPCR+ plants % of efficiency
120 0.18 12 ± 3x 10 ± 2.5
Data are the average of six different experiments, each one with 120 explants. zBFC = bud forming capacity index (average number of shoots per explant) X (% explants forming shoots) / 100. (Martinez-Pulido et al. 1992). yPCR+ = Polymerase chain reaction positive for transgenes. xMean value plus-minus standard error. plants (Saroha et al. 1998; Raymer and Grey, 2003). Also, it is well known that ethylene
is a plant hormone related to ‘stress responses’ (Klee and Clark, 2002). Therefore, it is
plausible that epinastic phenotype was induced by Glyphosate. A similar response was
observed in positive explants for β-D-glucuronidase gene (GUS) growing on Glyphosate
as well (Nunez-Palenius et al. unpublished results).
In summary, transgenic shoots were obtained by using Glyphosate as a selectable
agent and were identified by means of PCR assay. This PCR system also allows us to
identify those shoots which were non-transgenic.
4.3.2 Ploidy Level of Primary Regenerants
Melon plants regenerated through plant tissue culture methodologies are very
susceptible to increases in ploidy level while they are in vitro cultivated (Bouabdallah
and Branchard, 1986; Fassuliotis and Nelson, 1992; Ezura et al. 1992a; 1992b;
Debeaujon and Branchard, 1992; Kathal et al. 1992; Ezura and Oosawa, 1994a; Ezura et
al. 1994; Guis et al. 1998). Therefore, flow cytometry analyses were performed to
determine the ploidy level of primary regenerants. Young leaves from all in vitro
transgenic regenerated plants and also from wild-type plants obtained from seed were
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Figure 4.3 Stable expression of β-D-Glucuronidase (GUS) gene in T0 shoots (A and B)
and roots (C and D) of ‘Galia’ muskmelon male parental line.
used. This was done with the aim of discarding any triploid, aneuploid, and tetraploid or
mixoploid plants. Based on these analyses, only diploid plants were used in subsequent
experiments.
Unexpectedly, some leaves from plants obtained from seeds resulted as tetraploids.
This condition has been reported in melon plants field conditions as well (Nugent and
Ray, 1992). In Arabidopsis it has been described that ethylene and gibberellins might
have an important role in inducing the cellular endoreduplication process, which leads to
A
B
C
D
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Figure 4.4 Transgenic (left) and non-transgenic (right) in vitro ‘Galia’ male line explants.
Transgenic explants, growing on 50 µM Glyphosate, had curled leaves and shorter internodes than wild type.
an increase in ploidy level (Kondorosi et al. 2000). Figure 4.6 depicts charts for wild-type
diploid and tetraploid plants, as well as transgenic diploid and tetraploid plants. In Figure
4.6a, nuclei sample was obtained from the 3rd leaf below shoot apex (diploid), whereas
nuclei in Figure 4.6b were obtained from shoot re-growth from the plant base (4th and 5th
node distal to the cotyledonary-leaf). For subsequent experiments using flow cytometry
analysis, all leaf samples were harvested from the 3rd leaf below shoot apex. In Figure
4.7a and 4.7b, a transgenic diploid and tetraploid plant is shown. Using flow cytometry
analysis it was found that only 20% of the transgenic plants were diploid. This number of
diploid melon plants attained through in vitro culture is lower compared with results
previously reported (Guis et al. 2000; Curuk et al. 2003). This is because our system is
based on using cotyledons as explants, which is a tissue with high propensity to bear
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tetraploid cells since the mature seed stage in cucurbits (Colijn-Hooymans et al. 1994).
After an entire flow cytometry evaluation (at least seven leaves from different nodes) of
all transgenic regenerants, two completely diploid independent transgenic plants were
selected, which were named as TGM-AS-1 and TGM-AS-2. Plants that were PCR
positive and completely diploid were advanced to the next generation by selfing.
4.3.3 Southen Blot Analysis
The presence of the introduced CP4 syn gene in T1 plants, both TGM-1 and TGM-2
lines, was established by genomic Southern blot analysis (Figure 4.8). Likewise, this
assay allowed determining the copy number of the transgene insertion. The 32P-labeled
1.4 Kb PCR-product from CP4 syn gene used as a probe hybridized with a single BamHI-
released fragment of genomic DNA isolated from three individual T1 plants from TGM-1
(Figure 4.8B, lanes five, six and seven) and three individual T1 plants from TGM-2 lines
(Figure 4.8B, lanes one, two and four). These data indicated that a single copy of the T-
DNA was incorporated into the ‘Galia’ male parental line genome in TGM-AS-1 and
TGM-AS-2 lines. There was no hybridization signal in any non-PCR positive T1 plants
(Figure 4.8B, Lanes 3 and 8).
4.3.4 Transgene Inheritance in the T1 Progenies of Primary Transformants
On a population of 62 T1 plants randomly chosen from each transgenic line (TGM-
AS-1 and TGM-AS-2), DNA was extracted individually, at least three times, to
determine the transgene distribution inheritance pattern. PCR analysis of the progeny of
TGM-AS-1 and TGM-AS-2 using CP4 syn- and ACO-antisense specific primers revealed
segregation for the presence and absence of both CP4 syn and ACO-antisense fragments.
This observed distribution of the ACO-antisense and CP4 syn genes was consistent with
a 3:1 ratio (X2 value for TGM-AS-1 and TGM-AS-2 was 0.193 and 0.021, with a
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probability of 66% and 88%, respectively), which corresponded to the segregation of one
single copy insertion of T-DNA. This conclusion is supported by the Southern blot
analysis results as well
4.4.1 Conclusion
We have successfully transformed a parental line of ‘Galia’ hybrid muskmelon
with a gene of interest and obtained two completely diploid transgenic regenerants.
Analysis of T1 progenies from TGM-AS-1 and TGM-AS-2 by segregation and Southern
blot revealed that both transgenic lines had a single T-DNA insertion.
Preliminary analysis of the transgenic fruits from ACO-1 antisense male line plants
has revealed that these fruits produced less ethylene and have a lower ACC oxidase
activity in vivo than their wild type counterpart.
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A
B
Figure 4.5 Flow cytometry analysis of propidium iodide-stained nuclei from wild type leaf tissue of ‘Galia’ male parental line. 10,000 individual nuclei were measured for each sample. (A) wild-type plant having most of nuclei (55%) at diploid level (M1). (B) wild-type plant having most of nuclei (51%) at tetraploid level (M2).
Fluorescence intensity (arbitrary units)
WT
0
800 M2 M3
M1
1 600
Num
ber
of n
ucle
i
0 200 400 600 800
Fluorescence intensity (arbitrary units)
0 200 400 600 800 1000
Num
ber
of n
ucle
i
WT
0
800
M1
M2
M3
1 600
1000
126
A
B
Figure 4.6 Flow cytometry analysis of propidium iodide-stained nuclei from transgenic leaf tissue of ‘Galia’ male parental line. 10,000 individual nuclei were measured for each sample. (A) transgenic plant having most of nuclei (64%) at diploid level (M1). (B) transgenic plant having most of nuclei (58%) at tetraploid level (M2).
Fluorescence intensity (arbitrary units)
Num
ber
of n
ucle
i
PCR+ # 2
0 200 400 600 800 0
800
M1
MM3
1 600 N
umbe
r of
nuc
lei
PCR+ # 11
0 200 400 600 800 0
1 600
800
M1
M2
M3
1000
Fluorescence intensity (arbitrary units)
1000
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A B
Figure 4.7 Southern blot hybridization assay of male muskmelon transgenic plants. (A) Total genomic DNA (20 µg) extracted from leaves of T1 plants was digested and electrophoresed according to Material and Methods section. M: HyperLadder (Bioline), WT: wild type ‘Galia’ male plant. 1 through 4: T1 plants from T0 TGM-AS-2 line. 5 through 8: T1 plants from T0 TGM-1 line. (B) Southern blot hybridization assay for BamHI-digested genomic DNA. 1, 2 and 4: PCR-positive T1 plants of T0 TGM-AS-2 line. 3: PCR-negative T1 plant of T0 TGM-AS-2 line. 5, 6 and 7: PCR-positive T1 plants of T0 TGM-AS-1 line, 8: PCR-negative T1 plant of T0 TGM-1 line.
4.5.1 Summary
‘Galia’ muskmelon (Cucumis melo L. var. reticulatus Ser.) has been recalcitrant to
transformation by Agrobacterium tumefaciens. Transformation of the ‘Galia’ male
parental line with an ACC oxidase (CMACO-1) gene in antisense orientation is described
herein. Explants were transformed using Agrobacterium tumefaciens strain ABI, which
contained a vector pCmACO1-AS plasmid, bearing an antisense gene of CMACO-1 and
the CP4 syn gene (glyphosate-tolerance). Both CMACO-1 and CP4 syn genes were
assessed by a polymerase chain reaction method. Flow cytometry analysis was performed
M WT 1 2 3 4 5 6 7 8 M
Kb 5.0 4.0 3.0 2.5 2.0
M WT 1 2 3 4 5 6 7 8 M
128
to determine plant ploidy level of primary transformants. Two completely diploid
independent transgenic plants were obtained. Southern blot and segregation analysis in
the T1 generation determined that each independent transgenic line had one single
insertion of the transgene. These transgenic muskmelon male parental lines have potential
for use in the production of ‘Galia’ F1 hybrids with improved shelf life.
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CHAPTER 5 EMBRYO-RESCUE CULTURE IN ‘GALIA’ MALE PARENTAL LINE MELON
(CUCUMIS MELO L. VAR. RETICULATUS SER.)
5.1 Introduction
As part of specific hybridization and breeding programs, crosses between distant
elite-plant genotypes sometimes fail to produce a complete embryo inside the seed, due to
embryo abortion during the process of embryogenesis. In other cases, even though the
embryo is formed, the seed fails to germinate and grow. Several embryo rescue
techniques, such as ovule, ovary and embryo culture, have been applied to save valuable
dicot and monocot plant materials (Bridgen, 1994; Brown et al. 1997; Kumlehn et al.
1997; 1998; 1999; Momotaz et al. 1998; Sukno et al. 1999; Chrungu et al. 1999;
Ramming et al. 2000; Kato et al. 2001; Ishikawa et al. 2001; Ribeiro and Giordano, 2001;
Yamada 2001; Faure et al. 2002a; 2002b; 2002c). These embryo rescue techniques have
also been useful to enhance hybridization, reduce generation time of elite germplasm, and
obtain valuable haploid plants in many crops such as onion (Martinez et al. 1997), wheat
(Xynias et al. 2001), maize (Weymann et al. 1993), potato (Eijlander et al. 1994),
sunflower (Faure et al. 2002b; 2002c), rice (Alemanno and Guiderdoni, 1994), melon
(Lotfi et al. 2003), squash (Metwally et al. 1998a; 1998b), and barley (Hoekstra et al.
1992). Not all attempts to obtain plant material through embryo rescue have been
successful; embryos generally failed to undergo complete differentiation (Dryanovska
and Ilieva, 1983; Shail and Robinson, 1987; Marcellan and Camadro, 2000; de Oliveira
et al. 2003).
130
In cucurbits, embryo rescue techniques have recovered normal seedlings from
anther, ovule, and zygotic-embryo cultures to obtain interspecific hybrids or dihaploid
lines (Lazarte and Sasser 1982; Shail and Robinson, 1987; Metwally et al. 1998a; 1998b;
Chen et al. 1997; Chen et al. 2002; Gemes-Juhasz et al. 2002; de Oliveira et al. 2003;
Sisko et al. 2003; Lotfi et al. 2003; Chen et al. 2003). Similar to other plant species,
embryo-rescue culture for cucurbits is affected by genotype (Malepszy et al. 1998;
Mackiewicz et al. 1998; Lotfi et al. 2003), formulation of media culture (Malepszy et al.
1998; de Oliveira et al. 2003 ), plant hormone-type and -dosage included into the media
(Beharav and Cohen, 1995a; 1995b; Metwally et al. 1998b), environmental factors such
as temperature and light (Metwally et al. 1998a; Gémes-Juhász et al. 2002), components
added to the media such as carbohydrate source (Metwally et al. 1998b), and embryo-
developmental stage at the time of explant isolation (Ezura et al. 1994a; 1994b; Beharav
and Cohen, 1995).
Because of these factors which affect efficiency rate of embryo culture, conditions
need to be predetermined for success with specific germplasm. This paper describes an
improved procedure for recovery of normal seedlings from wild type and transgenic
‘Galia’ muskmelon male parental line zygotic-embryos. Results are presented on the
influence of six new supplements for E-20A basic medium (Sauton and Dumax de Vaulx,
1987), five different fruit harvesting dates and two embryo-inoculation methods for plant
materials for which no information on embryo rescue exists.
5.2 Materials and Methods
5.2.1 Plant Material
Transgenic muskmelon plants with an ACC oxidase gene in antisense orientation
were obtained using the protocol previously described (Nunez-Palenius et al. 2005a).
131
Mature seeds of wild type and transgenic (ACC oxidase antisense) ‘Galia’ (Cucumis melo
L. var. reticulatus Ser.) male parental line were germinated on a mixture of 70% Terra
Lite Plug Mix (Terra Asgrow, Apopka, FL) and 30% coarse vermiculite in polystyrene
flats (cell size 2.25 cm2 and 164 cells per flat, Speedling, Bushnell, FL). Seedlings were
grown under drip fertigation in plastic pots (11.3 L) filled with soil-less media (coarse-
grade perlite) in an evaporative-cooled fan and pad glasshouse, with temperatures
maintained at 28oC day and 20oC night. Growing practices were those recommended by
Rodriguez and Cantliffe (2001). An integrated pest management program (IPM) was used
to control pests (http://www.hos.ufl.edu/protectedag/). A complementary light regime (18
h) was supplied by MetalarcR lamps (Osram Sylvania, Inc.) with a light intensity of 350 –
530 µmol . m-2 . s-1. Hermaphrodite flowers were isolated from foreign pollen with a
twist-tie band in the evening, one day before anthesis, and pollinated by hand on the next
morning (7:00-10:00 AM) using at least three male flowers. Stigmas were covered with a
gelatin capsule (Capsuline ™ size 1, Capsuline, Inc. Pompano Beach, FL) after
pollination to avoid excessive pollen dehydration.
5.2.2 Embryo Culture
Wild type and transgenic fruits were harvested at 4, 10, 17, 24 and 30 days after
pollination (DAP) in the morning (6:00 AM), and taken to the lab for subsequent rescue
procedures. The surface of the fruit was thoroughly washed with liquid detergent (5%
Liqui-Nox®), rinsed with tap water, and at room temperature. Washed fruits were then
surface-sterilized with 70% ethanol for 10 min, followed by a 40-min soak in 1.2%
sodium hypochlorite (20% commercial bleach solution containing two drops of Tween
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20™ per 100 ml) in a sterile beaker. Fruits were then rinsed three times with sterilized
distilled water under axenic conditions in a laminar-flow cabinet.
In fruits harvested 4 and 10 DAP, seeds were aseptically dissected from wild type
and transgenic fruits using a stereomicroscope. For 17, 24 and 30 DAP-fruits, seeds were
large enough to be visually dissected. Excised seeds were kept in 9% sterile sucrose
solution during the process (Ondrej et al. 2002). Embryos were excised from seeds 17, 24
and 30 DAP using a stereomicroscope. Intact seeds and embryos were cultured
immediately in 100X15-mm Petri dishes containing either E-20A (Table 5.1) or E-21
media [E-20A medium supplemented with 5% coconut water, 0.02 mg.L-1 xylose, 1
mg.L-1 glutamine, 0.25 mM putrescine, 0.01 mg.L-1 indole-3-butyric acid (IBA), and 0.01
mg.L-1 6-benzylaminopurine (BA)]. Two inoculation systems were used to culture the
embryos. In one system, immature embryos were excised only from seeds 17, 24 and 30
DAP and directly placed on either E-20A or E-21 media. In the other system (intact
seed), immature embryos from seeds 4, 10, 17, 24 and 30 DAP were not removed from
the seeds but left to develop, by directly placing the whole seed in the Petri dish with the
hilum facing the medium.
Cultures were incubated for 35 days in a growth chamber (Lab-Line Instruments,
Inc. Melrose Park, IL) in dark and constant 25±1°C temperature. After the incubation
period, plant material was transferred to maturation medium (½ strength E-21 medium
supplemented with 0.7% phytagar) and cultured between 2 to 5 more weeks under 100
µmol . m-2 . s-1 light and a 16 h photoperiod provided by cool-white fluorescent lamps and
constant 25±1°C temperature. Well-developed seedlings (cotyledonary stage) were
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Table 5.1 Components of E-20A nutrient medium. Macroelements (mg.L-1) Microelements (mg.L-1)
KNO3 1,075.0 MnSO4 11.065
NH4NO3 619.0 ZnSO4.7H20 1.812
MgSO4.7H2O 206.0 H3BO3 1.575
CaCl2.2H2O 156.5 KI 0.345
KH2PO4 71.0 Na2Mo4.2H2O 0.094
Ca(NO3)2.4H2O 25.0 CuSO4
.5H2O 0.008
NaH2PO4.4H2O 19.0 CoCl2
.6H2O 0.008
(NH4)2SO4 17.0 Na2EDTA 37.3
KCl 3.5 FeSO4.7H2O 27.8
Organics (mg.L-1)
Plant growth regulators (mg.L-1) and
other supplements
myo-Inositol 50.300 Indole-3-acetic acid 0.01
Pyridoxine-HCl 5.500
Nicotinic acid 0.700 Sucrose (g.L) 20
Thiamine 0.600 Agar (g.L) 10
Ca-D-Pantothenate 0.500 pH 5.9
d-Biotine 0.005
Glycine 0.100
(Sauton and Dumas de Vaulx 1987).
134
transferred to soil (mixture of 70% Terra Lite Plug Mix and 30% coarse vermiculite) in
polystyrene flats of cell size 2.25 cm2 and 164 cells per flat (Speedling, Bushnell, FL),
and grown in a walking-growth chamber (250 µmol . m-2 . s-1 light and a 16 h photoperiod
provided by cool-white fluorescent lamps and constant 25±1°C temperature) until a 2-3-
true-leaf stage was reached. Seedlings were then evaluated for percent regeneration
efficiency [(No. of 2-3-true-leaf stage seedlings X 100)/No. of cultured seeds].
5.2.3 Experimental Design and Statistical Analysis
The experimental design was an incomplete factorial (2 x 2 x 2 x 5 or 3) with three
replicates, having two levels for genotype, two levels for media, two levels for
inoculation system, and five or three levels for harvesting dates. Original data was
transformed by the arcsine square root in order to be analyzed for analysis of variance
(ANOVA). Means were separated by Tukey’s Studentized Range Test at P≤ 0.05 (SAS
Institute, Cary, N.C.).
5.3 Results and Discussion
5.3.1 Embryo Development
Seeds were isolated from wild type and transgenic ‘Galia’ male parental line fruits,
which were harvested at 4, 10, 17, 24, and 30 DAP. Due to small embryo size at 4 and 10
DAP, it was not possible to dissect the embryos from seeds harvested on that stage, only
intact seeds were cultured for those dates (Figure 5.1 and 5.2). Embryos, inside of intact
seed at 4 or 10 DAP stage, underwent normal development after being cultured with the
hilum facing either E-20A or E-21 media (Figures 5.1 and 5.2). It has been reported that
culture of intact ovules, avoids embryo damage during dissection (Monnier, 1976,
Thomas, 1976, Momotaz et al., 1998). After one week of culture, embryos from intact
seeds 4 DAP became green and elongated forming the torpedo stage of development
135
(Figure 5.1.c.B). After three more weeks of culture, an immature seedling with apical and
radical meristems was observed (Figure 5.1.c.E). These seedlings formed normal plants
(2-3-true-leaf stage) after the following steps: one more subculture on either E-20A or E-
21 media for two weeks then culture on maturation medium for three weeks and finally
transferred to soil. More than 12 weeks were needed to obtain complete wild type and
transgenic ‘Galia’ male parental line plants using seeds from 4 DAP fruits.
A similar development pattern was observed when intact seeds from fruits 10 DAP
were cultured on E-20A and E-21 media (Figure 5.2). However, the period to obtain full
seedlings was shorter than it was for 4 DAP-intact seeds. After one week of culture on
either E-20A or E-21 media, embryos became green and developed primordial cotyledons
(Figure 5.2.c). Two weeks later, the immature seedling had developed a normal root,
bearing root hairs, and had an apical meristem (Figure 5.2.d). At this stage, embryos
could be transferred to maturation media for further development (Figure 5.2.e).
Complete muskmelon ‘Galia’ male parental plants were obtained in 9 weeks after seeds
were dissected from 10 DAP fruits.
Embryos from fruits 17, 24 and 30 DAP were at different developmental stages and
had diverse sizes (Figures 5.3.b, 5.4.c and 5.4.f). Two inoculation systems were applied
for these embryos: excising the embryo from the seed and placing it directly on culture
media or leaving the immature embryo inside the seed (intact seed) and culturing those
seeds with the hilum facing the media (Figure 5.3.c). Using both inoculation systems,
complete and normal wild type and transgenic ‘Galia’ male parental line plants were
obtained after 4-5 weeks of in vitro culture (Figure 5.5).
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Figure 5.1 ‘Galia’ male parental line fruit at 4 DAP stage (a and b). (c) in vitro embryo
development from 4 DAP stage. A, B, C, D and E are stages after 0, 7, 15, 20 and 27 days, respectively, of in vitro culture.
5.3.2 Regeneration Efficiency
The regeneration efficiency of wild type and transgenic ‘Galia’ male muskmelon
embryos was affected by media, DAP, and inoculation system used (Table 5.2). Greater
regeneration efficiency levels were obtained when embryos or intact seeds from both
genotypes were cultured on E-21 medium than on E-20A medium (Figure 5.6 and 5.7).
These differences were significant (Table 5.3) and observed independently of DAP or
inoculation system used; i.e. wild type-30 DAP-intact seed on E-20A had a regeneration
efficiency of 50.1%, whereas the regeneration efficiency for wild-type-30 DAP-intact
seed on E-21 was more than 90% (Table 5.2).
a
b c
BA D C E
10 mm
10 mm
1 mm
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Figure 5.2 ‘Galia’ male parental line fruit at 10 DAP stage (a). In vitro embryo
development from 10 DAP stage, (b), (c), (d) and (e) are stages after 0, 7, 21 and 30 days, respectively, of in vitro culture. (b) Embryo (yellow circle) and seed coat (yellow arrow). (c) Embryo (red circle) and seed coat (red arrow). (c) Seedlings growing on elongation media.
It has been reported that more developed embryos are easier to rescue than embryos
from earlier developmental phases (Liu et al. 1993; Ondrej and Navratilova 2000).
Developed embryos may require fewer nutrients and hormones, and a lower osmotic
potential to fully develop (Ondrej and Navratilova 2000; Ondrej et al. 2002). A similar
a
b c
d e
10 mm
1 mm
5 mm
1 mm
138
pattern, regarding that older embryos are easier to rescue than younger ones, was
observed when embryos and intact seeds were obtained from fruits harvested on different
dates (Figure 5.6 and 5.7).
Figure 5.3 ‘Galia’ male parental line fruit at 17 DAP stage (a). In vitro embryo
development from 17 DAP stage, (b) yellow circle encloses the embryo, (c) inoculated seeds (without dissecting the embryo) with the hilum facing the culture medium, (d) testa removal from seeds after 15 days of in vitro culture, (e) seedlings after one week of testa removal.
b
a
c
d
10 mm
1 mm
e
139
Figure 5.4 ‘Galia’ male parental line fruit (a and b) and embryo (c) at 24 DAP stage.
‘Galia’ male parental line fruit (d and e) and embryo (f) at 30 DAP stage.
Indeed, the efficiency of this technique was greater when the time after pollination (4, 10,
17, 24 and 30 DAP) to rescue the embryos was increased (Table 5.4).
Regeneration efficiency between inoculation systems (intact seed and embryo
removed) was different (Figure 5.6 and 5.7). Firstly, unlike embryo removed system,
using the intact seed method is possible to rescue embryos from earlier stages such as 4
and 10 DAP. Secondly, the greatest amount of plants (90%) was regenerated through the
intact seed method (Figure 5.6B). Thirdly, significant differences were observed between
both inoculation systems (Table 5.5). Thus, a greater quantity of plants can be obtained in
a shorter period of time if the embryo is left inside the seed coat.
It has been reported that plant genotype can have a profound effect on the
efficiency of plant regeneration systems, and it is an important factor in establishing cell
selection and genetic transformation protocols (Machii et al. 1998; Yamada, 2001; Faure
et al. 2002c; El-Itriby et al. 2003). Therefore, plant tissue culture methods which have the
a b c
d e f
140
Figure 5.5 Normal ‘Galia’ male parental line seedlings obtained from embryo rescue,
having well-developed cotyledonary (red arrows) and true leaves (blue arrows). These plants were attained from 4, 10, 17, 24 and 30 DAP stage embryos.
capability to support sustainable growth disregarding plant genotype are considered
important tools. Similar regeneration efficiency levels on either media were attained
when wild type and transgenic ‘Galia’ male parental line embryos were cultured. Thus,
the presence of the transgene did not have any effect on regeneration efficiency values. It
might be interesting to test more GMO-melon genotypes on this improved E-21 medium.
141
Table 5.2 Regeneration efficiency of ‘Galia’ male parental line immature embryos that underwent development to form normal plants.
Media DAPz Inoculation
systemy (IS)
Wild type
(%)
Transgenic
(%)
E-20A 4 A 4.0 4.0
B NDx ND
10 A 36.9 41.5
B ND ND
17 A 53.9 45.2
B 29.6 32.7
24 A 53.1 54.0
B 34.5 44.5
30 A 50.1 51.5
B 49.7 47.1
E-21 4 A 8.8 7.3
B ND ND
10 A 48.8 53.9
B ND ND
17 A 80.6 87.1
B 54.1 53.3
24 A 90.8 90.4
B 62.1 61.4
30 A 92.3 94.0
B 66.4 69.3
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Table 5.2 Continued. Factorial treatments
Media * DAP *
Genotype NS IS *
Media x Genotype * Media x DAP *
Media x IS * Genotype x DAP *
Genotype x IS NS IS x DAP *
Media x Genotype x DAP * Media x Genotype x IS *
Genotype x DAP x IS * Media x DAP x IS *
Media x Genotype x DAP x IS *
zDAP) days after pollination. yA) intact seed, B) embryo removed from seed. xND) non-determined. NS, *Non-significant or significant, respectively, by Tukey’s Studentized Range Test at P≤ 0.05.
The described improved medium (E-21) and protocol (direct inoculation with the
hilum facing the medium) proved to be efficient in regenerating healthy seedlings from
wild type and transgenic immature ‘Galia’ male parental line embryos. One novelty of E-
21 medium is the amendment with putrescine (polyamine) to rescue embryos from
cucurbit seeds (melon). Putrescine has been used in other plant species, such as grape,
where adding 2 mM putrescine to media culture was able to significantly increase the
percentage of rescued embryos and normal plants (Ponce et al 2002a; 2002b). It is known
that polyamines are active regulators of plant growth and have the ability to interact
synergistic with plant hormones (Srivastava 2002; Bais and Ravishankar 2002; 2003).
143
Figure 5.6 Percentage of ‘Galia’ male parental line immature embryos that developed to
form normal plants. Complete seeds were directly inoculated with the hilum facing either E-20A (A) or E-21 (B) medium. Lines on bars are SE.
0.0
10.0
20.0
30.0
40.0
50.0
60.0
70.0
80.0
90.0
100.0
4 DAP 10 DAP 17 DAP 24 DAP 30 DAP
% re
gene
ratio
n ef
ficie
ncy
W.T.PCR+
0.0
10.0
20.0
30.0
40.0
50.0
60.0
70.0
80.0
90.0
100.0
4 DAP 10 DAP 17 DAP 24 DAP 30 DAP
% re
gene
ratio
n ef
ficie
ncy
W.T.PCR+
A
B
144
Figure 5.7 Percentage of ‘Galia’ male parental line immature embryos that developed to
form normal plants. Immature embryos were dissected and inoculated on either E-20A (A) or E-21 (B) medium. Lines on bars are SE.
0.0
10.0
20.0
30.0
40.0
50.0
60.0
70.0
80.0
90.0
100.0
17 DAP 24 DAP 30 DAP
% r
egen
erat
ion
effic
ienc
y
W.T.PCR+
0.0
10.0
20.0
30.0
40.0
50.0
60.0
70.0
80.0
90.0
100.0
17 DAP 24 DAP 30 DAP
% re
gene
ratio
n ef
ficie
ncy
W.T.PCR+
A
B
145
Table 5.3 Regeneration efficiency of ‘Galia’ male parental embryos cultured on two different media.
Media Regeneration efficiency (%)
E-20A 37.8 b
E-21 65.3 az
zMean separation by Tukey’s Studentized Range Test at P≤ 0.05.
Table 5.4 Regeneration efficiency of ‘Galia’ male parental embryos depending on harvesting dates.
DAP harvesting dates Regeneration efficiency (%)
4 5.5dz
10 45.2c
17 55.4b
24 63.0a
30 67.3a
zMean separation by Tukey’s Studentized Range Test at P≤ 0.05.
Table 5.5 Regeneration efficiency of ‘Galia’ male parental embryos depending on inoculation system (IS).
Inoculation system Regeneration efficiency (%)
Intact seed 70.3 az
Embryo removed 50.4 b
zMean separation by Tukey’s Studentized Range Test at P≤ 0.05.
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In cucurbits, several regeneration rates for different zygotic embryo-rescue methods
have been reported. Values such as 9% (Fassuliotis and Nelson 1988), 37.3% (Chen et al.
1997; 2002; 2003), 9.1-74% (Metwally et al. 1998a; 1998b), 59.4% (Malepszy et al.
1998), 4.5-39.0% (Mackiewicz et al. 1998), 7.1% (Gémes-Juhász et al. 2002), 27.2%
(Ondrej et al. 2002), 28% (Sisko et al. 2003), and 66.7% (de Oliveira et al. 2003) have
been described. In Cucumis melo, regeneration rates from 0.09% to 76.8% have been
obtained (Ezura et al. 1994a; Beharav and Cohen 1995a; 1995b; Lotfi et al. 2003). The
regeneration rates (90%) obtained for melon in the present study exceeds significantly
those previously reported.
Unlike other embryo rescue methods for cucurbits, some of which require double-
layer culture with two or more different media, and several subcultures in order to
regenerate healthy and complete plants (Ondrej et al. 2002), this competent embryo-
rescue technique for melon, using only one medium culture type, can be applied to save
valuable GMO hybrid-melon embryos.
5.4 Summary
In order to obtain a reliable embryo-rescue technique for wild type and transgenic
‘Galia’ muskmelon male parental line, an improved (five new supplements) nutrient
medium (named E-21) from the E-20A basic medium (Sauton and Dumax de Vaulx,
1987), an inoculation system (removing the embryo from the seed or intact seed), and the
use of different fruit harvesting dates were evaluated. Transgenic muskmelon with the
ACC oxidase gene in antisense orientation was obtained using the protocol previously
described (Nuñez-Palenius et al. 2005a). Wild type and transgenic muskmelon plants
were grown using commercial growing practices that included pruning and training to
one vertical stem and the use of soil-less media and drip fertigation. Fruits of wild type
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and transgenic (ACC oxidase gene in antisense orientation) ‘Galia’ male parental line
were harvested at 4, 10, 17, 24 and 30 days after pollination (DAP). Subsequently, seeds
were removed from fruit under sterile conditions. These seeds were used either to dissect
the embryos or placed directly with the hilum facing E-20A or E-21 medium. Seedlings
from all treatments were transferred to E-21 elongation medium, incubated five weeks,
and transferred to soil to evaluate growth. The efficiency of this technique was greater
when the time after pollination (4, 10, 17, 24 and 30 DAP) to rescue the embryos was
increased. Therefore, 30 DAP was the best time to rescue the embryos. The number of
rescued embryos using E-21 medium was greater than E-20A basic medium. We did not
find any significant differences in survival efficiency rate between wild type and
transgenic embryos. We have obtained a competent embryo-rescue technique for wild
type and transgenic ‘Galia’ male parental line, which can be applied to rescue valuable
GMO hybrid-melon embryos.
148
CHAPTER 6 FRUIT RIPENING CHARACTERISTICS IN A TRANSGENIC ‘GALIA’ MALE
PARENTAL LINE MUSKMELON (CUCUMIS MELO L. VAR. RETICULATUS SER.)
6.1 Introduction
Melon fruit ripening is a genetically determined event that involves a series of changes
in color, texture, firmness, aroma, and flavor, making fruit scent and flavor appealing to
consumers (Lelievre et al. 1997; Jiang and Fu, 2000). Ethylene is known to regulate the
ripening of climacteric fruits, such as melon (Giovannoni, 2001). This plant hormone is
produced substantially and accumulates during the climacteric stage, which coincides with
the ripening process in melon fruits (Seymour and McGlasson, 1993; Giovannoni, 2001).
‘Galia’ F1 hybrid muskmelon (Cucumis melo L.) is a climacteric fruit, having a short storage
life, which is limited to two weeks or less, even when it is maintained in low-temperature
(8oC) storage (Karchi, 2000).
Since ethylene induces ripening of climacteric fruits, it is a potential target for control
of ripening (Ayub et al. 1996; Guis et al. 1997b; Clendennen et al. 1999; Silva et al. 2004).
Two regulatory enzymes in the ethylene biosynthesis pathway are ACC synthase (ACS) (EC
4.4.1.14) and ACC oxidase (ACO) (EC 1.4.3.-) (Seymour and McGlasson, 1993). RNA
antisense technology has permitted regulating the expression of specific genes involved in
tomato fruit ripening (Gray et al. 1992; Fray et al. 1993; Chen et al. 1996b). Targeting ACO
via antisense technology has been successfully applied to cantaloupe Charentais (cv.
‘Vedrantais’) melon fruits in order to reduce ethylene production, and as a consequence
improve fruit quality by delaying ripening and softening processes (Ayub et al. 1996; Guis et
149
al. 1997b; Silva et al. 2004). The reduction of ethylene production in these trangenic melon
fruits was 97-99%, compared to their wild type counterpart. However, this strong ethylene-
production inhibition did not delay, but rather arrested completely the ripening process in
those transgenic fruits. Therefore, a continuous ethylene treatment was needed in order to
restore fruit ripening, as observed by rind yellowing, fruit softening and activation of the
peduncle abscission zone (Ayub et al. 1996; Guis et al. 1997b; Silva et al. 2004). A similar
RNA antisense technology targeting ACO (CMACO-1) might be applied to ‘Galia’ male
parental line for use of ‘Galia’ F1 hybrids with improved shelf life.
Two completely diploid independent ACC oxidase antisense transgenic plants of
‘Galia’ inbred male parental line (TGM-AS-1 and TGM-AS-2) were previously obtained
(Nunez-Palenius et al. 2005a). Experiments were conducted to compare fruit quality
characteristics between transgenic ACC oxidase antisense (TGM-AS), azygous-AS,
transgenic GUS (T-GUS) and wild type (WT) fruits from plants grown in greenhouse
conditions. Physiological and biochemical fruit parameters, such as weight, length, width,
rind color, soluble solids, titratable acidity, pH, flesh thickness, firmness, ripening index,
seed cavity size, seed number, ACC oxidase activity in vivo and ethylene production were
measured during fruit development, specifically, at zero-, half- and full-slip developmental
stages.
6.2 Materials and Methods
6.2.1 Plant Material
‘Galia’ male parental line transgenic plants (Cucumis melo var. reticulatus cv.
‘Krymka’), harboring either an ACC oxidase antisense (CMACO-1) or uidA (GUS) gene,
were obtained by a cotyledon-protocol described in Nunez-Palenius et al. (2005). Two
independent diplod transgenic lines (TGM-AS-1 and TGM-AS-2) were attained with the
150
CMACO-1 construct, whereas a single independent diplod transgenic line (T-GUS) was
obtained using the GUS gene. In vitro non-transgenic-AS ‘escape’ seedlings were obtained
after Agrobacterium tumefaciens-mediated transformation. These plants were called
azygous-AS to emphasize the absence of the ACC oxidase antisense transgene.
In order to increase plant numbers, lateral branch cuttings from each T0 transgenic and
non-transgenic lines were rooted by exogenous application of Green Light™ (0.1% indole-3-
butyric acid) rooting hormone on severed stem bases. Ploidy was confirmed by flow
cytometry analysis according to the procedure described in Nuñez-Palenius et al. (2005a).
Only completely diploid plants were used to set fruit. Non-transformed WT, T-GUS, and
azygous-AS ‘Galia’ male parental plants were used as controls.
Plants were cultivated inside of an evaporative-cooled fan and pad glasshouse in
Gainesville, FL, 28oC day and 20oC night. Plants were grown in plastic pots (11.3 L) filled
with soil-less media (course-grade perlite) following common growing practices
recommended by Rodriguez and Cantliffe (2001). Complementary light was supplied by
MetalarcR lamps with a light intensity of 350-530 µmol m-2 s-1 for 18 hours per day. Training,
pruning, and fertigation of plants, as well as application of fungicides, were performed
according to those recommended by Rodriguez and Cantliffe (2001). An integrated pest
management program (IPM) was used to keep pests under control
(http://www.hos.ufl.edu/protectedag/).
Hermaphrodite flowers were self-pollinated by hand and tagged for date of pollination.
Only three fruits were kept on each plant. A sample of 10 fruit from wild type, azygous-AS
and T-GUS were harvested at 37, 42 and 50 days after pollination (DAP), which
corresponded to zero-, half- and full-slip developmental stages, respectively. TGM-AS-1 and
151
TGM-AS-2 fruits were harvested at 42, 50 and 56 DAP, which corresponded to zero-, half-
and full-slip developmental stages, respectively. Fruits harvested at full-slip stage were kept
on the vine by pantyhose (Figure 6.1).
6.2.2 Determination of Fruit Size
Harvested fruits were weighed, and measured for length and width. In order to avoid
microbial-ethylene production, fruits were gently brushed, washed in tap water (∼25°C),
dipped into 200 µL . L-1 chlorinated water for 60 sec and then air-dried for 12 h at room
temperature to pursue subsequent analysis.
6.2.3 Determination of Physical and Biochemical Characteristics
Rind color was measured with a Minolta Chroma Meter (Model CR-200 Minolta
Camera Co. Ltd Japan) using the Hue angle (°) parameter (Hurr and Huber, 2005). Due to
‘Galia’ muskmelon fruit does not develop a rind-yellowing uniform pattern, and in order to
have a more precise rind color assessment, four equidistant and independent point
measurements in the equatorial region of each melon fruit were taken.
Fruit firmness was measured as described by Jeong et al. (2002). Whole unpeeled fruits
were tested using an Instron Universal Testing Instrument (Model 4411-C8009, Canton, MA)
fitted with a flat-plate probe (31 mm diameter) and 50-kg load cell. After establishing zero
force contact between the probe and the equatorial zone of the fruit, the probe was driven
with a crosshead speed of 50 mm.min-1. The force was recorded at 2 mm deformation and
was performed at two equidistant points on the equatorial zone of each fruit.
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Figure 6.1 Wild type and TGM-AS ‘Galia’ male parental line fruit at 50 DAP. A) Wild type
fruits have already slipped from the vine. B) Transgenic fruit remain still attached to the vine at 50 DAP.
Each fruit was cut lengthwise from the stem-scarf towards the blossom end and the
flesh size was measured in six different points (A1, A2, B1, B2, C1 and C2) in both halves as
showed in Figure 6.2. Length, width and flesh measurements were used to calculate the seed
cavity area size by means of ellipse equation (Figure 6.2). The area of the quarter that
corresponds to the measurements A1, B1 and C1 is given by:
¼ Seed Cavity Size= X1Y2 + X2Y1
2
Where (X1Y1) correspond to the coordinates of the point P in Figure 6.2, and
X2= a-A1 and Y2= b-C1 (Figure 6.2).
Seeds were collected, washed and dried according to standard seed-harvesting
procedures (Desai et al. 1997). Empty and full seeds were separated and counted for each
fruit.
A B
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Total soluble solids (TSS), titratable acidity (TA), and pH were determined, in
triplicate, from juice obtained after the mesocarpic tissue was macerated, centrifugated
(28,000xg), and filtered through Whatman paper No.1. TSS, TA, and pH were quantificated
using a digital refractometer (Abbe Mark-10480, Buffalo, N.Y.), a Fisher-395 dispenser
connected to an electrometer (Fisher 380), and a digital pH meter (model 340, Corning,
N.Y.), respectively. TA was expressed as percent malic acid equivalents. The fruit ripening
index was calculated as the quotient between TSS and TA.
Ethylene evolution and ACC oxidase activity in vivo
Twelve hours after harvest, fruits were placed in airtight plastic containers (1 fruit per
container) (3.7 L) and sealed for 2 h at 25°C. Ethylene production for each fruit was
determined by measuring the ethylene concentration in the headspace of the containers.
Sampling for ethylene was taken through a serum stopper where 1 mL of headspace was
drawn and injected into a gas chromatograph (Hewlett Packard 5890 Series II, Avondale,
Pa.) as described in Ciardi et al. (2000). The results were expressed as µL ethylene produced
per kg of tissue per hour (µL.kg-1.h-1).
ACC oxidase activity was measured in vivo in melon mesocarpic tissue based on the
conversion of exogenous ACC to ethylene (Smith et al. 1994; Amor et al. 1998). Samples of
mesocarpic tissue were taken in triplicated with a No.5 cork-borer from the equatorial region
of the fruit. After removing the peel, 1 g of tissue, was incubated for three hours at 25°C in 3
ml reaction buffer, which contained 50 mM Tris.HCl (pH 7), 100 mM sucrose, 250 µM ACC,
and 100 µM cycloheximide (Amor et al. 1998). Boiled (95°C for 10 min) mesocarpic tissue
and reaction buffer alone were used as negative controls. After the incubation period, a 1-mL
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gas sample was taken from the head space and analyzed by gas chromatography (Ciardi et al.
2000). Negative controls always had non-detectable ACC oxidase activity.
6.2.4 Experimental Design and Statistical Analysis
A Completely Randomized Design (CRD) was used to set up the experiment. Original
data was evaluated for analysis of variance (ANOVA). Means were separated by Duncan’s
Multiple Range Test at P≤ 0.05 (SAS Institute, Cary, N.C.).
Figure 6.2 Flesh size and seed cavity size determination in ‘Galia’ male parental line fruit. Six measurements were made in both halves as indicated by A1, A2, B1, B2, C1 and C2 for flesh size.
Y2
X2
P (X1,Y1)
a
b
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6.3 Results
6.3.1 ACC Oxidase Activity In Vivo
When ‘Galia’ male parental mesocarpic tissue was incubated in the presence of
reaction buffer mixture, ACC oxidase activity was detected via quantification of ethylene
evolution. At zero-slip developmental stage, the enzyme activity in vivo was below 1 nl.g-1.h-1
for all genotypes (Figure 6.3). An increase in ACC oxidase activity was observed in WT,
azygous-AS and T-GUS mesocarpic tissue at half-slip stage. Conversely, TGM-AS-1 and
TGM-AS-2 fruit did not have that increase in ACC oxidase activity at the same
developmental stage. Indeed, expression of the ACC oxidase antisense gene in transgenic
fruits caused a reduction in ACC oxidase activity, which was four times less compared to
WT, azygous-AS and T-GUS fruit at half-slip stage (Figure 6.3). Therefore, significant
differences in ACC oxidase activity in vivo were found between ACC oxidase antisense fruit
and WT, azygous-AS and T-GUS at half-slip developmental stage (data not shown). At full-
slip stage, the lowest level of ACC oxidase activity was detected in TGM-AS-2 mesocarpic
tissue, which was significantly different to other genotypes (Figure 6.3).
6.3.2 Ethylene Production
Average ethylene production in WT, TGM-AS-1, TGM-AS-2, azygous-AS and T-GUS
fruit harvested at zero-slip stage was 7.6, 7.5, 2, 2, and 1.4 µl.kg-1.h-1, respectively (Figure
6.4). On the next developmental stage, half-slip, a substantial increase in ethylene production
was observed for WT, azygous-AS and T-GUS fruit, but not for TGM-AS-1 and TGM-AS-2
genotypes (Figure 6.4). Indeed, the ethylene production level for the ACC oxidase antisense
lines was below 7 µl.kg-1.h-1 at half-slip stage. Therefore, significant differences were
observed between ACC oxidase antisense fruit and other treatments at half-slip stage (data
not shown).
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Figure 6.3 ACC oxidase activity in vivo in WT (●), TGM-AS-1 (○), TGM-AS-2 (▼), azygous-AS (∇) and T-GUS (■) fruits. Vertical bars represent standard error of the means (n=10 fruits). Each fruit was assayed by triplicated.
TGM-AS-2 fruit always had a lower ethylene level than TGM-AS-1. A significant (P<
0.001) regression coefficient (R2=0.91) was obtained between ACC oxidase activity and
ethylene production data, supporting that both parameters are absolutely related (Figure 6.5).
Developmental stage
0 SLIP HALF SLIP FULL SLIP
AC
C o
xida
se (n
l. g-1. h-1
)
-0.5
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
WT TGM-AS-1 TGM-AS-2 Azygous-AS T-GUS
157
Figure 6.4 Ethylene production from WT (●), TGM-AS-1 (○), TGM-AS-2 (▼), azygous-AS (∇) and T-GUS (■) fruits. Vertical bars represent standard error of the means (n=10 fruits).
6.3.3 Firmness, Rind Color and TSS
In order to analyze and compare more easily fruit firmness, rind color and total soluble solids
parameters to ethylene production, the firmness data, as well as rind color and total soluble
solids data, from WT, azygous-AS and T-GUS genotypes were considered as a single
average value at zero-, half- and full-slip stages, and named it as ‘WT’.
Developmental stage
0 SLIP HALF SLIP FULL SLIP
Ethy
lene
( µl. kg
-1. h-1
)
-5
0
5
10
15
20
25
30
WTTGM-AS-1TGM-AS2Azygous-AST-GUS
158
Figure 6.5 Regression analysis between ACC oxidase activity and ethylene production in ‘Galia’ male parental fruits.
Likewise, TGM-AS-1 and TGM-AS-2 data for firmness, as well as rind color and total
soluble solids data, were regarded as one single average value at zero-, half- and full-slip
stages, and named as ‘TGM-AS’.
Ethylene production data from WT, azygous-AS and T-GUS were averaged to one
single value and considered as WT. TGM-AS-1 and TGM-AS-2 ethylene production data
were regarded as TGM-AS.
Fruit softening was observed in WT and TGM-AS during the ripening process (Figure
6.6). The maximum decrease in firmness was detected in WT fruit, which had an initial
average fruit firmness value of 52 N at zero-slip stage and the final value was below 18 N at
full-slip stage. The reduction of ethylene production in TGM-AS fruits induced a delayed
y = 7.6664x - 1.2328R2 = 0.9115
-5
0
5
10
15
20
25
30
0.00 0.50 1.00 1.50 2.00 2.50 3.00 3.50
ACC oxidase activity
Ethy
lene
pro
duct
ion
159
fruit softening process (Figure 6.6). The reduction of firmness in TGM-AS from half-slip
stage to full-slip stage was only 28% from WT displayed. At full-slip stage, the TGM-AS
firmness value was above 29 N. Therefore, significant differences were observed between
WT and TGM-AS fruits at full-slip developmental stage (Figure 6.6).
According to the color-chart (Konica-Minolta, Inc), green color has a higher Hue angle
(°) value than yellow. Similarly as most of muskmelon fruits, ‘Galia’ male parental fruit
turns from green to yellow rind color during the ripening process. In TGM-AS fruits, the Hue
angle (°) value was higher than WT at half- and full-slip developmental stage (Figure 6.7).
Significant differences between WT and TGM-AS treatments were observed at those
two stages (data not shown). Despite some ACC oxidase antisense transgenic fruits were last
harvested until full-slip stage, they did not reach a full golden-yellow color as WT (Figure
6.8). TSS content of WT and TGM-AS fruits increased along with ripening (Figure 6.9).
Therefore, higher TSS contents were found on fruits harvested at full-slip stage. No
significant differences on TSS accumulation were detected between WT and TGM-AS fruits
at any developmental stage. Although TGM-AS fruits remained a longer time attached to the
vine than WT fruits, they did not accumulate more TSS.
6.3.4 Mesocarpic Titratable Acidity, pH and Ripening Index
In contrast to TSS content, which had an increase along ripening, mesocarp TA level
had an important decrease, which took place simultaneously with the fruit ripening process
(Table 6.1). On zero-slip stage, the lower and greater TA values were observed for WT and
T-GUS fruit, respectively, although they were not significantly different. TGM-AS-2 TA
value was higher than WT, azygous-AS, T-GUS and TGM-AS-1 at full-slip stage, and it was
significantly different (Table 6.1). The regression coefficient (R2= 0.62, y= -0.037x + 0.45)
between TSS and TA had a significant value (P< 0.001).
160
Figure 6.6 Ethylene production from WT (●) and TGM-AS (○) fruits compared to firmness of WT (■) and TGM-AS (□) intact fruits. Vertical bars represent standard error of the means (n=30 fruits for WT and n= 20 for TGM-AS).
Similarly as TSS accumulation pattern, mesocarpic pH values of WT, azygous-AS, T-
GUS, TGM-AS-1, and TGM-AS-2 increased concomitantly with fruit ripening (Table 6-1).
No significant differences in mesocarpic pH values were found among all treatments at zero-,
half- and full-slip stages (Table 6.1). TA and pH were inversely related since they had a
significant (P< 0.001) regression coefficient and negative slope (R2= 0.80, y= -7.73x + 7.42).
Fruit ripening index increased in all treatments from zero-slip to full-slip
developmental stages (Table 6.1). In general, TGM-AS-2 fruits had a lower ripening index
than WT, azygous-AS, TGM-AS-1, and T-GUS counterpart. Significant differences were
Developmental stage
0 SLIP HALF SLIP FULL SLIP
Ethy
lene
( µl. kg
-1. h-1
)
0
5
10
15
20
25
30
Firm
ness
(N)
10
20
30
40
50
60
WT-Ethylene TGM-AS-Ethylene WT-Firmness TGM-AS-Firmness
161
Figure 6.7 Ethylene production from WT (●) and TGM-AS (○) fruits compared to rind color
of WT (■) and TGM-AS (□) intact fruits. Vertical bars represent standard error of the means (n=30 fruits for WT and n= 20 for TGM-AS).
only observed at full-slip developmental stage between TGM-AS-2 fruits and other
treatments (Table 6.1).
6.3.5 Determination of Fruit Size and Seed Number
Maximum average fruit weight, length and width of WT fruits occurred at full-slip
stage (Table 6.2). These measurements were the same as those from azygous-AS, T-GUS,
TGM-AS-1, and TGM-AS-2 counterparts at full-slip developmental stage (Table 6.2).
Minimum average fruit weight, length and width were observed at zero-slip stage, the
minimum weight parameter was found in WT fruits, whereas minimum length and width
were determined in TGM-AS-1 fruits. Similarly as maximum values, there were no
significant differences among minimum parameters from different plant genotypes
162
Figure 6.8 Rind color in WT (A) and TGM-AS (B) ‘Galia’ male muskmelon fruit.
Figure 6.9 Ethylene production from WT (●) and TGM-AS (○) fruits compared to TSS content of WT (■) and TGM-AS (□) intact fruits. Vertical bars represent standard error of the means (n=30 fruits for WT and n= 20 for TGM-AS).
BA
Developmental stages
0 SLIP HALF SLIP FULL SLIP
Ethy
lene
( µl. kg
-1. h-1
)
0
5
10
15
20
25
30
TSS
%
6
8
10
12
14WT-EthyleneTGM-AS-EthyleneWT-TSSTGM-AS-TSS
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Table 6.1 Postharvest fruit characteristics of ‘Galia’ male parental line. Genotype Titratable acidity (%) pH Ripening indexz
0-Slipy Half-Slip Full-Slip 0-Slip Half-Slip Full-Slip 0-Slip Half-Slip Full-Slip
Wild type 0.15 0.106 0.076b 6.2 6.5 6.9 55.5 86.9 123.3a
Azygous-AS 0.19 0.108 0.095b 5.6 6.2 6.8 38.4 81.4 103.6b
T-GUS 0.21 0.099 0.082b 6.0 6.5 6.7 40.7 88.68 113.25ab
TGM-AS-1 0.16 0.108 0.095b 6.0 6.4 6.9 48.9 86.13 102.3b
TGM-AS-2 0.17 0.102 0.103a 6.0 6.4 6.5 46.8 88.1 93.7c
Significancex nsv ns * ns ns ns ns ns *
zFruit ripening index was calculated as the quotient between total soluble solids (TSS) and titratable acidity (TA). yDevelopmental stage. xDuncan’s Multiple Range Test at P≤0.05. vns= not-significant, * significant.
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(Table 6.2). Significant (P<0.001) regression coefficients for length-width, weight-width,
and weight-length were 0.87 (y= 0.776x + 2.6), 0.56 (y= 0.0034x + 8.8) and 0.60 (y=
0.0042x + 8.1817), respectively.
The minimum value for flesh size on all treatments was recorded in TGM-AS-1 at
zero-slip stage, but, it was not significantly different from WT, azygous-AS, T-GUS, and
TGM-AS-2 data (Table 6.3). Azygous-AS fruits had the maximum value for flesh size at
full-slip stage, although it was not significant different to other treatments (Table 6.3).
The maximum value for seed cavity size was observed in TGM-AS-2 at full-slip
stage, whereas minimum seed cavity size was detected in TGM-AS-1 at zero-slip stage.
Likewise, as previously evaluated fruit parameters (weight, length, width, and flesh size)
there were no significant differences among treatments.
The production of viable and high-vigor seeds within plant breeding programs has
a paramount importance. Therefore, full and empty seeds were evaluated on each fruit for
all genotypes. The minimum percentage of full seeds (70%) from all treatments was
determined in azygous-AS fruits at half-slip stage (Table 6.3). Consequently, the greatest
percentage of empty seeds was recorded on those fruits as well. TGM-AS-2 had the
highest full seed percentage at half-slip stage. Nevertheless, no significant differences for
full seed percentage were observed among treatments on zero- half- and full-slip
developmental stages (Table 6.3).
6.4 Discussion
Fruit ripening is a genetically determined event, and considered as a highly
complex development process (Seymour and McGlasson, 1993). Fruit in general can be
classified as either climacteric or non-climacteric on the basis of their respiration pattern
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Table 6.2 Postharvest fruit characteristics of ‘Galia’ male parental line. Genotype Weight (Kg) Length (cm) Width (cm)
0-Slipz Half-Slip Full-Slip 0-Slip Half-Slip Full-Slip 0-Slip Half-Slip Full-Slip
Wild type 0.94 1.12 1.55 12.6 13.6 15.8 12.3 12.7 14.7
Azygous-AS 1.05 0.92 1.48 13.1 11.8 14.2 12.8 11.8 13.9
T-GUS 1.10 1.21 1.37 12.8 12.0 11.50 13.0 11.7 11.4
TGM-AS-1 1.05 1.24 1.39 11.5 13.3 13.6 11.5 12.9 13.5
TGM-AS-2 1.21 1.42 1.51 13.9 12.7 14.7 13.8 12.4 14.7
Significancey nsv ns ns ns ns ns ns ns ns
zDevelopmental stage. yDuncan’s Multiple Range Test at P≤0.05. vnot-significant.
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Table 6.3 Postharvest fruit characteristics of ‘Galia’ male parental line. Genotype Flesh size (cm) Seed cavity size (cm2) Full seeds (%)
0-Slipz Half-Slip Full-Slip 0-Slip Half-Slip Full-Slip 0-Slip Half-Slip Full-Slip
Wild type 3.0 3.2 3.0 29.2 34.6 46.2 85 85 84
Azygous-AS 2.9 2.9 3.6 36.8 25.3 39.1 86 70 84
T-GUS 3.2 2.9 2.9 30.8 28.6 38.1 76 89 84
TGM-AS-1 2.7 3.1 3.0 27.0 34.5 38.1 76 78 78
TGM-AS-2 3.4 3.0 3.0 37.9 31.3 49.0 83 90 79
Significancey nsv ns ns ns ns ns ns ns ns
zDevelopmental stage. yDuncan’s Multiple Range Test at P≤0.05. vnot-significant.
167
and autocatalytic ethylene production peak during ripening (Tucker, 1993). Climacteric
fruits, such as most melon varieties, have a respiratory burst and a pronounced
autocatalytic ethylene production while the ripening process is proceeding.
The use of ACC oxidase antisense transgenic Charentais melon fruit has allowed
discriminating between ethylene-dependent and –independent processes during fruit
ripening (Guis et al. 1997b; Guis et al. 1999; Flores et al. 2001a; Flores et al. 2001b;
Silva et al. 2004). Indeed, it has been suggested that yellowing of the rind, fruit softening,
volatile production, climacteric respiration, and formation of abscission layer in the
peduncule are ethylene-dependent events, while sugar accumulation, loss of acidity and
pigmentation of the flesh are ethylene-independent processes (Guis et al. 1997b; Guis et
al. 1999; Flores et al. 2001a; Flores et al. 2001b). Recently, Silva et al. (2004) suggested
that organic acid metabolism in Cantaloupe Charentais melon fruit might not be an
ethylene-independent process. However, it can not be excluded that some of those
processes involved in melon ripening might encompass ethylene-dependent and –
independent mechanisms (Guis et al. 1999), which may be active at the same time. More
research, at molecular and physiological level, is needed to address the specific role of
ethylene on melon ripening.
The edible part of most melon fruits is the mesocarpic tissue, also commonly
known as flesh (Seymour and McGlasson, 1993). Most of the consumers prefer a melon
fruit with small seed cavity, and firm, thick and colorful flesh (Yamaguchi, 1977; Artes et
al. 1993; Goldman, 2002). Due to the insertion of certain trangenes, some secondary
unwanted and/or deleterious effects on recipient plants have occurred (Birch, 1997;
Yoshida and Shinmyo, 2000; Gomez-Lim and Litz, 2004; Halford, 2004). Therefore, in
168
order to address that possibility, several postharvest quality characteristics on transgenic
ACC oxidase antisense ‘Galia’ male parental fruit were evaluated in this study.
The highest ACC oxidase in vivo activity was observed in WT, azygous-AS and T-
GUS fruits at half-slip stage. Conversely, TGM-AS-1 and TGM-AS-2 did not have an
enzyme activity peak at half-slip stage. Smith et al. (1994) reported that the presence of
ascorbate in the reaction buffer may have deleterious effect on ACC oxidase activity in
‘Galia’ F1 hybrid fruit. These authors described that the high initial rate activity declined
rapidly after 1 h of incubation if ascorbate was present in the reaction buffer; half-life of
19 min with ascorbate. The ACC oxidase reaction buffer assay utilized in the present
study was void of ascorbate in order to circumvent this. Low levels of ethylene
production by ACC oxidase antisense melon fruit can be ascribed to a considerable
reduction in ACC oxidase activity (Ayub et al. 1996; Guis et al. 1997b; Silva et al. 2004).
Certainly, ACC oxidase activity in TGM-AS-1 and TGM-AS-2 fruit was reduced by 4.0-
and 186.7-fold, respectively, compared to WT, azygous-AS and T-GUS fruit.
External ethylene production in ‘Galia’ male muskmelon fruit had a similar pattern
as mesocarpic ACC oxidase activity during ripening. WT, azygous-AS and T-GUS fruit
displayed a rapid increase in ethylene production at half-slip stage. That ethylene peak
was not present in any of the TGM-AS lines. Interestingly, ethylene production in TGM-
AS-1 fruit was always higher than TGM-AS-2 at any date of harvest. The average
ethylene production at zero-, half- and full-slip stages by TGM-AS-1 and TGM-AS-2
was 7.71 µl.kg-1.h-1 and 0.86 µl.kg-1.h-1, respectively. These differences in ethylene
production are not related to the number of T-DNA copies inserted into the melon
genome, because both transgenic lines had a single copy of the ACC oxidase antisense
169
transgene (Nunez-Palenius et al. 2005a). Rather, T-DNA insertion position effects on
transgene expression might have played some role in that different ethylene production.
T-DNA position effects have been reported in other transgenic plants (Deblock 1993;
Zhu et al. 1999; Cotsaftis et al. 2002).
It has been reported that transgenic ACC oxidase antisense Charentais melon fruit
attached to the vine, exhibited very low internal ethylene levels: <0.5 µl.L-1 (Guis et al.
1997b) and ≤0.09 µl.L-1 (Silva et al. 2004). However, after harvesting at 38 DAP, the
internal ethylene content increased up to 4 µl.L-1 (Guis et al. 1997b). These authors
described that detachment of the fruit from the vine induces an increase on fruit ethylene
production (Guis et al. 1997; Bower et al. 2002).The value reported by Guis et al.
(1997b) on internal ethylene content in detached fruit is similar to the external ethylene
production level by TGM-AS-1 fruit separated from the vine. Even though TGM-AS-2
fruits were removed from the plant, ethylene production was 99.9% less than WT,
azygous-AS and T-GUS fruit at half-slip stage. In summary, the insertion of CMACO-1
gene in antisense orientation lead to reduced ethylene production in the ‘Galia’ male
parental fruit. The average extent of reduction compared to WT, azygous-AS, and a T-
GUS fruit was 76.9% and 99.1% in TGM-AS1 and TGM-AS-2, respectively.
Fruit softening observed during ripening is associated with textural changes that are
thought to result from modification and disassembly of the primary cell wall (Fischer and
Bennett, 1991). Fruit softening and the underlying cell wall structural changes are
complex. Softening or loss of firmness of the edible mesocarp of melon fruit may start in
the middle (around 30-45 days after anthesis, depending on cultivar) of the development
170
cycle, along with other typical changes connected with the ripening process (Lester and
Dunlap, 1985).
Among the different plant hormones which are involved in melon fruit
development, ethylene might have the main role during melon fruit softening, because
this gaseous plant hormone regulates the expression of several proteins involved in the
softening process (Rose et al., 1997, 1998). According to Guis et al. (1997), Guis et al.
(1999), Flores et al. (2001a), Flores et al. (2001b), and Silva et al. (2004), fruit softening
in melon is an ethylene-dependent event. Their ACC oxidase antisense transgenic
Cantaloupe Charentais fruits had a delayed fruit softening process, compared to wild type
counterpart. A similar response was observed in ACC oxidase antisense ‘Galia’ male
parental fruits (Figure 6.6). These fruits retained a higher firmness than WT, azygous-AS
and T-GUS fruits, mainly at full-slip developmental stage, when significant differences
were detected.
Yellowing of the rind in ‘Galia F1 hybrid fruit is induced by increased chlorophyll
degradation during the ripening process, as well as a partial decrease in total carotenoids
(Flügel and Gross 1982). Likewise, chlorophyll is degraded by the action of
chlorophyllase (EC 3.1.1.14), whose de novo synthesis is ethylene regulated (Jacob-Wilk
et al. 1999). Rind color in WT, azygous-AS, and T-GUS fruits, turned from green to
golden-yellow during ripening, whilst, ACC oxidase antisense fruit did not reach a full
golden-yellow color (Figure 6.8). It seems that lower ethylene production in CMACO-1
proves this assumption correct. The antisense transgenic ‘Galia’ male fruits did not allow
complete chlorophyll degradation, leaving partial green-patches on the rind. Analogous
results were reported in ACC oxidase antisense transgenic Cantaloupe Charentais melon
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fruits (Guis et al. 1997b; Martinez-Madrid et al. 1999; Flores et al. 2001a; Flores et al.
2001b; Martinez-Madrid et al. 2002; Silva et al. 2004).
Sweetness is one of the most important edible quality attribute of ripe melon fruits
(Yamaguchi, et al., 1977; Lester and Shellie, 1992; Artes et al. 1993). The trait for sugar
accumulation in melon is controlled by a single recessive gene, called suc (Burger et al.
2002). Therefore, sucrose accumulation is controlled through several plant hormones
such as auxins and ABA, enzymes such as sucrose phosphate synthase (EC 2.4.1.14) and
acid invertase (EC 3.2.1.26), and compartmentation processes, as well as is directly
related to fruit ripening (McCollum et al. 1988; Hubbard et al. 1989; Ofosu-Anim and
Yamaki, 1994; Lee et al. 1997; Ofosu-Anim et al. 1998; Gao et al. 1999; Gao and
Schaffer, 1999; Feusi et al. 1999; Carmi et al. 2003; Volk et al. 2003). The TSS content
of WT, azygous-AS, T-GUS, TGM-AS-1 and TGM-AS-2 mesocarp increased in average
from 7.69% to 9.89% at zero- and full-slip stage, respectively. Thus, TSS accumulation
was a simultaneous event to fruit ripening and an ethylene-independent phenomenon.
Similar results have been observed in most of sweet-type melons (McCollum et al. 1988;
Seymour and McGlasson, 1993; Guis et al. 1997b; Burger et al. 2002; Burger et al. 2003;
Silva et al. 2004; Liu et al. 2004; Ergun et al. 2005)
Although TGM-AS-1 and TGM-AS-2 remained for a longer time attached to the
vine than WT, azygous-AS and T-GUS fruits, they did not accumulate more sugars.
These results on TSS content for ACC oxidase antisense transgenic fruit are similar to
results reported by Guis et al. (1997b), but dissimilar from others (Flores et al. 2001b;
Martinez-Madrid et al. 2002; Silva et al. 2004). Guis et al. (1997b) claimed that
transgenic (ACC oxidase antisense) Cantaloupe Charentais melon fruit remained attached
172
to the vine for 10 more days than its wild type counterpart, allowing the accumulation of
more sugars, and increasing the soluble solids content from ∼11.3 (wild type) to ∼12
°Brix (antisense). However, differences between wild type and transgenic Cantaloupe
Charentais melon TSS values were not significant, since their standard errors overlap (see
Figure 3A in Guis et al. 1997b). Flores et al. (2001b) and Martinez-Madrid et al. (2002)
studied biochemical and physiological fruit characteristics of some transgenic Cantaloupe
melon plants obtained from the Guis’ (1997b) T0 original line ‘B17’. These authors found
that ACC oxidase antisense fruits accumulated significantly more sugars than wild type
fruits at 40 DAP, but not at 15, 24, 35 and 37 DAP. Silva et al. (2004) developed
transgenic (ACC oxidase antisense from apple) Cantaloupe Charentais melon which were
not ripe on 38 DAA, whereas WT fruit were ripe at ∼ 30-32 DAA. The authors concluded
that as transgenic fruit remain attached ∼5-8 more days, they were able to accumulate
more TSS. Unlike Guis’ study, transgenic fruit TSS values were significantly different
from wild type fruit counterpart.
The differences on TSS accumulation between transgenic ACC oxidase antisense
‘Galia’ male parental muskmelon and transgenic ACC oxidase antisense Cantaloupe
Charentais cv. ‘Vedrantais’ fruits (Flores et al. 2001b; Martinez-Madrid et al. 2002; Silva
et al. 2004) can be ascribed to the fact that our transgenic melons belonged to variety
reticulatus, whereas transgenic melon fruits obtained by those authors correspond to
variety cantaloupensis. As it has been reported, genetic background has a profound
effect on melon fruit sugar accumulation (Seymour and McGlasson, 1993; Stepansky et
al. 1999; Burger et al. 2002; Burger et al. 2003; Liu et al. 2004). Moreover, different
plant growing environmental conditions might have played a role on fruit-TSS buildup.
173
Sugar accumulation in melon fruit is affected quantitatively by environmental and
physiological factors, such as salinity, nutrient availability, shading, cellular size in the
fruit, and available foliar area (Hubbard et al. 1990; del Amor et al. 1999; Nishizawa et
al. 2000; 2002; 2004; Kano, 2002; 2004). ACC oxidase antisense gene insertion did not
reduce or increase the fruit TSS content in any of CMACO-1 transgenic lines at fruit
maturity.
Unlike other ripe fruits, such as strawberry, pineapple and apricot, where high
organic acids content have an imperative role in developing acceptable taste for
consumers, sweet melons have a low organic acid content. Nevertheless, sensory quality
of melon fruit is also determined by organic acid levels (Sweeney et al. 1970; Yamaguchi
et al. 1977). In ‘Galia’ male parental line, TA and pH appear to be inversely related.
While TS in all treatments had a sharp decrease since the first date of harvest, pH values
started to increase steadily. Although, differences in TA and pH among all treatments
were observed, they were not significant. Similar results were obtained by Guis et al.
(1997b) and Martinez-Madrid et al. (2002). These authors reported that TA had a sharp
decrease in WT Cantaloupe Charentais melon fruit during ripening, and a similar trend
was observed in transgenic ACC oxidase antisense fruit.
Fruit ripening index calculation is commonly used as a factor to measure fruit
sensory quality, and is obtained as the quotient between the TSS content and the TA level
(Leshem et al. 1986). A similar ripening index was observed in WT, azygous-AS, T-
GUS, TGM-AS-1 and TGM-AS-2 fruits on all fruit development stages, except at full-
slip stage where significant differences were found between TGM-AS-2 and other
treatments. It has been suggested by Silva et al. (2004) that organic acid metabolism in
174
melon fruit is an ethylene-dependent process. Likewise, Flores et al. (2001b) and
Martinez-Madrid et al. (2002) reported that transgenic (ACC oxidase antisense) had a
greater ripening index than wild type Cantaloupe Charentais melon fruit. Considering that
TGM-AS-2 genotype had the lowest ethylene production level among treatments, it is
possible that this low-ethylene level in TGM-AS-2 has contributed to attain a high TA
value at full-slip stage, consequently, the lowest fruit ripening index level at full-slip
stage was observed for TGM-AS-2.
Although differences in weight, length, width, flesh size and cavity seed size were
found among WT, TGM-AS-1, TGM-AS-2, azygous-AS and T-GUS fruits, they were
not significantly different. Moreover, comparable variation in fruit weight and size has
been reported in other muskmelon cultivars (Kultur et al. 2001; Nerson et al. 2002; Liu et
al. 2004). Overall, the CMACO-1 gene single insertion in antisense orientation did not
have either a positive or negative effect on fruit size of ‘Galia’ male parental line.
Because there were not significant differences in total number of seeds, as well as
number of full seeds among treatments, it is clear that CMACO-1 gene single insertion
did not have any effect on seed development in ‘Galia’ male parental line fruit.
In summary, the results of these experiments describe that the insertion of ACC
oxidase gene in antisense orientation in ‘Galia’ male parental inbred reduced the ethylene
synthesis in TGM-AS T0 fruits. That inhibition was more evident in TGM-AS-2 than
TGM-AS-1 line. Reduced ethylene production may be a direct consequence of a low
ACC oxidase activity detected in those fruits. As a result of low ethylene production by
TGM-AS fruits, several parameters such as, yellowing of the rind, ripening index, and
fruit softening were delayed. Other traits, such as fruit size, seed development, and
175
mesocarpic total soluble solids, titratable acidity and pH were not affected by the
transgene presence. TGM-AS-1 and TGM-AS-2 T1 seeds, obtained from these T0
evaluated fruits, will be used to obtain and select future improved lines with extended
shelf-life.
6.5 Summary
‘Galia’ is a high-quality muskmelon cultivar that is grown in greenhouses or
tunnels to maximize fruit quality and yield. Maximum fruit quality and flavor are
achieved when ‘Galia’ fruits are harvested at ¾ to full-slip stage. One disadvantage of
‘Galia’ is its storage life, which is limited to two to three weeks due to rapid fruit
softening. In vitro regeneration and transformation of ‘Galia’ melon parental lines with
antisense technology, targeting enzymes involved in ethylene biosynthesis pathway, is a
feasible strategy that can be used to increase its fruit shelf-life. The male parental line of
‘Galia’ muskmelon has been transformed with two different constructs according to the
protocol described by Nunez-Palenius et al. (2005a): one plasmid was bearing the GUS
gene and another had an ACC oxidase gene (CMACO-1) in antisense orientation (Nunez-
Palenius et al. 2005a). Transgenic ACC oxidase antisense (TGM-AS), azygous-AS (PCR
negative), transgenic GUS (T-GUS) and wild type (WT) fruits, from plants grown in the
greenhouse, were harvested at zero-, half-, and full-slip developmental stage. Wild type,
azygous-AS and transgenic (both TGM-AS and T-GUS) weight, length, width, soluble
solids, pH, flesh thickness, seed cavity size, and full seed percentage parameters were not
significantly different on all fruit developmental stages. Fruit firmness from full-slip
TGM-AS was almost twice than wild type, azygous-AS and T-GUS. Ethylene production
and ACC oxidase from half-slip wild type, azygous-AS and T-GUS fruits were greater
176
than from TGM-AS fruits. TGM-AS ‘Galia’ male parental melon fruits had a delayed
fruit ripening process compared to wild type fruits.
177
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BIOGRAPHICAL SKETCH
Hector Gordon Nuñez-Palenius was born on January 19, 1962, in Guadalajara,
Jalisco state, México. He got his Master of Science degree in December, 1997 in plant
biology from the Genetic Engineering Department at the Unit of Biotechnology and Plant
Genetic Engineering in the Center of Research and Advanced Studies (CINVESTAV-
IPN. Unidad Irapuato). Afterwards, Hector G. Nuñez-Palenius started a Ph.D. program at
the University of Florida, Horticultural Sciences Department, Seed Physiology Lab. His
research focused on transformation of ‘Galia’ muskmelon to improve fruit quality,
specifically on in vitro regeneration and Agrobacterium-mediated transformation of
‘Galia’ parental lines. His future plans are to continue working in the area of
biotechnology of cucurbits, with special emphasis on genetic improvement.
.