in vitro propagation of tamarillo in rwanda, submitted by eng. rodrigue ishimwe as his research...
DESCRIPTION
iNATIONAL UNIVERSITY OF RWANDA NATIONAL UNIVERSITY OF RWANDA FACULTY OF AGRICULTURE FACULTY OF AGRICULTURE DEPARTMENT OF CROP OF CROP PRODUCTION AND DEPARTMENT PRODUCTION AND HORTICULTURE HORTICULTURE RESEARCH PROPOSALIN VITRO PROPAGATION OF TAMARILLO IN RWANDAIN VITRO PROPAGATION OF TAMARILLO IN RWANDABY BY ISHIMWE RODRIGUE ISHIMWE RODRIGUESUPERVISORS: Prof PETER YAO KANZE SALLAH SUPERVISORS: PROF PETER YAO KANZE SALLAH Dr JANE KAHIA DR JANE KAHIA20112011ii TABLE OF CONTENTSTABTRANSCRIPT
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NATIONAL UNIVERSITY OF RWANDA
FACULTY OF AGRICULTURE
DEPARTMENT OF CROP PRODUCTION AND
HORTICULTURE
IN VITRO PROPAGATION OF TAMARILLO IN RWANDA
BY
ISHIMWE RODRIGUE
SUPERVISORS: Prof PETER YAO KANZE SALLAH
Dr JANE KAHIA
2011
NATIONAL UNIVERSITY OF RWANDA
FACULTY OF AGRICULTURE
DEPARTMENT OF CROP PRODUCTION AND HORTICULTURE
RESEARCH PROPOSAL
BY
ISHIMWE RODRIGUE
SUPERVISORS: PROF PETER YAO KANZE SALLAH
DR JANE KAHIA
2011
IN VITRO PROPAGATION OF TAMARILLO IN RWANDA
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TABLE OF CONTENTS
TABLE OF CONTENTS...................................................................................................................... ii
LIST OF ABBREVIATIONS AND ACRONYMS.........................................................................iv
LIST OF PLATES AND TABLES......................................................................................................v
CHAPTER 1: GENERAL INTRODUCTION........................................................................................1
1.1. Classification of Tamarillo (CAB Abstracts, 1998):..................................................................1
1.2. General description of Tamarillo...............................................................................................1
1.3. Uses...........................................................................................................................................1
1.4. Ecology......................................................................................................................................2
1.5. Structure....................................................................................................................................2
1.6. Roots..........................................................................................................................................2
1.7. Leaves........................................................................................................................................3
1.8. Flowers......................................................................................................................................3
1.9. Fruits..........................................................................................................................................4
1.10. Pollination.................................................................................................................................4
1.11. Germination...............................................................................................................................4
1.12. Chemical composition...............................................................................................................5
1.13. Propagation................................................................................................................................5
1.14. Major diseases...........................................................................................................................5
1.15. Major pests................................................................................................................................6
CHAPTER 2: LITERATURE REVIEW.................................................................................................7
2.1. Tissue culture - Review................................................................................................................7
2.2. Statement of the problem...........................................................................................................8
2.3. Justification................................................................................................................................8
2.4. General objective.......................................................................................................................9
2.5. Specific objectives.....................................................................................................................9
2.6. Hypothesis.................................................................................................................................9
CHAPTER 3: GENERAL METHODS AND MATERIALS...............................................................10
3.1. Plant materials............................................................................................................................10
3.2. Plant growth regulators...............................................................................................................10
3.3. Media preparation.......................................................................................................................10
3.4. Surface sterilisation of explants..................................................................................................11
3.5. Aseptic techniques......................................................................................................................11
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3.6. Dissecting tools..........................................................................................................................11
3.7. Incubation conditions..................................................................................................................11
3.8. Cleaning of glassware.................................................................................................................12
3.10. Photography..............................................................................................................................12
3.12. Data to be collected..................................................................................................................12
WORK PLAN..........................................................................................................................................13
REFERENCES........................................................................................................................................14
APPENDIX..............................................................................................................................................15
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LIST OF ABBREVIATIONS AND ACRONYMS
2iP: 2-isopentyl adenine
2, 4-D: Dichlorophenoxy – acetic acid
ADAR: Rwanda Agribusiness Development Assistance
ANOVA: Analysis of varieties
BA: 6-benzyladenine
Cm: Centimeter
GA3: Gibberellic Acid
HCL: Hydrochloride acid
IAA: Indole-3-acetic acid
IBA: Indole-3-butyric acid
ICRAF: World Agroforestry Center
ISAR: Institut des Sciences Agronomique du Rwanda
Kg: Kilogram
l: Litre
mg: milligram
ml: Milliliter
MS: MURASHIGE and SKOOG (culture media)
NAA: 1-naphtylacetic acid
NaOH: Sodium hydroxide
OC: Celsius degrees
TDZ: Thidiazuron
v/v: Volume by volume
%: Percent
χ: Chi-square
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LIST OF PLATES
Plate 1.1: Tamarillo roots
Plate 1.2: Tamarillo leaves
Plate 1.3: Tamarillo flowers
Plate 1.4: Tamarillo fruits
Plate 1.5: Tamarillo seeds inside the fruit
LIST OF TABLES
Table 1: Solvents used to solubilise plant growth substances.
Table 2: Composition of Murashige and Skoog’s Medium
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CHAPTER 1: GENERAL INTRODUCTION
1.1. Classification of Tamarillo (CAB Abstracts, 1998):
Domain: Eukaryota
Kingdom: Viridiplantae
Phylum: Spermatophyta
Subphylum: Angiospermae
Class: Dicotyledonae
Order: Solanales
Family: Solanaceae
Genus:Cyphomandra
Species: Cyphomandra betacea
1.2. General description of Tamarillo
Cyphomandra betacea (Cav.) Sendtn. is a woody plant of the Solanaceae family commonly
known as tamarillo or tree tomato (Correia et al., 2009). It is the best-known of about 30 species
of Cyphomandra (family Solanaceae) (Morton, 1987). Among its various regional names
are: tomate, tomate extranjero, tomate de arbol, tomate granadilla, granadilla, pix, and caxlan
pix (Guatemala); tomate de palo (Honduras); arbre à tomates (France); arvore do tomate,
tomate de arvore (Brazil);lima tomate, tomate de monte, sima (Bolivia); pepino de
arbol (Colombia); tomate dulce (Ecuador); tomate cimarron (Costa Rica); ikinyomoro
(Rwanda); Mgogwe (Kenya); Munyanya (Uganda) and tomate francés (Venezuela, Brazil). In
1970, or shortly before, the construed name "tamarillo" was adopted in New Zealand and has
become the standard commercial designation for the fruit (Morton, 1987).
1.3. Uses
Tamarillos are grown mainly for their edible fruits and, to a lesser extent, as an outdoor
ornamental (Guimaraes et al., 1996). The fruits, when ripe, have the same application as the
common tomato, and are a good substitute during the winter months when tomatoes are difficult
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to obtain. They have several culinary uses and can be eaten raw in salads or as dessert but
preferentially cooked (Guimaraes et al., 1996). In addition, they can be used as a condiment with
grilled steak or ham, for making preserves, pies, sauces pickles, chutneys, and also in the
canning industry. In all cases, the seeds and especially the skin should be removed, since the
latter is fairly tough and quite disagreeable. In Jamaica and the West Indies, tamarillo fruits are
considered to have beneficial effect in relieving disorders of the liver, and for that reason they
were given the name vegetable mercury (Guimaraes et al., 1996).
Tamarillo is widely grown throughout Rwanda (ADAR, 2002). The fruit are larger and better
tasting than those from Zimbabwe, which exports a small amount as fresh fruit, and may be of
interest (albeit on a small scale) to European fresh produce importers. Consumption of tamarillo
fruit is traditionally recommended by Rwandans for people suffering from stomach ailments.
Tamarillos are mainly used in Rwanda for making jams and juices but unfortunately in low
quantities because of its low area coverage which can mainly be due to some viral diseases.
1.4. Ecology
Although C. betacea can be grown in a variety of soils and climates, there are some limitations
to its cultivations imposed mainly by temperature, wind and soil conditions. Tamarillos do not
withstand very low temperatures (frost may kill the leaves and tender growths), or the very high
tropical heat. They do best in subtropical conditions or in tropical regions at altitudes between
700 and 2000 m. Wind may cause damage by breaking leaves and branches, or uprooting the
plant. They do not tolerate waterlogged conditions, requiring light, and well – drained soils.
1.5. Structure
Cyphomandra betacea is a semi-woody shrub or small tree 2-3 m high, rarely 5 m. It is unarmed,
pubescent, with a short trunk and stout lateral branches (ICRAF, 2009). The bark is grey.
1.6. Roots
Tamarillo has shallow root system (Plate 1), it has little ability to withstand drought and is easily
blown over (ICRAF, 2009). The shallow roots and large, soft leaves of C. betacea make it
particularly susceptible to wind damage. They are apparently intolerant to constant high
temperatures and often their fruits fail to mature in lowland tropical climates owing to excessive
heat.
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Plate 1.1: Tamarillo roots
1.7. Leaves
Leaves alternate, simple, entire, usually grouped at the branch tips, with a robust petiole, 4-8 cm
long. The limb is large, 15-30 x 10-20 cm, ovate, shortly acuminate, with a cordate base (Plate
1.2). Young leaves covered on both surfaces with a soft pubescence; with age, the upper surface
becomes glabrous. Midrib and principal veins are prominent on both surfaces.
Plate 1.2 Tamarillo Leaves
1.8. Flowers
Flowers of tamarillo are fleshy pink (Plate 1.3), in groups of 3-10 in axillary cymes or racemes,
near the ends of the branches. They are hermaphroditic, pentamerous, fragrant, pedicellate, 13-15
mm diameter. The calyx is campanulate with broadly ovate, subacute lobes, which are thick and
crescent in fruit. The corolla rotate-campanulate, 12 mm long, with 5 long, narrow, lanceolate
segments; reflexed at the apex and the stamens 5, yellow, inserted at the throat of the corolla.
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Plate 1.3 Tamarillo Flowers
1.9. Fruits
Fruits are ovoid berry, measuring 4-6 (max. 10) cm long and 3-5 cm wide (ICRAF, 2009). They
are suspended at the end of a long stalk (Plate 1.4), and surrounded at the base by the persistent
green calyx. Skin is thin, smooth, and reddish-brown to violet changing to orange-red at
maturity. Some varieties become deep purple at maturity. The pulp contains numerous small
seeds that are circular, flat, thin and hard (Plate 1.5).
Plate 1.4: Tamarillo fruits Plate 1.5: Tamarillo seeds inside the fruit
1.10. Pollination
Tree tomato flowers are normally self-pollinating (Morton, 1987). If wind is completely cut off
so as not to stir the branches, this may adversely affect pollination unless there are bees to
transfer the pollen. Unpollinated flowers will drop prematurely.
1.11. Germination
Seeds should be selected from true to type plants. Chilling is claimed to result in virtually 100%
germination within 4-6 days (Morton, 1987). Seedbeds should be prepared with manure or
compost and lightly shaded.
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1.12. Chemical composition
The pulp, which varies in colour from yellow to orange – red, is relatively acidic (pH 3.7 – 3.8;
Cacioppo 1984) and has an agreeable aromatic flavour. Tamarillos are an interesting crop from
the nutritional viewpoint. They are comparatively high in protein (1.5 – 2 g /100 g of food),
vitamin C (30 – 45 mg/100 g) and E (1.85 mg/100 g), provitamin A, mineral elements (K, P),
and low in carbohydrates (4.7 g/100 g) and in calories (about 28 Kcal/100 g) (Guimaraes et al.,
1996).
1.13. Propagation
Tamarillos may be raised from seeds, cuttings or by grafting onto wild tobacco tree (Solanum
mauritianum). Seeds germinate easily, but a pretreatment with fungicide may be recommendable
to prevent “damping off”. Mature cuttings (1 – 2 – year – old wood), 30 to 40 cm in length and 1
to 2.5 cm diameter, are indicated for rooting. Tamarillo scions have been successfully grafted
onto Solanum mauritianum in New Zealand and in Australia with the main goal of improving the
tolerance to wet soil conditions by reducing susceptibility to root rot. Propagation from cuttings
is an alternative, but it is difficult to ensure freedom from virus infections. Container growing
can cut planting-out losses. Cuttings of 1- to 2-year-old wood 10-30 cm thick and 45-100 cm
long can be defoliated and planted directly in the field. In Trees on the stock are slightly
dwarfed, but they bear prolifically and need to be staked. Fruit will keep up to 12 weeks at 3.5-
4.5 deg. C with a 7-day shelf life afterwards (ICRAF, 2009).
1.14. Major diseases
Tamarillo is susceptible to several viral infections like the tamarillo mosaic virus (TaMV;
(Guimaraes et al., 1996)) which is also a problem which is affecting tamarillo tree in Rwanda,
especially in areas where the crop has been grown for some time (ADAR, 2002). It makes the
plants to become stunted, with puckered and mottled leaves. Also others can be seen in various
regions in the World: cucumber mosaic virus, and potato virus Y, which not only affect the vigor
and health of the plant, nut also cause distortions in the leaves and blemishes on the skin, its
commercial value.
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1.15. Major pests
Tamarillos is attacked by aphids, white flies, caterpillars, and the green vegetable bug as the
main pests, and powdery mildew, sclerotina, bacterial blast, leaf spot, and root rot (in
waterlogged conditions) as the principal diseases (Guimaraes et al., 1996).
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CHAPTER 2: LITERATURE REVIEW
2.1. Tissue culture - Review
Tissue culture is an in-vitro method for the development of new plants in artificial medium under
aseptic conditions from plant tissues. Different plant parts: leaves, nodes, roots, internodes,
stems of plants can be used during tissue culture. The requirement to rapidly multiply important
cultivars of tamarillo can be achieved through tissue culture which has great potential for
facilitating rapid propagation of elite materials.
Obando et al.,1992 regenerated Cyphomandra betacea axillary buds plantlets using MS basal
medium and phytohormones NAA, BA, and GA3 all in concentration 0.2 mg/l. Omitting GA3,
lowering NAA to 0.02, and adding Zeatin 2.5 mg/l instead of BA, resulted in 70% of explants
with multiple shoots but no roots. Shoots formed easily from leaf explants when only TDZ was
used as cytokinin. Leaf sections also showed morphogenic responses, forming abundant shoots.
The incorporation of TDZ (5 and 10 mg/l) promoted this response in the absence or presence of
IAA (1 mg/l).
Barghchi, 1998, established a protocol for the efficient micropropagation and plant improvement
of Cyphomandra betacea. Explants from axillary and flower buds of 2 mature tamarillo plants
were cultured on MS medium supplemented with a combination of different growth regulators
(BA 0.1-4.0 mg/l, kinetin 0.25-4.0 mg/l and NAA 0.25-4.0 mg/l). Regeneration of plantlets was
studied using 3 types of in vitro regeneration methods: axillary shoot culture, terminal bud
culture and adventitious shoot regeneration.
Obando and Jordan, 2001, examined the potential of in vitro regeneration in Cyphomandra
betacea (Cav.) Sendt. Morphogenic responses were observed in a series of organs, mainly
through somatic embryogenesis, adventitious shoots from leaf explants and root formation in
axillary buds leading to plantlets. Somatic embryos were induced from ovaries, petioles and
cotyledons. In axillary buds and leaf explants it was found that, at the same time related with
initiation of morphogenic events, a substantial increase in soluble protein synthesis occurred,
while browning and necrosis decreased.
Tamarillo propagation through tissue culture has been successfully done by the India’s Tissue
Culture Lab Department’s located in the Government fruit Garden in Shillong in 2007(Indian
Agriculture Information, 2009). During the trial, yellow colour tamarillo has been found to be
very promising. They first initiated the seeds in kinetin media after sterilizing them in mercury
8
chloride for 7 minutes. In three to four weeks, the seeds started to germinate with one plumule.
This plumule was then used as a base for various micro propagation processes in the lab. The
regenerated plantlets were rooted in a basal media for about 5-6 weeks. Once hardened, the
plantlets were then hardened in coco peat in a poly house.
Correia et al., 2009, attempted to induce somatic embryogenesis from adult plants of
Cyphomandra betacea with the objective of cloning selected genotypes. To achieve this goal
assays with the pith stem and floral tissues were performed. The ability of different tamarillo
genotypes to undergo somatic embryogenesis was also tested, with preliminary results indicating
that some genotypes are more suitable than others for somatic embryo formation.
2.2. Statement of the problem
The cultivation of Tamarillo in Rwanda is facing challenges caused mainly by viral diseases like
mosaic virus (TaMV) (ADAR, 2002) caused by pathogens which are difficult to control and are
transferred by vegetative propagation often resulting in loss of plant production and a poor
quality product. The lack of adequate, healthy planting materials is hampering tamarillo
production in Rwanda.
2.3. Justification
Tamarillo seed propagation systems faces limitations such as undesirable variability, diseased
seedlings, inadequate and seasonal supply, and the tissue culture of tamarillo can bring an
answer to this problem as it offers large scale production of disease free planting materials.
Micropropagated tamarillo plants give higher yield and shorter gestation period compared to
traditional methods (Indian Agriculture Information, 2009). Besides, the other advantages
offered by tamarillo tissue culture methods is the large scale availability of its planting materials
at any time of the year without depending on the season of production. Although in vitro
propagation of tamarillo is more expensive than naturally propagated seedlings, they offer to the
horticulturist the advantages of uniform fruits characteristics which are important in international
market.
Multiplication by tissue culture techniques could provide a viable alternative to these traditional
methods of tamarillo propagation. Tissue culture methods permit the production of relatively
uniform plants on a massive scale in a shorter period than under conventional methods.
Tamarillo plants produced by tissue culture flowers earlier than the plants produced through
conventional methods.
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2.4. General objective
To develop an efficient tissue culture protocol for propagating Tamarillo (Cyhomandra betacea)
plantlets.
2.5. Specific objectives
To determine the optimum sterilization technique for Cyphomandra
betacea
To compare effects of different cytokinins in regenerating plantlets of
Cyphomandra betacea
2.6. Hypothesis
Tissue culture through use of nodes for regenerating plantlets provides a feasible method for
mass crop propagation of Cyphomandra betacea.
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CHAPTER 3: GENERAL METHODS AND MATERIALS
3.1. Plant materials
The nodal explants will be obtained from tamarillo growing in the green house at ISAR Rubona.
3.2. Plant growth regulators
Plant growth regulators will be weighted and stocks prepared using appropriate solvents (Table
1). The stocks will be clearly labelled and stored in the refrigerator at 8oC.
Table 1: Solvents used to solubilise plant growth substances.
PLANT GROWTH SUBSTANCES SOLVENT
BA 0.1N NaoH & heat if required
Kinetin 0.1N NaoH
IAA Absolute alcohol
IBA Absolute alcohol
NAA 90% alcohol
2, 4-D Absolute alcohol
TDZ NaOH
2iP Acidified water
3.3. Media preparation
The MS (1962) media will be used for all the experiments (Appendix 1). Media will be prepared
by dissolving the organic and inorganic components in distilled water. The solutions will be
stirred until they dissolved and made up to final volume. The media pH will be adjusted between
5.7 and 5.8 by using either 1N HCL or 1N NaOH before the gelling agent is added. Media will
then be heated on a hot plate with continuous stirring using a magnetic stirrer until agar is
dissolved and media dispensed in the culture vessels. The culture vessels will be capped with lids
and placed in trays and autoclaved. Autoclave will be set at a temperature of 121oC and a
pressure of 1.1kg/cm2 for 20 minutes. All media will be autoclaved within 12 hours of
preparation and when possible freshly autoclaved media will be used. However, when it will not
be possible to use the media immediately it will be stored in a refrigerator at 4oC for no longer
than two weeks before use.
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3.4. Surface sterilisation of explants
Healthy looking leaf explants will be selected from healthy plants. They will be put into a beaker
containing tap water and taken to the laboratory for cleaning. The explants will then be
transferred to the lamina flow cabinet, immersed in 70% (v/v) ethanol for 30 seconds and rinsed
twice with sterile distilled water. This will be followed by surface sterilization using different
JIK concentrations and time intervals. They will then be rinsed twice 4 times in sterile distilled
water.
3.5. Aseptic techniques
The process of sterilization and dissection of plant materials will be carried out under sterile
conditions in lamina flow cabinet. The cabinet will be switched on and swabbed down with 70%
ethanol using cotton wool or sterile towel and kept running for about 15 minutes before the work
in the cabinet starts. All the plant materials will be dissected on the sterile pieces of paper. The
lamina flow cabinet will be frequently swabbed down with 70% alcohol and sterile pieces of
paper will be used between each transfer in order to ensure that sterile surfaces are used for each
culture. Hands will be sprayed with 70% ethanol at suitable intervals while working for
protracted periods in front of the cabinets. Following completion of transfer work, Lamina flow
cabinets will be swabbed down with 70% ethanol. Personal hygienic precautions will be
observed by wearing a clean lab coat and gloves while carrying out experiments in the lamina
flow cabinet.
3.6. Dissecting tools
All tools will be placed in an aluminium foil and sterilised in an autoclave. During their use in
the cabinet, tools will be dipped in 70% ethanol followed by heat sterilization in steribead
steriliser maintained at 250 o C. In between operations, the tools will be frequently sterilized by
dipping them in ethanol and in steribead sterilizer.
3.7. Incubation conditions
For regenerating tamarillo nodes, the cultures will be incubated in growth rooms maintained at
25oC and 16 hours photoperiod.
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3.8. Cleaning of glassware
All glassware and vessels will be washed in hot water to which few drops of liquid detergent will
have been added. The glassware will then be rinsed in cold water three times followed by a final
rinse in distilled water with a few drops of commercial bleach (JIK). All this will be carried out
in a clean dust free washing room. The glassware will then be dried in the oven at 600C in a clean
dust free place.
3.10. Photography
Photographs of the experimental materials will be taken using a Sony Digital Camera.
3.11. Experimental design and statistical analyses
All experiments will be laid out in Completely Randomised Design. The level of replication
which will be used per treatment combination may vary depending upon the availability of
experimental materials. For the micropropagation experiments 10 replicates per treatment will be
used at the outset of experiments. Chi-square tests will be used in the case of percentages
(frequency data); were chi-square values will be presented, the figure in the brackets following
the derived value should be the one obtained from statistical tables. A number of hypotheses
should be used for χ2 test. For the majority of the data analysed statistically, a standard Analysis
of Variance (ANOVA) will be used on either transformed or untransformed data values. The
level of significance used for treatment comparison will be either p≤0.01 or p≤0.05. Analysis of
variance and data transformation will be performed using Genstat Statistical Software. The
Genstat Statistical Software will be used in cases of unequal numbers of replications were
present in some batches due to accidental contamination or in those cases where it will be
relevant, e.g. number of roots per rooted microshoots. Standard errors of means (SE) will be
indicated in tables where a statistical analysis would be conducted.
3.12. Data to be collected
The following data will be collected:
Percent clean explants
Number of microshoot per node
Length of microshoot
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WORK PLAN
Task February March April May June July August September
Project
proposal
writing
Setting up the
experiment
Data
collection
Data
analysis
Data
interpretation
report writing
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REFERENCES
1.ADAR (Rwanda Agribusiness Development Assistance) . (2002). Developing a Horticultural Export Industry in Rwanda Progress Report: May - June 2002. Kigali: USAID.
2. Barghchi, M. (1998). In vitro regeneration, plant improvement and virus elimination of tamarillo (Cyphomandra betaceae (Cav.) Sendt.). In Davey M. R., Alderson P. G., Lowe K. C., & Power J. B., Tree biotechnology: towards the millennium (pp. 173-185). Nottingham, UK: Nottingham University Press.
3. Correia S. I., Lopes M.L. and Canhoto J.M.. (2009). Somatic embryogenesis in
tamarillo (cyphomandra betacea): recent advances. In F. D. M.-V. Hanke, I
International Symposium on Biotechnology of Fruit Species: Biotechfruit2008.
Dresden, Germany: ISHS Acta Horticulturae.
4.Guimaraes M.L., Tomé M.C., and Cruz G.S. (1996)., Cyphomandra Betacea (Cav.) Sendtn. (Tamarillo). In Y. P. Bajaj, Biotechnology in Agriculture and Forestry 35 (pp. 120 - 135). New Delhi: Springer.
5. ICRAF (World Agroforestry Center). (2009). Cyphomandra betacea. Retrieved March 21, 2011, from Agroforestry Tree Database: http://www.worldagroforestrycentre.org/sea/Products/AFDbases/AF/asp/SpeciesInfo.asp?SpID=639
6.Morton, J. F. (1987). Tree Tomato. In J. F. Morton, Fruits of warm climates (pp. 437–440). Miami, FL.
7. Obando M. and Jordan M. (2001). Regenerative responses of cyphomandra betacea (Cav.) Sendt. (Tamarillo) cultivated in vitro. In S. K. S. Sorvari, IV International Symposium on In Vitro Culture and Horticultural Breeding. Tampere, Finland: ISHS Acta Horticulturae.
8. Obando M., Goreux A. and Jordan M. (1992). In vitro regeneration of Cyphomandra betacea (Tamarillo) and Andean fruit species. Ciencia e Investigacion Agraria , p. 125-130
9. The Indian Agriculture Information Wing. (2009). Micropropagation of Tamarillo. Agricultural Newsletter , p. 8. Agricultural Information Offset Press, Fruit Garden, Meghalaya, Shillong, India.
15
APPENDIX
Table 2: Composition of Murashige and Skoog’s Medium:
Stock solution
Constituents Concentration in stock solution g/l
Volume of stock solution in final medium ml/l
Final concentration in medium mg/l
A NH4NO3 82.5 20 1650
B KNO3 95.0 20 1900
C H3BO3 1.24 5 6.2
KH2PO4 34 170
KI 0.166 0.83
Na2MoO4.2H2O 0.05 0.25
COcl2.6H2O 0.005 0.025
D Cacl2.2H2O 88.0 5 440.0
E MgSO4.7 H2O 74.0 5 370.0
MnSO4.4 H2O 4.46 22.3
ZnSO4.7 H2O 1.72 8.6
CuSO4.5 H2O 0.005 0.025
F Na2.EDTA 7.45 5 37.35
FeSO4.7 H2O 5.57 27.85
G Thiamine HCL 0.02 5 0.1
Nicotinic Acid 0.1 0.5
Pyridoxine HCL 0.1 0.5
Glycine 0.4 2.0