cell-suspension cultures
TRANSCRIPT
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In Vitro Developmental Pathways
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Sterile pieces of a whole plant from which cultures are generally initiated
Types of explant:Generally all plant cells can be used as an explant, however young and rapidly growing tissue (or tissue at an early stage of development) are preferred.
Explants
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a) Root tip: Root cultures can be established from explants of the root
tip of either primary or lateral roots.b) Shoot tip: The shoot apical meristem from either axillary or
adventitious buds can be cultured in vitro.c) Embryo: Both immature and mature embryos can be used as explants
to generate callus cultures or somatic embryos. Immature, embryo-derived callus is the most popular
method of monocot plant regeneration.d) Haploid tissueMale gametophyte (Pollen in anthers) or female gametophyte
(the ovule) can be used as an explant. Haploid tissue cultures can produce haploid or di-haploid
plants due to doubling of chromosomes during the culture periods.
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Definition: It is an unspecialized and unorganized, growing and dividing mass of cells, produced when explants are cultured on the appropriate solid medium, with both an auxin and a cytokinin and correct conditions.
During callus formation there is some degree of dedifferentiation both in morphology and metabolism, resulting in the lose the ability to photosynthesis.
Callus
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•Callus cultures may be compact or friable.
Compact callus shows densely aggregated cells
Friable callus shows loosely associated cells and the
callus becomes soft and breaks apart easily.
•Habituation: it is the lose of the requirement for auxin
and/or cytokinin by the culture during long-term
culture.
Callus
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• When friable callus is placed into the appropriate liquid medium and agitated, single cells and/or small clumps of cells are released into the medium and continue to grow and divide, producing a cell-suspension culture.
• The inoculum used to initiate cell suspension culture should neither be too small to affect cells numbers nor too large too allow the build up of toxic products or stressed cells to lethal levels.
• Cell suspension culture techniques are very important for plant biotransformation and plant genetic engineering.
Cell-suspension cultures
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Three stages of callus culture• Induction:
Cells in explant dedifferentiate and begin to divide
• Proliferative Stage: Rapid cell division
• Morphogenesis stage:Differentiation and formation of organized structures; specifically processes that lead to plant regeneration from somatic cells
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Induction
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Division
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Plant morphogenesis• Organogenesis
The formation of organs (such as leaves, shoots, roots) on a plant organ, usually of a different kind.1. Enhancement of axillary bud proliferation/
development2. Adventitious shoot formation
• 3. Adventitious root formation• Somatic embryogenesis
Embryo initiation and development from somatic cells
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Shoot initiation and development with subsequent formation of adventitious
roots
Enhancement of axillary bud proliferation and development - stimulation of the shoot apical meristem in vitro that includes proliferation of lateral buds
Adventitious shoot formation - dedifferentiation and/or differentiation and development of shoots from non-meristematic cells (one or more than one) either directly or indirectly
Adventitious root formation - roots are initiated adventitiously at the base of the shoot apex and a vascular continuum is established to complete plant regeneration.
Organogenesis
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Somatic EmbryogenesisDedifferentiation is typically minimal but a
meristemoid-like tissue can be formed in the latter case
Histogenesis of somatic embryogenesis is characterized by the formation of a bipolar structure, in contrast to adventitious organogenesis
Single cell origin of somatic embryos makes chimerism infrequent; adventitious shoots can arise from more than one cell
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Somatic Embryos
• Bipolar• Not connected to explant or callus cells by vascular tissue
• In most woody plants, tissue must be juvenile or reproductive
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Cell Developmental Phases Leading to Morphogenesis