Somaclonal Variations

1. Somaclonal Variations

2. New variety production (somaclonal variation)

5. Tuberosum cultivar and new andigenum introduction

6. Somaclonal Variation • Somaclonal variation is a general phenomenon of all plant regeneration systems that involve a callus phase • There are two general types: • Heritable, genetic changes (alter the DNA) • •Stable, but non-heritable changes (alter gene expression, epigenetic) • With or without mutagen

7. Somaclonal/Mutation Breeding • Advantages: • Screen very high populations (cell based) • Can apply selection to single cells • Disadvantages: • Many mutations are non-heritable • Requires dominant mutation (or double recessive mutation); most mutations are recessive • Can avoid this constraint by not applying selection pressure in culture, but you lose the advantage of high through-put screening –have to grow out all regenerated plants, produce seed, and evaluate the M2

8. Targets for Somaclonal Variation • Herbicide resistance and tolerance • Specific amino acid accumulators • Screen for specific amino acid production • e.g.Lysine in cereals • Abiotic stress tolerance • Add or subject cultures to selection agent–e.g.: salt, temperature stress • Disease resistance • Add toxin or culture filtrate to growth media

10. SomaclonalVariation Genetic variations in plants that have been produced by plant tissue culture and can be detected as genetic or phenotypic traits.

11. In vitro plant regeneration. The choice of different tissue types and culture conditions including plant growth regulators (PGRs), nutrients, light/dark, and temperature, and the occurrence of extensive cell division before organogenesis or somatic embryogenesis may affect the regeneration of variant plants. Chromatin modifiers (in green) referred to in the text as well as interacting genes (in black) or putative targets with a potential role during cell fate switch/cell division and differentiation of plant cells cultured in vitro are represented. Although many key regulators have been identified, it is still not well understood how they function at the molecular level. For a detailed overview of the genes taking part in these plant developmental processes refer to Desvoyes et al. (2010). Abbreviations: BRM, BRAHMA; PKL, PICKLE; PKR2, PICKLE RELATED 2; SWN, SWINGER; SYD, SPLAYED.

13. Visual observations regarding somaclonal variation

14. Basic Features of Somaclonal Variations • Variations for Karyotype, isozyme characteristics and morphology in somaclones may also observed. • Calliclone (clones of callus), mericlone (clones of meristem) and protoclone (clones of Protoplast) produced. • Generally heritable mutation and persist in plant population even after plantation into the field

15. Mechanism of Somaclonal Variations • Genetic (Heritable Variations) • Pre-existing variations in the somatic cells of explant • Caused by mutations and other DNA changes • Occur at high frequency • Epigenetic (Non-heritable Variations) • Variations generated during tissue culture • Caused by temporary phenotypic changes • Occur at low frequency

16. Callus Tissue Somaclonal Variants Organogenesis Hardening and Selfing Regenerated plants Steps involved in induction and selection of Somaclonal Variations

17. Causes of Somaclonal Variations Physiological Cause Biochemical Cause Genetic Cause

18. Physiological Cause • Exposure of culture to plant growth regulators. • Culture conditions

19. Genetic Cause • Change in chromosome number • Euploidy: Changes chromosome Sets • Aneuploidy: Changes in parts of chromosome Sets • Polyploidy: Organisms with more than two chromosome sets • Monoploidy: Organism with one chromasomes set • Change in chromosome structure • Deletion • Inversion • Duplication • Translocation

20. Genetic Cause 3.Gene Mutation • TansitionDNA substitution mutations are of two types. Transitions are interchanges of two-ring purines(AG) or of one-ring pyrimidines(CT): they therefore involve bases of similar shape. • TransversionTransversionsare interchanges of purine for pyrimidine bases, which therefore involve exchange of one-ring and two-ring structures. • Insertion • Deletion 4.Plasmagene Mutationa self-replicating genetic particle postulated to be in the cytoplasm of a cell, as in mitochondria. 5.Transposable element activation

22. Transposable element activation Under most circumstances this process is highly efficient, and the vast majority of transposons are inactive. Nevertheless, transposons are activated by a variety of conditions likely to be encountered by natural populations, and even closely related species can have dramatic differences in transposon copy number. Transposon silencing has proved to be closely related to other epigenetic phenomena, and transposons are known to contribute directly and indirectly to regulation of host genes. Together, these observations suggest that naturally occurring changes in transposon activity may have had an important impact on the causes and consequences of epigenetic silencing in plants.

23. Genetic Cause 6.DNA sequence • Change in DNA • Detection of altered fragment size by using Restriction enzyme • Change in Protein • Loss or gain in protein band • Alteration in level of specific protein • Methylation of DNA • Methylation inactivates transcription process.

24. Biochemical Cause • Lack of photosynthetic ability due to alteration in carbon metabolism • Biosynthesis of starch via carotenoid pathway • Nitrogen metabolism • Antibiotic resistance.

25. Detection and Isolation of Somaclonal Variants • Analysis of morphological characters • Qualitative characters: Plant height, maturity date, flowering date and leaf size • Quantitative characters: yield of flower, seeds and wax contents in different plant parts • Variant detection by cytological Studies • Staining of meristematic tissues like root tip, leaf tip with feulgen and acetocarmine provide the number and morphology of chromosomes. • Variant detection by DNA contents • Cytophotometer detection of feulgen stained nuclei can be used to measure the DNA contents

26. 4. Variant detection by gel electrophoresis • Change in concentration of enzymes, proteins and chemical products like pigments, alkaloids and amino acids can be detected by their electrophoretic pattern 5. Detection of disease resistance variant • Pathogen or toxin responsible for disease resistance can be used as selection agent during culture. 6. Detection of herbicide resistance variant • Plantlets generated by the addition of herbicide to the cell culture system can be used as herbicide resistance plant.

27. Detection and Isolation of Somaclonal Variants 7. Detection of environmental stress tolerant variant • Selection of high salt tolerant cell lines in tobacco • Selection of water-logging and drought resistance cell lines in tomato • Selection of temperature stress tolerant in cell lines in pear. • Selection of mineral toxicities tolerant in sorghum plant (mainly for aluminium toxicity)

28. Advantages of Somaclonal Variations • Help in crop improvement • Creation of additional genetic variations • Increased and improved production of secondary metabolites • Selection of plants resistant to various toxins, herbicides, high salt concentration and mineral toxicity • Suitable for breeding of tree species

29. Disadvantages of Somaclonal Variations • A serious disadvantage occurs in operations which require clonal uniformity, as in the horticulture and forestry industries where tissue culture is employed for rapid propagation of elite genotypes • Sometime leads to undesirable results • Selected variants are random and genetically unstable • Require extensive and extended field trials • Not suitable for complex agronomic traits like yield, quality etc. • May develop variants with pleiotropic effects which are not true.