The objective of the study has been to determine the usefulness of six different
Inter Simple Sequence Repeat (ISSR) primers for the genetic stability in the chrysanthemum
plants produced through somatic embryogenesis (SE). The research material consisted of
the lines of two cultivars: ‘Lady Salmon’ (LS1–LS5) and ‘Lady Vitroflora’ (LV1–LV5).
The plants derived from meristems constituted the standard. The primers used in the
PCR reaction have shown a notable polymorphism between the genotypes analyzed. All
the primers (S1–S6) demonstrated a polymorphism in the inter-microsatellite region;
the highest polymorphism in ‘Lady Salmon’ and ‘Lady Vitroflora’ lines with primer S3,
whereas the lowest – in ‘Lady Salmon’ cultivar with primers S5 and S6, and in ‘Lady
Vitroflora’ – with primer S1. UPGMA dendrogram clearly separated all the cultivars and its
lines into two main clusters and two subclusters. ISSR markers can be applied to assess the
genetic stability of SE-derived chrysanthemum.
REFERENCJE(28)
1.
Baliyan D., Sirohi A., Kumar M., Kumar V., Malik S., Sharma S., Sharma S., 2014. Comparative genetic diversity analysis in chrysanthemum: A pilot study based on morpho-agronomic traits and ISSR markers. Sci. Hortic. 167, 164–168.
Carvalho-Zanão M.P., Zanao Junior L.A., Barbosa J.G., Grossi J.A.S., De ÁVila V.T., 2012. Yield and shelf life of chrysanthemum in response to the silicon application. Hortic. Bras. 30(3), 403–408.
Chang L., Chen D., Cheng X., Liu H., Li Y., Huang C., 2018. SSR Analysis of Genetic Relationship and Classification in Chrysanthemum Germplasm Collection. Hortic. Plant J. 4(2), 73–82.
Kalia R.K., Rai M.K., Kalia S., Singh R., Rohtas S., Dhawan A.K., 2011. Microsatellite markers: An overview of the recent progress in plants. Euphytica 177(3), 309–334.
Kulpa D., 2012. Somatyczna embriogeneza w kulturach chryzantemy wielokwiatowej (Chrysanthemum ×grandiflorum) (Ramat.) Kitam.). Wydawnictwo Uczelniane Zachodniopomorskiego Uniwersytetu Technologicznego w Szczecinie, Szczecin.
Lema-Rumińska J., Mellem A., 2017. Genetic diversity of chrysanthemum plants derived via somatic embryogenesis using RAPD markers. Acta Sci. Pol. Hortorum Cultus 16(6), 149–156.
Lema-Rumińska J., Śliwińska E., 2015. Evaluation of the genetic stability of plants obtained via somatic embryogenesis in Chrysanthemum ×grandiflorum (Ramat./Kitam.). Acta Sci. Pol. Hortorum Cultus 14(3), 131–139.
Liang-Yu W., Hong-Zhou G., Xun-Lei W., Jian-Hui Y., Jian-Liang L., Yue-Rong L., 2010. Analysis of chemical composition of Chrysanthemum indicum flowers by GC/MS and HPLC. J. Med. Plants Res. 4(5), 421–426.
Mei Z., Zhang X., Liu X., Imani S., Fu J., 2017. Genetic analysis of Canarium album in different areas of China by improved RAPD and ISSR. C.R. Biol. 340, 558–564.
Miler N., Zalewska M., 2014. Somaclonal variation of chrysanthemum propagated in vitro from different explants types. Acta Sci. Pol. Hortorum Cultus 13(2), 69–82.
Mukherjee A.K., Dey A., Acharya L., Palai S.K., Panda P.C., 2013. Studies on genetic diversity in elite varieties of Chrysanthemum using RAPD and ISSR markers. Indian J. Biotechnol. 12, 161–169.
Naing A.H., Min J.S., Park K.I., Chung M.Y., Lim S.H., Lim K.B., Chang K.K., 2013. Primary and secondary somatic embryogenesis in Chrysanthemum (Chrysanthemum morifolium) cv. ‘Baeksun’ and assessment of ploidy stability of somatic embryogenesis process by flow cytometry. Acta Physiol. Plant. 35, 2965–2974.
Podwyszyńska M., Kuras A., Korbin M., 2010. Somaclonal variation in micropropagated tulips as a source of novel genotypes – field and molecular characteristic. Acta Hortic. 855, 225–231.
Tamboli A.S., Dalavi J.V., Patil S.M., Yadav S.R., Govindwar S.P., 2018. Implication of ITS phylogeny for biogeographic analysis, and comparative study of morphological and molecular interspecies diversity in Indian Impatiens. Meta Gene 16, 108–116.
Yu K., Park S.J., Poysa V.W., Gepts P., 2000. Integration of Simple Sequence Repeat (SSR) markers into a molecular linkage map of common bean (Phaseolus vulgaris L.). Am. Genet. Assoc. 91(6), 429–434.
Zalewska M., Lema-Rumińska J., Miler N., 2007. Induction of adventitious shoot regeneration in chrysanthemum as affected by the season. In Vitro Cell. Dev. Biol. – Plant 47(3), 375–378.
Zhang W., He H., Guan Y., Du H., Yuan L., Li Z., Yao D., Pan J., Cai R., 2010. Identification and mapping of molecular markers linked to the tuberculate fruit gene in the cucumber (Cucumis sativus L.). Theor. Appl. Genet. 120(3), 645–654.
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