Establishing Taxonomic Identity and Selecting Genetically Diverse Populations for Conservation of Threatened Plants Using Molecular Markers
The extent of genetic diversity within a species is an important determinant of successful adaptation to adverse environmental conditions. Assessment of extent of genetic diversity/variability is also important to monitor genetic erosion within a species. In threatened plant species, genetic diversity assessment helps in selection of genetically diverse populations to enrich the genetically impoverished populations, thus minimizing the probability of genetic drift. Confirming taxonomic identity of threatened species, particularly those belonging to species complexes with dispute identity, is another essential task in the conservation of threatened species, which is best resolved through molecular approaches. The present study estimated the genetic variability within and among the populations of four threatened species, viz. Justicia beddomei (C.B. Clarke) Bennet (Acanthaceae), Embelia ribes Burm. f. (Myrsinaceae), Madhuca insignis (Radlk.) H.J. Lam (Sapotaceae) and Cycas beddomei Dyer (Cycadaceae) using Inter Simple Sequence Repeat (ISSR) and Simple Sequence Repeat (SSR) markers for selecting the genetically diverse populations. The phylogeny was analysed through ITS (nrDNA) and matK (cpDNA) sequences to confirm the species identity.
The phylogenetic analyses confirmed four distinct species of Justicia, which also revealed that J. beddomei and J. adhatoda were sister groups with a common ancestor showing rapid parallel speciation with J. gendarussa in one clade and J. betonica in another. Madhuca insignis with extremely small population in the Western Ghats (Karnataka to Kerala) might have undergone either extensive hybridization or incipient speciation. In case of Embelia species, a greater evolutionary closeness between E. subcoraceae and E. floribunda was revealed, while E. ribes had a distinct clad. Both ISSR and SSR markers distinguished various genotypes of Cycas beddomei.
Keywords
- Li, X., Li, Y., Zhang, Z. and Li, X., Influences of environmental factors on leaf morphology of Chinese Jujubes. PLOS ONE, 2015, 10(5), e0127825; http://doi.org/10.1371/journal.pone.0127825
- Doyle, J. A. and Endress, P. K., Morphological phylogenetic analysis of basal angiosperms: comparison and combination with molecular data. Int. J. Plant Sci., 2000, 161(S6), S121–S153.
- Schluter, D., Ecology and the origin of species. Trends Ecol. Evol., 2002, 16(7), 372–380.
- Neel, M. C. and Ellstrand, N. C., Conservation of genetic diversity in the endangered plant Eriogonum ovalifolium var. vineum (Polygonaceae). Conserv. Genet., 2003, 4(3), 337–352.
- Pauls, S. U., Nowak, C., Bálint, M. and Pfenninger, M., The impact of global climate change on genetic diversity within populations and species. Mol. Ecol., 2013, 22(4), 925–946.
- Dhankhar, S., Kaur, R., Ruhil, S., Balhara, M., Dhankhar, S. and Chhillar, A. K., A review on Justicia adhatoda: a potential source of natural medicine. Afr. J. Plant Sci., 2011, 5(11), 620–627.
- Bhat, K. G., Flora of Udupi, Indian Naturalist (R), Udupi, 2003, p. 339.
- Udayan, P. S., A new location for Madhuca insignis (Radlk.) H.J. Lam. – a rare, endemic and red listed plant near Venur of Dakshina Kannada district, Karnataka. Sliva’s Newsl., 2004, p. 295.
- Ravikumar, K., Sankar, R. V., Ved, D. K. and Bhat, K. G., Is Madhuca insignis (Radlk) H.J. Lam (Sapotaceae) really extinct? Phytotaxonomy, 2004, 4, 119–123.
- Raveendran, K., Madhuca insignis (Radlk.) H.J. Lam. (Sapotaceae) – new addition to the flora of Kerala. Zoo’s PRINT, 2013, 28(4), 25–26.
- Kumar, G. K., Shenoy, H. S. and Kaveriappa, K. M., Rediscovery of Madhuca insignis (Radlkofer) H.J. Lam (Sapotaceae) – a critically endangered species of the Western Ghats, India. Phytomorphology, 2004, 54(3&4), 209–213.
- Shenoy, H. S., Rajasekharan, P. E., Souravi, K. and Anand, M., Extended distribution of Madhuca insignis (Radlk.) H.J. Lam. (Sapotaceae) – a critically endangered species in Shimoga district of Karnataka. Zoo’s PRINT, 2014, XXIX(6), 21–23.
- Dubearnes, A., Julius, A. and Utteridge, T. M., A synopsis of the genus Embelia in Peninsular Malaysia and Singapore. Studies in Malaysian Myrsinaceae III. Kew Bull., 2015, 70(2), 1–33.
- Asadulla, S. and Ramandang, R., Pharmacognosy of Embelia ribes Burm f. Int J. Res. Pharm. Chem., 2011, 1(4), 1236–1251.
- Shankar, R., Lavekar, G. S., Deb, S., Sharma, B. K. and Rawat, M. S., Distribution, conservation and folk uses of Vaibidang (Embelia ribes Burm. f.). Int. J. Biodiv. Conserv., 2012, 4(13), 525–529.
- Arora, R. B., Ghatak, N. and Gupta, P. S., Anti-fertility activity of Embelia ribes. J. Res. Indian Med., 1971, 6(2), 107–110.
- Chitra, M., Devi, C. S. and Sukumar, E., Antibacterial activity of embelin. Fitoterapia, 2003, 74(4), 401–403.
- Chitra, M. S., Sukumar, E., Suja, V. and Devi, C. S. S., Antitumor, anti-inflammatory and analgesic property of embelin, a plant product. Chemotherapy, 1994, 40, 109–113.
- Chitra, M., Devi, C. S. and Sukumar, E., Effect of embelin on carbohydrate moieties of glycoprotein in tumour-bearing rats. J. Nat. Remedies, 2004, 4(1), 77–80.
- Seth, S. D., Nera, J. and Sundran, K. R., Antispermatogenic effect of embelin from Embelia ribes. Indian J. Pharmacol., 1982, 14(2), 207.
- Sreepriya, M. and Bali, G., Chemopreventive effects of embelin and curcumin against N-nitrosodiethylamine/phenobarbital-induced hepatocarcinogenesis in Wistar rats. Fitoterapia, 2005, 76(6), 549–555.
- Doyle, J. J. and Doyle, J. L., Isolation of plant DNA from fresh tissue. Focus, 1990, 12, 13–15.
- Baldwin, B. G., Phylogenetic utility of the internal transcribed spacers of nuclear ribosomal DNA in plants: an example from the Compositae. Mol. Phylogenet. Evol., 1992, 1, 3–16.
- White, T. J., Bruns, T., Lee, S. J. W. T. and Taylor, J. W., Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics. PCR Protocols: a Guide Meth. Appl., 1990, 18(1), 315–322.
- Ooi, K., Endo, Y., Yokoyamea, J. and Murakami, N., Useful primer designs to amplify DNA fragments of the plastid gene matK from angiosperm plants. J. Jpn. Bot., 1995, 70(6), 328–331.
- Cibrian-Jaramillo, A., Daly, A. C., Brenner, E., Desalle, R. and Marler, T. E., When North and South do not mix: genetic connectivity of a recently endangered oceanic cycad, Cycas micronesica, in Guam using EST‐microsatellites. Mol. Ecol., 2010, 19(12), 2364–2379.
- Zhang, F., Su, T., Yang, Y., Zhai, Y., Ji, Y. and Chen, S., Development of seven novel EST-SSR markers from Cycas panzhihuaensis (Cycadaceae). Am. J. Botany, 2010, 97(12), e159–e161.
- Tamura, K., Peterson, D., Peterson, N., Stecher, G., Nei, M. and Kumar, S., MEGA5: molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. Mol. Biol. Evol., 2011, 28(10), 2731–2739.
- Ronquist, F. and Huelsenbeck, J. P., MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatics, 2003, 19(12), 1572–1574.
- Kimura, M., A simple method for estimating evolutionary rates of base substitutions through comparative studies of nucleotide sequences. J. Mol. Evol., 1980, 16(2), 111–120.
- Nei, M., Genetic distance between populations. Am. Nat., 1972, 106(949), 283–292.
- Rohlf, F. J., NTSYS pc numerical taxonomy and multivariate system Ver. 2.1. Exeter Pub Ltd, Setauket, New York, USA, 2002.
- Mantel, N., The detection of tissue clustering and a generalized regression approach. Cancer Res., 1967, 27, 209–220.
- Hammer, Ø., Harper, D. A. T. and Ryan, P. D., PAST-palaeontological statistics, ver. 1.89. Paleontological Museum, University of Oslo, Noruega, 2008 (También disponible en línea: http://folk.uio.no/ohammer/past/index.html).
- Kumar, A., Mishra, P., Singh, S. C. and Sundaresan, V., Efficiency of ISSR and RAPD markers in genetic divergence analysis and conservation management of Justicia adhatoda L., a medicinal plant. Syst. Evol., 2014, 300, 1409–1420.
- Garg, M., Tamboli, E. T., Singh, M., Chester, K., Abdin, M. Z., Chandna, R. and Ahmad, S., RAPD based assessment of genetic diversity of Adhatoda vasica leaves from different sub-continents of India. Indian J. Pharmaceut. Edu. Res., 2015, 49(3), 268–276.
- Pal, M. D. and Raychaudhuri, S. S., Estimation of genetic variability in Plantago ovata cultivars. Biol. Plant., 2003, 47, 459–462.
- Segarra-Moragues, J. G., Palop-Esteban, M., González-Candelas, F. and Catalan, P., On the verge of extinction: genetics of the critically endangered Iberian plant species, Borderea chouardii (Dioscoreaceae) and implications for conservation management. Mol. Ecol., 2005, 14, 969–982.
- Senapati, S. K., Das, G. K., Aparajita, S. and Rout, G. R., Assessment of genetic variability in the Asoka tree of India. Biodiversity, 2012, 13, 16–23.
- Rajaseger, G., Tan, H. T. W., Turner, I. M. and Kumar, P. P., Analysis of genetic diversity among Ixora cultivars (Rubiaceae) using random amplified polymorphic DNA. Ann. Bot., 1997, 80(3), 355–361.
- Bank, H., Wink, M., Vorster, P., Treutlein, J., Brand, L., Bank, M. and Hurter, J., Allozyme and DNA sequence comparisons of nine species of Encephalartos (Zamiaceae). Biochem. Syst. Ecol., 2001, 29, 241–266.
- Xiao, L. Q., Ge, X. J., Gong, X., Hao, G. and Zheng, S. X., ISSR variation in the endemic and endangered plant Cycas guizhouensis (Cycadaceae). Ann. Bot., 2004, 94, 133–138.
- Duminil, J., Fineschi, S., Arndt, H., Pedro, J., Salvini, D., Vendramin, G. G. and Petit, R. J., Can population genetic structure be predicted from life history traits? Am. Nat., 2007, 169(5), 662–672.
- Kaushik, N., Kumar, S., Kumar, K., Beniwal, R. S., Kaushik, N. and Roy, S., Genetic variability and association studies in pod and seed traits of Pongamia pinnata (L.) Pierre in Haryana, India. Genet. Res. Crop. Evol., 2007, 54, 1827–1832.
- Maguire, T. L. and Sedgley, M., Genetic diversity in Banksia and Dryandra (Proteaceae) with emphasis on Banksia cuneata, a rare and endangered species. Heredity, 1997, 79, 394–401.
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