Houttuynia cordata is an important traditional Chinese herb with unresolved genetics and taxonomy, which lead to potential problems in the conservation and utilization of the resource. Inter-simple sequence repeat (ISSR) markers were used to assess the level and distribution of genetic diversity in 226 individuals from 15 populations of H. cordata in China. ISSR analysis revealed low genetic variations within populations but high genetic differentiations among populations. This genetic structure probably mainly reflects the historical association among populations. Genetic cluster analysis showed that the basal clade is composed of populations from Southwest China, and the other populations have continuous and eastward distributions. The structure of genetic diversity in H. cordata demonstrated that this species might have survived in Southwest China during the glacial age, and subsequently experienced an eastern postglacial expansion. Based on the results of genetic analysis, it was proposed that as many as possible targeted populations for conservation be included.
References
[1]
Liang, H.X. On the evolution and distribution in Saururaceae. Acta Bot. Yunnanica 1995, 17, 255–267.
[2]
Fang, W.P. Flora Sichuanica; Sichuan People Press: Chengdu, China, 1981; Volume 1, pp. 126–127.
[3]
Tseng, Y.C. Florae Reipublicae Popularis Sinicae; Science Press: Beijing, China, 1982; Volume 20, p. 8.
[4]
Mihara, T. On the reduction division of Houttuynia cordata Thunb. Bot. Mag. Tokyo 1960, 73, 498.
[5]
Shibata, K.; Miyake, H. Ueber Parthenogenesis bei Houttuynia cordata. Bot. Mag. Tokyo 1908, 22, 141–144.
[6]
Lu, H.M.; Liang, Y.Z.; Yi, L.Z.; Wu, X.J. Anti-inflammatory effect of Houttuynia cordata injection. J. Ethnopharmacol 2006, 104, 245–249.
[7]
Hayashi, K.; Kamiya, M.; Hayashi, T. Virucidal effects of the steam distillate from Houttuynia cordata and its components on HSV-1, influenza virus, and HIV. Planta Med 1995, 61, 237–241.
[8]
Wallace, L.E. Examining the effects of fragmentation on genetic variation in Platanthera leucophaea (Orchidaceae): Inferences from allozyme and random amplified polymorphic DNA markers. Plant Species Biol 2002, 17, 37–49.
[9]
Bego?a, R.M.; Sergio, G.; Nebauer, E.S.; Joel, A.; Caligari, P.S.; Egura, J. Genetic diversity and structure of natural and managed populations of Cedrus atlantica (Pinaceae) assessed using random amplified polymorphic DNA. Am. J. Bot 2005, 92, 875–884.
[10]
Wu, W.; Zheng, Y.L.; Chen, L.; Yang, R.W.; Yan, Z.H.; Wei, Y.M. Isozymes variations among the germplasm resources of Houttuynia in Sichuan. J. Chin. Med. Mater 2002, 25, 695–698.
[11]
Wu, W.; Zheng, Y.L.; Yang, R.W.; Chen, L.; Wei, Y.M. Variation of the chromosome number and cytomixis of Houttuynia cordata from China. Acta Phytotaxonomica Sinica 2003, 41, 245–257.
Moreno, S.; Martin, J.P.; Ortiz, J.M. Inter-simple sequence repeats PCR for characterization of closely related grapevine germplasm. Euphytica 1998, 101, 117–125.
[14]
Nybom, H.; Bartish, I.V. Effects of life history traits and sampling strategies on genetic diversity estimates obtained with RAPD markers in plants. Perspect. Plant Ecol. Evol. Syst 2000, 31, 93–114.
Wu, W.; Zheng, Y.L.; Chen, L.; Wei, Y.M.; Yan, Z.H.; Yang, R.W. PCR-RFLP analysis of cpDNA and mtDNA in the genus Houttuynia in some areas of China. Hereditas 2005, 142, 1–9.
[17]
Barrett, S.C.H.; Kohn, J.K. Genetic and Evolutionary Consequences of Small Population Size in Plants: Implications for Conservation. In Genetics and Conservation of Rare Plants; Falk, D.A., Holsinger, K.E., Eds.; Oxford University Press: New York, NY, USA, 1991.
[18]
Ellstrand, N.C.; Elam, D.R. Population genetic consequences of small population size: Implication for plant conservation. Annu. Rev. Ecol. Syst 1993, 24, 217–242.
[19]
Wu, W.; Zheng, Y.L.; Chen, L.; Wei, Y.M.; Yan, Z.H.; Yang, R.W. RAPD analysis on the germplasm resources of herba Houttuynia. Acta Pharm. Sin 2002, 37, 986–992.
[20]
Zhu, Z.Y.; Zhang, S.L. A new species of Houttuynia medicinal plants in Emeishan. Bull. Bot. Res 2001, 21, 1–2.
[21]
Doyle, J. DNA Protocols for Plants CTAB Total DNA Isolation. In Molecular Techniques in Taxonomy; Hewitt, G.M., Johnston, A., Eds.; Springer: Berlin, Germany, 1991.
[22]
Lynch, M.; Milligan, B.G. Analysis of population genetic structure with RAPD markers. Mol. Ecol 1994, 3, 91–99.
[23]
Lee, S.W.; Ledig, F.T.; Johnson, D.R. Genetic variation at allozyme and RAPD markers in Pinus longaeva (Pinaceae) of the White Mountains, California. Am. J. Bot 2002, 89, 566–577.
[24]
Krauss, S.L. Accurate gene diversity estimates from amplified fragment length polymorphism (AFLP) markers. Mol. Ecol 2000, 9, 1241–1245.
[25]
Arafeh, R.M.H.; Sapir, Y.; Shmida, A.; Iraki, N.; Fragman, O.; Comes, H.P. Patterns of genetic and phenotypic variation in Iris haynei and I. atrofusca (Iris sect. Oncocyclus 5 the Royal Irises) along an ecogeographical gradient in Israel and the West Bank. Mol. Ecol 2002, 11, 39–53.
[26]
Yeh, F.C.; Yang, R.C.; Boyle, T. POPGENE Microsoft Windows-Based Freeware for Population Genetic Analysis. Release 1.31; University of Alberta: Edmonton, Canada, 1999.
[27]
Nei, M. Analysis of gene diversity in subdivided populations. Proc. Natl. Acad. Sci. USA 1973, 70, 3321–3323.
[28]
Lewontin, R.C. The apportionment of human diversity. Evol. Biol 1972, 6, 381–394.
[29]
Slatkin, M.; Barton, N.H. A comparison of three indirect methods for estimating average levels of gene flow. Evolution 1989, 43, 1349–1368.
[30]
Excoffier, L.; Smouse, P.E.; Quattro, J.M. Analysis of molecular variance inferred from metric distances among DNA haplotypes: Application to human mitochondrial DNA restriction data. Genetics 1992, 131, 479–491.
