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Genetic Diversity and Spatial Structure in Populations of Abelia tyaihyoni  

Jeong, Ji-Hee (Division of Biotechnology, College of Life Sciences and Biotechnology, Korea University)
Kim, Kyu-Sick (Division of Forest Resources Conservation, Korea National Arboretum)
Lee, Cheul-Ho (Division of Forest Resources Conservation, Korea National Arboretum)
Kim, Zin-Suh (Division of Biotechnology, College of Life Sciences and Biotechnology, Korea University)
Publication Information
Journal of Korean Society of Forest Science / v.96, no.6, 2007 , pp. 667-675 More about this Journal
Abstract
The genetic diversity and the spatial structure in two populations of Abelia tyaihyoni in Yeongwol region were studied by employing I-SSR markers. In spite of the limited distribution and small population sizes of Abelia tyaihyoni, the amount of genetic diversity estimated at the individual level was comparable to other shrub species (S.I.=0.336, h=0.217). Genetic diversity at the genet level was very similar to that at individual level. (S.l.=0.339, h=0.219). About 18.7 percent of total variation was allocated between two populations, which was slightly higher or similar level as compared with other shrub species. Genotypic diversity estimated by the ratio of the number of genets ($N_G$) over the total number of individuals (N) and a modified Simpson's index ($D_G$) were also higher than those of other shrubs. The maximum diameter of a genet did not exceed 5.5 m. The high level of gene and genotypic diversity, and the relatively limited maximum diameter of a genet suggested that the clonal propagation is not the most dominant factor in determining the population structure of Abelia tyaihyoni. Spatial autocorrelation analysis revealed significant spatial genetic structure within 12 m and 18 m distances in two populations A and B, respectively. Autocorrelations among individuals at the both individual and genet levels in each population didn't show any considerable differences. As a sampling strategy for ex-situ conservation of populations showing continuous distribution, a minimum distance of 18 m between individuals was recommended. For the populations with many segments, it was considered very crucial to sample materials from as many segments as possible.
Keywords
Abelia tyaihyoni; I-SSR marker; spatial genetic structure; genetic diversity; genotypic diversity;
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Times Cited By KSCI : 4  (Citation Analysis)
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