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Genes & Genomics

, Volume 41, Issue 4, pp 381–387 | Cite as

Genetic diversity and population structure of Lychnis wilfordii (Caryophyllaceae) with newly developed 17 microsatellite markers

  • Bora Kim
  • Koh Nakamura
  • Saya Tamura
  • Byoung Yoon Lee
  • Myounghai KwakEmail author
Research Article

Abstract

Lychnis wilfordii (Regel) Maxim. is a perennial plant designated as an endangered species by the Korean government because of rapid reduction in its population size. Thus, a population genetic study of this species is needed to establish the strategy for management and conservation based on scientific evidences. The goals of this study were to develop useful microsatellite markers for L. wilfordii and to understand current genetic status of L. wilfordii in Korean peninsula. Seventeen microsatellite markers were identified using next-generation sequencing and bioinformatic analysis and then analyzed genetic diversity in one hundred forty-five individuals from Korea (KI1, KI2, and KP), China (CX, CF) and Russia (RP). Analysis of molecular variance (AMOVA), principal coordinates analysis (PCoA) and STRUCTURE results consistently showed discontinuity among L. wilfordii populations. AMOVA showed that the percentage of variation among populations was 53%, which was higher than the variation within populations (19%). PCoA showed that the populations were divided into three genetic clusters, (1) Chinese (CX, CF), (2) Russian (RP) populations and Korean populations (KI1, KI2) excluding KP, and (3) the KP population. In particular, KP, the most southern population on the Korean peninsula, showed significantly lower observed and expected heterozygosity, number of effective alleles, and Shannon index (I) than those of KI1 and KI2. L. wilfordii showed high differentiation between populations with low genetic diversity within populations. Among Korean populations, KP is likely to be affected by genetic drift due to small population size, low genetic diversity and limited gene flow.

Keywords

Lychnis wilfordii Microsatellite Genetic diversity Population structure Genetic drift 

Notes

Acknowledgements

This work was supported by a grant from the National Institute of Biological Resources (NIBR), funded by the Ministry of Environment (MOE) of the Republic of Korea (NIBR201703101). The authors gratefully acknowledge the contributions of Jong-Soo Kang and Jaram Hong at the National Institute of Biological Resources, the late Dr. Kozhevnikov at the Institute of Biology and Soil Science of the Russian Academy of Sciences and Dr. Xian-chun Zhang at Institute of Botany, Chinese Academy of Sciences for sample collection.

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Copyright information

© The Genetics Society of Korea and Springer Nature B.V. 2018

Authors and Affiliations

  1. 1.Plant Resources DivisionNational Institute of Biological ResourcesIncheonRepublic of Korea
  2. 2.Botanical Garden, Field Science Center for Northern BiosphereHokkaido UniversitySapporoJapan
  3. 3.Japan Wildlife Research CenterTokyoJapan

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