Genetic diversity and gene flow within and between two different habitats of Primula merrilliana (Primulaceae), an endangered distylous forest herb in eastern China

Understanding whether and how different habitats shape population genetics is a fundamental question and a specific goal for evolutionary and conservation biology research. This study examined genetic diversity and gene flow within and between mountain and foothill habitats of Primula merrilliana, a...

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Published inBotanical journal of the Linnean Society Vol. 179; no. 1; pp. 172 - 189
Main Authors Shao, Jian-Wen, Wang, Jian, Xu, Yan-Nian, Pan, Qiang, Shi, Ya, Kelso, Sylvia, Lv, Guo-Sheng
Format Journal Article
LanguageEnglish
Published Oxford Blackwell Publishing Ltd 01.09.2015
Oxford University Press
Subjects
breeding system
chloroplast DNA
genetic structure
microsatellites
population genetics
Primula
Primulaceae
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Summary:Understanding whether and how different habitats shape population genetics is a fundamental question and a specific goal for evolutionary and conservation biology research. This study examined genetic diversity and gene flow within and between mountain and foothill habitats of Primula merrilliana, an endangered distylous forest herb in eastern China. Eleven population characteristics, including area, size and density variation, from the two habitats were also investigated. Mountain populations had significantly higher mean genetic diversity than foothill populations, which may be explained by stronger self‐incompatibility breeding system, more opportunity to use elevational shifts to track suitable sites under conditions of climate change and more heterogeneous environments in the former habitat, rather than by the differences of population size, gene flow and genetic drift intensity between them. Genetic analysis revealed that two distinct lineages, corresponding to the two habitats, diverged at China's ‘Last Glaciation’ (11 700–67 500 yr BP), suggesting this divergence was probably triggered by warmer climates during inter‐ (or post‐) glacial periods. Low unidirectional gene flow from mountain to foothill habitats, chiefly by seed dispersal, played a more important role in overall gene flow between habitats than within‐habitat gene flow. Within habitats, pollen contributes more substantially to gene flow than seed dispersal, especially in foothill habitats, possibly due to higher individual density and larger population sizes. These results have implications for the conservation in this and similar landscape areas and indicate the need to protect suitable habitats with wide elevational spans and sufficient size to permit ecological and elevational shifts in response to climatic changes. © 2015 The Linnean Society of London, Botanical Journal of the Linnean Society, 2015, 179, 172–189.
Bibliography:istex:FB7B5F035791717AE325B90A0A720A4962342447
Table S1. Microsatellite primers used for population samples and diversity arrays, indicating the repeat unit sequence, dye incorporated in the forward primer, allelic size range and number of alleles found across populations. Table S2. Distribution of 35 cpDNA haplotypes per population and GenBank accession numbers of Primula merrilliana. Table S3. Likelihood estimates of MIGRATE of long-term gene flow among 11 sampled populations of P. merrilliana. Table S4. Likelihood estimates of BayesAss of recent genes among 11 sampled populations of P. merrilliana. Table S5. Maximum-likelihood estimates (MLE) and 90% highest posterior density (HPD) intervals of demographic parameters of Primula merrilliana from IMa multilocus analyses. θG, θH and θA refer to the scaled effective population sizes (Ne) of the foothill habitat lineage, the mountain habitat lineage and the ancestral population, respectively. mG-H and mH-G are the scaled migration rates forward in time from the hilly habitat lineage to the mountainous habitat lineage and vice versa. 2NmG-H and 2NmH-G are the effective migration rates (number of migrants per generation). t is the time since ancestral population splitting in mutational units.
National Science Foundation of China - No. 31170317
ark:/67375/WNG-3LW86R13-Z
Anhui Provincial Scientific Research Projects in Universities - No. KJ2011A132
ArticleID:BOJ12305
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0024-4074
1095-8339
DOI:10.1111/boj.12305