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个体空间聚集与睫毛剪秋罗(石竹科)精细尺度遗传结构的种群间变异相关。

Individual spatial aggregation correlates with between-population variation in fine-scale genetic structure of Silene ciliata (Caryophyllaceae).

作者信息

Lara-Romero C, García-Fernández A, Robledo-Arnuncio J J, Roumet M, Morente-López J, López-Gil A, Iriondo J M

机构信息

Biodiversity and Conservation Area, School of Experimental Sciences (ESCET), Universidad Rey Juan Carlos, Madrid, Spain.

Department of Forest Ecology and Genetics, INIA-CIFOR, Madrid, Spain.

出版信息

Heredity (Edinb). 2016 May;116(5):417-23. doi: 10.1038/hdy.2015.102. Epub 2015 Nov 25.

DOI:10.1038/hdy.2015.102
PMID:26604191
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4834382/
Abstract

Fine-scale genetic structure (FSGS) can vary among populations within species depending on multiple demographic and environmental factors. Theoretical models predict that FSGS should decrease in high-density populations and increase in populations where individuals are spatially aggregated. However, few empirical studies have compared FSGS between populations with different degrees of individual spatial aggregation and microhabitat heterogeneity. In this work, we studied the relationship between spatial and genetic structure in five populations of alpine specialist Silene ciliata Poiret (Caryophyllaceae). We mapped all individuals in each population and genotyped 96 of them using 10 microsatellite markers. We found significant FSGS consistent with an isolation-by-distance process in three of the five populations. The intensity of FSGS was positively associated with individual spatial aggregation. However, no association was found between FSGS and global population density or microhabitat heterogeneity. Overall, our results support theoretical studies indicating that stronger spatial aggregation tends to increase the magnitude of FSGS. They also highlight the relevance of characterizing local plant distribution and microhabitat to better understand the mechanisms that generate intraspecific variation in FSGS across landscapes.

摘要

精细尺度遗传结构(FSGS)在物种内的不同种群间可能会有所不同,这取决于多种人口统计学和环境因素。理论模型预测,FSGS在高密度种群中应会降低,而在个体呈空间聚集分布的种群中会增加。然而,很少有实证研究比较过不同个体空间聚集程度和微生境异质性的种群之间的FSGS。在这项研究中,我们调查了高山特有植物睫毛剪秋罗(石竹科)五个种群的空间结构与遗传结构之间的关系。我们绘制了每个种群中所有个体的分布图,并使用10个微卫星标记对其中96个个体进行了基因分型。我们发现,在五个种群中的三个种群里,存在与距离隔离过程一致的显著FSGS。FSGS的强度与个体空间聚集呈正相关。然而,未发现FSGS与总体种群密度或微生境异质性之间存在关联。总体而言,我们的结果支持了理论研究,即更强的空间聚集往往会增加FSGS的程度。它们还强调了描述当地植物分布和微生境对于更好地理解在不同景观中产生FSGS种内变异机制的重要性。

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