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Large- and small-scale geographic structures affecting genetic patterns across populations of an Alpine butterfly

机译:影响阿尔卑斯蝴蝶种群遗传模式的大尺度和小尺度地理结构

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Understanding factors influencing patterns of genetic diversity and the population genetic structure of species is of particular importance in the current era of global climate change and habitat loss. These factors include the evolutionary history of a species as well as heterogeneity in the environment it occupies, which in turn can change across time. Most studies investigating spatio-temporal genetic patterns have focused on patterns across wide geographic areas rather than local variation, but the latter can nevertheless be important particularly in topographically complex areas. Here, we consider these issues in the Sooty Copper butterfly (Lycaena tityrus) from the European Alps, using genome-wide SNPs identified through RADseq. We found strong genetic differentiation within the Alps with four genetic clusters, indicating western, central, and eastern refuges, and a strong reduction of genetic diversity from west to east. This reduction in diversity may suggest that the southwestern refuge was the largest one in comparison to other refuges. Also, the high genetic diversity in the west may result from (a) admixture of different western refuges, (b) more recent demographic changes, or (c) introgression of lowland L. tityrus populations. At small spatial scales, populations were structured by several landscape features and especially by high mountain ridges and large river valleys. We detected 36 outlier loci likely under altitudinal selection, including several loci related to membranes and cellular processes. We suggest that efforts to preserve alpine L. tityrus should focus on the genetically diverse populations in the western Alps, and that the dolomite populations should be treated as genetically distinct management units, since they appear to be currently more threatened than others. This study demonstrates the usefulness of SNP-based approaches for understanding patterns of genetic diversity, gene flow, and selection in a region that is expected to be particularly vulnerable to climate change.
机译:在当前全球气候变化和栖息地丧失的时代,了解影响遗传多样性模式和物种种群遗传结构的因素尤为重要。这些因素包括物种的进化历史以及它所处环境的异质性,而异质性又会随着时间而变化。大多数调查时空遗传模式的研究都集中在广阔地理区域的模式上,而不是局部变异,但后者仍然很重要,特别是在地形复杂的地区。在这里,我们使用通过 RADseq 鉴定的全基因组 SNP 在来自欧洲阿尔卑斯山的烟灰铜蝴蝶 (Lycaena tityrus) 中考虑了这些问题。我们发现阿尔卑斯山内有强烈的遗传分化,有四个遗传簇,表明西部、中部和东部的避难所,以及从西到东的遗传多样性的强烈减少。这种多样性的减少可能表明,与其他避难所相比,西南避难所是最大的避难所。此外,西部的高遗传多样性可能是由于(a)不同西部避难所的混合,(b)最近的人口变化,或(c)低地L. tityrus种群的渗入。在较小的空间尺度上,种群由几个景观特征构成,特别是由高山脊和大河谷构成。我们检测到 36 个可能在海拔选择下的异常位点,包括几个与膜和细胞过程相关的位点。我们建议,保护高山 L. tityrus 的努力应集中在阿尔卑斯山西部的遗传多样性种群上,并且白云石种群应被视为遗传上不同的管理单位,因为它们目前似乎比其他种群受到的威胁更大。这项研究证明了基于SNP的方法对于理解预计特别容易受到气候变化影响的地区的遗传多样性、基因流动和选择模式的有用性。

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