Intraspecific genetic consequences of Pleistocene climate change on Lupinus microphyllus (Fabaceae) in the Andes

IF 2.6 3区 生物学 Q2 PLANT SCIENCES
Diana L. A. Vásquez, Michael Møller Hansen, Henrik Balslev, Roswitha Schmickl
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引用次数: 1

Abstract

The role of Pleistocene climate change in shaping patterns of genetic and species diversity has been widely demonstrated. However, tropical mountains remain less explored. In the northern Andes, distributional shifts of the vegetation during the Pleistocene are believed to have promoted plant diversification. In this regard, the role of gene flow and geographic isolation has been intensively debated. Here, we use a population genetic approach, microsatellite markers, and Bayesian statistics to assess the impact of Pleistocene climate change on intraspecific patterns of gene flow and genetic variation, and on the demographic history of the populations. We study Lupinus microphyllus, which belongs to a clade of Andean Lupinus species that has emerged as a model group in studies of plant diversification. We detect signatures of historical gene flow and negligible contemporary gene flow between populations. We find very low within-population genetic diversity and signals of an ancient decline in population size that may be lasting until today. We conclude that, in spite of periods of increased connectivity and gene flow, intraspecific genetic differentiation is mainly driven by periods of geographic isolation, restricted gene flow, and genetic drift. The intraspecific genetic pattern of high-elevation Andean plant species has been also shaped by local environmental factors, such as volcanic activity or glacier coverage, and by species-specific traits, such as the reproductive and dispersal strategies.

Abstract Image

更新世气候变化对安第斯山脉小叶羽扇豆属植物的种内遗传影响
更新世气候变化在形成遗传和物种多样性模式方面的作用已得到广泛证明。然而,热带山脉的探索仍然较少。在安第斯山脉北部,更新世期间植被的分布变化被认为促进了植物的多样化。在这方面,基因流动和地理隔离的作用一直备受争议。在这里,我们使用种群遗传学方法、微卫星标记和贝叶斯统计来评估更新世气候变化对种内基因流动和遗传变异模式以及种群人口统计学历史的影响。我们研究了小叶羽扇豆,它属于安第斯羽扇豆物种的一个分支,已成为植物多样化研究的模式群体。我们检测了种群之间历史基因流动和可忽略的当代基因流动的特征。我们发现种群内部的遗传多样性非常低,这是种群规模古老下降的信号,可能会持续到今天。我们得出的结论是,尽管存在连通性和基因流动增加的时期,但种内遗传分化主要是由地理隔离期、基因流动受限期和遗传漂移期驱动的。高海拔安第斯植物物种的种内遗传模式也受到当地环境因素的影响,如火山活动或冰川覆盖,以及物种特有的特征,如繁殖和扩散策略。
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来源期刊
Alpine Botany
Alpine Botany PLANT SCIENCES-
CiteScore
5.10
自引率
18.50%
发文量
15
审稿时长
>12 weeks
期刊介绍: Alpine Botany is an international journal providing a forum for plant science studies at high elevation with links to fungal and microbial ecology, including vegetation and flora of mountain regions worldwide.
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