Wogan Guinevere O U, Voelker Gary, Oatley Graeme, Bowie Rauri C K
Department of Integrative Biology Museum of Vertebrate Zoology University of California Berkeley CA USA.
Department of Wildlife and Fisheries Sciences Biodiversity Research and Teaching Collections Texas A&M University College Station TX USA.
Ecol Evol. 2020 Mar 27;10(9):4066-4081. doi: 10.1002/ece3.6175. eCollection 2020 May.
Environments are heterogeneous in space and time, and the permeability of landscape and climatic barriers to gene flow may change over time. When barriers are present, they may start populations down the path toward speciation, but if they become permeable before the process of speciation is complete, populations may once more merge. In Southern Africa, aridland biomes play a central role in structuring the organization of biodiversity. These biomes were subject to substantial restructuring during Plio-Pleistocene climatic fluctuations, and the imprint of this changing environment should leave genetic signatures on the species living there. Here, we investigate the role of adjacent aridland biome boundaries in structuring the genetic diversity within a widespread generalist bird, the Cape Robin-chat (). We find evidence supporting a central role for aridland biomes in structuring populations across Southern Africa. Our findings support a scenario wherein populations were isolated in different biome refugia, due to separation by the exceptionally arid Nama Karoo biome. This biome barrier may have arisen through a combination of habitat instability and environmental unsuitability, and was highly unstable throughout the Plio-Pleistocene. However, we also recovered a pattern of extensive contemporary gene flow and admixture across the Nama Karoo, potentially driven by the establishment of homesteads over the past 200 years. Thus, the barrier has become permeable, and populations are currently merging. This represents an instance where initial formation of a barrier to gene flow enabled population differentiation, with subsequent gene flow and the merging of populations after the barrier became permeable.
环境在空间和时间上是异质的,景观和气候屏障对基因流动的渗透性可能会随时间变化。当存在屏障时,它们可能会使种群走上物种形成的道路,但如果在物种形成过程完成之前屏障变得具有渗透性,种群可能会再次融合。在南部非洲,干旱地区生物群落对生物多样性组织的构建起着核心作用。这些生物群落在上新世 - 更新世气候波动期间经历了重大重组,这种不断变化的环境印记应该会在生活在那里的物种上留下遗传特征。在这里,我们研究相邻干旱地区生物群落边界在构建一种分布广泛的泛化鸟类——海角歌鸲(Cape Robin-chat)的遗传多样性中的作用。我们发现证据支持干旱地区生物群落在构建南部非洲各地种群方面发挥核心作用。我们的研究结果支持这样一种情况,即由于异常干旱的纳马夸兰生物群落的分隔,种群被隔离在不同的生物群落避难所中。这种生物群落屏障可能是由于栖息地不稳定和环境不适宜共同作用而产生的,并且在上新世 - 更新世期间一直高度不稳定。然而,我们还发现了一种跨越纳马夸兰的广泛当代基因流动和混合模式,这可能是由过去200年中家园的建立所驱动的。因此,屏障已经变得具有渗透性,种群目前正在融合。这代表了一个例子,即基因流动屏障的最初形成促成了种群分化,随后在屏障变得具有渗透性后出现了基因流动和种群融合。
