Aleman Alberto, Arteaga Maria Clara, Gasca-Pineda Jaime, Bello-Bedoy Rafael
Departamento de Biología de la Conservación, Centro de Investigación Científica y de Educación Superior de Ensenada (CICESE), Ensenada, Baja California, México.
Environmental and Life Sciences Graduate Program, Trent University, Peterborough, Ontario, Canada.
Am J Bot. 2024 Sep;111(9):e16385. doi: 10.1002/ajb2.16385. Epub 2024 Aug 7.
Globally, barriers triggered by climatic changes have caused habitat fragmentation and population allopatric divergence. Across North America, oscillations during the Quaternary have played important roles in the distribution of wildlife. Notably, diverse plant species from the Baja California Peninsula in western North America, isolated during the Pleistocene glacial-interglacial cycles, exhibit strong genetic structure and highly concordant divergent lineages across their ranges. A representative plant genus of the peninsula is Yucca, with Y. valida having the widest range. Although a dominant species, it has an extensive distribution discontinuity between 26° N and 27° N, suggesting restricted gene flow. Moreover, historical distribution models indicate the absence of an area with suitable conditions for the species during the Last Interglacial, making it an interesting model for studying genetic divergence.
We assembled 4411 SNPs from 147 plants of Y. valida throughout its range to examine its phylogeography to identify the number of genetic lineages, quantify their genetic differentiation, reconstruct their demographic history and estimate the age of the species.
Three allopatric lineages were identified based on the SNPs. Our analyses support that genetic drift is the driver of genetic differentiation among these lineages. We estimated an age of less than 1 million years for the common ancestor of Y. valida and its sister species.
Habitat fragmentation caused by climatic changes, low dispersal, and an extensive geographical range gap acted as cumulative mechanisms leading to allopatric divergence in Y. valida.
在全球范围内,气候变化引发的障碍导致了栖息地破碎化和种群异域分化。在北美,第四纪的振荡在野生动物分布中发挥了重要作用。值得注意的是,北美西部下加利福尼亚半岛的多种植物物种在更新世冰期 - 间冰期循环中被隔离,在其分布范围内表现出强烈的遗传结构和高度一致的分歧谱系。该半岛的一个代表性植物属是丝兰属,其中瓦利达丝兰(Yucca valida)分布范围最广。尽管它是优势物种,但在北纬26°和27°之间存在广泛的分布间断,这表明基因流动受限。此外,历史分布模型表明,末次间冰期期间不存在适合该物种生存的区域,这使其成为研究遗传分化的有趣模型。
我们从瓦利达丝兰分布范围内的147株植物中组装了4411个单核苷酸多态性(SNP),以研究其系统地理学,确定遗传谱系的数量,量化它们的遗传分化,重建它们的种群历史并估计该物种的年龄。
基于SNP鉴定出三个异域谱系。我们的分析支持遗传漂变是这些谱系间遗传分化的驱动因素。我们估计瓦利达丝兰及其近缘物种的共同祖先年龄小于100万年。
气候变化导致的栖息地破碎化、低扩散率以及广泛的地理范围差距是导致瓦利达丝兰异域分化的累积机制。
