Lucek Kay
Department of Environmental Sciences, University of Basel, Schönbeinstrasse 6, 4056 Basel, Switzerland.
Genes (Basel). 2018 Mar 16;9(3):166. doi: 10.3390/genes9030166.
The evolution of intrinsic barriers to gene flow is a crucial step in the process of speciation. Chromosomal changes caused by fusion and fission events are one such barrier and are common in several groups of Lepidoptera. However, it remains unclear if and how chromosomal changes have contributed to speciation in this group. I tested for a phylogenetic signal of varying chromosome numbers in butterflies by combining existing sequence data with karyological information. I also compared different models of trait evolution in order to infer the underlying evolutionary mechanisms. Overall, I found significant phylogenetic signals that are consistent with non-neutral trait evolution only when parts of the mitochondrial genome were included, suggesting cytonuclear discordances. The adaptive evolutionary model tested in this study consistently outperformed the neutral model of trait evolution. Taken together, these results suggest that, unlike other Lepidoptera groups, changes in chromosome numbers may have played a role in the diversification of butterflies.
基因流内在障碍的演变是物种形成过程中的关键一步。由融合和裂变事件引起的染色体变化就是这样一种障碍,在鳞翅目几个类群中很常见。然而,染色体变化是否以及如何促成了该类群的物种形成仍不清楚。我通过将现有序列数据与核型信息相结合,来检测蝴蝶中染色体数目变化的系统发育信号。我还比较了不同的性状进化模型,以推断潜在的进化机制。总体而言,我发现只有当包含部分线粒体基因组时,才存在与非中性性状进化一致的显著系统发育信号,这表明了细胞核与细胞质的不一致。本研究中测试的适应性进化模型始终优于性状进化的中性模型。综上所述,这些结果表明,与其他鳞翅目类群不同,染色体数目的变化可能在蝴蝶的多样化过程中发挥了作用。