Kyle M Benowitz, Carson W Allan, Coline C Jaworski, Michael J Sanderson, Fernando Diaz, Xingsen Chen, Luciano M Matzkin
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引用次数: 0
摘要
要透彻了解适应和物种变异,就需要既有生态学和表型研究历史,又有全套基因组资源的模式生物。评估基因组结构的进化及其在适应和物种分化中的作用尤其需要高质量的生态模式生物基因组组装。在这里,我们生成了嗜仙人掌果蝇的新基因组,这是了解干旱环境中物种演化和生态适应的一个重要模式支系。我们生成了染色体水平的基因组组装,并为莫哈金果蝇(D. mojavensis)、阿里宗果蝇(D. arizonae)和纳沃乔果蝇(D. navojoa)的七个种群进行了完整的注释。我们首先利用这些数据为该支系建立了迄今为止最稳健的系统进化,并评估了整个系统进化过程中的分子进化模式,结果显示与有关该系统中适应性基因的先验假设一致。我们随后表明,结构进化在整个系统发育过程中以恒定的速度发生,因染色体而异,并且与分子进化相关。这些结果通过展示核心进化遗传模式,并整合这些模式以产生新的基因水平的适应性假说,推进了对 D. mojavensis 支系的了解。我们的数据在一个新的公共数据库(cactusflybase.arzona.edu)中展示,为分析种间和种内进化基因组数据提供了最深入的资源之一。此外,我们预计这里确定的结构进化模式将成为未来比较研究的基线,以确定影响不同类群基因组结构进化的因素。
Fundamental Patterns of Structural Evolution Revealed by Chromosome-Length Genomes of Cactophilic Drosophila.
A thorough understanding of adaptation and speciation requires model organisms with both a history of ecological and phenotypic study as well as a complete set of genomic resources. In particular, high-quality genome assemblies of ecological model organisms are needed to assess the evolution of genome structure and its role in adaptation and speciation. Here, we generate new genomes of cactophilic Drosophila, a crucial model clade for understanding speciation and ecological adaptation in xeric environments. We generated chromosome-level genome assemblies and complete annotations for seven populations across Drosophila mojavensis, Drosophila arizonae, and Drosophila navojoa. We use these data first to establish the most robust phylogeny for this clade to date, and to assess patterns of molecular evolution across the phylogeny, showing concordance with a priori hypotheses regarding adaptive genes in this system. We then show that structural evolution occurs at constant rate across the phylogeny, varies by chromosome, and is correlated with molecular evolution. These results advance the understanding of the D. mojavensis clade by demonstrating core evolutionary genetic patterns and integrating those patterns to generate new gene-level hypotheses regarding adaptation. Our data are presented in a new public database (cactusflybase.arizona.edu), providing one of the most in-depth resources for the analysis of inter- and intraspecific evolutionary genomic data. Furthermore, we anticipate that the patterns of structural evolution identified here will serve as a baseline for future comparative studies to identify the factors that influence the evolution of genome structure across taxa.
期刊介绍:
About the journal
Genome Biology and Evolution (GBE) publishes leading original research at the interface between evolutionary biology and genomics. Papers considered for publication report novel evolutionary findings that concern natural genome diversity, population genomics, the structure, function, organisation and expression of genomes, comparative genomics, proteomics, and environmental genomic interactions. Major evolutionary insights from the fields of computational biology, structural biology, developmental biology, and cell biology are also considered, as are theoretical advances in the field of genome evolution. GBE’s scope embraces genome-wide evolutionary investigations at all taxonomic levels and for all forms of life — within populations or across domains. Its aims are to further the understanding of genomes in their evolutionary context and further the understanding of evolution from a genome-wide perspective.