Boyd Bret M, Allen Julie M, de Crécy-Lagard Valérie, Reed David L
Florida Museum of Natural History, University of Florida, Gainesville, Florida 32611 Genetics and Genomics Graduate Program, University of Florida, Gainesville, Florida 32610
Illinois Natural History Survey, University of Illinois at Urbana-Champaign, Champaign, Illinois 61820.
G3 (Bethesda). 2014 Sep 11;4(11):2189-95. doi: 10.1534/g3.114.012567.
The obligate-heritable endosymbionts of insects possess some of the smallest known bacterial genomes. This is likely due to loss of genomic material during symbiosis. The mode and rate of this erosion may change over evolutionary time: faster in newly formed associations and slower in long-established ones. The endosymbionts of human and anthropoid primate lice present a unique opportunity to study genome erosion in newly established (or young) symbionts. This is because we have a detailed phylogenetic history of these endosymbionts with divergence dates for closely related species. This allows for genome evolution to be studied in detail and rates of change to be estimated in a phylogenetic framework. Here, we sequenced the genome of the chimpanzee louse endosymbiont (Candidatus Riesia pediculischaeffi) and compared it with the closely related genome of the human body louse endosymbiont. From this comparison, we found evidence for recent genome erosion leading to gene loss in these endosymbionts. Although gene loss was detected, it was not significantly greater than in older endosymbionts from aphids and ants. Additionally, we searched for genes associated with B-vitamin synthesis in the two louse endosymbiont genomes because these endosymbionts are believed to synthesize essential B vitamins absent in the louse's diet. All of the expected genes were present, except those involved in thiamin synthesis. We failed to find genes encoding for proteins involved in the biosynthesis of thiamin or any complete exogenous means of salvaging thiamin, suggesting there is an undescribed mechanism for the salvage of thiamin. Finally, genes encoding for the pantothenate de novo biosynthesis pathway were located on a plasmid in both taxa along with a heat shock protein. Movement of these genes onto a plasmid may be functionally and evolutionarily significant, potentially increasing production and guarding against the deleterious effects of mutation. These data add to a growing resource of obligate endosymbiont genomes and to our understanding of the rate and mode of genome erosion in obligate animal-associated bacteria. Ultimately sequencing additional louse p-endosymbiont genomes will provide a model system for studying genome evolution in obligate host associated bacteria.
昆虫的专性遗传性内共生菌拥有一些已知最小的细菌基因组。这可能是由于共生过程中基因组物质的丢失。这种侵蚀的方式和速率可能会随进化时间而变化:在新形成的共生关系中较快,而在长期建立的共生关系中较慢。人类和类人猿灵长类虱子的内共生菌为研究新建立(或年轻)共生菌的基因组侵蚀提供了独特的机会。这是因为我们有这些内共生菌的详细系统发育史以及密切相关物种的分化日期。这使得能够详细研究基因组进化,并在系统发育框架内估计变化速率。在这里,我们对黑猩猩虱子内共生菌(暂定名为里氏虱内共生菌)的基因组进行了测序,并将其与人体虱子内共生菌的密切相关基因组进行了比较。通过这种比较,我们发现了近期基因组侵蚀导致这些内共生菌基因丢失的证据。尽管检测到了基因丢失,但它并不比蚜虫和蚂蚁中较古老的内共生菌显著更大。此外,我们在两种虱子内共生菌基因组中搜索了与B族维生素合成相关的基因,因为这些内共生菌被认为能合成虱子饮食中缺乏的必需B族维生素。除了参与硫胺素合成的基因外,所有预期的基因都存在。我们未能找到编码参与硫胺素生物合成的蛋白质的基因或任何完整的硫胺素补救外源途径,这表明存在一种未描述的硫胺素补救机制。最后,编码泛酸从头生物合成途径的基因与一个热休克蛋白一起位于两个分类群的质粒上。这些基因转移到质粒上可能在功能和进化上具有重要意义,可能会增加产量并防止突变的有害影响。这些数据增加了专性内共生菌基因组的不断增长的资源,并增进了我们对专性动物相关细菌基因组侵蚀速率和方式的理解。最终,对更多虱子p型内共生菌基因组进行测序将为研究专性宿主相关细菌的基因组进化提供一个模型系统。
