利用扩大的类群样本进行膜翅目(昆虫)线粒体基因组重排和系统发生组学研究。

Nan Song, Shu-Jun Wei, Miaomiao Wang
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引用次数: 0

摘要

膜翅目是物种最丰富的昆虫目之一,有超过 150,000 个已描述的现存物种。与假定的昆虫祖先组织相比,许多膜翅目昆虫的线粒体基因组(有丝分裂基因组)组织非常不同。在这项研究中,我们对膜翅目昆虫中的 18 个代表物种的线粒体基因组进行了测序,以增加分类取样。共有 475 个物种被用于系统发育分析,包括 18 个新的有丝分裂基因组和 457 个现有的有丝分裂基因组。与最大似然分析和基于聚合的物种分析相比,利用位点异构模型,贝叶斯氨基酸数据推断得出的膜翅目昆虫之间的关系更加清晰。交翅目的单系性未得到支持。Xyeloidea 是膜翅目中最早出现分支的支系。Orussoidea 与 Apocrita 关系密切。在 Apocrita 中,寄生虫纲是非单系的。大多数寄生虫超科的单系性得到了强有力的支持。在贝叶斯分析中,Proctotrupomorpha 支系得到了支持。在排除 Ampulex compressa 的情况下,Apoidea 是单系的。超科 Vespoidea 和 Chrysidoidea 被认为是非单系的。对线粒体基因顺序的比较显示,寄生生活方式的品系中基因重排的频率较高,这在蛹虫纲中尤为突出。基因重排的程度在鞘翅目(Cynipoidea)和Ichneumonoidea的特定类群中位居第二。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Mitochondrial genome rearrangements and phylogenomics of the Hymenoptera (Insecta) using an expanded taxon sample.

The order Hymenoptera is one of the most species-rich insect orders, with more than 150,000 described extant species. Many hymenopteran insects have very different mitochondrial genome (mitogenome) organizations compared to the putative ancestral organization of insects. In this study, we sequenced 18 mitogenomes of representatives in the order Hymenoptera to increase taxonomic sampling. A total of 475 species were used in phylogenetic analyses, including 18 new mitogenomes and 457 existing mitogenomes. Using a site-heterogeneous model, Bayesian's inference from amino acid data yielded more resolved relationships among Hymenoptera than maximum-likelihood analysis and coalescent-based species analyses. The monophyly of Symphyta was not supported. The Xyeloidea was the earliest branching clade in the Hymenoptera. The Orussoidea was closely related to Apocrita. Within Apocrita, the Parasitoida was non-monophyletic. The monophyly of most Parasitoida superfamilies received strong support. The Proctotrupomorpha clade was supported in Bayesian's analysis. The Apoidea was monophyletic when excluding Ampulex compressa from consideration. The superfamilies Vespoidea and Chrysidoidea were found to be non-monophyletic. Comparisons of mitochondrial gene order revealed a higher frequency of gene rearrangement among lineages with a parasitoid lifestyle, particularly prominent in Chalcidoidea. The degree of gene rearrangement ranked second in specific taxa of Cynipoidea and Ichneumonoidea.

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