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化石昆虫的产卵器和口器支持了早期直翅目昆虫在 3 亿年前森林中的一种新的生态角色。

Ovipositor and mouthparts in a fossil insect support a novel ecological role for early orthopterans in 300 million years old forests.

机构信息

College of Life Sciences and Academy for Multidisciplinary Studies, Capital Normal University, Beijing, China.

Institute of Ecological Agriculture, College of Agronomy, Sichuan Agricultural University, Chengdu, China.

出版信息

Elife. 2021 Nov 30;10:e71006. doi: 10.7554/eLife.71006.

DOI:10.7554/eLife.71006
PMID:34844668
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8631945/
Abstract

A high portion of the earliest known insect fauna is composed of the so-called 'lobeattid insects', whose systematic affinities and role as foliage feeders remain debated. We investigated hundreds of samples of a new lobeattid species from the Xiaheyan locality using a combination of photographic techniques, including reflectance transforming imaging, geometric morphometrics, and biomechanics to document its morphology, and infer its phylogenetic position and ecological role. sp. nov. possessed a sword-shaped ovipositor with valves interlocked by two ball-and-socket mechanisms, lacked jumping hind-legs, and certain wing venation features. This combination of characters unambiguously supports lobeattids as stem relatives of all living Orthoptera (crickets, grasshoppers, katydids). Given the herein presented and other remains, it follows that this group experienced an early diversification and, additionally, occurred in high individual numbers. The ovipositor shape indicates that ground was the preferred substrate for eggs. Visible mouthparts made it possible to assess the efficiency of the mandibular food uptake system in comparison to a wide array of extant species. The new species was likely omnivorous which explains the paucity of external damage on contemporaneous plant foliage.

摘要

早期已知的昆虫动物群中很大一部分由所谓的“叶角蝉类昆虫”组成,其系统亲缘关系和作为食叶动物的作用仍存在争议。我们使用反射变换成像、几何形态测量和生物力学等摄影技术,对来自 Xiaheyan 产地的一种新的叶角蝉类物种的数百个样本进行了研究,以记录其形态,并推断其系统发育位置和生态作用。 sp. nov. 具有带有由两个球窝机构互锁的阀的剑形产卵器,缺乏跳跃的后足,以及某些翅膀脉序特征。这些特征组合明确支持叶角蝉类是所有活的直翅目(蟋蟀、蚱蜢、螽斯)的祖先。鉴于本文提出的和其他遗骸,可知该组经历了早期多样化,并且个体数量也很高。产卵器的形状表明,地面是产卵的首选基质。可见的口器使其有可能评估与广泛的现存物种相比,下颌食物摄取系统的效率。新物种可能是杂食性的,这解释了同时代植物叶子上外部损伤的缺乏。

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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/13e1/8631945/7ad47eec5195/elife-71006-app1-fig9.jpg
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Phylogenomic analysis sheds light on the evolutionary pathways towards acoustic communication in Orthoptera.系统基因组分析揭示直翅目昆虫声学通讯进化途径。
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