A microCT-based atlas of the central nervous system and midgut in sea spiders (Pycnogonida) sheds first light on evolutionary trends at the family level

IF 2.6 2区生物学 Q1 ZOOLOGY

Frontiers in Zoology Pub Date : 2022-03-31 DOI:10.1186/s12983-022-00459-8

Frankowski, Karina, Miyazaki, Katsumi, Brenneis, Georg

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引用次数: 5

Abstract

Pycnogonida (sea spiders) is the sister group of all other extant chelicerates (spiders, scorpions and relatives) and thus represents an important taxon to inform early chelicerate evolution. Notably, phylogenetic analyses have challenged traditional hypotheses on the relationships of the major pycnogonid lineages (families), indicating external morphological traits previously used to deduce inter-familial affinities to be highly homoplastic. This erodes some of the support for phylogenetic information content in external morphology and calls for the study of additional data classes to test and underpin in-group relationships advocated in molecular analyses. In this regard, pycnogonid internal anatomy remains largely unexplored and taxon coverage in the studies available is limited. Based on micro-computed X-ray tomography and 3D reconstruction, we created a comprehensive atlas of in-situ representations of the central nervous system and midgut layout in all pycnogonid families. Beyond that, immunolabeling for tubulin and synapsin was used to reveal selected details of ganglionic architecture. The ventral nerve cord consistently features an array of separate ganglia, but some lineages exhibit extended composite ganglia, due to neuromere fusion. Further, inter-ganglionic distances and ganglion positions relative to segment borders vary, with an anterior shift in several families. Intersegmental nerves target longitudinal muscles and are lacking if the latter are reduced. Across families, the midgut displays linear leg diverticula. In Pycnogonidae, however, complex multi-branching diverticula occur, which may be evolutionarily correlated with a reduction of the heart. Several gross neuroanatomical features are linked to external morphology, including intersegmental nerve reduction in concert with trunk segment fusion, or antero-posterior ganglion shifts in partial correlation to trunk elongation/compaction. Mapping on a recent phylogenomic phylogeny shows disjunct distributions of these traits. Other characters show no such dependency and help to underpin closer affinities in sub-branches of the pycnogonid tree, as exemplified by the tripartite subesophageal ganglion of Pycnogonidae and Rhynchothoracidae. Building on this gross anatomical atlas, future studies should now aim to leverage the full potential of neuroanatomy for phylogenetic interrogation by deciphering pycnogonid nervous system architecture in more detail, given that pioneering work on neuron subsets revealed complex character sets with unequivocal homologies across some families.

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基于微ct的海蜘蛛(Pycnogonida)中枢神经系统和中肠图谱首次揭示了家族水平上的进化趋势

海蜘蛛是所有现存螯合动物(蜘蛛、蝎子及其近亲)的姐妹类群，因此是早期螯合动物进化的一个重要分类群。值得注意的是，系统发育分析挑战了传统的关于主要蛇蛛谱系(家族)关系的假设，表明以前用于推断家族间亲缘关系的外部形态特征是高度同质的。这削弱了外部形态学中系统发育信息内容的一些支持，并要求研究额外的数据类别来测试和支持分子分析中提倡的群体内关系。在这方面，锥虫的内部解剖结构仍然很大程度上未被探索，现有研究的分类覆盖范围有限。基于微型计算机x射线断层扫描和3D重建，我们创建了一个全面的地图集，包括所有pynogonid家族的中枢神经系统和中肠布局。除此之外，微管蛋白和突触蛋白的免疫标记被用来揭示神经节结构的选定细节。腹侧神经束始终以一系列独立的神经节为特征，但由于神经细胞融合，某些谱系表现出扩展的复合神经节。此外，神经节间距离和相对于节段边界的神经节位置各不相同，在几个科中有前移。节间神经以纵肌为目标，纵肌萎缩时神经缺失。跨科，中肠显示线性腿憩室。然而，在碧萝蛛科中，复杂的多分支憩室出现，这可能与心脏的缩小在进化上相关。一些大体的神经解剖学特征与外部形态学有关，包括与躯干节段融合相一致的节间神经复位，或与躯干伸长/压实部分相关的前后神经节移位。最近的系统基因组系统发育图显示了这些特征的不相交分布。其他性状则没有这种依赖性，并有助于巩固碧果科亚分支之间更密切的亲缘关系，如碧果科和舌胸科的食道下神经节。在这个大体解剖图谱的基础上，未来的研究现在应该致力于利用神经解剖学的全部潜力，通过更详细地破译巨核神经系统结构来进行系统发育研究，因为在神经元子集上的开创性工作揭示了一些家族中具有明确同源性的复杂字符集。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Frontiers in Zoology ZOOLOGY-

CiteScore

4.90

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Frontiers in Zoology is an open access, peer-reviewed online journal publishing high quality research articles and reviews on all aspects of animal life. As a biological discipline, zoology has one of the longest histories. Today it occasionally appears as though, due to the rapid expansion of life sciences, zoology has been replaced by more or less independent sub-disciplines amongst which exchange is often sparse. However, the recent advance of molecular methodology into "classical" fields of biology, and the development of theories that can explain phenomena on different levels of organisation, has led to a re-integration of zoological disciplines promoting a broader than usual approach to zoological questions. Zoology has re-emerged as an integrative discipline encompassing the most diverse aspects of animal life, from the level of the gene to the level of the ecosystem. Frontiers in Zoology is the first open access journal focusing on zoology as a whole. It aims to represent and re-unite the various disciplines that look at animal life from different perspectives and at providing the basis for a comprehensive understanding of zoological phenomena on all levels of analysis. Frontiers in Zoology provides a unique opportunity to publish high quality research and reviews on zoological issues that will be internationally accessible to any reader at no cost. The journal was initiated and is supported by the Deutsche Zoologische Gesellschaft, one of the largest national zoological societies with more than a century-long tradition in promoting high-level zoological research.