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通过修订和扩充已发表的最大相关数据矩阵对古生代有肢脊椎动物的系统发育进行重新评估。

Phylogeny of Paleozoic limbed vertebrates reassessed through revision and expansion of the largest published relevant data matrix.

作者信息

Marjanović David, Laurin Michel

机构信息

Science Programme "Evolution and Geoprocesses", Museum für Naturkunde-Leibniz Institute for Evolutionary and Biodiversity Research, Berlin, Germany.

Centre de Recherches sur la Paléobiologie et les Paléoenvironnements (CR2P), Centre national de la Recherche scientifique (CNRS)/Muséum national d'Histoire naturelle (MNHN)/Sorbonne Université, Paris, France.

出版信息

PeerJ. 2019 Jan 4;6:e5565. doi: 10.7717/peerj.5565. eCollection 2019.

DOI:10.7717/peerj.5565
PMID:30631641
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6322490/
Abstract

The largest published phylogenetic analysis of early limbed vertebrates (Ruta M, Coates MI. 2007. 5:69-122) recovered, for example, Seymouriamorpha, Diadectomorpha and (in some trees) Caudata as paraphyletic and found the "temnospondyl hypothesis" on the origin of Lissamphibia (TH) to be more parsimonious than the "lepospondyl hypothesis" (LH)-though only, as we show, by one step. We report 4,200 misscored cells, over half of them due to typographic and similar accidental errors. Further, some characters were duplicated; some had only one described state; for one, most taxa were scored after presumed relatives. Even potentially continuous characters were unordered, the effects of ontogeny were not sufficiently taken into account, and data published after 2001 were mostly excluded. After these issues are improved-we document and justify all changes to the matrix-but no characters are added, we find (Analysis R1) much longer trees with, for example, monophyletic Caudata, Diadectomorpha and (in some trees) Seymouriamorpha; either crownward or rootward of ; and Anthracosauria either crownward or rootward of Temnospondyli. The LH is nine steps shorter than the TH (R2; constrained) and 12 steps shorter than the "polyphyly hypothesis" (PH-R3; constrained). (Lysorophia) is not found next to Lissamphibia; instead, a large clade that includes the adelogyrinids, urocordylid "nectrideans" and aïstopods occupies that position. As expected from the taxon/character ratio, most bootstrap values are low. Adding 56 terminal taxa to the original 102 increases the resolution (and decreases most bootstrap values). The added taxa range in completeness from complete articulated skeletons to an incomplete lower jaw. Even though the lissamphibian-like temnospondyls , and and the extremely peramorphic salamander are added, the difference between LH (R4; unconstrained) and TH (R5) rises to 10 steps, that between LH and PH (R6) to 15; the TH also requires several more regains of lost bones than the LH. , in which we tentatively identify a postbranchial lamina, emerges rather far from amniote origins in a gephyrostegid-chroniosuchian grade. Bayesian inference (Analysis EB, settings as in R4) mostly agrees with R4. High posterior probabilities are found for Lissamphibia (1.00) and the LH (0.92); however, many branches remain weakly supported, and most are short, as expected from the small character sample. We discuss phylogeny, approaches to coding, methods of phylogenetics (Bayesian inference vs. equally weighted vs. reweighted parsimony), some character complexes (e.g. preaxial/postaxial polarity in limb development), and prospects for further improvement of this matrix. Even in its revised state, the matrix cannot provide a robust assessment of the phylogeny of early limbed vertebrates. Sufficient improvement will be laborious-but not difficult.

摘要

例如,已发表的关于早期有肢脊椎动物的最大系统发育分析(鲁塔M,科茨MI。2007年。5:69 - 122)发现,例如壳椎类、离片锥类以及(在某些树状图中)有尾目是并系群,并且发现关于滑体两栖类起源的“块椎类假说”(TH)比“全椎类假说”(LH)更简约——不过正如我们所展示的,仅领先一步。我们报告了4200个计分错误的单元格,其中一半以上是由于排版及类似的偶然错误。此外,一些性状被重复;一些性状只有一种描述状态;对于一个性状而言,大多数分类单元是在假定的亲缘类群之后计分的。甚至潜在的连续性状也未排序,个体发育的影响未得到充分考虑,并且2001年之后发表的数据大多被排除。在对这些问题进行改进之后——我们记录并说明了对矩阵所做的所有更改——但未添加任何性状,我们发现(分析R1)树状图长得多,例如有尾目、离片锥类以及(在某些树状图中)壳椎类是单系群; 在 的冠向或根向;以及炭螈目在块椎类的冠向或根向。全椎类假说比块椎类假说短9步(R2;受限),比“多系群假说”(PH - R3;受限)短12步。(笠头螈目)未在滑体两栖类旁边被发现;相反,一个包括阿氏螈科、尾索螈科“缺肢目动物”和无足目动物的大分支占据了那个位置。正如从分类单元/性状比例所预期的那样,大多数自展值较低。在最初的102个分类单元基础上增加56个终端分类单元提高了分辨率(并降低了大多数自展值)。新增的分类单元完整程度从完整的关节骨骼到不完整的下颌不等。即使添加了类似滑体两栖类的块椎类 、 和 以及极度幼态持续的蝾螈 ,全椎类假说(R4;无约束)和块椎类假说(R5)之间的差异增加到10步,全椎类假说和多系群假说(R6)之间的差异增加到15步;块椎类假说相比全椎类假说还需要更多次重新获得已丢失的骨骼。 在其中我们初步识别出鳃后板,它在一个结节螈 - 久洛鱷类等级中离羊膜动物起源较远的位置出现。贝叶斯推断(分析EB,设置与R4相同)大多与R4一致。滑体两栖类(概率为1.00)和全椎类假说(概率为0.92)具有较高的后验概率;然而,正如从小的性状样本所预期的那样,许多分支的支持度仍然较弱,并且大多数分支较短。我们讨论了系统发育、编码方法、系统发育学方法(贝叶斯推断与等权重简约法与重新加权简约法)、一些性状复合体(例如肢体发育中的轴前/轴后极性)以及进一步改进这个矩阵的前景。即使处于修订状态,该矩阵也无法对早期有肢脊椎动物的系统发育提供可靠的评估。充分的改进将是费力的——但并非难事。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2ef8/6322490/7da867641c0c/peerj-07-5565-g032.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2ef8/6322490/7da867641c0c/peerj-07-5565-g032.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2ef8/6322490/3f08e1ebc453/peerj-07-5565-g020.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2ef8/6322490/6d1a9a0bf2c3/peerj-07-5565-g021.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2ef8/6322490/6f31b1899ec5/peerj-07-5565-g022.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2ef8/6322490/4dee3bb854b3/peerj-07-5565-g023.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2ef8/6322490/3d83ef17c165/peerj-07-5565-g024.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2ef8/6322490/cdef30f3ff43/peerj-07-5565-g025.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2ef8/6322490/1ae3a440ca3f/peerj-07-5565-g026.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2ef8/6322490/8933924268b4/peerj-07-5565-g027.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2ef8/6322490/b8ba15d9e435/peerj-07-5565-g028.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2ef8/6322490/eb90931c9c2c/peerj-07-5565-g029.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2ef8/6322490/168939c7aa46/peerj-07-5565-g030.jpg
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