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比较功能形态学表明同域分布的海洋爬行动物之间存在生态位划分。

Comparative functional morphology indicates niche partitioning among sympatric marine reptiles.

作者信息

Foffa Davide, Young Mark T, Brusatte Stephen L

机构信息

Department of Geosciences, Virginia Tech, Blacksburg, VA, USA.

School of Geography, Earth and Environmental Sciences, University of Birmingham, Birmingham, UK.

出版信息

R Soc Open Sci. 2024 May 15;11(5):231951. doi: 10.1098/rsos.231951. eCollection 2024 May.

DOI:10.1098/rsos.231951
PMID:39076819
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11285779/
Abstract

Mesozoic marine ecosystems were dominated by diverse lineages of aquatic tetrapods. For over 50 Ma in the Jurassic until the Early Cretaceous, plesiosaurians, ichthyosaurians and thalattosuchian crocodylomorphs coexisted at the top levels of trophic food webs. We created a functional dataset of continuous craniomandibular and dental characters known from neontological studies to be functionally significant in modern aquatic tetrapods. We analysed this dataset with multivariate ordination and inferential statistics to assess functional similarities and differences in the marine reptile faunas of two well-sampled Jurassic ecosystems deposited in the same seaway: the Oxford Clay Formation (OCF, Callovian-early Oxfordian, Middle-Late Jurassic) and the Kimmeridge Clay Formation (KCF, Kimmeridgian-Tithonian, Late Jurassic) of the UK. Lower jaw-based macroevolutionary trends are similar to those of tooth-based diversity studies. Closely related species cluster together, with minimal overlaps in the morphospace. Marine reptile lineages were characterized by the distinctive combinations of features, but we reveal multiple instances of morphofunctional convergence among different groups. We quantitatively corroborate previous observations that the ecosystems in the OCF and KCF were markedly distinct in faunal composition and structure. Morphofunctional differentiation may have enabled specialization and was an important factor facilitating the coexistence of diverse marine reptile assemblages in deep time.

摘要

中生代海洋生态系统由各种水生四足动物谱系主导。在侏罗纪直至早白垩世的5000多万年时间里,蛇颈龙类、鱼龙类和海生鳄形类共存于营养食物网的顶层。我们创建了一个功能性数据集,其中包含从现代生物学研究中得知的、对现代水生四足动物具有功能重要性的连续颅颌和牙齿特征。我们使用多元排序和推断统计分析了这个数据集,以评估沉积在同一条海道中的两个采样良好的侏罗纪生态系统中海洋爬行动物群落在功能上的异同:英国的牛津黏土层(OCF,卡洛夫阶-早牛津阶,侏罗纪中晚期)和金梅尔黏土层(KCF,启莫里阶-提通阶,侏罗纪晚期)。基于下颌的宏观进化趋势与基于牙齿的多样性研究相似。亲缘关系密切的物种聚集在一起,在形态空间中的重叠最小。海洋爬行动物谱系具有独特的特征组合,但我们揭示了不同类群之间多次形态功能趋同的实例。我们定量证实了先前的观察结果,即OCF和KCF中的生态系统在动物组成和结构上明显不同。形态功能分化可能促成了特化,并且是在漫长的时间里促进各种海洋爬行动物组合共存的一个重要因素。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/915d/11285779/58a64802fa61/rsos.231951.f008.jpg
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