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Susceptibility to mass extinctions: Ammonites as a case study for integrating morphological, developmental, phylogenetic and biomechanical data

对大规模灭绝的敏感性：菊石作为整合形态学、发育、系统发育和生物力学数据的案例研究

基本信息

批准号：
NE/K014951/1
负责人：
Matthew Wills
金额：
$ 50.67万
依托单位：
University of Bath
依托单位国家：
英国
项目类别：
Research Grant
财政年份：
2014
资助国家：
英国
起止时间：
2014 至无数据
项目状态：
已结题

来源：
https://gtr.ukri.org/projects?ref=NE%2FK014951%2F1
关键词：
Susceptibility mass extinctions Ammonites case

项目摘要

Do present rates of biodiversity loss imply that we are entering a sixth 'mass extinction' comparable to the 'big five' of the geological past? If so, can we predict which species are likely to be hardest hit, and is it possible to identify those groups most likely to re-radiate and diversify in the wake of environmental catastrophe? If so, can we use these findings more broadly for global conservation planning? One way to answer these questions is to follow the evolution of a large group that has repeatedly been hit by mass extinctions, but in which multiple lineages have survived in order to re-radiate. Fossils record a complex series of natural experiments that allow us to make generalisations about parallel phenomena occurring in different branches of the evolutionary tree, and at multiple mass extinction events. Ammonites - perhaps the most iconic and instantly recognisable of all fossil groups - have an exceptional fossil record that is ideally suited for this purpose. Originating in the Devonian they transit the end Devonian, end Permian and end Triassic mass extinction events prior to their demise at the end Cretaceous.Ammonites are uniquely suited to a study of extinction selectivity for several other reasons. Firstly, their shells grow by accreting chambers into a (typically) spiral form, such that all post-embryonic stages are fossilized together. This is important because it allows us to account for developmental changes in morphology (and associated shifts in mode of life). Secondly, the external shells of most ammonites can be modeled very simply in a theoretical morphospace, as well as in more complex empirical morphospaces. The manner in which these spaces are depopulated (e.g., the extinction of extreme morphologies first versus random extinction) at successive mass extinction events will reveal the nature of extinction selectivity. Additionally, by modeling developmental trajectories in allometric and other developmental spaces, we can further test whether particular growth patterns increase the risk of extinction, or promote the radiation of lineages after environmental crises. A third advantage of using ammonites is that (unlike virtually any other swimming animals) their bodies do not deform for locomotion. This makes them particularly suitable for hydrodynamic studies. Do any such biomechanical properties correlate with extinction risk? Ammonites were able to swim by jet propulsion; repeatedly squirting water from a siphon within the mantle. We will model how well, fast and efficiently they were able to swim and manoeuvre using two complementary methods; computational fluid dynamics and physical modeling in water tanks. For the former approach, we will write new software much better-suited to simulating the complex flow around moving and rotating bodies than standard computational fluid dynamics (CFD) packages. For the latter we will use structured light or CT scanning coupled with 3D printing in a variety of media to yield realistically weighted and balanced models. Computer design will further enable us to virtually and physically test any potential ammonite morphology from within the theoretical morphospace. Were many physically possible geometries not realised because they had undesirable hydrodynamic properties, and did ammonites repeatedly converge on the same small sample of efficient designs? Or does the dense packing of ammonite genera in certain regions of morphospace reflect wide variation in hydrodynamic parameters in these same regions (and an associated finer subdivision of niche space)?A central objective of this project is to make all of our data, computer code, software, representative video and results available to the widest possible community of academics, educational users and the public. All will be released under Creative Commons (CC0) and OSI approved licenses, and we will promote their re-use and repurposing in other fields of the natural sciences.

目前的生物多样性丧失速度是否意味着我们正在进入第六次“大灭绝”，与地质历史上的“五大灭绝”相当？如果是这样的话，我们能否预测哪些物种可能受到最严重的打击，以及是否有可能确定那些在环境灾难之后最有可能重新辐射和多样化的群体？如果是这样，我们是否可以将这些发现更广泛地用于全球保护规划？回答这些问题的一种方法是，追踪一个大群体的进化，这个群体多次受到大规模灭绝的打击，但其中多个血统幸存下来，以便重新辐射。化石记录了一系列复杂的自然实验，使我们能够对发生在进化树不同分支和多个大灭绝事件中的平行现象进行概括。菊石-也许是所有化石群中最具标志性和最容易识别的-具有特殊的化石记录，非常适合这一目的。它们起源于泥盆纪，在白垩纪末消亡之前，它们经历了泥盆纪末、二叠纪末和三叠纪末的大规模灭绝事件。首先，它们的壳通过吸积腔生长成（典型的）螺旋形，这样所有的胚后阶段都被聚集在一起。这很重要，因为它使我们能够解释形态学的发育变化（以及相关的生活方式转变）。其次，大多数菊石的外壳可以在理论形态空间以及更复杂的经验形态空间中非常简单地建模。这些空间的人口减少方式（例如，极端形态的灭绝首先与随机灭绝）将揭示灭绝选择性的本质。此外，通过在异速生长和其他发展空间中建模发展轨迹，我们可以进一步测试特定的生长模式是否会增加灭绝的风险，或者在环境危机后促进谱系的辐射。使用菊石的第三个优点是（与几乎任何其他游泳动物不同）它们的身体不会因运动而变形。这使得它们特别适合于流体动力学研究。这些生物力学特性是否与灭绝风险相关？菊石能够通过喷射推进游泳;从地幔内的虹吸管中反复喷出水。我们将使用两种互补的方法来模拟他们能够游泳和操纵的速度，速度和效率;计算流体动力学和水箱中的物理建模。对于前一种方法，我们将编写新的软件，比标准的计算流体动力学（CFD）软件包更适合模拟运动和旋转物体周围的复杂流动。对于后者，我们将使用结构光或CT扫描结合各种介质中的3D打印，以产生逼真的加权和平衡模型。计算机设计将进一步使我们能够从理论形态空间内虚拟和物理地测试任何潜在的菊石形态。许多物理上可能的几何形状没有实现，因为他们有不受欢迎的流体动力学特性，菊石反复收敛在同一个小样本的有效设计？或者，菊石属在某些区域的形态空间的密集包装反映了在这些相同的地区（和相关的更精细的细分生态位空间）的水动力参数的变化很大？该项目的一个中心目标是使我们所有的数据，计算机代码，软件，代表性的视频和结果提供给尽可能广泛的学术界，教育用户和公众。所有这些都将在Creative Commons（CC 0）和OSI批准的许可下发布，我们将促进它们在自然科学的其他领域中的再利用和再利用。