Laboratoire de Paléontologie et Biologie évolutive, Département de biologie, chimie et géographie, Université du Québec à Rimouski, Rimouski, Québec, Canada G5L 3A1.
Department of Biology and Biochemistry, University of Houston, Houston, TX 77204, USA.
Biol Lett. 2023 Feb;19(2):20220454. doi: 10.1098/rsbl.2022.0454. Epub 2023 Feb 22.
Actinopterygians are the most diversified clade of extant vertebrates. Their impressive morphological disparity bears witness to tremendous ecological diversity. Modularity, the organization of biological systems into quasi-independent anatomical/morphological units, is thought to increase evolvability of organisms and facilitate morphological diversification. Our study aims to quantify patterns of variational modularity in a model actinopterygian, the zebrafish (), using three-dimensional geometric morphometrics on osteological structures isolated from micro-CT scans. A total of 72 landmarks were digitized along cranial and postcranial ossified regions of 30 adult zebrafishes. Two methods were used to test modularity hypotheses, the covariance ratio and the distance matrix approach. We find strong support for two modules, one comprised paired fins and the other comprised median fins, that are best explained by functional properties of subcarangiform swimming. While the skull is tightly integrated with the rest of the body, its intrinsic integration is relatively weak supporting previous findings that the fish skull is a modular structure. Our results provide additional support for the recognition of similar hypotheses of modularity identified based on external morphology in various teleosts, and at least two variational modules are proposed. Thus, our results hint at the possibility that internal and external modularity patterns may be congruent.
肉鳍鱼类是现生脊椎动物中多样性最高的类群。它们令人印象深刻的形态差异见证了巨大的生态多样性。模块化是将生物系统组织成准独立的解剖/形态学单元的组织方式,被认为可以增加生物体的可进化性并促进形态多样化。我们的研究旨在使用三维几何形态测量学,对从微 CT 扫描中分离出的骨骼结构,对模式肉鳍鱼(斑马鱼)的变异性模块化模式进行量化。我们在 30 条成年斑马鱼的颅后骨和骨化区域共标记了 72 个标志点。我们使用协方差比和距离矩阵方法来检验模块化假设。我们发现有强烈的证据支持两个模块,一个由成对的鳍组成,另一个由中鳍组成,这两个模块最好由次栉状游泳的功能特性来解释。虽然头骨与身体的其他部分紧密结合,但它的内在整合性相对较弱,这支持了先前的研究结果,即鱼类的头骨是一个模块化结构。我们的研究结果为基于外部形态在各种硬骨鱼中识别类似的模块化假设提供了额外的支持,并且提出了至少两个变异性模块。因此,我们的研究结果表明内部和外部模块化模式可能是一致的。