鸟类的周期性着色是通过体节起源的预先模式形成的。

The periodic coloration in birds forms through a prepattern of somite origin.

机构信息

Center for Interdisciplinary Research in Biology, CNRS 7241, INSERM U1042, Collège de France, Paris, France.

GenPhySE, Toulouse University, INRA, INPT ENVT 31326, Castanet-Tolosan, France.

出版信息

Science. 2018 Sep 21;361(6408). doi: 10.1126/science.aar4777.

DOI:10.1126/science.aar4777

PMID:30237324

Abstract

The periodic stripes and spots that often adorn animals' coats have been largely viewed as self-organizing patterns, forming through dynamics such as Turing's reaction-diffusion within the developing skin. Whether preexisting positional information also contributes to the periodicity and orientation of these patterns has, however, remained unclear. We used natural variation in colored stripes of juvenile galliform birds to show that stripes form in a two-step process. Autonomous signaling from the somite sets stripe position by forming a composite prepattern marked by the expression profile of Subsequently, regulates stripe width through dose-dependent control of local pigment production. These results reveal that early developmental landmarks can shape periodic patterns upstream of late local dynamics, and thus constrain their evolution.

摘要

动物皮毛上常见的周期性条纹和斑点在很大程度上被视为自组织模式，通过图灵反应扩散等动力学在发育中的皮肤中形成。然而，预先存在的位置信息是否也有助于这些模式的周期性和方向性尚不清楚。我们利用幼年鸟类的有色条纹的自然变异表明条纹是分两步形成的。来自体节的自主信号通过形成一个由表达谱标记的复合前模式来确定条纹的位置随后，通过剂量依赖的局部色素产生控制来调节条纹宽度。这些结果表明，早期发育标志可以在晚期局部动力学之前塑造周期性模式，从而限制它们的进化。

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鸟类的周期性着色是通过体节起源的预先模式形成的。

The periodic coloration in birds forms through a prepattern of somite origin.

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