羽毛的发育、再生和演化。

Development, regeneration, and evolution of feathers.

机构信息

Center for the Integrative and Evolutionary Galliformes Genomics, Taichung, Taiwan.

出版信息

Annu Rev Anim Biosci. 2015;3:169-95. doi: 10.1146/annurev-animal-022513-114127. Epub 2014 Nov 3.

DOI:10.1146/annurev-animal-022513-114127

PMID:25387232

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5662002/

Abstract

The feather is a complex ectodermal organ with hierarchical branching patterns. It provides functions in endothermy, communication, and flight. Studies of feather growth, cycling, and health are of fundamental importance to avian biology and poultry science. In addition, feathers are an excellent model for morphogenesis studies because of their accessibility, and their distinct patterns can be used to assay the roles of specific molecular pathways. Here we review the progress in aspects of development, regeneration, and evolution during the past three decades. We cover the development of feather buds in chicken embryos, regenerative cycling of feather follicle stem cells, formation of barb branching patterns, emergence of intrafeather pigmentation patterns, interplay of hormones and feather growth, and the genetic identification of several feather variants. The discovery of feathered dinosaurs redefines the relationship between feathers and birds. Inspiration from biomaterials and flight research further fuels biomimetic potential of feathers as a multidisciplinary research focal point.

摘要

羽毛是一种具有层次分支模式的复杂外胚层器官。它具有恒温、通讯和飞行等功能。羽毛生长、循环和健康的研究对鸟类生物学和家禽科学具有重要的基础意义。此外，由于羽毛易于获取，并且其独特的图案可用于评估特定分子途径的作用，因此羽毛是形态发生研究的极佳模型。在这里，我们回顾了过去三十年中在发育、再生和进化方面的进展。我们涵盖了鸡胚羽芽的发育、羽毛毛囊干细胞的再生循环、羽枝分支模式的形成、羽毛内色素模式的出现、激素与羽毛生长的相互作用以及几种羽毛变体的遗传鉴定。有羽毛恐龙的发现重新定义了羽毛与鸟类之间的关系。从生物材料和飞行研究中获得的灵感进一步推动了羽毛作为多学科研究重点的仿生潜力。

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