Multiple Regulatory Modules Are Required for Scale-to-Feather Conversion

Wu, Ping; Yan, Jie; Lai, Yung-Chih; Ng, Chen Siang; Li, Ang; Jiang, Xueyuan; Elsey, Ruth M.; Widelitz, Randall B.; Bajpai, Ruchi; Li, Wen-Hsiung; Chuong, Cheng‐Ming

doi:10.1093/molbev/msx295

Cited by 49 publications

(66 citation statements)

References 63 publications

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“…2015 ). Recruitments of multiple regulatory modules of scale-feather converters (SOX2, ZIC1, GREM1, SPRY2, and SOX18) may allow more complex morphogenetic events to occur ( Wu et al. 2018 ).…”

Section: Diversity Of Feather Morphotypementioning

confidence: 99%

“…In addition, bioinformatics analyses of identified genes that are associated with feather and scale differences ( Chang et al. 2015 ; Wu et al. 2018 ) and miRNAs that target the cell signaling, cell adhesion, and cell structure genes required in feather morphogenesis ( Zhang et al.…”

Section: Diversity Of Feather Morphotypementioning

confidence: 99%

“…One lineage of feathered theropod dinosaurs survived the mass extinction and became the ancestor of birds ( Chatterjee 2015 ). Feather is believed to have evolved from scale, and novel scale-feather converters have just been identified ( Wu et al. 2018 ).…”

Section: Introductionmentioning

confidence: 99%

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Genetic and Molecular Basis of Feather Diversity in Birds

2018

Genome Biology and Evolution

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Feather diversity is striking in many aspects. Although the development of feather has been studied for decades, genetic and genomic studies of feather diversity have begun only recently. Many questions remain to be answered by multidisciplinary approaches. In this review, we discuss three levels of feather diversity: Feather morphotypes, intraspecific variations, and interspecific variations. We summarize recent studies of feather evolution in terms of genetics, genomics, and developmental biology and provide perspectives for future research. Specifically, this review includes the following topics: 1) Diversity of feather morphotype; 2) feather diversity among different breeds of domesticated birds, including variations in pigmentation pattern, in feather length or regional identity, in feather orientation, in feather distribution, and in feather structure; and 3) diversity of feathers among avian species, including plumage color and morph differences between species and the regulatory differences in downy feather development between altricial and precocial birds. Finally, we discussed future research directions.

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Section: Diversity Of Feather Morphotypementioning

confidence: 99%

Section: Diversity Of Feather Morphotypementioning

confidence: 99%

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Genetic and Molecular Basis of Feather Diversity in Birds

2018

Genome Biology and Evolution

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“…Until today, there is no simple model to explain why so many molecules can make feathered feet (ptilopody). More recently, we have found five novel molecules (Sox2, Zic1, Grem1, Spry2 and Sox18) expressed in the mesenchyme that have the ability to convert scale forming skin toward feather morphogenesis [ 17 ]. Each of these molecules seems to act along a different molecular pathway toward the morphological conversion of scales to feathers.…”

Section: Introductionmentioning

confidence: 99%

“…Each of these molecules seems to act along a different molecular pathway toward the morphological conversion of scales to feathers. Based on these findings, we postulate these molecular modules are part of a larger morpho-regulatory gene network that may have been co-opted in evolution to generate diverse appendage types, in this case, feathers and scales [ 17 ]. It should be noted avian scales include tarso-metatarsal scutate scale and plantar reticulate scales [ 2 ] and we only study scutate scales in this paper.…”

Section: Introductionmentioning

confidence: 99%

Transcriptome analyses of reprogrammed feather / scale chimeric explants revealed co-expressed epithelial gene networks during organ specification

et al. 2018

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BackgroundThe molecular mechanism controlling regional specific skin appendage phenotypes is a fundamental question that remains unresolved. We recently identified feather and scale primordium associated genes and with functional studies, proposed five major modules are involved in scale-to-feather conversion and their integration is essential to form today’s feathers. Yet, how the molecular networks are wired and integrated at the genomic level is still unknown.ResultsHere, we combine classical recombination experiments and systems biology technology to explore the molecular mechanism controlling cell fate specification. In the chimeric explant, dermal fate is more stable, while epidermal fate is reprogrammed to be similar to the original appendage type of the mesenchyme. We analyze transcriptome changes in both scale-to-feather and feather-to-scale transition in the epidermis. We found a highly interconnected regulatory gene network controlling skin appendage types. These gene networks are organized around two molecular hubs, β-catenin and retinoic acid (RA), which can bind to regulatory elements controlling downstream gene expression, leading to scale or feather fates. ATAC sequencing analyses revealed about 1000 altered widely distributed chromatin open sites. We find that perturbation of a key gene alters the expression of many other co-expressed genes in the same module.ConclusionsOur findings suggest that these feather / scale fate specification genes form an interconnected network and rewiring of the gene network can lead to changes of appendage phenotypes, acting similarly to endogenous reprogramming at the tissue level. This work shows that key hub molecules, β-catenin and retinoic acid, regulate scale / feather fate specification gene networks, opening up new possibilities to understand the switches controlling organ phenotypes in a two component (epithelial and mesenchyme) system.Electronic supplementary materialThe online version of this article (10.1186/s12864-018-5184-x) contains supplementary material, which is available to authorized users.

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Comparison of vertebrate skin structure at class level: A review

Akat

Yenmiş

Pombal

et al. 2022

The Anatomical Record

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The skin is a barrier between the internal and external environment of an organism. Depending on the species, it participates in multiple functions. The skin is the organ that holds the body together, covers and protects it, and provides communication with its environment. It is also the body's primary line of defense, especially for anamniotes. All vertebrates have multilayered skin composed of three main layers: the epidermis, the dermis, and the hypodermis. The vital mission of the integument in aquatic vertebrates is mucus secretion. Cornification began in apmhibians, improved in reptilians, and endured in avian and mammalian epidermis. The feather, the most ostentatious and functional structure of avian skin, evolved in the Mesozoic period. After the extinction of the dinosaurs, birds continued to diversify, followed by the enlargement, expansion, and diversification of mammals, which brings us to the most complicated skin organization of mammals with differing glands, cells, physiological pathways, and the evolution of hair. Throughout these radical changes, some features were preserved among classes such as basic dermal structure, pigment cell types, basic coloration genetics, and similar sensory features, which enable us to track the evolutionary path. The structural and physiological properties of the skin in all classes of vertebrates are presented. The purpose of this review is to go all the way back to the agnathans and follow the path step by step up to mammals to provide a comparative large and updated survey about vertebrate skin in terms of morphology, physiology, genetics, ecology, and immunology.

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Multiple Regulatory Modules Are Required for Scale-to-Feather Conversion

Cited by 49 publications

References 63 publications

Genetic and Molecular Basis of Feather Diversity in Birds

Genetic and Molecular Basis of Feather Diversity in Birds

Transcriptome analyses of reprogrammed feather / scale chimeric explants revealed co-expressed epithelial gene networks during organ specification

Comparison of vertebrate skin structure at class level: A review

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