A Stress Response Program at the Origin of Evolutionary Innovation in the Skin

Overview

Journal Evol Bioinform Online

Publisher Sage Publications

Specialty Biology

Date 2019 Jul 20

PMID 31322629

Citations 10

Authors

Leopold Eckhart

Florian Ehrlich

Erwin Tschachler

Affiliations

Soon will be listed here.

Abstract

The skin epithelium, ie, the epidermis, of dolphins and whales (cetaceans) is up to 50 times thicker than that of humans and other mammals living on land. Recently, comparative genomics revealed further striking differences in the cytoskeleton of the outer layers of the epidermis in aquatic and terrestrial mammals. Cetaceans lack the cytoskeletal keratins, which make up more than half of the total protein mass in the cornified epidermal layer of terrestrial mammals under homeostatic conditions. By contrast, orthologs of stress-inducible epithelial keratins are conserved in cetaceans and these keratins are constitutively expressed in their skin. Thus, the epidermal stress response program of a terrestrial common ancestor of modern mammals has become the default program of epidermal differentiation and a central component of the unique cutaneous organization of cetaceans. We propose that phenotypic plasticity during stress responses plays important roles in the evolution of the skin.

Citing Articles

Three stepwise pH progressions in stratum corneum for homeostatic maintenance of the skin.

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Validating a Non-Invasive Method for Assessing Cortisol Concentrations in Scraped Epidermal Skin from Common Bottlenose Dolphins and Belugas.

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Comparative genomics of sirenians reveals evolution of filaggrin and caspase-14 upon adaptation of the epidermis to aquatic life.

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Cetacean epidermal specialization: A review.

Menon G, Elias P, Wakefield J, Crumrine D Anat Histol Embryol. 2022; 51(5):563-575.

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Defining Wound Healing Progression in Cetacean Skin: Characteristics of Full-Thickness Wound Healing in Fraser's Dolphins ().

Su C, Hughes M, Liu T, Chuong C, Wang H, Yang W Animals (Basel). 2022; 12(5).

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