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  • Disrupted ectodermal organ morphogenesis in mice with a conditional histone deacetylase 1, 2 deletion in the epidermis.

Disrupted ectodermal organ morphogenesis in mice with a conditional histone deacetylase 1, 2 deletion in the epidermis.

The Journal of investigative dermatology (2013-06-25)
Michael W Hughes, Ting-Xin Jiang, Sung-Jan Lin, Yvonne Leung, Krzysztof Kobielak, Randall B Widelitz, Cheng M Chuong
ABSTRACT

Histone deacetylases (HDACs) are present in the epidermal layer of the skin, outer root sheath, and hair matrix. To investigate how histone acetylation affects skin morphogenesis and homeostasis, mice were generated with a K14 promoter-mediated reduction of Hdac1 or Hdac2. The skin of HDAC1 null (K14-Cre Hdac1(cKO/cKO)) mice exhibited a spectrum of lesions, including irregularly thickened interfollicular epidermis, alopecia, hair follicle dystrophy, claw dystrophy, and abnormal pigmentation. Hairs are sparse, short, and intermittently coiled. The distinct pelage hair types are lost. During the first hair cycle, hairs are lost and replaced by dystrophic hair follicles with dilated infundibulae. The dystrophic hair follicle epithelium is stratified and is positive for K14, involucrin, and TRP63, but negative for keratin 10. Some dystrophic follicles are K15 positive, but mature hair fiber keratins are absent. The digits form extra hyperpigmented claws on the lateral sides. Hyperpigmentation is observed in the interfollicular epithelium, the tail, and the feet. Hdac1 and Hdac2 dual transgenic mice (K14-Cre Hdac1(cKO/cKO) Hdac2(+/cKO)) have similar but more obvious abnormalities. These results show that suppression of epidermal HDAC activity leads to improper ectodermal organ morphogenesis and disrupted hair follicle regeneration and homeostasis, as well as indirect effects on pigmentation.