A Mouse Model of Androgenetic Alopecia

雄激素受体 雄激素 毛囊 内分泌学 脱发 二氢睾酮 内科学 Wnt信号通路 角蛋白 男性型秃发 生物 转基因小鼠 转基因 信号转导 头皮 医学 前列腺癌 细胞生物学 遗传学 癌症 激素 解剖 基因
作者
Judy S. Crabtree,Edward J. Kilbourne,Bryan J. Peano,Susan Chippari,Thomas Kenney,Christopher J. McNally,Wei Wang,Heather A. Harris,Richard C. Winneker,Sunil Nagpal,Catherine C. Thompson
出处
期刊:Endocrinology [Oxford University Press]
卷期号:151 (5): 2373-2380 被引量:63
标识
DOI:10.1210/en.2009-1474
摘要

Androgenetic alopecia (AGA), commonly known as male pattern baldness, is a form of hair loss that occurs in both males and females. Although the exact cause of AGA is not known, it is associated with genetic predisposition through traits related to androgen synthesis/metabolism and androgen signaling mediated by the androgen receptor (AR). Current therapies for AGA show limited efficacy and are often associated with undesirable side effects. A major hurdle to developing new therapies for AGA is the lack of small animal models to support drug discovery research. Here, we report the first rodent model of AGA. Previous work demonstrating that the interaction between androgen-bound AR and β-catenin can inhibit Wnt signaling led us to test the hypothesis that expression of AR in hair follicle cells could interfere with hair growth in an androgen-dependent manner. Transgenic mice overexpressing human AR in the skin under control of the keratin 5 promoter were generated. Keratin 5-human AR transgenic mice exposed to high levels of 5α-dihydrotestosterone showed delayed hair regeneration, mimicking the AGA scalp. This effect is AR mediated, because treatment with the AR antagonist hydroxyflutamide inhibited the effect of dihydrotestosterone on hair growth. These results support the hypothesis that androgen-mediated hair loss is AR dependent and suggest that AR and β-catenin mediate this effect. These mice can now be used to test new therapeutic agents for the treatment of AGA, accelerating the drug discovery process.
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