Skin Transcriptome Reveals the Intrinsic Molecular Mechanisms Underlying Hair Follicle Cycling in Cashmere Goats Under Natural and Shortened Photoperiod Conditions

Overview

Journal Sci Rep

Specialty Science

Date 2017 Oct 19

PMID 29044192

Citations 14

Authors

Min Yang

Shen Song

Kunzhe Dong

Xiaofei Chen

Xuexue Liu

Marhaba Rouzi

Qianjun Zhao

Xiaohong He

Yabin Pu

Weijun Guan

Yuehui Ma

Lin Jiang

Affiliations

Soon will be listed here.

Abstract

The growth of cashmere exhibits a seasonal pattern arising from photoperiod change. However, the underlying molecular mechanism remains unclear. We profiled the skin transcriptome of six goats at seven time points during hair follicle cycling via RNA-seq. The six goats comprised three goats exposed to a natural photoperiod and three exposed to a shortened photoperiod. During hair cycle transition, 1713 genes showed differential expression, and 332 genes showed a pattern of periodic expression. Moreover, a short photoperiod induced the hair follicle to enter anagen early, and 246 genes overlapped with the periodic genes. Among these key genes, cold-shock domain containing C2 (CSDC2) was highly expressed in the epidermis and dermis of Cashmere goat skin, although its function in hair-follicle development remains unknown. CSDC2 silencing in mouse fibroblasts resulted in the decreased mRNA expression of two key hair-follicle factors, leading to reduced cell numbers and a lower cell density. Cashmere growth or molting might be controlled by a set of periodic regulatory genes. The appropriate management of short light exposure can induce hair follicles to enter full anagen early through the activation of these regulators. The CSDC2 gene is a potentially important transcription factor in the hair growth cycle.

Citing Articles

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