The co-repressor hairless has a role in epithelial cell differentiation in the skin.

Although mutations in the mammalian hairless (Hr) gene result in congenital hair loss disorders in both mice and humans, the precise role of Hr in skin biology remains unknown. We have shown that the protein encoded by Hr (HR) functions as a nuclear receptor co-repressor. To address the role of HR in vivo, we generated a loss-of-function (Hr-/-) mouse model. The Hr-/- phenotype includes both hair loss and severe wrinkling of the skin. Wrinkling is correlated with increased cell proliferation in the epidermis and the presence of dermal cysts. In addition, a normally undifferentiated region, the infundibulum, is transformed into a morphologically distinct structure (utricle) that maintains epidermal function. Analysis of gene expression revealed upregulation of keratinocyte terminal differentiation markers and a novel caspase in Hr-/- skin, substantiating HR action as a co-repressor in vivo. Differences in gene expression occur prior to morphological changes in vivo, as well as in cultured keratinocytes, indicating that aberrant transcriptional regulation contributes to the Hr-/- phenotype. The properties of the cell types present in Hr-/- skin suggest that the normal balance of cell proliferation and differentiation is disrupted, supporting a model in which HR regulates the timing of epithelial cell differentiation in both the epidermis and hair follicle.

The thyroid hormone-regulated corepressor hairless associates with histone deacetylases in neonatal rat brain.

Thyroid hormone (TH) influences multiple aspects of neural development, presumably by controlling the transcriptional activity of TH receptors to modulate gene expression. The mammalian hairless (hr) gene is likely an important component of TH action as 1) hr expression is directly regulated by TH in brain, and 2) the protein encoded by hr (Hr) acts as a corepressor, facilitating transcriptional repression by unliganded TH receptors. Here we examine the properties of endogenous Hr in developing rat brain. Using coimmunoprecipitation, we show that Hr interacts with TH receptor and histone deacetylases (HDACs) in brain extracts. We find that inhibition of HDAC activity impairs Hr-mediated transcriptional repression, indicating that Hr-HDAC interaction is functionally significant. To identify potential sites of Hr action in developing brain, we assessed hr transcript and protein expression. We show that hr is broadly expressed in brain and overlaps with the expression of multiple HDACs in multiple regions including cortex, hippocampus, and cerebellum. Additionally, Hr expression is TH sensitive and developmentally regulated. The striking correlation of Hr expression with brain regions, cell types, and developmental stages influenced by TH, together with its function as a corepressor, suggests Hr is a key mediator of TH action in developing brain.