Transcriptomics

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Mediator 1 deficiency enhances epidermal cell fate and accelerates injury induced epidermal regeneration


ABSTRACT: Cell fates are defined by specific transcriptional program. Previously, we developed a unique stem cell regeneration mouse model, in which transcriptional program for ectoderm organs such as tooth and skin is switched. Genomic deletion of one subunit of Mediator complex, Med1, resulted in defective enamel regeneration, in which dental stem cells were inhibited from undergoing transcriptional program for dental fate. In stead, they exerted skin program for both hair and epidermis, and post-natally regenerate ectopic hairs in the incisors. Here, we report that Med1 also modulates epidermal and hair cell fates in the skin. Med1 ablation further enhanced epidermal and sebocyte fates, and accelerated injury induced epidermal regeneration. However, it blunted hair fate resulting in hair loss in the skin. Ablation of Med1 increased the number of isthmus stem cells and epidermal stem cells, which regenerate epidermis during cutaneous wound healing process. Med1 deficiency also constitutively activated these stem cells and increased their proliferation. Microarray profiling indicated that Med1 deletion causes activation of β-catenin and suppression of TGFβ signaling. Med1 deficiency induced the expression of β-catenin target genes to control cell fate and proliferation. It also decreased TGFβ expression in interfollicular epidermis. Med1 deficiency increased the proliferation and migration of epidermal cells, and induced nuclear translocation of β-catenin, and decreased TGFβ1 expression in vitro. Our finding together with previous observations demonstrated that Med1 governs ectoderm cell fate in both tooth and skin. Med1 ablation blunts hair fate but induces epidermal and sebocyte cell fates to accelerated injury induced epidermal regeneration in the skin. Accelerated regeneration is derived from constitutive activation of epidermal stem cells accompanied with increased proliferation and migration of their progeny by balancing of β-catenin induced growth promoting and TGFβ mediated growth inhibitory activities in the skin.

ORGANISM(S): Mus musculus

PROVIDER: GSE89967 | GEO | 2017/06/30

SECONDARY ACCESSION(S): PRJNA354355

REPOSITORIES: GEO

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