Project description:How developmental programs reactivate in regeneration is a fundamental question in biology. We addressed this question through the study of Wound Induced Hair follicle Neogenesis (WIHN), an adult organogenesis model where stem cells regenerate entirely new hair follicles de novo following deep wounding. The exact mechanism is uncertain. Here we show that self-noncoding dsRNA activates the anti-viral receptor TLR3 to induce intrinsic retinoic acid (RA) synthesis in a gradient that predicts new hair follicle formation after wounding in mice. Additionally, in humans, rejuvenation lasers induce gene expression signatures for dsRNA and RA, with measurable increases in intrinsic RA synthesis. These results demonstrate a novel stimulus for retinoic acid synthesis by non-coding dsRNA, relevant to their broad functions in development and immunity. The goal of this experiment is to investigate the profile of gene expression rescued by atRA in TLR3KO mice.

Project description:This SuperSeries is composed of the SubSeries listed below. How developmental programs reactivate in regeneration is a fundamental question in biology. We addressed this question through the study of Wound Induced Hair follicle Neogenesis (WIHN), an adult organogenesis model where stem cells regenerate de novo hair follicles following deep wounding. The exact mechanism is uncertain. Here we show that self-noncoding dsRNA activates the anti-viral receptor toll like receptor 3 (TLR3) to induce intrinsic retinoic acid (RA) synthesis in a pattern that predicts new hair follicle formation after wounding in mice. Additionally, in humans, rejuvenation lasers induce gene expression signatures for dsRNA and RA, with measurable increases in intrinsic RA synthesis. These results demonstrate a potent stimulus for RA synthesis by non-coding dsRNA, relevant to their broad functions in development and immunity.

Project description:How developmental programs reactivate in regeneration is a fundamental question in biology. We addressed this question through the study of Wound Induced Hair follicle Neogenesis (WIHN), an adult organogenesis model where stem cells regenerate entirely new hair follicles de novo following deep wounding. The exact mechanism is uncertain. Here we show that self-noncoding dsRNA activates the anti-viral receptor TLR3 to induce intrinsic retinoic acid (RA) synthesis in a gradient that predicts new hair follicle formation after wounding in mice. Additionally, in humans, rejuvenation lasers induce gene expression signatures for dsRNA and RA, with measurable increases in intrinsic RA synthesis. These results demonstrate a novel stimulus for retinoic acid synthesis by non-coding dsRNA, relevant to their broad functions in development and immunity. Hand keratinocytes were treated with atRA (0.1 uM) and/or Poly I:C (0.1 ug/ml). RNA was extracted and sent for microarray analysis

Project description:Noncoding dsRNA induces retinoic acid synthesis to stimulate hair follicle regeneration via TLR3

Project description:Stem cells upended from their niche upon injury display lineage plasticity, a transient multi-lineage state essential for tissue repair. Employing high-throughput approaches and three-dimensional cultures of hair follicle stem cells (HFSCs), we investigate the signals that govern the transition between homeostatic regeneration and lineage plasticity. We identify retinoic acid (RA) as a master orchestrator of HFSC behavior during these two processes. In the hair follicle, RA signals within defined niches and interacts with WNT and BMP cues to drive hair regeneration. In wounded skin, reduced RA signaling prompts HFSCs to prioritize epidermal re-epithelialization and must be restored to promote hair regrowth. Substantiated in vivo, our findings have profound therapeutic implications for hair growth and for chronic wounds and cancers, where lineage plasticity is unresolved.

Project description:Transcriptome analysis on Gata3 conditional knock out murine hair follicles. Background. The transcription factor Gata3 is critically involved in epidermis and hair follicle differentiation. Yet, little is known about how Gata3 co-ordinates stem cell lineage determination in skin, which processes are mostly implicated and how Gata3 differentially regulates distinct cell populations within the hair follicle. Here, we describe a conditional Gata3-/- mouse (K14-Gata3-/-) in which Gata3 is specifically deleted in epidermis and hair follicles. Principal findings. K14-Gata3-/- mice show aberrant postnatal growth and development, delayed hair growth and maintenance, abnormal hair follicle organization and irregular pigmentation. After the first hair cycle, the germinative layer surrounding the dermal papilla was not restored; instead, proliferation was pronounced in basal epidermal cells. Transcriptome analysis of laser-dissected K14-Gata3-/- hair follicles as compared to wild type littermate controls, revealed mitosis, epithelial differentiation and the Notch, WNT and BMP signalling pathways to comprise significantly overrepresented processes. Conclusions. Subsequent elucidation of these pathways at the RNA and protein levels and physiologic endpoints shows that Gata3 integrates diverse signalling networks to regulate the balance between hair follicle and epidermal cell fates.

Project description:Primary outcome(s): Comparison of the gene expression profile in hair follicle between cancer patients and healthy volunteer

Project description:Wound Induced Hair Follicle neogenesis (WIHN) is a hair neogenesis phenomenon which occurred in the center of scar. Neonatal hair follicle are separated from the preexisting follicles by a hairless circular. We analysed the differentially expressed proteins between inner and outer area of scar at post-wound day 15 by iTRAQ technology.

Project description:To assess potential differences in skin stem cells and their associated stromal cells Total RNA of specific substructures of the hair follicle (bulge and hairshaft) were collected by laser-capture micro-dissection and resulting amplified cDNA hybridized to Affymetrix Mouse Genome 430 2.0 arrays.

Project description:In a rare example akin to organogenesis in adult mammals, large wounds in mice lead to de novo morphogenesis of hair follicles. It is still not fully clear what controls this process, known as Wound Induced Hair Neogenesis (WIHN). In other tissues, prostaglandin E2 (PGE2) is an important effector of regeneration and has been shown to stimulate the Wnt/beta-catenin pathway, which in turn is known to control WIHN. Previously, our group has demonstrated that noncoding dsRNA released during wounding is both necessary and sufficient to stimulate WIHN through TLR3. Here, we hypothesize that dsRNA similarly induces the beta-catenin pathway through PGE2. We find that WIHN levels correlate closely to Wnt7b production in vivo, and that dsRNA potently induces Wnt7b in a manner that requires prostaglandin-endoperoxide synthase 2 (Ptgs2). The Ptgs2 inhibitor celecoxib reduces dsRNA-induced WIHN and Wnt7b, and exogenous PGE2 can rescue WIHN and Wnt7b. These results highlight noncoding dsRNA as a novel upstream coordinator of prostaglandin and Wnt levels in regeneration. We used microarrays to identify the human keratinocyte genes most upregulated or downregulated by poly(I:C)