Project description:Skin and its appendages such as hair follicle and sweat gland are formed by Keratin-5 expressing (Krt5+) epidermal cells that are specified from primitive, Keratin-8 expressing (Krt8+) ectodermal progenitors shortly after gastrulation. Here we show that transcription factor ∆Np63 is required for converting Krt8+ ectodermal progenitors to Krt5+ epidermal progenitors and priming the underlying dermal cells to form dermal condensate by activating the Wnt/ß-Catenin pathway. These findings unearth the molecular cascades during the fate specification of epidermal cells, illuminate the essential role of ∆Np63 in initiating the Wnt signaling in the epidermis and programming the underlying dermal cells and provide new possibilities to harness the intrinsic developmental program for generating the skin and its appendages.

Project description:Skin and its appendages such as hair follicle and sweat gland are formed by Keratin-5 expressing (Krt5+) epidermal cells that are specified from primitive, Keratin-8 expressing (Krt8+) ectodermal progenitors shortly after gastrulation. Here we show that transcription factor ∆Np63 is required for converting Krt8+ ectodermal progenitors to Krt5+ epidermal progenitors and priming the underlying dermal cells to form dermal condensate by activating the Wnt/ß-Catenin pathway. These findings unearth the molecular cascades during the fate specification of epidermal cells, illuminate the essential role of ∆Np63 in initiating the Wnt signaling in the epidermis and programming the underlying dermal cells and provide new possibilities to harness the intrinsic developmental program for generating the skin and its appendages.

Project description:Eccrine sweat glands are indispensable for human thermoregulation and, similar to other mammalian skin appendages, form from multipotent epidermal progenitors. Limited understanding of how epidermal progenitors specialize to form these vital organs has precluded therapeutic efforts toward their regeneration. Herein, we applied single-nucleus transcriptomics to compare the expression content of wild-type, eccrine-forming mouse skin to that of mice harboring a skin-specific disruption of Engrailed 1 (En1), a transcription factor that promotes eccrine gland formation in humans and mice. We identify two concurrent but disproportionate epidermal transcriptomes in the early eccrine anlagen: one that is shared with hair follicles and one that is En1 dependent and eccrine specific. We demonstrate that eccrine development requires the induction of a dermal niche proximal to each developing gland in humans and mice. Our study defines the signatures of eccrine identity and uncovers the eccrine dermal niche, setting the stage for targeted regeneration and comprehensive skin repair.

Project description:Psoriasis is a chronic inflammatory skin disease characterized by marked proliferation of keratinocytes leading to pronounced epidermal hyperplasia, elongation of rete ridges and hyperkeratosis. The most common form of psoriasis, chronic plaque psoriasis (Psoriasis vulgaris), involves relatively stable occurrence and progression of sharply demarcated lesions, usually on the trunk and extremities, which share a combination of trademark histological features, including tortuous and dilated dermal capillaries, loss of the epidermal granular layer, and accumulation of neutrophils beneath parakeratotic scale. In this study, whole-genome transcriptional profiling was used to characterize gene expression in 4 lesional and uninvolved skin samples obtained from patients with stable chronic plaque psoriasis. Skin mRNA expression was analysed by microarray. Four individuals with chronic plaque psoriasis were enrolled. 6 mm punch biopsies were obtained under local anaesthesia (lidocaine) from uninvolved skin and a target plaque.

Project description:Psoriasis is a chronic inflammatory skin disease characterized by marked proliferation of keratinocytes leading to pronounced epidermal hyperplasia, elongation of rete ridges and hyperkeratosis. The most common form of psoriasis, chronic plaque psoriasis (Psoriasis vulgaris), involves relatively stable occurrence and progression of sharply demarcated lesions, usually on the trunk and extremities, which share a combination of trademark histological features, including tortuous and dilated dermal capillaries, loss of the epidermal granular layer, and accumulation of neutrophils beneath parakeratotic scale. In this study, whole-genome transcriptional profiling was used to characterize gene expression in 4 lesional and uninvolved skin samples obtained from patients with stable chronic plaque psoriasis.Skin mRNA expression was analysed by microarray.

Project description:Rete ridges form via evolutionarily distinct mechanisms in mammalian skin

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:The epidermis and associated appendages ensure a number of critical functions necessary for survival and social interactions. Perturbations of epidermal stem cell homeostasis lead to a variety of skin diseases affecting humans and dogs. Therefore, the establishment of an in vitro system to investigate canine epidermal stem cells, representing a model for human diseases, is essential. Here we report the establishment and characterization of organoids derived from microdissected canine hair follicles (HFs) and interfollicular epidermal (IFE). Gene and protein expression analysis revealed high mRNA and protein levels of keratin 5 and 14, IFE differentiation markers and intercellular molecules (e.g., keratin 10 and desmoglein), indicating a strong basal cell signature as well as differentiation towards mature epidermis. Key markers of HF stem cells were lacking. This suggests that, independently of the tissue of origin, both organoid lines develop into the same cell type (basal IFE-like keratinocytes). Signaling pathways members important for regulation of HF growth and cycling (such as Wnt, Hh, BMP and Notch) were present in both HF and IFE organoids at low levels. Withdrawal of growth factors (Noggin, R-spondin and FGFs) resulted in upregulation of markers such as KRT16, IVL, KRT17 and SOX9, showing the potential of the organoids to develop towards more differentiated tissue. However, for induction of HF signatures or hair growth, addition of different growth factors or dermal papilla co-culture might be required. Taken together, our in vitro culture system can provide the basis to address hair growth and explore epidermal function/regeneration, allowing us to further investigate pathomechanisms of cutaneous disorders in dogs and potentially human patients.

Project description:Sweat glands are abundant glands of our body and essential for thermoregulation. Like mammary glands, they originate from epidermal progenitors. However, they display few signs of cellular turnover, and whether they have stem cells and tissue regenerative capacity remain largely unexplored. Here we address these issues. Using lineage-tracing, we identify multipotent progenitors in sweat duct that transition to unipotency after developing the sweat gland. In characterizing four adult stem cell populations of glandular skin, we show that they display distinct regenerative capabilities and remain unipotent when healing epidermal, myoepithelial-specific and luminal-specific injuries. We devise purification schemes, isolate and transcriptionally profile progenitors. Exploiting molecular differences between sweat and mammary glands, we show that only some progenitors regain multipotency to produce de novo ductal and glandular structures, but that these can retain their identity even within certain foreign microenvironments. Our findings provide new concepts about glandular stem cells and sweat gland biology. 10 samples from mouse paw pads were analyzed

Project description:As the biggest organ of human body, skin and its appendages offer excellent experimental systems for aging studies. Skin wrinkling, hair greying and hair loss are among the most striking and observable traits of aging. However, the chronic changes and cell-to-cell variation accumulated during aging in different hair follicle lineages remain unexplored. Here we present a detailed analysis of scRNAseq and scATACseq data from young and aging animals. We found distinct cellular state changes of individual hair follicle populations.