Project description:Epidermis, a continuously self-renewing and differentiating organ, produces a protective stratum corneum that shields us from external chemical, physical and microbial threats. Epidermal differentiation is a multi-step process regulated by influences, some unknown, others insufficiently explored. Detachment of keratinocytes from the basement membrane is one such pro-differentiation stimulus. Here, we define the transcriptional changes during differentiation, especially those caused by detachment from the substratum. Using comprehensive transcriptional profiling, we revisited the effects of detachment as a differentiation signal to keratinocytes. We identified the genes regulated by detachment, the corresponding ontological categories and, using metaanalysis, compared the genes and categories to those regulated by other pro-differentiating stimuli. We identified 762 genes overexpressed in suspended keratinocyte, including known and novel differentiation markers, and 1427 in attached cells, including basal layer markers. Detachment induced epidermis development, cornification and desmosomal genes, but also innate immunity, proliferation inhibitors, transcription regulators and MAPKs; conversely the attached cells overexpressed cell cycle, anchoring, motility, splicing and mitochondrial genes, and both positive and negative regulators of apoptosis. Metaanalysis identified which detachment-regulated categories overlap with those induced by suprabasal location in vivo, by reaching confluency in vitro, and by inhibition of JUN kinases. Attached and in vivo basal cells shared overexpression of mitochondrial components. Interestingly, melanosome trafficking components were also overexpressed in the attached and in vivo basal keratinocytes. Reaching confluency did not affect adhesion and ECM proteins. Lipid metabolism and steroid metabolism were induced by confluency and by JNK inhibition, respectively. These results suggest that specific pro-differentiation signals induce specific features of the keratinization process, which are in vivo orchestrated into harmonious epidermal homeostasis. Human epidermal keratinocytes are grown in standard growth medium either attached in tissue culture plates, or suspended, in the same medium, in bacteriological plates. After 48 hrs, attached and suspended cultures were harvested and their transcriptomes compared.

Project description:Troy/Tnfrsf19 marks epidermal cells that govern interfollicular epidermal renewal and cornification

Project description:Whether epidermal factors play a primary role in immune-mediated skin diseases such as psoriasis is unknown. We now show that the pro-differentiation transcription factor Grainyhead-like 3 (GRHL3), essential during epidermal development but dispensable in adult skin homeostasis, is required for barrier repair after adult epidermal injury. Consistent with activation of a GRHL3-regulated repair pathway in psoriasis, we find GRHL3 up-regulation in lesional skin where GRHL3 binds known epidermal differentiation gene targets. Furthermore, we show the functionality of this pathway in the Imiquimod mouse model of immune-mediated epidermal hyperplasia where loss of Grhl3 exacerbates the epidermal damage response, conferring greater sensitivity to disease induction, delayed resolution of epidermal lesions, and resistance to anti-IL-22 therapy. ChIP-seq and gene expression profiling studies show that while GRHL3 regulates differentiation genes both in development and during repair from immune-mediated damage, it targets distinct sets of genes in the two processes. In particular, GRHL3 suppresses a number of alarmin and other pro-inflammatory genes after immune injury. This study identifies a GRHL3-regulated epidermal barrier repair pathway that suppresses disease initiation and helps resolve existing lesions in immune-mediated epidermal hyperplasia. A single timepoint was assessed after physical injury of the epidermal barrier and two timepoints were assessed after immune mediated injury of the epidermis following Imiquimod treatment (psoriasis mouse model)

Project description:Though Traumatic Brain Injury (TBI) and skin trauma often occur together, it is unresolved whether TBI changes healing of skin wounds. We here explored whether TBI impacts on the sequence of events during skin wound healing. Incisional skin wounds from mice subjected to TBI were assessed employing unbiased transcriptome analysis and immunostaining. Transcriptome analysis at day 1 after combined trauma detects a significant enrichment of genes involved in macrophage and T cell recruitment and activation in contrast to skin wounds without TBI. At day 7 after combined trauma, genes in pathways of re-epithelialization including cornification and keratinization and of anti-inflammatory responses were highly enriched. These findings were confirmed by immunostaining with increased re-epithelialisation and cornification and an increased number of macrophages and T cells resolving inflammation. Moreover, the number of dermal myofibroblasts are highly increased in skin wounds after combined trauma. Collectively, TBI enforces an unprecedented defence response with an early onset of enhanced immunity, faster epidermal barrier formation, and a myofibroblast driven acceleration of wounds closure, all together likely counteracting systemic infection.

Project description:The epidermal barrier protects the body against mechanical injury, infection and dehydration. The respective contribution of type I and type II keratins which form the major cytoskeleton in epidermal keratinocytes in barrier formation and stress protection is incompletely understood. Here, we reveal a novel mechanism by which keratins control anti-oxidant responses through barrier-dependent and cell-autonomous mechanisms. Mice lacking the entire type I (KtyI) or type II (KtyII) keratin gene clusters suffer from distinct prenatal barrier defects. Comparative transcriptome profiling identifies essential cornified envelope components and reveals strong upregulation of the bZIP transcription factor Nrf2 in situ. Isolated keratinocytes from both strains of mice show elevated mitochondrial oxygen consumption and Nrf2 activity, decreased upon keratin re-expression. We propose a model in which keratins control mitochondria-derived oxidative stress via Nrf2 activation. Our findings reveal major contributions of keratins to chronic inflammation and autoimmune disorders. Total RNA obtained from E18.5 embryo back skin from typeI and II keratin knockout compared with respective wild type.

Project description:Effect of EGFR inhibitors on the epidermis Epidermal Growth Factor inhibitors (EGFRi) used in oncology therapy modify the keratinocyte differentiation processes, impairing proper skin barrier formation and leading to Cutaneous Adverse Drug Reactions (CADR). To uncover the molecular signatures associated with CADRs, we applied phospho-proteomic and transcriptomic assays on Reconstructed Human Epidermis (RHE) tissues exposed to a therapeutically relevant concentration of afatinib, a second EGFRi generation. Following drug exposure, we observed an increased expression of gene families involved in keratinocyte differentiation, senescence, oxidative stress and alterations in the epidermal immune-related markers. Furthermore, our results show that afatinib may interfere with Vitamin D3 (VD3) metabolism, acting via CYP27A1 and CYP24A1 to regulate calcium concentration through the PI3K/AKT pathway. Consequently, basal layer keratinocytes switch from a pro-proliferating to a pro-differentiative program, characterized by upregulation of biomarkers associated with increased keratinization, cornification, Th2 response and decreased innate immunity. Such effects may increase the skin susceptibility to cutaneous penetration of irritants and pathogens.

Project description:Background: While atopic dermatitis (AD) often starts in early childhood, detailed tissue profiling of early-onset AD in children is lacking, hindering therapeutic development for this patient population with a particularly high unmet need of better treatments. Objective: We sought to globally profile the skin of infants with AD compared to adults with AD and healthy controls. Methods: We performed microarray, RT-PCR and fluorescence microscopy studies in infants and young children (<5yo) with early-onset AD (<6mo) compared to age-matched controls and adults with longstanding AD. Results: Transcriptomic analyses revealed profound differences between early-onset pediatric vs. longstanding adult AD, not only in lesional but also non-lesional tissues. While both patient populations harbored Th2-centered inflammation, pediatric AD also showed significant Th17-skewing, but lacked the Th1 upregulation that characterizes adult AD. Defects in lipid barrier (e.g. ELOVL3, DGAT2) and tight junction regulation (e.g. Claudins 8 and 23) were evident in both groups but, unlike adult AD which showed the classic downregulation of epidermal differentiation and cornification products, pediatric AD exhibited relatively normal expression of these genes. Some lipid-associated mediators (such as FAR2 and FA2H) even showed preferential downregulation in pediatric AD, and lipid barrier genes (FA2H, DGAT2) showed inverse correlations with transepidermal water loss/TEWL, a functional measure of the epidermal barrier. Conclusions: Children and adult AD skin samples share lipid metabolism and tight junction alterations, but epidermal differentiation complex defects are only present in adult AD, potentially resulting from chronic immune aberration that is not yet present in early-onset disease.

Project description:Epidermis, a continuously self-renewing and differentiating organ, produces a protective stratum corneum that shields us from external chemical, physical and microbial threats. Epidermal differentiation is a multi-step process regulated by influences, some unknown, others insufficiently explored. Detachment of keratinocytes from the basement membrane is one such pro-differentiation stimulus. Here, we define the transcriptional changes during differentiation, especially those caused by detachment from the substratum. Using comprehensive transcriptional profiling, we revisited the effects of detachment as a differentiation signal to keratinocytes. We identified the genes regulated by detachment, the corresponding ontological categories and, using metaanalysis, compared the genes and categories to those regulated by other pro-differentiating stimuli. We identified 762 genes overexpressed in suspended keratinocyte, including known and novel differentiation markers, and 1427 in attached cells, including basal layer markers. Detachment induced epidermis development, cornification and desmosomal genes, but also innate immunity, proliferation inhibitors, transcription regulators and MAPKs; conversely the attached cells overexpressed cell cycle, anchoring, motility, splicing and mitochondrial genes, and both positive and negative regulators of apoptosis. Metaanalysis identified which detachment-regulated categories overlap with those induced by suprabasal location in vivo, by reaching confluency in vitro, and by inhibition of JUN kinases. Attached and in vivo basal cells shared overexpression of mitochondrial components. Interestingly, melanosome trafficking components were also overexpressed in the attached and in vivo basal keratinocytes. Reaching confluency did not affect adhesion and ECM proteins. Lipid metabolism and steroid metabolism were induced by confluency and by JNK inhibition, respectively. These results suggest that specific pro-differentiation signals induce specific features of the keratinization process, which are in vivo orchestrated into harmonious epidermal homeostasis.

Project description:Epidermal deletion of the lipid modifying enzyme CerS4 causes epidermal barrier impairments associated with human skin diseases. Proteomes of Wt newborn and P47 mice were compared in order to identify molecular differences between barrier formation and maintenance. Proteomes of epidermal splits from Ctr and CerS4epi-/- at different ages (P21, P33, P47) were compared, to identify the effect of CerS4 on barrier maintenance.

Project description:Genome-wide gene expression changes triggered by Ca2+-induced differentiation of epidermal progenitors