Project description:Skin aging is one of the hallmarks of the aging process that causes physiological and morpho-logical changes. Recently, several nutritional studies were conducted to delay or suppress the aging process. This study investigated whether nutritional supplementation of the eggshell membrane (ESM) has a beneficial effect on maintaining skin health and improving the skin ag-ing process using neonatal normal human epidermal keratinocytes (NHEK-Neo). 1 mg/mL of enzymatically hydrolyzed ESM (eESM) upregulated the expression of keratinocyte differentiation markers, including keratin 1, filaggrin and involucrin, and changed the keratinocyte morphology.

Project description:Defects of filaggrin (FLG) compromise epidermal barrier function and represent an important known genetic risk factor for atopic dermatitis (AD), but also for systemic atopy, including allergic sensitization and asthma. A loss of epidermal barrier integrity can provide a significant stress for the keratinocytes in the skin, either due to the increased moisture evaporation from the skin or increased penetration of the antigens and microflora into the lower epidermal layers. To understand the effect of this loss of barrier integrity on keratinocyte function our aim is to analyze the alterations in the transcriptional profile of keratinocytes from Flg-deficient mice.

Project description:Loss-of-function mutations in the filaggrin gene are heavily associated with the incidence and severity of atopic dermatitis. Moreover, filaggrin insufficiency in epidermal keratinocytes can lead to persistent allergic inflammation and an associated immune response suggesting a role for this protein in regulation of immunity. Here, we investigate how filaggrin insufficiency affects the gene expression pattern in a filaggrin-insufficient (shFLG) keratinocyte cell line HaCaT in response to stimulation with various inflammatory mediators and allergens.

Project description:ADAM17 and EGFR are essential key players for epidermal integrity. Keratinocyte-specific deletion of ADAM17 in mice results in pronounced alterations in terminal differentiation of keratinocytes leading to severe epidermal barrier defects with enhanced transepidermal water loss. Thereby, mice deficient for ADAM17 in keratinocytes phenocopy mice with a keratinocyte-specific deletion of EGFR, highlighting the role of ADAM17 as a “ligand sheddase”, as it sheds membrane bound EGFR ligands from the cell surface and finally modulates EGFR signaling. In this study we aim for the first proteomic / degradomic approach to characterize the disruption of the ADAM17-EGFR signaling axis and its consequences for epidermal barrier formation. Proteomic profiling of the epidermal proteome of mice deficient for either ADAM17 or EGFR in keratinocytes at postnatal days 3 and 10 revealed highly similar protein alterations for ADAM17 and EGFR deficiency. These include massive proteome alterations of structural and regulatory components important for barrier formation, like transglutaminases, involucrin, S100 protein family members and S100 fused-type proteins, such as filaggrin, filaggrin-2 and hornerin. Cleavage site analysis using TAILS reveals, among other ADAM17 dependent cleavage sites, increased proteolytic processing of S100 fused-type proteins, including filaggrin-2. Alterations in proteolytic processing are supported by altered protein abundance of numerous proteases upon keratinocyte-specific Adam17 or Egfr deletion, among them kallikreins, cathepsins and their inhibitors. In addition, N-terminal proteomics indicated usage of alternative translation start sites. This study highlights the essential role of proteolytic processing for maintenance of a functional epidermal barrier. Furthermore it suggests that most defects in formation of the postnatal epidermal barrier upon keratinocyte-specific ADAM17 deletion are mediated via EGFR.

Project description:The breakdown of epidermal barrier and consequent loss of skin hydration is a feature of skin aging and eczematous dermatitis. Few treatments, however, resolve these underlying processes to provide full symptomatic relief. In this study, we generated a novel compound, isosorbide di-(linoleate/oleate) (IDL), by esterifying isosorbide with sunflower fatty acids. Topical effects of IDL in skin were compared to those of ethyl linoleate/oleate (EL), which has previously been shown to improve skin barrier function. Both IDL and EL down-regulated inflammatory gene expression, but IDL more effectively up-regulated the expression of genes associated with keratinocyte differentiation (e.g., KRT1, GRHL2, SPRR4). Consistent with this, IDL increased abundance of epidermal barrier proteins (filaggrin and involucrin) and prevented cytokine-mediated stratum corneum degradation. IDL also down-regulated expression of “unhealthy skin signature” genes linked to loss of epidermal homeostasis and uniquely repressed an interferon-inducible co-expression module activated in multiple skin diseases including psoriasis. In a double-blind placebo-controlled trial enrolling females with dry skin, 2% IDL lotion applied over 2 weeks significantly improved skin hydration and decreased transepidermal water loss (NCT04253704). These results demonstrate mechanisms by which IDL improves skin hydration and epidermal barrier function, supporting IDL as an effective intervention for treatment of xerotic pruritic skin.

Project description:Filaggrin (FLG) is a key structural protein expressed in epidermal keratinocytes. Mutations in the filaggrin gene (FLG) are strongly linked to atopic dermatitis (AD) and allergic inflammation occurring later in life at distant body locations in AD patients. Keratinocytes secrete exosomes, small, lipid-rich membrane vesicles to communicate with distant cells, including within the immune system. The FLG gene was silenced in the HaCaT keratinocyte cell line by shRNA delivered using a lentiviral vector. HaCaT cells transduced with scrambled shRNA were used as a control.

Project description:The Aryl Hydrocarbon Receptor (AHR) is an environmental sensor and an indispensable regulator of epithelial homeostasis. To investigate AHR-mediated gene regulation, we performed a comprehensive transcriptomic and epigenomic analysis using human primary epidermal keratinocytes. Our results showed that AHR activation led to the induction of canonical transcription factors involved in epidermal differentiation as an early response, i.e. Transcription Factor AP-2α (TFAP2A), while epidermal differentiation-related genes, such as filaggrin and keratins, were activated as late responsive genes. The identified AHR-TFAP2A axis and its role in keratinocyte terminal differentiation was confirmed through AHR and TFAP2A knockout using CRISPR/Cas9. Our findings demonstrate that AHR regulates epidermal differentiation through the transient activation of specific transcription factors, such as TFAP2A, in response to environmental cues. The herein identified AHR-TFAP2A axis provides a promising target for the treatment of diseases related to skin barrier dysfunction.

Project description:The Aryl Hydrocarbon Receptor (AHR) is an environmental sensor and an indispensable regulator of epithelial homeostasis. To investigate AHR-mediated gene regulation, we performed a comprehensive transcriptomic and epigenomic analysis using human primary epidermal keratinocytes. Our results showed that AHR activation led to the induction of canonical transcription factors involved in epidermal differentiation as an early response, i.e. Transcription Factor AP-2α (TFAP2A), while epidermal differentiation-related genes, such as filaggrin and keratins, were activated as late responsive genes. The identified AHR-TFAP2A axis and its role in keratinocyte terminal differentiation was confirmed through AHR and TFAP2A knockout using CRISPR/Cas9. Our findings demonstrate that AHR regulates epidermal differentiation through the transient activation of specific transcription factors, such as TFAP2A, in response to environmental cues. The herein identified AHR-TFAP2A axis provides a promising target for the treatment of diseases related to skin barrier dysfunction.

Project description:Background: Atopic eczema (AE) is a common chronic inflammatory skin disorder. In order to dissect the genetic background several linkage and genetic association studies have been performed. Yet very little is known about specific genes involved in this complex skin disease, and the underlying molecular mechanisms are not fully understood. Results: We used human DNA microarrays to identify a molecular picture of the programmed responses of the human genome to AE. The transcriptional program was analyzed in skin biopsy samples from lesional and patch-tested skin from AE patients sensitized to Malassezia sympodialis (M. sympodialis), and corresponding biopsies from healthy individuals. The most notable feature of the global gene-expression pattern observed in AE skin was a reciprocal expression of induced inflammatory genes and repressed lipid metabolism genes. The overall transcriptional response in M. sympodialis patch-tested AE skin was similar to the gene-expression signature identified in lesional AE skin. In the constellation of genes differentially expressed in AE skin compared to healthy control skin, we have identified several potential susceptibility genes that may play a critical role in the pathological condition of AE. Many of these genes, including genes with a role in immune responses, lipid homeostasis, and epidermal differentiation, are localized on chromosomal regions previously linked to AE. Conclusion: Through genome-wide expression profiling, we were able to discover a distinct reciprocal expression pattern of induced inflammatory genes and repressed lipid metabolism genes in skin from AE patients. We found a significant enrichment of differentially expressed genes in AE with cytobands associated to the disease, and furthermore new chromosomal regions were found that could potentially guide future region-specific linkage mapping in AE. A disease state experiment design type is where the state of some disease such as infection, pathology, syndrome, etc is studied. Disease State: Skin biopsies from normal ('normal') and lesional and patch-tested ('leisonal') skin from Atopic eczema patients sensitized to Malassezia sympodialis Organism Part: location of skin biopsy Keywords: disease state analysis Computed

Project description:Background: Atopic eczema (AE) is a common chronic inflammatory skin disorder. In order to dissect the genetic background several linkage and genetic association studies have been performed. Yet very little is known about specific genes involved in this complex skin disease, and the underlying molecular mechanisms are not fully understood. Results: We used human DNA microarrays to identify a molecular picture of the programmed responses of the human genome to AE. The transcriptional program was analyzed in skin biopsy samples from lesional and patch-tested skin from AE patients sensitized to Malassezia sympodialis (M. sympodialis), and corresponding biopsies from healthy individuals. The most notable feature of the global gene-expression pattern observed in AE skin was a reciprocal expression of induced inflammatory genes and repressed lipid metabolism genes. The overall transcriptional response in M. sympodialis patch-tested AE skin was similar to the gene-expression signature identified in lesional AE skin. In the constellation of genes differentially expressed in AE skin compared to healthy control skin, we have identified several potential susceptibility genes that may play a critical role in the pathological condition of AE. Many of these genes, including genes with a role in immune responses, lipid homeostasis, and epidermal differentiation, are localized on chromosomal regions previously linked to AE. Conclusion: Through genome-wide expression profiling, we were able to discover a distinct reciprocal expression pattern of induced inflammatory genes and repressed lipid metabolism genes in skin from AE patients. We found a significant enrichment of differentially expressed genes in AE with cytobands associated to the disease, and furthermore new chromosomal regions were found that could potentially guide future region-specific linkage mapping in AE. A disease state experiment design type is where the state of some disease such as infection, pathology, syndrome, etc is studied. Disease State: Skin biopsies from normal ('normal') and lesional and patch-tested ('leisonal') skin from Atopic eczema patients sensitized to Malassezia sympodialis Organism Part: location of skin biopsy Keywords: disease state analysis