The Tissue-Engineered Human Psoriatic Skin Substitute: A Valuable In Vitro Model to Identify Genes with Altered Expression in Lesional Psoriasis
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ABSTRACT: Psoriasis is a chronic inflammatory skin disease for which no cure has emerged. Its complex etiology requires the development of an in vitro model representative of the pathology. Various skin substitutes were produced by tissue-engineering using biopsies from normal, healthy donors, or from lesional or non-lesional skin samples from patients with psoriasis, and their gene expression profiles were examined by DNA microarray.
Project description:To explore the psoriasis phenotype and pathways involved in psoriasis, we characterized gene expression in lesional and non-lesional skin from psoriasis patients. Furthermore, we explored the effects of various doses of brodalumab on lesional skin over time.
Project description:To explore the psoriasis phenotype and pathways involved in psoriasis, we characterized gene expression in lesional and non-lesional skin from psoriasis patients. Furthermore, we explored the effects of various doses of brodalumab on lesional skin over time. From each of the 25 psoriasis patients, we obtained two pre-dose biopsies, one from a lesion and the other from non-lesional skin in the same general body geography, and two post-dose biopsies. Total RNA was extracted from 6mm punch biopsies that were split in half. A total of 99 samples were run on Affymetrix HU133 Plus 2.0 microarrays. There was no paired non-lesional sample for 'T_lesional_pre-dose' (skn55789).
Project description:To explore the psoriasis phenotype and pathways involved in psoriasis, we characterized gene expression in lesional and non-lesional skin from psoriasis patients. From each of the 24 psoriasis patients, we obtained two biopsies, one from a lesion and the other from non-lesional skin in the same general body geography. Total RNA was extracted from 6mm punch biopsies that were split in half. A total of 48 samples were run on Affymetrix HU133 Plus 2.0 microarrays.
Project description:To explore the psoriasis phenotype and pathways involved in psoriasis, we characterized gene expression in lesional and non-lesional skin from psoriasis patients.
Project description:Background: Plaque psoriasis is a chronic autoimmune disorder characterized by the development of red scaly plaques. To date psoriasis lesional skin transcriptome has been extensively studied, whereas only few proteomic studies of psoriatic skin are available. Aim: The aim of this study was to compare protein expression patterns of lesional and normally looking skin of psoriasis patients with skin of the healthy volunteers, reveal differentially expressed proteins and identify changes in cell metabolism caused by the disease. Methods: Skin samples of normally looking and lesional skin donated by psoriasis patients (n = 5) and samples of healthy skin donated by volunteers (n = 5) were analyzed by liquid chromatography-tandem mass spectrometry (LC-MS/MS). After protein identification and data processing, the set of differentially expressed proteins was subjected to protein ontology analysis to characterize changes in biological processes, cell components and molecular functions in the patients' skin compared to skin of the healthy volunteers. Results: The performed analysis identified 405 and 59 differentially expressed proteins in lesional and normally looking psoriatic skin compared to healthy control. We discovered decreased expression of KNG1, APOE, HRG, THBS1 and PLG in normally looking skin of the patients. Presumably, these changes were needed to protect the epidermis from spontaneous activation of kallikrein-kinin system and delay the following development of inflammatory response. In lesional skin, we identified several large groups of proteins with coordinated expression. Mainly, these proteins were involved in different aspects of protein and RNA metabolism, namely ATP synthesis and consumption; intracellular trafficking of membrane-bound vesicles, pre-RNA processing, translation, chaperoning and degradation in proteasomes/immunoproteasomes. Conclusion: Our findings explain the molecular basis of metabolic changes caused by disease in skin lesions, such as faster cell turnover and higher metabolic rate. They also indicate on downregulation of kallikrein-kinin system in normally looking skin of the patients that would be needed to delay exacerbation of the disease.
Project description:To explore the psoriasis phenotype, we characterize gene expression in lesional and non-lesional skin from psoriasis patients. We extracted total RNA from 5mm punch biopsies taken from 14 psoriatic patients. From each patient, we obtained two biopsies, one from a lesion and the other from non-lesional skin in the same general body geography. A total of 28 samples were run on Affymetrix HU133 Plus 2.0 microarrays.
Project description:Psoriasis is a chronic, debilitating, immune-mediated inflammatory skin disease. As IFN-gamma is involved in many cellular processes, including activation of T cells and dendritic cells (DCs), antigen processing and presentation, cell adhesion and trafficking, and cytokine and chemokine production, IFN-gamma-producing Th1 cells were proposed to be integral to the pathogenesis of psoriasis. Recently, IFN-gamma was shown to enhance IL-23 and IL-1 production by DCs and subsequently induce Th17 cells, important contributors to the inflammatory cascade in psoriasis lesions. To determine if IFN-gamma indeed induces the pathways leading to the development of psoriasis lesions, a single intradermal injection of IFN-gamma was administered to an area of clinically normal, non-lesional skin of psoriasis patients and biopsies were collected 24 hours later. Although there were no visible changes in the skin, IFN-gamma induced molecular and histological features characteristic of psoriasis lesions. IFN-gamma increased a number of differentially expressed genes in the skin, including many chemokines concomitant with an influx of T cells and inflammatory DCs. Furthermore, inflammatory DC products TNF, iNOS, IL-23, and TRAIL were present in IFN-gamma-treated skin. Thus, IFN-gamma, which is significantly elevated in non-lesional skin compared to healthy skin, appears to be a key pathogenic cytokine that can induce the inflammatory cascade in psoriasis. RNA was isolated from whole skin punch biopsies of either healthy or non-lesional psoraisis patients at baseline or 24 hours after placebo or IFN-g injection.
Project description:We used microarry to charactarize differences in gene expression between lesional and non-lesional psoriasis skin. Our hypothethis was that IL-37 is downregulated in psoriasis.
Project description:Biopsies from uninvolved and from lesional skin of 13 patients with plaque-type psoriasis. Based on paired samples, 179 genes were more than 2-fold differentially expressed in lesional skin. Experiment Overall Design: Comparative RNA expression profiles from uninvolved and lesional skin of 13 patients with mild to severe plaque-type psoriasis.