Project description:Atopic dermatitis and psoriasis are driven by alternate type 2 and type 17 immune responses, but some proteins might be critical to both diseases. We show that a deficiency of the TNF superfamily molecule TWEAK (TNFSF12) in mice results in defective maintenance of atopic dermatitis-specific Th2 and psoriasis-specific Th17 cells in the skin, and impaired expression of disease-characteristic chemokines and cytokines, such as CCL17 and TSLP in atopic dermatitis, and CCL20 and IL-19 in psoriasis. The TWEAK receptor, Fn14, is upregulated in keratinocytes and dermal fibroblasts, and TWEAK induces these cytokines and chemokines alone and in synergy with the signature T helper cytokines of either disease, IL-13 and IL-17. Furthermore, subcutaneous injection of recombinant TWEAK into naïve mice induces cutaneous inflammation with histological and molecular signs of both diseases. TWEAK is therefore a critical contributor to skin inflammation and a possible therapeutic target in atopic dermatitis and psoriasis.

Project description:Type 2 inflammation contributes to the pathology of skin diseases such as atopic dermatitis and urticaria. Type 2 innate lymphoid cells are key mediators of skin inflammation by releasing type 2 cytokines in response to certain environmental stimuli. We recently found that Rag1 knockout mice exhibit more pronounced skin inflammation in a mouse model of atopic-dermatitis-like disease, despite lacking adaptive immune cells like T helper 2 cells, implicating a critical role of type 2 innate lymphoid cells in this condition. The goal of this study was to characterize transcriptional differences between WT and Rag KO type 2 innate lymphoid cells to determine if Rag knockout leads to cell-intrinsic alterations in innate lymphoid cell function.

Project description:To generate novel atopic dermatitis model, we used Nestin-cre mediated Ikk2FL/FL mice. Nestincre-mediated conditional knockout mice of Ikk2 gene were generated by crossing female Ikk2FL/FL mice to male Nestin-cre;Ikk2FL/+mice. Nestin-cre;Ikk2FL/FL mice spontaneously develop chronic AD-like skin inflammation and severe pruritus. We further performed Cap analysis of gene expression (CAGE) to elucidate transcriptional profiles in lesional skin of Nestin-cre;Ikk2FL/FL mice.

Project description:Low environmental humidity aggravates symptoms of inflammatory skin diseases, e.g. of Atopic Dermatitis (AD). Using mice that develop AD-like symptoms, we show that an increase in environmental humidity rapidly rescues their cutaneous inflammation and associated epidermal abnormalities. Quantitative proteomics analysis of epidermal lysates of mice kept at low or high humidity identified novel humidity-regulated proteins, including Clca2/Clca3a2, a protein with previously unknown function in the skin.

Project description:Type 2 inflammation contributes to the pathology of skin diseases such as atopic dermatitis (AD) and urticaria. We previously found that AD-like inflammation induced by calcipotriol in mice is critically mediated by group 2 innate lymphoid cells (ILC2s), while T cells and B cells are dispensable given development of robust AD-like disease in RAG knockout mice. Indeed, we found that in RAG knockout mice AD-like inflammation was worse, with a proportion of ILC2s displaying increased markers of activation. The goal of this study was to characterize transcriptional and epigenomic changes in ILC populations with a history, or not, of expressing RAG1 in the setting of AD-like skin inflammation.

Project description:Atopic dermatitis (AD) is the chronic inflammatory skin disease accompanied with severe pruritus. To explore the roles of EGR1 in atopic dermatitis and the relationship between EGR1 and pruritus-scratching behavior, we used a atopic dermatitis-like mouse model driven by house dust mite (HDM) treatment in wild type and EGR1 KO mice, followed with RNA-sequencing analysis.

Project description:Occupational and environmental exposure to polycyclic aromatic hydrocarbons (PAHs) has been suggested to provoke inflammatory and/or allergic disorders including asthma, rhinitis and dermatitis. The molecular mechanisms of this PAH-mediated inflammation remain to be clarified. Previous studies implied the involvement of PAHs as irritants and allergens, with the reactive oxygen species generated from the oxygenated PAHs believed to be an exacerbating factor. As well, the possibility exists that PAHs contribute to the pathogenesis through activation of aryl-hydrocarbon receptor (AhR)-mediated transcription, since PAHs are potent inducers of the AhR. To address this point, we generated transgenic mouse lines expressing the constitutive active form of the AhR in keratinocytes. In these lines of mice, the AhR activity was constitutively enhanced in the absence of ligands, so that any other direct effects of PAHs and their metabolites could be ignored. At birth, these transgenic mice were normal, but severe skin lesions with itching developed postnatally. The skin lesions were accompanied by inflammation and immunological imbalance and resembled typical atopic dermatitis. Our present study demonstrates that constitutive activation of the AhR pathway causes inflammatory skin lesions and suggests a new mechanism for the exacerbation of inflammatory diseases following exposure to occupational and environmental xenobiotics. Experiment Overall Design: transgenic mice expressing constitutive active form of AhR in keratinocytes vs. non-transgenic mice (wild type littermates)

Project description:Atopic dermatitis (AD) is a common pruritic dermatitis with macroscopically nonlesional skin that is often abnormal. Therefore, we used high-density oligonucleotide arrays to identify cutaneous gene transcription changes associated with early AD inflammation as potential disease control targets. Skin biopsy specimens analyzed included normal skin from five healthy nonatopic adults and both minimally lesional skin and nearby or contralateral nonlesional skin from six adult AD patients. Keywords: disease state analysis We used high-density oligonucleotide Affymetrix Human U133A GeneChip arrays to identify cutaneous gene transcription changes associated with early AD inflammation as potential disease control targets. Skin biopsy specimens analyzed included normal skin from five healthy nonatopic adults and both minimally lesional skin and nearby or contralateral nonlesional skin from six adult AD patients.

Project description:We recently generated FADS mouse (Nestincre-mediated conditional knockout mouse of Ikk2 gene), a mouse model of atopic dermatitis. To examine the functions of periostin in dermatitis, periostin KO FADS mice were prepared. We then performed Cap analysis of gene expression (CAGE) to elucidate transcriptional profiles in lesional skin of periostin KO FADS mice.

Project description:Periostin is a matricellular protein known to be alternatively spliced to produce isoforms with a molecular weight of 78-91 kDa. In the extracellular matrix, periostin attach to cell surfaces and induce signaling via integrin-binding and participates in fibrillogenesis to organize collagen in the extracellular space. In the atopic diseases atopic dermatitis and asthma, periostin is known to participate in driving the disease-causing type 2 inflammation. The periostin isoforms expressed in these diseases and the implication of the alternative splicing events are unknown. Here we present two universal assays to map the expression of periostin isoforms on both the transcriptional (RT-qPCR) and translational (PRM-based mass spectrometry) level. We use these assays to study the splice profile of periostin in atopic dermatitis lesions from patients in active treatment vs. normal skin and in in vitro models of atopic dermatitis and asthma. All isoforms expect isoform 3 show decreased expression at the transcriptional level in AD lesions from patients treated with corticosteroids compared to normal skin. The isoforms display an elevated amount at the translational level indicating a delayed response in periostin level during treatment. Expression of the isoforms were upregulated in the in vitro models of atopic dermatitis and asthma at both the transcriptional and translational level with isoform 3 and 5 displaying the highest level of overexpression. Interestingly, the often overlooked isoform 9 and 10 behaved opposite to the other isoforms as they were equally or even less abundant in the disease models compared to the control, and they were identified in the normal skin samples but not in atopic dermatitis lesions. With the assays and findings presented in the publication connected to this dataset we can take further steps in mapping and understanding the role of periostin isoforms.