Project description:Atopic dermatitis (AD) is a common disease, with an increasing prevalence. The primary pathogenesis of the disease is still elusive, resulting in lack of specific treatments. The prevailing view is that AD is a biphasic, T-cell polarized disease, with Th2 predominating acute AD, and a switch to Th1 characterizing chronic disease. Identification of factors that participate in onset of lesions and maintenance of chronic lesions is critical for development of targeted therapeutics. We performed global genomic, molecular and cellular profiling of paired non-lesional, acute, and chronic skin biopsies from ten AD patients. Onset of acute lesions is associated with a striking increase in a subset of terminal differentiation proteins, specifically the IL-22-modulated S100A7-9. Correspondingly, acute disease is associated with significant increases in gene expression levels of the major Th22- (IL-22) and Th2- (IL-4, IL-31) cytokines and Th17-regulated genes (CCL20, PI3/Elafin), without significant changes in IL-17. A lesser induction of Th1- (IFNγ, MX-1, CXCL9-11) associated genes was detected in acute disease. Chronic skin lesions are characterized by significantly intensified activation of Th22, Th2 and Th1. Our data establish increased expression of S100A7-9 and other epidermal genes at onset of acute AD, with parallel activation of Th2 and Th22 cytokines. Our findings suggest an absence of switch mechanism in chronic disease and instead indicate that progression to chronic lesions is associated with intensified activation of immune axes that initiate onset of acute lesions, particularly Th22 and Th2. This alters the prevailing view of pathogenesis, with important therapeutic implications. Acute, chronic, and non-lesional skin samples were collected from ten patients with moderate-to-severe AD that met our inclusion criteria, under an institutional review board–approved protocol. The following criteria were employed to define acute AD and distinguish true acute from “acute on chronic” skin lesions: a) new lesions of <72 hours duration, as previously defined;14 b) lack of skin lichenification; c) lack of regenerative hyperplasia, as defined by epidermal thickness ≤150μ [hematoxylin and eosin (H&E)] and basal or confluent supra-basal Keratin 16 (K16) positivity. No systemic or topical treatments were allowed for ≥4 weeks prior to biopsies. Biopsy specimens were frozen in optimal cutting temperature (OCT) for immunohistochemistry (IHC) and liquid nitrogen for RNA extraction.

Project description:House dust mite/HDM atopy patch test/APT elicits positive reactions in the majority of atopic dermatitis/AD and healthy individuals. Experimental systems for new-onset/chronic AD are needed to support rapid therapeutic development, particularly since animal models representing AD pathology in humans are lacking. HDM APT historically simulated AD, but its suitability to model the emerging AD skin phenotype as Th2/Th22 polarized with Th1 and Th17 components is unknown. To assess whether HDM APT tissues reproduce acute or chronic AD, positive HDM APT (n=14) were compared with nonlesional, acute (<72hrs; n=10), and chronic phase AD biopsies (n=8), allergic contact reactions (to nickel [n=10] and fragrance [n=3]) using arrays.

Project description:Background: Atopic dermatitis (AD) is a common inflammatory skin disease with a TH2 immune polarity and is often colonized with Staphylococcus aureus. Despite recent advances in understanding Staphylococcus species infection and the impact of polar TH cytokines on the skin, the interactions between these factors in AD pathology are poorly understood. Methods: AD-related key immune biomarkers were measured by quantitative real-time PCR in human keratinocytes exposed heat-killed S. epidermidis or S. aureus with/without polar T-cell derived cytokines such as IFN-γ (TH1), IL-4/IL-13 (TH2), and IL-22 (TH22). Further analysis was performed by RNA-sequencing to define broader responses in both Staphylococcus species and polar cytokines. The similarity of gene expression patterns in AD skin lesions and stimulated keratinocytes was evaluated by gene-set variation analysis (GSVA). Results: Gene expression analysis exhibited distinct immune responses in keratinocytes depending on individual bacterial or polar cytokine exposure. Besides, numerous genes were synergistically upregulated by the combination exposure of bacteria and polar TH cytokines. Moreover, GSVA revealed that combined exposure of S. aureus and IL-4 + IL-13 exhibited significantly higher correlations with a genomic signature of AD skin lesions than their single exposure or combinations of other polar TH cytokines. Conclusions: Our findings provide novel insights into AD-related transcriptional activation and illustrate a potentially novel pathogenic function of S. aureus and IL-4/IL-13 interactions in AD.

Project description:In this study we performed the first global RNA-seq analysis in 54 ichthyosis patients (7 Netherton syndrome/NS, 13 epidermolytic ichthyosis/EI, 16 lamellar ichthyosis/LI, 18 congenital ichthyosiform erythroderma/CIE) and 40 healthy controls. Differentially expressed genes (DEGs) were defined based on fold changes/FCH>2 and false discovery rate/FDR<0.05 criteria. We found robust and significant Th22/Th17 skewing in all subtypes (e.g. IL-17A/C/F, S100A7/8/9/12; p<0.001) with modest changes in Th2 pathway, primarily in NS, and Th1 skewing in CIE.

Project description:Progressive Activation of Th2/Th22 characterizes acute and chronic atopic dermatitis

Project description:After 2 and 12 weeks of treatment, we observed significant reductions of 51% and 72%, respectively, in SCORAD scores. Clinical improvements were associated with significant gene expression changes in lesional but also nonlesional skin, particularly reductions in levels of TH2-, TH22-, and some TH17-related molecules (ie, IL-13, IL-22, CCL17, S100As, and elafin/peptidase inhibitor 3), and modulation of epidermal hyperplasia and differentiation measures. Cyclosporine A (CsA)'s effects on AD skin pathology were evaluated by using gene expression and immunohistochemistry studies in baseline, week 2, and week 12 lesional and nonlesional biopsy specimens from 19 patients treated with 5 mg/kg/day CsA for 12 weeks.

Project description:Th subsets are defined according to their production of lineage-indicating cytokines and functions. In this study, we have identified a subset of human Th cells that infiltrates the epidermis in individuals with inflammatory skin disorders and is characterized by the secretion of IL-22 and TNF-a, but not IFN-g, IL-4, or IL-17. In analogy to the Th17 subset, cells with this cytokine profile have been named the Th22 subset. Th22 clones derived from patients with psoriasis were stable in culture and exhibited a transcriptome profile clearly separate from those of Th1, Th2, and Th17 cells; it included genes encoding proteins involved in tissue remodeling, such as FGFs, and chemokines involved in angiogenesis and fibrosis. Primary human keratinocytes exposed to Th22 supernatants expressed a transcriptome response profile that included genes involved in innate immune pathways and the induction and modulation of adaptive immunity. These proinflammatory Th22 responses were synergistically dependent on IL-22 and TNF-a. Furthermore, Th22 supernatants enhanced wound healing in an in vitro injury model, which was exclusively dependent on IL-22. In conclusion, the human Th22 subset may represent a separate T cell subset with a distinct identity with respect to gene expression and function, present within the epidermal layer in inflammatory skin diseases. Future strategies directed against the Th22 subset may be of value in chronic inflammatory skin disorders.

Project description:In psoriasis, inflammation and epidermal hyperplasia are thought to be controlled by T cell-derived cytokines. Evidence now suggests that Th17 and Th22 cells infiltrate psoriasis lesions and by secreting IL-17 and IL-22, respectively, may drive disease-specific gene or cell responses. While studies in model systems indicate that IL-22 has a dominant pathogenic role, there is evolving evidence that IL-17 contributes to features of psoriasis. To more fully understand the role of IL-17 in human disease pathogenesis, we examined psoriatic skin lesions obtained from patients treated with an anti-IL-17 (IL-17 A) monoclonal antibody, LY2439821. In a phase 1, randomized, double-blind, placebo-controlled dose escalation trial, patients with chronic psoriasis were randomized to receive 3 doses of subcutaneous LY2439821 at 5 mg (n=8), 15 mg (n=8), 50 mg (n=8), 150 mg (n=8) or placebo (n=8) at weeks 0, 2 and 4. Repeat biopsies were taken from the same lesional area at baseline, week 2 and 6. At week 6, a PASI75 was observed in 0/8, 2/8, 5/7 and 8/8 patients receiving 5 mg, 15 mg, 50 mg or 150 mg LY2439821 respectively and 0/8 patients receiving placebo. The antibody was well-tolerated. In patients receiving the two highest doses, histological and immunohistochemical analyses of biopsies revealed significant reductions from baseline in keratinocyte proliferation, hyperplasia and epidermal thickness after 2 weeks, as well as reduced infiltration into the dermis and epidermis by T-cells (CD3+) and dendritic cells (CD11c and DC-LAMP). Keratinocyte expression of innate defense proteins, S100A7, S100A8, beta-defensin2 and LL37/cathelicidin was also reduced. By week 6, the skin appeared normal with a reversal of disease defining pathological features. Quantitative RT-PCR revealed decreased expression of interferon gamma (IFN-gamma), IL-22 and IL-17, key cytokines from T cell subsets Th1, Th22 and Th17, respectively. In order to explore the extent to which IL-17 blockade influences an even broader set of inflammatory or psoriatic disease related genes, mRNA levels from skin biopsy samples were evaluated using whole genome microarrays. At week 2, the highest dose of LY2439821 modulated over 1500 genes significantly (>1.5 fold change [FC], p<0.05). Of these, 51 genes were strongly suppressed (>7-fold) including IL-19, lipocalin, amphiregulin, granzyme B, and several chemokines. In a separate analysis, those genes known to be synergistically regulated by both IL-17 and TNF-alpha showed the greatest normalization in expression compared to genes known to be regulated by TNF-alpha alone, IFN-gamma or Interferon alpha. Our data suggest that Th17 cells, through the expression of IL-17, mediate psoriasis pathogenesis, and that neutralization of IL-17 with LY2439821 suppresses signaling through multiple inflammatory circuits by inhibiting expression of cytokines from multiple T cell subsets, as well as chemokines, and antimicrobial proteins from keratinocytes. In a phase 1, randomized, double-blind, placebo-controlled dose escalation trial, patients with chronic psoriasis were randomized to receive 3 doses of subcutaneous LY2439821 at 5 mg (n=8), 15 mg (n=8), 50 mg (n=8), 150 mg (n=8) or placebo (n=8) at weeks 0, 2 and 4. Repeat biopsies were taken from the same lesional area at baseline, week 2 and 6. At week 6, a PASI75 was observed in 0/8, 2/8, 5/7 and 8/8 patients receiving 5 mg, 15 mg, 50 mg or 150 mg LY2439821 respectively and 0/8 patients receiving placebo.

Project description:We applied untargeted lipidomic analysis to the atopic dermatitis-like dermatitis model (Spade mice) to capture the comprehensive lipidome profile in the course of dermatitis onset and progression. Spade mice harbor a single amino acid mutation in Jak1 that causes hyperactivation, leading to Th2 dermatitis. Progressive dermatitis develops as desquamation and redness of the ears at approximately 8 weeks of age. At 10 weeks of age, serum IgE and IgG1 levels are increased, and Th2 cytokines, such as IL-4, IL-5, and IL-13, produced by CD4+ cells are upregulated, followed by elevated serum histamine levels at 12 weeks of age. Skin lesions manifest as epidermal hyperplasia at 8 weeks of age, while there are few morphological changes at 4 weeks of age. TEWL, the readout for barrier function, is significantly elevated in Spade mice at 4 weeks of age, suggesting that barrier defects had occurred before disease onset. WT and Spade skin tissues in P0, 4, 8, and 10 weeks of age were applied to untargeted lipidomics. Over 700 skin lipids including glycerophospholipids, ceramides, neutral lipids, and fatty acids were successfully annotated, and many of them were found to be significantly changed after dermatitis onset as determined by pruritus and erythema. Among them, the levels of Cer[NdS] containing very long-chain (C22 or more) fatty acids were significantly downregulated before AD onset.

Project description:Background: Atopic dermatitis (AD) predominantly affects young children, but our understanding of AD pathogenesis is based on skin and blood samples from longstanding adult AD. Genomic biopsy profiling from early pediatric AD showed significant Th2 and Th17/Th22-skewing, without the characteristic adult Th1 up-regulation. Since obtaining pediatric biopsies is difficult, blood gene expression profiling may provide a surrogate for the pediatric skin signature. Objective: To define the blood profile and associated biomarkers of early moderate-to-severe pediatric AD. Methods: We compared microarrays and RT-PCR of blood cells from 28 AD children (<5yrs and within 6 months of disease onset) to healthy control blood cells. Differentially expressed genes/DEGs in blood (fold change/FCH>1.2 and false discovery rate/FDR<0.05) were then compared with skin DEGs. Results: Eosinophil and Th2 markers (IL5RA, IL1RL1/ST2, HRH4, CCR3, SIGLEC8, PRSS33, CLC from gene arrays; IL13/IL4/CCL22 from RT-PCR) were upregulated in early pediatric AD blood, while IFNG/Th1 was decreased. Th1 markers were negatively correlated with clinical severity (EASI, pruritus, transepidermal water loss/TEWL), whereas Th2/Th17-induced IL19 was positively correlated with SCORAD. While a few RT-PCR-defined immune markers (IL13/CCL22) were increased in blood, as previously also reported for skin, there was minimal overlap based on gene array DEGs. Conclusion: The whole blood signature of early moderate-to-severe pediatric AD blood cells show predominantly a Th2/eosinophil profile, but markers largely differ from the skin profile. Given their complementarity, pooling of biomarkers from blood and skin may improve profiling and predictions, providing insight regarding disease course allergic comorbidity development, and response to systemic medications.