Project description:Pathogenesis of allergic diseases including asthma is strongly associated with robust responses of allergen-specific Th2 cells, which produce high levels of IL-4, IL-5, IL-9, and IL-13. Despite evidence for pathogenic Th2 cells in the induction and propagation of allergic disorders, signals required for differentiation of such cells remain largely unknown. Thymic stromal lymphopoietin (TSLP) is a cytokine that is expressed upon epithelial injury, dysfunction or infection and is strongly implicated in the pathogenesis of atopic dermatitis (AD) and asthma. Although indirect regulation of Th2 differentiation via TSLP-stimulated dendritic cells well known, direct effects of TSLP on Th2 differentiation in vivo have not been rigorously analyzed. We show that TSLP may initiate Th2 response independent on IL-4 signal and increases sensitivity of CD4 cells to IL-4 stimulation inducing more robust expression of IL-4, IL-5, and IL-13 by human and mouse CD4 cells. This more potent effector state appears to be stably programmed in memory Th2 cells. As part of molecular mechanism, we demonstrate that TSLP and IL-4 signals induce distinctive genome wide alterations in activating histone modification (H3K27Ac, H3K36Me3, and H3K4Me3). We propose that TSLP acts in coordination with IL-4 to generate a more potent Th2 state that could underlie persistence and propagation of allergic disorders.

Project description:Innate pattern recognition receptors for conserved structural elements play critical roles in immunity against viruses, bacteria and fungi, but analogous pathways linking innate recognition of diverse allergens or helminths with type 2 immunity remain elusive. The discovery of group 2 innate lymphoid cells (ILC2s), which produce similar cytokines as CD4+ T helper 2 (Th2) cells1, has suggested models whereby ILC2s directly or indirectly induce adaptive Th2 cells,2-8 but current understanding of how these cells interact in tissue microenvironments to coordinate allergic immunity is limited. Here, we show that tissue Th2 cells differentiate independently of ILC2s, but that both cell types share overlapping transcriptional and functional programs, which require exposure to the tissue-derived cytokines such as interleukin (IL)-25, IL-33, and thymic stromal lymphopoietin (TSLP). Combined loss of these epithelial cytokines affects neither Th2 cell priming nor T cell-dependent antibody production, but abrogates allergic lung inflammation due to requirements for local tissue signals to promote differentiation of effector function in both ILC2s and Th2 cells. Our findings reveal how diverse perturbations, including proteases, venoms and mechanical irritants, converge on common pathways to activate type 2 immune responses, thus uncovering a shared checkpoint that can be exploited to control both innate and adaptive allergic inflammation.

Project description:Eosinophilic esophagitis (EoE) is an allergic disorder characterized by the recruitment of eosinophils to the esophagus, resulting in chronic inflammation. We sought to understand the cellular populations present in the esophageal biopsies of patients with EoE and to determine how these populations are altered between active disease and remission. To this end, we analyzed cells from the esophageal biopsies, duodenal biopsies, and peripheral blood of EoE patients in active disease or remission using single-cell RNA and TCR sequencing. We identified gene modules regulated by transcription factors from the NF-κB family that characterize activated eosinophils in patients with active disease. Pathogenic effector Th2 (peTh2) cells present in the esophageal biopsies of patients with active disease expressed unique gene signatures associated with the synthesis of eicosanoids that are predicted to directly promote activation of tissue-resident eosinophils. The tissue-resident peTh2 population also exhibited clonal expansion, suggesting antigen-specific activation. Peripheral CRTH2+CD161- and CRTH2+CD161+ memory CD4+ T cells were enriched for either a conventional Th2 phenotype or a peTh2 phenotype, respectively. These cells also exhibited significant clonal expansion and convergence of TCR sequences, indicating that these cells are expanded in response to a defined set of antigens. The esophagus-homing receptor GPR15 was upregulated by peripheral peTh2 clonotypes that were also detected in the esophagus. Lastly, peTh2 cells and GPR15+ cells were enriched among milk-reactive CD4+ T cells in patients with milk-triggered disease, suggesting that peTh2 cells in EoE are an expanded, food antigen-specific population with enhanced esophagus homing potential.

Project description:Introduction Disruption of the epithelial barrier can induce eosinophilic esophagitis (EoE), a TH2-mediated food- and aeroallergen associated chronic inflammatory disease 1, 2. The expression of IL-20 subfamily cytokines, IL-19, IL-20 and IL-24, is increased in TH2-mediated diseases, yet their function in EoE is unknown. Methods Combining RNA-sequencing (RNA-seq) and proteome analysis, we have examined the effects of the IL-20 subfamily on esophageal epithelial cells using patient-derived organoids and an experimental EoE mouse model. Results When stimulated with IL-20 subfamily cytokines patient-derived esophageal organoids showed decreased expression of Filaggrin (FLG) and Filaggrin 2 (FLG2) responsible for epithelial cornification. In agreement, EoE patients with active inflammation showed elevated IL-20 subfamily cytokines and decreased FLG and FLG2 expression. Topical corticosteroid treatment in EoE patients restored filaggrin expression, while reducing IL-20 subfamily cytokines. Abolishment of IL-20 subfamily signalling in Il20R2-/- animals attenuated experimental EoE in an OVA-induced mouse model. In the esophageal keratinocyte cell line, KYSE-180, we identified IL-20 subfamily-induced STAT3 and MAPK (ERK1/2) pathway activation. However, Stat3fl/flKrt5cre mice with an epithelium specific deletion of Stat3 developed exacerbated experimental EoE with a pronounced decrease of Flg2. In line, combined stimulation of patient-derived esophageal organoids with IL-20 subfamily cytokines and pharmacological inhibition of STAT3 resulted in aggravated decrease of FLG and FLG2. In addition, pharmacological STAT3 inhibition resulted in reduced transepithelial electrical resistance (TEER) and increased macromolecular flux in patient-derived air liquid interface (ALI) cultures. Whereas, inhibition of the MAPK (ERK1/2) pathway hampered IL-20 subfamily induced TEER reduction and paracellular flux increment. Finally, MAPK (ERK1/2) inhibitor treatment reduced infiltrating CD45+ immune cells in the esophagus and alleviated experimental EoE in mice. Conclusion We discovered a novel regulatory function of the IL-20 subfamily for epithelial barrier integrity. Aberrant IL-20 subfamily signaling disturbs the epithelial barrier function, while abrogation of IL-20 subfamily and ERK1/2 signaling restores epithelial integrity and attenuates experimental EoE. Therefore, we propose that targeting the IL-20 subfamily pathway could present a novel therapeutic strategy for EoE treatment.

Project description:Unraveling the diversity of Th2 effector cells subsets may help us to understand their pathogenic role in Type-2 associated inflammatory disorders, including allergic diseases and helminth infections. To characterize the heterogeneity and function of these effector Th2 cells, we analyzed 47 subjects’ PBMCs [23 filarial-infected (Fil+) with or without coincident HDM sensitization (Fil+HDM+ n=12; Fil+HDM-, n=11) and 24 subjects without filarial infection (Fil-) (Fil-HDM+ n=12; and Fil-HDM-, n=12) using multiparameter flow cytometry and two-level FlowSOM analysis. The frequency of 3 memory CD4+ T cell clusters, including CCR4+CCR6+CRTH2- (subset 1), CCR4+CCR6-CRTH2+ (subset 2), and CCR6+CCR4+CRTH2+ (subset 3) were markedly enriched among Fil+ subjects. The functional characterization indicated subset 2 and 3 as distinct Th2 cytokine producers, which together were responsible for the majority of IL-4, IL-5, or IL-13 produced among the Fil+ subjects. These subsets were sorted and analyzed by multiomic single cell RNA profiling. Indeed, both subset 2 and subset 3 presented features of pathogenic Th2 effector cells based on their single cell molecular signature, including downregulation of cd27 and high expression levels of itga4, il-17rb, hpgds, klrb1, ptgdr2, il-9r, il-4, il5 and il-13 genes when compared with conventional Th2 cells from healthy controls. When the Fil+ subjects were divided based on allergic status, the Fil+HDM+ subjects had an expansion of both subset 2 (3.19% vs 1.28%, p=0.001) and subset 3 (0.39% vs 0.15%, p=0.002) Th2 cells when compared with Fil+HDM-. Gene expression analysis further demonstrated that concomitant HDM sensitization in the presence of filarial infection reshaped the molecular program of these pathogenic effector Th2 subsets by even further upregulating the expression of gata3, il17rb, clrf2, and klrb1. Notably, Fil+HDM+ patients’ cells showed higher responsiveness to filarial or HDM antigenic stimulation, producing even higher levels of IL-4, IL-5 and IL-13 when compared with Fil+HDM- patients. This distinct molecular and functional program of Th2 effector cells subsets sheds new light on the Th2 cell plasticity and their contribution to immune regulation in helminth infection and allergic diseases.

Project description:The Ikaros zinc finger transcription factor Eos has been commonly implicated in regulatory T cells to promote their immunosuppressive functions. Paradoxically, a new role is emerging for Eos in promoting pro-inflammatory responses of conventional CD4+ T cells in the dysregulated setting of autoimmunity. Even so, the precise role of Eos in regulating the differentiation and function of healthy effector CD4+ T cell subsets remains unclear. Here, we find that Eos is a positive regulator of CD4+ T helper 2 (TH2) cells—effector T cells implicated in the induction of allergic asthma. Using murine in vitro TH2 cells and an in vivo house dust mite asthma model, we found that Eos-deficient T cells had reduced expression of key TH2 transcription factors, effector cytokines, and differentiation receptors. Mechanistically, among various TH2-polarizing pathways, the IL-2/STAT5 axis and its downstream TH2 gene targets emerged as one of the most significantly downregulated networks in Eos deficiency. Using in vitro TH2 cells and overexpression of Eos zinc-finger-domain mutants, we discovered that Eos forms a novel complex with and supports the tyrosine-phosphorylated signaling activity of STAT5. Overall, these data define a novel regulatory mechanism whereby Eos promotes IL-2/STAT5 activity to facilitate TH2 differentiation.

Project description:T helper type 2 (Th2) responses are crucial for defense against infections by helminths and are responsible for the development of allergic reactions that can lead to severe clinical disorders, such as asthma or anaphylaxis, and ultimately to death. The induction of Th2 responses requires a specific activation process, triggered by specialized dendritic cells (DCs), by which naive CD4+ Th0 cells acquire the capacity to produce Th2 cytokines. However, the mechanistic basis of the functional specialization enabling DCs for the initiation of Th2 responses has remained elusive. Here we show that interleukin-4 (IL-4), a cytokine produced by basophils, mast cells and Th2-polarized CD4+ T helper cells, exerting a crucial function during anti-helminths and allergic Th2 responses, has a key role in the licensing/conditioning of DCs for the induction of Th2 responses, by bloking their potential to produce Th1-driving cytokines, such as IL-12, IL-18 and IL-23. Microarray analyses (duplicates) were for two types of comparisons: 1. moDCs stimulated with LPS from Escherichia coli versus C-moDCs non stimulated (control). 2. moDCs stimulated with LPS from Escherichia coli in presence of IL4 versus C-moDCs non stimulated (control).

Project description:T helper type 2 (Th2) responses are crucial for defense against infections by helminths and are responsible for the development of allergic reactions that can lead to severe clinical disorders, such as asthma or anaphylaxis, and ultimately to death. The induction of Th2 responses requires a specific activation process, triggered by specialized dendritic cells (DCs), by which naive CD4+ Th0 cells acquire the capacity to produce Th2 cytokines. However, the mechanistic basis of the functional specialization enabling DCs for the initiation of Th2 responses has remained elusive. Here we show that interleukin-4 (IL-4), a cytokine produced by basophils, mast cells and Th2-polarized CD4+ T helper cells, exerting a crucial function during anti-helminths and allergic Th2 responses, has a key role in the licensing/conditioning of DCs for the induction of Th2 responses, by bloking their potential to produce Th1-driving cytokines, such as IL-12, IL-18 and IL-23. Microarray analyses (duplicates) were used to compared the transcriptional profile of monocyte-derived dendritic cells (moDCs) cultured with GM-CSF in the absence or presence of interleukin-4: IL4-moDCs versus C-moDCs.

Project description:Antigen encounter directs CD4+ T cells to differentiate into T-helper or -regulatory cells. This process focuses the immune response on the invading pathogen and limits tissue damage. Mechanisms that govern -helper versus -regulatory fate remain poorly understood. Here, we show that the E3 ubiquitin ligase Cul5 determines fate selection in CD4+ T cells by regulating IL-4 receptor signaling. Mice lacking Cul5 in T cells developed enhanced Th2 and Th9 inflammation and pathophysiological features of atopic asthma upon allergen exposure. Following T cell activation, Cul5 formed a complex with CIS and pJak1. Loss of Cul5 function resulted in reduced ubiquitylation and increased stability of pJak1, elevated STAT6 activity, and a reduced threshold for IL-4 receptor signaling. In keeping with this, Cul5-deficient T cells deviated from Treg to Th9 differentiation in low IL-4 conditions. These data support that Cul5 promotes a tolerogenic T cell fate choice and reduces susceptibility to allergic asthma.

Project description:T helper type 2 (Th2) responses are crucial for defense against infections by helminths and are responsible for the development of allergic reactions that can lead to severe clinical disorders, such as asthma or anaphylaxis, and ultimately to death. The induction of Th2 responses requires a specific activation process, triggered by specialized dendritic cells (DCs), by which naive CD4+ Th0 cells acquire the capacity to produce Th2 cytokines. However, the mechanistic basis of the functional specialization enabling DCs for the initiation of Th2 responses has remained elusive. Here we show that interleukin-4 (IL-4), a cytokine produced by basophils, mast cells and Th2-polarized CD4+ T helper cells, exerting a crucial function during anti-helminths and allergic Th2 responses, has a key role in the licensing/conditioning of DCs for the induction of Th2 responses, by bloking their potential to produce Th1-driving cytokines, such as IL-12, IL-18 and IL-23.