Project description:CD4+ tissue-resident memory T cells (TRM) drive tissue-specific chronic inflammation by expressing characteristic functional molecules, but how tissue microenvironment-derived stimuli orchestrate their characteristics remains unclear. We found that intracellular hypoxia-dependent activation of EPAS1 programmed human and mouse type 2 CD4+ TRM to acquire immunoregulatory properties through the upregulation of CTLA-4 and IL-10. Genetic deletion of Epas1 in CD4+ T cells decreases the expression of immunoregulatory molecules in type 2 CD4+ TRM, consequently exacerbating lung inflammation. Spatial transcriptomic profiling of human asthmatic lungs identified FOXP3-negative CTLA4+GATA3+ TRM cells with activated hypoxic gene signatures in tertiary lymphoid structures. Our findings revealed that hypoxic pathway activation is a critical determinant of type 2 CD4+ TRM characteristics and highlight Epas1-dependent pathways as promising targets for treating chronic inflammatory disorders.

Project description:CD4+ tissue-resident memory T cells (TRM) drive tissue-specific chronic inflammation by expressing characteristic functional molecules, but how tissue microenvironment-derived stimuli orchestrate their characteristics remains unclear. We found that intracellular hypoxia-dependent activation of EPAS1 programmed human and mouse type 2 CD4+ TRM to acquire immunoregulatory properties through the upregulation of CTLA-4 and IL-10. Genetic deletion of Epas1 in CD4+ T cells decreases the expression of immunoregulatory molecules in type 2 CD4+ TRM, consequently exacerbating lung inflammation. Spatial transcriptomic profiling of human asthmatic lungs identified FOXP3-negative CTLA4+GATA3+ TRM cells with activated hypoxic gene signatures in tertiary lymphoid structures. Our findings revealed that hypoxic pathway activation is a critical determinant of type 2 CD4+ TRM characteristics and highlight Epas1-dependent pathways as promising targets for treating chronic inflammatory disorders.

Project description:CD4+ tissue-resident memory T cells (TRM) drive tissue-specific chronic inflammation by expressing characteristic functional molecules, but how tissue microenvironment-derived stimuli orchestrate their characteristics remains unclear. We found that intracellular hypoxia-dependent activation of EPAS1 programmed human and mouse type 2 CD4+ TRM to acquire immunoregulatory properties through the upregulation of CTLA-4 and IL-10. Genetic deletion of Epas1 in CD4+ T cells decreases the expression of immunoregulatory molecules in type 2 CD4+ TRM, consequently exacerbating lung inflammation. Spatial transcriptomic profiling of human asthmatic lungs identified FOXP3-negative CTLA4+GATA3+ TRM cells with activated hypoxic gene signatures in tertiary lymphoid structures. Our findings revealed that hypoxic pathway activation is a critical determinant of type 2 CD4+ TRM characteristics and highlight Epas1-dependent pathways as promising targets for treating chronic inflammatory disorders.

Project description:Transcriptional profiling of mouse chondrocytes comparing chondrocytes infected with empty adenovirus and Epas1 adenovirus. RNA was extracted from each chondrocytes. We used microarrays to determine the effect of Epas1 overexpression on chondrocytes and identify the noble regulatory molecules during osteoarthritic pathogenesis.

Project description:Transcriptional profiling of mouse fibroblast-like synoviocytes (FLS) comparing FLS infected with empty adenovirus and Epas1 adenovirus. RNA was extracted from each FLS. We used microarrays to determine the effect of Epas1 overexpression on FLS and identifying the noble regulatory molecules during rheumatoid arthritic pathogenesis

Project description:Purpose: By integrating DNA methylation and gene expression of COPD lung tissues, we identified EPAS1 as a key regulator whose downstream genes significantly overlapped with multiple genes sets associated with COPD disease severity. EPAS1 is distinct in comparison with other key regulators in terms of methylation profiles and downstream target genes. Genes predicted to be regulated by EPAS1 were enriched for biological processes including signaling, cell communications, and system developement. As EPAS1 downstream genes were significantly enriched for hypoxia responsive genes in endothelial cells, we tested EPAS1 function in human and mouse endothelial cells HUVEC and C166. EPAS1 knockdown by siRNA in endothelial cells impacted genes that significantly overlapped with EPAS1 downstream genes in lung tissue including hypoxia responsive genes. Methods: The cell lines of HUVEC (Lonza, MD, USA) and C166 (American Type Culture Collection, VA, USA) were cultured in the appropriate media at 37M-BM-0C with 5% CO2. The cells were transfected with EPAS1 siRNA and non-targeting negative control siRNA (Life Technologies, CA, USA) using Lipofectamine RNAiMAX as recommended transfection protocols by the manufacturer. After the treatments with 5nM SilencerM-BM-. Select siRNA (s4700 for EPAS1, s65525 for Epas1; Life Technologies, USA) for 48 hours, the total RNA was purified with RNeasy Mini Kit (QIAGEN, Germany). The efficiencies of knocked down the EPAS1 expression were assessed by qPCR with 1.4% for HUVEC, 3.2% for C166. Approximately 250 ng of total RNA per sample were used for library construction by the TruSeq RNA Sample Prep Kit (Illumina) and sequenced using the Illumina HiSeq 2500 instrument with 100nt single read setting according to the manufacturer's instructions. Sequence reads were aligned to human genome assembly hg19 and mouse genome assembly mm10, respectively, using Tophat [96]. Total 23,228 human and 22,609 mouse genes were quantified using Cufflinks [96]. siRNA signatures were derived by comparing expression profiles of EPAS1 or Epas1 siRNAs with non-targeting siRNAs at paired t-test p-value cutoff 0.05 with resulting signature sizes of 2,796 and 3,730, and corresponding q-values [97] 0.11 and 0.07 for HUVEC and C166, respectively. Results: When comparing endothelial cells treated with EPAS1 siRNAs and scrambled siRNAs, we identified an EPAS1 siRNA signature consisting of 2796 and 3730 genes in human and mouse endothelial cell lines, respectively, whose expression levels significantly changed (t-test p-value<0.05), including EPAS1 itself (p-value = 0.002 and 0.02) and the EPAS1 downstream target gene VEGFA (p-value = 0.03 and 0.01). The EPAS1 siRNA signatures derived from human and mouse cell lines were highly consistent, with 695 genes in common to both signatures (p-value = 7.2x10-65). Both signatures not only significantly overlapped with EPAS1 downstream genes (p-value = 7.3x10-7 and 1.5x10-12), but also with hypoxia response genes in endothelial cells (FisherM-bM-^@M-^Ys Exact Test p-value = 5.8x10-8 and 1.2x10-12 in the human and mouse signatures, respectively). Moreover, the EPAS1 siRNA signatures consistently overlapped genes associated with the COPD severity phenotypes. These results together validate that EPAS1 causally regulates the downstream target genes we predicted, and that these genes in turn affect COPD development and progression. For each of human and mouse cell lines, 3 siRNA control cells, and 3 siRNA EPAS1 knockdown cells were used and analyzed. To identify EPAS1 signatures, paired t-test was performed between control siRNA and EPAS1 siRNA samples.

Project description:In this study we explored the role of hypoxia and the hypoxia-inducible transcription factor EPAS1 in regulating spermatogonial stem cell (SSC) function in the mouse. We demonstrated that SSCs reside in hypoxic microenvironments in the testis through utilisation of the oxygen-sensing probe pimonidazole, and by confirming the stable presence of EPAS1, which is degraded at >5% O2. Here we stabilised EPAS1 expression in primary cultures of undifferentiated spermatogonia with the small drug molecule Daprodustat, providing a platform to identify genes whose expression is regulated by EPAS1 in SSCs.

Project description:Arrhythmogenic cardiomyopathy (ACM) is frequently attributed to desmosomal mutations, such as those in the desmoplakin (DSP) gene. Patients with DSP- cardiomyopathy are predisposed to myocardial degeneration and arrhythmias. Despite advancements, the underlying molecular mechanisms remain incompletely understood, thus limiting therapeutic options. Here, we employed spatial transcriptomics on an explanted heart from a patient with a pathogenic DSP variant. Our transcriptional analysis revealed endothelial PAS domain-containing protein 1 (EPAS1) as a potential regulator of mitochondrial homeostasis in stressed cardiomyocytes. Elevated EPAS1 levels were associated with mitochondrial dysfunction and hypoxic stress in both human-relevant in vitro ACM models and additional explanted hearts with genetic cardiomyopathy. Collectively, cardiomyocytes bearing pathogenic DSP variants exhibit mitochondrial dysfunction, increased apoptosis, and impaired contractility, which are linked to the increased EPAS1 levels. These findings implicate EPAS1 as a key regulator of myocardial degeneration in DSP-cardiomyopathy, which expand to other forms of ACM.

Project description:Arrhythmogenic cardiomyopathy (ACM) is frequently attributed to desmosomal mutations, such as those in the desmoplakin (DSP) gene. Patients with DSP- cardiomyopathy are predisposed to myocardial degeneration and arrhythmias. Despite advancements, the underlying molecular mechanisms remain incompletely understood, thus limiting therapeutic options. Here, we employed spatial transcriptomics on an explanted heart from a patient with a pathogenic DSP variant. Our transcriptional analysis revealed endothelial PAS domain-containing protein 1 (EPAS1) as a potential regulator of mitochondrial homeostasis in stressed cardiomyocytes. Elevated EPAS1 levels were associated with mitochondrial dysfunction and hypoxic stress in both human-relevant in vitro ACM models and additional explanted hearts with genetic cardiomyopathy. Collectively, cardiomyocytes bearing pathogenic DSP variants exhibit mitochondrial dysfunction, increased apoptosis, and impaired contractility, which are linked to the increased EPAS1 levels. These findings implicate EPAS1 as a key regulator of myocardial degeneration in DSP-cardiomyopathy, which expand to other forms of ACM.

Project description:Resident memory T-cells (TRM) reside in the lung epithelium and mediate protective immunity against respiratory pathogens. While lung CD8+ TRM have been extensively characterized, the properties of CD4+ TRM remain unclear. Here we determined the transcriptional signature of CD4+ TRM, identified by the expression of CD103, retrieved from human lung resection material. Various tissue homing molecules were specifically upregulated on CD4+ TRM, while expression of tissue egress and lymph node homing molecules were low. CD103+ TRM expressed low levels of T-bet, only a small portion expressed Eomes, and while the mRNA levels for Hobit were increased, protein expression was absent. On the other hand, the CD103+ TRM showed a Notch signature. CD4+CD103+ TRM constitutively expressed high transcript levels of numerous cytotoxic mediators, which was functionally reflected by a fast recall response, magnitude of cytokine production, and a high degree of polyfunctionality. Interestingly, the superior cytokine production appears to be due to an accessible IFNγ locus and was partially due to rapid translation of preformed mRNA. Our studies provide a molecular understanding of the maintenance and potential function of CD4+ TRM in the human lung. Understanding the specific properties of CD4+ TRM is required to rationally improve vaccine design.