Project description:A specialized population of memory CD8+ T-cells resides in the epithelium of the respiratory tract to maintain protection against recurring infections. These cells express CD69 and the integrin αβ7 (CD103) and correspond to tissue resident memory T-cells (TRM) also described in intestine, liver and brain. A less well characterized population of CD103- CD8+ T-cells also resides in lungs and expresses markers characteristic of effector memory T-cells (TEM). We determined the transcriptional profiles of these memory CD8+ T-cell subsets retrieved from human lung resection samples and compared these with corresponding T-cell populations from peripheral blood of the same individuals. Our results demonstrate that each of the populations exhibits a distinct transcriptional identity. We found that the lung environment has a major impact on gene expression profiles. Thus, transcriptomes from CD103+ and CD103- subsets from lungs are much more resemblant to one another than to those from CD103+ or CD103- memory CD8+ T-cells from blood. TRM express specific sets of chemokine receptors, in accordance with their unique migratory properties. Furthermore, these cells constitutively express cytokine and cytotoxic genes for immediate effector function and chemokines to attract auxiliary immune cells. At the same time, multiple genes encoding inhibitory regulators are also expressed. This suggests that rapid ability to unleash effector functions is counterbalanced by programmed restraint, a combination that may be critical in the exposed but delicate tissue of the lung. Comprehensive sets of transcription factors were identified that characterize the memory CD8+ populations in the lungs. Prominent among these were components of the Notch pathway. Using mice genetically lacking expression of the NOTCH1 and NOTCH2 receptors in T-cells, we demonstrated that Notch controls both the number of lung TRM as well as the function of lung TEM. Our data illustrate the adaptation of lung resident T-cells to the requirements of the respiratory epithelial environment. Defining the molecular imprinting of these cells is important for rational vaccine design and may help to improve the properties of T-cells for adoptive cellular therapy. Material was collected from a total of 6 subjects. Three patients underwent a lobectomy for a peripheral primary lung tumor and three received lung transplantation because of end-stage pulmonary disease (COPD). Lung mononuclear cells where isolated after digestion of the partial or complete human lung resection material. Paired peripheral blood mononuclear cells were also isolated. CD8+CD16-CD56- T-cells were sorted for expression of CD103 (ITGAE). Lung and blood derived CD103+ and CD103- T-cell fractions were directly lysed after FACS sorting or stimulated overnight with antiCD3/28 beads. Due to the low frequency of resting (non-stimulated) CD103+ T-cells in peripheral blood this subset was obtained from five non-related buffy coat donors. RNA was isolated from 36 sorted cell samples and hybridized on Illumina HumanHT-12 V4.0 microarrays. Eight microarray samples (including two samples from the buffy coat donors) were excluded after hybridization since their average signal was too low.

Project description:Allergic asthma develops from allergen exposure in early childhood and progresses into adulthood. The central mediator of progressive allergic asthma is allergen-specific, T helper 2 (Th2) resident memory cells (TRMs). However, whether the immature lung facilitates residence of Th2-TRMs is unknown. Employing a mouse model of progressive allergic inflammation from neonates to adults, we found that maturing sympathetic nerves enable a dopamine-enriched lung environment in early life that promotes establishment of allergen-specific Th2-TRMs. To expore the molecular mechanism, we apply bulk RNA-seq to test the transcriptome changes in mouse Th2 cells after dopamine treatment.

Project description:There is an urgent need for humanized mouse models of viral respiratory diseases to study immunopathogenesis and therapeutic interventions. Although mice with a functional human immune system (HIS) permit analysis in real time of human immune responses in vivo, evolutionary divergences preclude their usefulness for studies of respiratory viruses that do not infect mouse lungs. Here, we sought to use HIS mice with human lung tissue xenografts (referred to as HISL mice) to address this issue. The grafted human lung tissue was found survived for over 30 weeks, maintained histologically normal structure, and populated with human tissue-resident immune cells, including CD11c+ DCs and CD4+ and CD8+ tissue-resident memory T cells (TRMs). HISL mice showed a marked expansion of TRMs and generation of viral antigen-specific T cells in the human lung xenografts, and production of antiviral IgM and class-switched IgG antibodies upon infection of the human lung xenograft by H1N1 influenza viruses. RNA-seq analysis on H1N1-infected and control human lung xenografts identified a total of 5089 differentially expressed genes (DEGs) with enrichments for genes involved in respiratory tract and lung diseases, viral infections and associated immune responses. Furthermore, prophylactic viral exposures resulted in protection against subsequent lethal challenge by intranasal viral inoculation, leading to reduced disease severity and mortality. This study supports the usefulness of this preclinical model in exploring the immunopathology and therapies of respiratory viral diseases.

Project description:Lung resident mesenchymal stem cells exert a pivotal role in tissue repair. Idiopathic pulmonary fibrosis is characterized by an aberrant tissue repair. We performed a transcriptomic analysis to characterize lung resident mesenchymal stem cells from idiopathic pulmonary fibrosis patients

Project description:Tissue-resident macrophages (TRMs) are innate immune cells that participate in tissue development, homeostasis, and immune surveillance. Extensive efforts have been made to recapitulate TRM development from pluripotent stem cells (PSCs) in vitro to study molecular and cellular mechanisms of TRM development and to create cellular models of disease. However, available PSC models of mouse TRM development exhibit low overall efficiencies of TRM generation, generate heterogeneous off-target populations, and rely upon undefined media components, thus limiting their reproducibility, scalability, and widespread application as an experimental platform for TRM biology. To address these important limitations, we developed an efficient and reproducible protocol to faithfully recapitulate the stepwise differentiation of mouse PSCs (epiblast stem cells) into unspecialized, proliferative TRMs through the pro-definitive hematopoietic program under defined conditions. These immature TRMs can stably integrate into developing mouse neural organoids in vitro and acquire features of microglia, the TRMs of the brain. In addition, immature TRMs can stably engraft into the lung niche in vivo and adopt alveolar macrophage characteristics. This new platform for modeling mouse TRM development will enable paired in vitro and in vivo studies that leverage the full suite of mouse genetic tools, and thus should be a powerful experimental model system for studying TRM function and dysfunction in development and disease.

Project description:A specialized population of memory CD8+ T-cells resides in the epithelium of the respiratory tract to maintain protection against recurring infections. These cells express CD69 and the integrin αβ7 (CD103) and correspond to tissue resident memory T-cells (TRM) also described in intestine, liver and brain. A less well characterized population of CD103- CD8+ T-cells also resides in lungs and expresses markers characteristic of effector memory T-cells (TEM). We determined the transcriptional profiles of these memory CD8+ T-cell subsets retrieved from human lung resection samples and compared these with corresponding T-cell populations from peripheral blood of the same individuals. Our results demonstrate that each of the populations exhibits a distinct transcriptional identity. We found that the lung environment has a major impact on gene expression profiles. Thus, transcriptomes from CD103+ and CD103- subsets from lungs are much more resemblant to one another than to those from CD103+ or CD103- memory CD8+ T-cells from blood. TRM express specific sets of chemokine receptors, in accordance with their unique migratory properties. Furthermore, these cells constitutively express cytokine and cytotoxic genes for immediate effector function and chemokines to attract auxiliary immune cells. At the same time, multiple genes encoding inhibitory regulators are also expressed. This suggests that rapid ability to unleash effector functions is counterbalanced by programmed restraint, a combination that may be critical in the exposed but delicate tissue of the lung. Comprehensive sets of transcription factors were identified that characterize the memory CD8+ populations in the lungs. Prominent among these were components of the Notch pathway. Using mice genetically lacking expression of the NOTCH1 and NOTCH2 receptors in T-cells, we demonstrated that Notch controls both the number of lung TRM as well as the function of lung TEM. Our data illustrate the adaptation of lung resident T-cells to the requirements of the respiratory epithelial environment. Defining the molecular imprinting of these cells is important for rational vaccine design and may help to improve the properties of T-cells for adoptive cellular therapy.

Project description:We use RNAseq to investigate the transcriptome of resident memory CD8 T cells (TRM) infiltrating human lung cancer. CD103+CD8+ T cells and KLRG1+CD8+ T cells (population paired) were sorted by flow cytometry from 7 primary non-small cell lung cancers to elucidate the genetic programs that underlie their immune functions. We compared the RNA expression profile of these two CD8 T cell populations to better describe CD103+CD8+ T cells, which correspond to TRM, and study their role in antitumor immunity.

Project description:Tissue-resident memory T (TRM) cells are crucial mediators of adaptive immunity in non-lymphoid tissues. However, the functional heterogeneity and pathogenic roles of CD4+ TRM cells that reside within chronic inflammatory lesions remain unknown. We found that CD69hiCD103low CD4+ TRM cells produced effector cytokines and promoted the inflammation and fibrotic responses induced by chronic exposure to Aspergillus fumigatus. Simultaneously, immunosuppressive CD69hiCD103hiFoxp3+ CD4+ regulatory T (Treg) cells were induced and constrained the ability of pathogenic CD103low TRM cells to cause fibrosis. Thus, lung tissue-resident CD4+ T cells play crucial roles in the pathology of chronic lung inflammation, and CD103 expression defines pathogenic effector and immunosuppressive tissue-resident cell subpopulations in the inflamed lung.

Project description:To examine differences in the transcriptome of resident memory CD8 T cells in the lung, influenza nucleoprotein-specific CD8 T cells from the airways , lung interstitium, lung vasculature, and spleen were FACS sorted and RNA isolated for RNA-seq. In some experiments, FACS sorted cells were transferred into the airways, peritoneum, or in vitro culture before subsequent isolation and RNA isolation.

Project description:Tissue-resident macrophages (TRMs) are long-lived cells that maintain locally and can be phenotypically distinct from monocyte-derived macrophages. Whether TRMs and monocyte-derived macrophages have district roles under differing pathologies is not understood. Here, we showed that a substantial portion of the macrophages that accumulated during pancreatitis and pancreatic cancer in mice had expanded from TRMs. Pancreas TRMs had an extracellular matrix remodeling phenotype that was important for maintaining tissue homeostasis during inflammation. Loss of TRMs led to exacerbation of severe pancreatitis and death, due to impaired acinar cell survival and recovery. During pancreatitis, TRMs elicited protective effects by triggering the accumulation and activation of fibroblasts, which was necessary for initiating fibrosis as a wound healing response. The same TRM-driven fibrosis, however, drove pancreas cancer pathogenesis and progression. Together, these findings indicate that TRMs play divergent roles in the pathogenesis of pancreatitis and cancer through regulation of stromagenesis.