Project description:Mycobacterial granulomas are categorical manifestations of tuberculosis pathogenesis. They result from an ensemble of immune responses to Mycobacterium tuberculosis infection, but the identities, arrangement, cellular interactions and regulation of the cells that comprise them has thus far been incompletely understood. We conducted spatial and single-cell RNA sequencing of clinical granuloma biopsy specimens from tuberculosis patients. We found that granulomas consist of concentric transcriptional laminae surrounding areas of central necrosis. Gene expression programs associated with regional architecture were conserved among samples. We identified distinct populations of granuloma-associated stromal cells, fibroblasts, lymphocytes, mast cells, dendritic cells, neutrophils and macrophages. Populations further differentiate into multiple granuloma-specific states that correlate with location. We used inferential analysis to predict dominant granuloma cell-cell interactions, the activity of major signaling pathways, and differential transcription factor activities. Using spatial deconvolution, we mapped a conserved pattern of cellular organization dominated by macrophages rich in osteopontin/SPP1 expression. Trajectory analysis of macrophage subtypes mapped their differentiation and supported the importance of SPP1 to granuloma macrophage polarization. Cumulatively, we have identified a dominant macrophage granuloma population as well as its central regulatory gene in human samples and confirmed its importance to granuloma biology in vivo.

Project description:Mycobacterial granulomas are categorical manifestations of tuberculosis pathogenesis. They result from an ensemble of immune responses to Mycobacterium tuberculosis infection, but the identities, arrangement, cellular interactions and regulation of the cells that comprise them has thus far been incompletely understood. Using the Mycobacterium marinum-zebrafish model we found that mycobacterial infection induces spp1 expression in macrophages and that spp1 ablation results in granuloma formation defects and reduced survival in adult animals. To determine the impact of mycobacterial infection on the transcriptional response of nascent granuloma macrophages we conducted bulk RNA-seq on flow-sorted infected and uninfected macrophages isolated from infected larvae or uninfected controls.

Project description:Purpose: Granulomas are lumps of immune cells that can form in various organs, causing chronic inflammation and tissue destruction. While most granulomas appear histologically heterogeneous and unstructured, they have a certain resemblance of lymphoid organ formation. We thus pursued the hypothesis that granuloma formation is a highly orchestrated process that mixes and repurposes various regulatory mechanisms of normal development Methods: We performed single-cell sequencing and spatial transcriptomics on granulomas from patients diagnosed with cutaneous sarcoidosis, and we bioinformatically reconstructed their gene-regulatory networks and cell-cell interactions Results: We observed regulatory processes underlying granuloma formation that were highly conserved across individuals and followed characteristic spatial patterns. We identified metabolically reprogrammed macrophages, various T cells subsets and structural cells including fibroblasts and endothelial cells as key players in granulomas. Specifically, exhausted interferon-gamma-producing Th17.1 cells with cytotoxic potential and inflammatory fibroblasts were identified as drivers of granuloma formation by attracting various immune cell types. Summary: we found that granuloma formation in sarcoidosis is a molecular and cellular process that adopts specific aspects of normal lymphoid organ development in aberrant combinations. Our study frames human granuloma formation as a developmental pathology and raises the future perspective of therapeutic targeting of granuloma-specific regulatory programs.

Project description:Using the zebrafish-M. marinum model, we identify the basis of granuloma macrophage transformation. Single-cell RNA-seq analysis of zebrafish granulomas as well as analysis of M. tuberculosis-infected macaques reveal that, even in the presence of robust type 1 immune responses, countervailing type 2 signals associate with macrophage epithelialization. We find that type 2 immune signaling, mediated via stat6, is absolutely required for epithelialization and granuloma formation.

Project description:Purpose: Granulomas are lumps of immune cells that can form in various organs, causing chronic inflammation and tissue destruction. While most granulomas appear histologically heterogeneous and unstructured, they have a certain resemblance of lymphoid organ formation. We thus pursued the hypothesis that granuloma formation is a highly orchestrated process that mixes and repurposes various regulatory mechanisms of normal development Methods: We performed single-cell sequencing and spatial transcriptomics on granulomas from patients diagnosed with cutaneous sarcoidosis, and we bioinformatically reconstructed their gene-regulatory networks and cell-cell interactions Results: We observed regulatory processes underlying granuloma formation that were highly conserved across individuals and followed characteristic spatial patterns. We identified metabolically reprogrammed macrophages, various T cells subsets and structural cells including fibroblasts and endothelial cells as key players in granulomas. Specifically, exhausted interferon-gamma-producing Th17.1 cells with cytotoxic potential and inflammatory fibroblasts were identified as drivers of granuloma formation by attracting various immune cell types. Summary: we found that granuloma formation in sarcoidosis is a molecular and cellular process that adopts specific aspects of normal lymphoid organ development in aberrant combinations. Our study frames human granuloma formation as a developmental pathology and raises the future perspective of therapeutic targeting of granuloma-specific regulatory programs.

Project description:Granulomas are lumps of immune cells that can form in various organs. Most granulomas appear unstructured, yet they have some resemblance to lymphoid organ formation. To better understand granuloma formation, we performed single-cell sequencing and spatial transcriptomics on granulomas from patients with sarcoidosis and bioinformatically reconstructed the underlying gene-regulatory networks. We discovered an immune stimulatory environment in granulomas that repurposed transcriptional programs associated with lymphoid organ development. Granuloma formation followed characteristic spatial patterns and involved genes linked to immunometabolism, cytokine and chemokine signaling, and extracellular matrix remodeling. Three cell types emerged as key players in granuloma formation: metabolically reprogrammed macrophages, cytokine-producing Th17.1 cells, and fibroblasts with inflammatory and tissue remodeling phenotypes. Pharmacological inhibition of one of the identified processes attenuated granuloma formation in a sarcoidosis mouse model. We show that human granulomas adopt characteristic aspects of normal lymphoid organ development in aberrant combinations, indicating that granulomas constitute aberrant lymphoid organs.

Project description:Mycobacterium tuberculosis infection in humans triggers formation of granulomas, tightly organized immune cell aggregates that are the central structure of tuberculosis. Infected and uninfected macrophages interdigitate, assuming an altered, flattened appearance. Although pathologists have described these changes for over a century, the molecular and cellular programs underlying this transition are unclear. We find that mycobacterial granuloma formation is accompanied by macrophage induction of canonical epithelial molecules and structures. Using the zebrafish-Mycobacterium marinum model, we identify fundamental macrophage reprogramming events that parallel E-cadherin-dependent mesenchymal-epithelial transitions. Macrophage-specific disruption of E-cadherin function results in disordered granuloma formation, enhanced immune cell access, decreased bacterial burden and increased host survival, suggesting that the granuloma can also serve a bacteria-protective role. In humans, we find that granuloma macrophages are similarly transformed. Long considered largely through the prism of immune signaling pathways, granuloma macrophages are reprogrammed by epithelial modules that alter the trajectory of mycobacterial infection.

Project description:Sarcoidosis is a multiorgan inflammatory disease that is characterized by tissue granulomas and remains so challenging for clinicians to diagnose that it has been called “the great imitator”. Here, by performing single-cell sequencing and spatial transcriptomics on skin granulomas from sarcoid and non-sarcoid patients, we discovered increased recruitment of innate lymphoid cells in granulomas. Sarcoid-associated cells exhibited increased cell migration compared to healthy individuals. Importantly, granuloma formation was attenuated in mice genetically lacking these cells or treated with a pharmacologic inhibitor.

Project description:Most individuals infected with Mycobacterium tuberculosis can control the infection by forming and maintaining TB granulomas at the local infection foci. However, when the chronic infection (also known as latency) becomes active, the caseous center of TB granuloma enlarges, and it liquefies and cavitates, ultimately releasing bacilli into airway. Deciphering how genes are regulated within TB granulomas will help to understand the granuloma biology. Therefore, we performed genome-wide microarray on caseous human pulmonary TB granulomas and compared with normal lung tissues.

Project description:Most individuals infected with Mycobacterium tuberculosis can control the infection by forming and maintaining TB granulomas at the local infection foci. However, when the chronic infection (also known as latency) becomes active, the caseous center of TB granuloma enlarges, and it liquefies and cavitates, ultimately releasing bacilli into airway. Deciphering how genes are regulated within TB granulomas will help to understand the granuloma biology. Therefore, we performed genome-wide microarray on caseous human pulmonary TB granulomas and compared with normal lung tissues. Laser capture microdissection (LCM) was used to dissect out caseous granulomas from TB patients' lung tissues, excluding uninvolved areas. Total RNA were isolated from LCM-derived materials and used for microarray. As a control, parenchyma from normal lung tissues was prepared in the same manner as caseous granulomas. Sample GSM501252, Caseum 2-C, is missing a CEL file.