Project description:The innate immune system provides the first response to pathogen infection and orchestrates the activation of the adaptive immune system. Though a large component of the innate immune response is common to all infections, pathogen-specific innate immune responses have been documented as well. The innate immune response is thought to be especially critical for fighting infection with Mycobacterium tuberculosis (MTB), the causative agent of tuberculosis (TB). While TB can be a deadly disease, only 5-10% of individuals infected with MTB develop active disease, and this inter-individual variation is, at least partly, heritable. Studies of inter-individual variation in the innate immune response to MTB infection may therefore shed light on the genetic basis for variation in susceptibility to TB. Yet, to date, we still do not know which properties of the innate immune response are specific to MTB infection and which represent a general response to pathogen infection. To begin addressing this gap, we infected macrophages with eight different bacterial pathogens, including different MTB strains and related mycobacteria, and studied the transcriptional response to infection. We found that although the gene expression changes were largely consistent across the bacterial infection treatments, we were able to identify a novel subset of genes whose regulation was affected specifically by infection with mycobacteria. Genetic variants that are associated with regulatory differences in these genes should be considered candidate loci for explaining inter-individual susceptibility TB. RNA-seq of monocyte-derived macrophages isolated from 6 healthy European males at 4, 18, and 48 hours post-infection with the following 8 bacteria: Mycobacterium tuberculosis (MTB) H37Rv, Mycobacterium tuberculosis GC1237, MTB GC1237, bacillus Calmette-Guérin (BCG), Mycobacterium smegmatis, Yersinia pseudotuberculosis, Salmonella typhimurium, and Staphylococcus epidermidis. table-s1.txt is a tab-delimited text file that contains the batch-corrected log2 counts per million for each of the 156 samples, as well as the Ensembl gene ID and gene name. BCG = bacillus Calmette-Guérin GC = Mycobacterium tuberculosis GC1237 Rv = Mycobacterium tuberculosis (MTB) H37Rv Rv+ = heat-inactivated MTB H37Rv Salm = Salmonella typhimurium Smeg = Mycobacterium smegmatis Staph = Staphylococcus epidermidis Yers = Yersinia pseudotuberculosis

Project description:Tuberculosis (TB) remains a deadly disease. The genetic diversity of Mycobacterium tuberculosis was neglected in the past, but is increasingly recognized as a determinant of immune responses and clinical outcomes of TB. However, how this bacterial diversity orchestrates immune responses to direct differences in TB severity remains unknown. We studied 681 patients with pulmonary TB and found that phylogenetically related M. tuberculosis isolates from cases with mild disease induced robust cytokine responses in macrophages. In contrast, isolates associated with severe TB cases failed to do so. Using representative isolates, we show that M. tuberculosis inducing a low cytokine response in macrophages also diminished activation of cytosolic surveillance systems, including cGAS and the inflammasome, suggesting a novel mechanism of immune escape. Isolates exhibiting this evasion strategy carried mutations in various components of the ESX-I secretion system. We conclude that host interactions with different M. tuberculosis strains results in variable TB severity.

Project description:It was shown that PD-1 were significantly up-regulated in several infectious diseases, suggesting the immune boosting anti-PD-1 therapy may have potential applications in the prevention and treatment of infectious diseases. Here we found that the ablation of the PD-1 was responsible for the TB consequence in a time-dependent manner. While long-term sustained PD-1 ablation results in worsen TB outcome, the early short-term PD-1 pathway perturbing have an active role in the protection of infection, suggesting that the early PD-1 ablation may alter the innate immune-response. Thus, we performed scRNA-seq analysis for the pulmonary transcriptomic landscape of WT and PD-1-/- mice during 7 days after infection. We uncovered that PD-1 pathway ablation at the early stage of infection remodulated pulmonary immune landscape characterized by changes in the cellular compositions, differential gene expression states, augmenting innate immune responses against tuberculosis, together with altering intercellular communications, with the potential to alter anti-TB immune fates.

Project description:Tuberculosis (TB), caused by Mycobacterium tuberculosis (Mtb), remains a significant global health burden, characterized by complex host–pathogen interactions that drive heterogeneous clinical outcomes. While pulmonary epithelial cells are increasingly recognized as active participants in innate immunity during Mtb infection, how host defences are altered when the epithelial barrier is compromised remains unclear . In this study, we developed a murine model combining naphthalene-induced airway epithelial injury with Mtb infection, and found a pronounced impairment in pulmonary bacterial clearance. Through single-cell RNA sequencing (scRNA-seq), we mapped the pulmonary cells landscape and identified widespread suppression of epithelial immune functions. Notably, we observed macrophages transition from an antimicrobial to an antigen-presenting phenotype, indicating waning pulmonary innate defenses and heightened adaptive immune activation. These findings highlight the pivotal role of pulmonary epithelial integrity in shaping host immunity against Mtb and offer new insights into potential therapeutic strategies targeting barrier–immune crosstalk.

Project description:Tuberculosis (TB) is a chronic granulomatous disease caused by the pathogen Mycobacterium tuberculosis. The success of M. tuberculosis can be attributed to its ability to evade protective host immune responses and its recalcitrance to antimicrobial chemotherapy. Detailed understanding of protective host immune response to TB is still lacking and there are limited reports that characterize host responses to TB at the site of disease. Furthermore, although cure of the majority of patients treated with the standard 6-month multidrug regimen indicates that treatment is highly effective, approximately 4-10% of clinically cured patients will develop recurrent disease within the first 12 months after completing therapy. We therefore analyzed BALF supernatant proteomes from pulmonary TB patients and patients at the end of standard anti-TB treatment to gain a better understanding of the host response at the site of disease. This would not only aid our understanding of localised host responses during TB disease, but could allow us to identify protein signatures associated with active TB disease or clinical cure.

Project description:Innate immune cells develop enhanced responsiveness to secondary challenges through trained immunity, a process reliant on memory of prior encounters. However, the intercellular regulatory mechanisms and mediators dictating host-protective trained immunity against infections remain incompletely understood. By profiling plasma exosomal long non-coding RNA (lncRNA) repertoires in a tuberculosis (TB) resister cohort resistant to Mycobacterium tuberculosis (Mtb) infection, we identify lncRNA TB Resister-derived CLOCK Regulator 1 (TRCR1) as an immune trainer for monocytes during their differentiation into macrophages. Mechanistically, internalized exosomal TRCR1 collaborates with RNA-binding protein FXR2 to stabilize CLOCK mRNA by forming condensed lncRNA-protein-mRNA complexes in the cytosol, thereby facilitating the expression of CLOCK, a circadian regulator with histone acetyltransferase activity. This upregulated CLOCK amplifies histone H3 acetylation (K9/K14) at promoters of cytokine-encoding and autophagy-related genes, establishing epigenetic memory in monocytes. We further demonstrate that Mtb-secreted antigens induce human lung epithelial cells to release TRCR1-enriched exosomes, which educate monocytes to develop augmented antimicrobial capacity. In mice, TRCR1 training strengthens host anti-Mtb immunity and improves bacille Calmette-Guérin (BCG) vaccine efficacy. Collectively, our findings unveil an intercellular immune training axis wherein exosomal TRCR1 orchestrates CLOCK-mediated epigenetic programming to potentiate innate memory, providing a strategy for refining BCG vaccination and preventing infectious diseases.

Project description:Innate immune cells develop enhanced responsiveness to secondary challenges through trained immunity, a process reliant on memory of prior encounters. However, the intercellular regulatory mechanisms and mediators dictating host-protective trained immunity against infections remain incompletely understood. By profiling plasma exosomal long non-coding RNA (lncRNA) repertoires in a tuberculosis (TB) resister cohort resistant to Mycobacterium tuberculosis (Mtb) infection, we identify lncRNA TB Resister-derived CLOCK Regulator 1 (TRCR1) as an immune trainer for monocytes during their differentiation into macrophages. Mechanistically, internalized exosomal TRCR1 collaborates with RNA-binding protein FXR2 to stabilize CLOCK mRNA by forming condensed lncRNA-protein-mRNA complexes in the cytosol, thereby facilitating the expression of CLOCK, a circadian regulator with histone acetyltransferase activity. This upregulated CLOCK amplifies histone H3 acetylation (K9/K14) at promoters of cytokine-encoding and autophagy-related genes, establishing epigenetic memory in monocytes. We further demonstrate that Mtb-secreted antigens induce human lung epithelial cells to release TRCR1-enriched exosomes, which educate monocytes to develop augmented antimicrobial capacity. In mice, TRCR1 training strengthens host anti-Mtb immunity and improves bacille Calmette-Guérin (BCG) vaccine efficacy. Collectively, our findings unveil an intercellular immune training axis wherein exosomal TRCR1 orchestrates CLOCK-mediated epigenetic programming to potentiate innate memory, providing a strategy for refining BCG vaccination and preventing infectious diseases.

Project description:The innate immune system provides the first response to pathogen infection and orchestrates the activation of the adaptive immune system. Though a large component of the innate immune response is common to all infections, pathogen-specific innate immune responses have been documented as well. The innate immune response is thought to be especially critical for fighting infection with Mycobacterium tuberculosis (MTB), the causative agent of tuberculosis (TB). While TB can be a deadly disease, only 5-10% of individuals infected with MTB develop active disease, and this inter-individual variation is, at least partly, heritable. Studies of inter-individual variation in the innate immune response to MTB infection may therefore shed light on the genetic basis for variation in susceptibility to TB. Yet, to date, we still do not know which properties of the innate immune response are specific to MTB infection and which represent a general response to pathogen infection. To begin addressing this gap, we infected macrophages with eight different bacterial pathogens, including different MTB strains and related mycobacteria, and studied the transcriptional response to infection. We found that although the gene expression changes were largely consistent across the bacterial infection treatments, we were able to identify a novel subset of genes whose regulation was affected specifically by infection with mycobacteria. Genetic variants that are associated with regulatory differences in these genes should be considered candidate loci for explaining inter-individual susceptibility TB.

Project description:Although host genetics influences susceptibility to tuberculosis, few genes determining disease outcome have been identified. We hypothesized that macrophages from individuals with different clinical manifestations of tuberculosis infection would have distinct gene expression profiles, and that polymorphisms in these genes may also be associated with susceptibility to TB. We measured gene expression levels of >38,500 genes from ex vivo Mtb- stimulated macrophages in 12 subjects with 3 clinical phenotypes: latent, pulmonary and meningeal tuberculosis (n=4 per group). After identifying differentially expressed genes, we confirmed these results in 34 additional subjects by real-time PCR. We also used a case-control study design to examine whether polymorphisms in differentially regulated genes were associated with susceptibility to these different clinical forms of TB. We compared gene expression profiles in Mtb-stimulated and unstimulated macrophages and identified 1608 and 199 genes that were differentially expressed by >2 and >5-fold, respectively. Using cluster analysis, we identified gene expression patterns that distinguished the different clinical forms of tuberculosis. In an independent sample set of 34 individuals and a subset of highly regulated genes, 90% of the microarray results were confirmed by RT-PCR, including expression levels of CCL1, which distinguished the 3 clinical groups. Furthermore, 6 single nucleotide polymorphisms (SNPs) in CCL1 were found to be associated with TB in a case-control genetic association study with 273 TB cases and 188 controls. To our knowledge, this is the first identification of CCL1 as a gene involved in host susceptibility to TB and the first study to combine microarray and DNA polymorphism studies to identify genes associated with TB susceptibility. These results suggest that genome-wide studies can provide an unbiased method to identify critical macrophage response genes that are associated with different clinical outcomes and that variation in innate immune response genes regulate susceptibility to tuberculosis. Experiment Overall Design: Latent TB (LTB) subjects were healthy nursing staff members who had worked at a tuberculosis hospital, for more than 20 years and were positive in ESAT-6 and CFP-10- specific IFN-ï?§ ELISPOT assays. All subjects with pulmonary (PTB) and meningeal (TBM) disease had been treated and were free of symptoms at the time of venipuncture. Gene expression of monocyte derived macrophages (MDMs) from subjects with three clinical forms of TB including LTB, PTB and TBM (n = 4 in each group) was examined by microarray. MDMs were stimulated either with a whole cell lysate of M. tuberculosis H37Rv or PBS for 4 hours. RNA expression was analyzed using a Human Genome U133 Plus 2.0 Array (Affymetrix, USA) which contains probe sets for 47,000 transcripts including 38,500 well-characterized human genes.

Project description:To further understand the host immune factors involved in the progression from latent tuberculosis infection (LTBI) to active tuberculosis (TB) and identify the potential signatures for discriminating TB from LTBI, the genome-wide transcriptional profile of the Mycobacterium.Tuberculosis (M.TB)–specific antigens stimulated peripheral blood mononuclear cells (PBMCs) from active TB, LTBI and health controls (HCs) were performed. A total of 209- and 234- differentially expressed genes (Fold change > 4, P < 0.05) were detected in comparisons of TB vs. LTBI and TB vs. HCs, respectively. Nineteen differentially expressed genes with top fold change between TB and the other two groups were validated in the same RNA samples by real-time PCR, and showed 94.7% consistent expression pattern with microarray test.