Project description:Humans are highly genetically diverse, and most are resistant to Mycobacterium tuberculosis. However, lung tissue from genetically resistant humans is not readily available to identify potential mechanisms of resistance. To address this, we model M. tuberculosis infection in Diversity Outbred mice. Like humans, Diversity Outbred mice also exhibit genetically determined susceptibility to M. tuberculosis infection: Progressors who succumb within 60 days of a low dose aerosol infection due to acute necrotizing granulomas, and Controllers who maintain asymptomatic infection for at least 60 days, and then develop chronic pulmonary TB with occasional necrosis and cavitation, over months to greater than 1 year. Here, we identified specific regions of granuloma-associated lymphoid tissue (GrALT) and B-cell gene expression pathways as key features of asymptomatic lung infection using cytokine, antibody, granuloma image, and gene expression datasets. Cytokines and anti-M. tuberculosis cell wall antibodies discriminated acute vs chronic pulmonary TB but not asymptomatic lung infection. To find unique features of asymptomatic lung infection, we trained a weakly supervised, deep-learning neural network on lung histology images. The neural network accurately produced an interpretable imaging biomarker: perivascular and bronchiolar lymphocytic cuffs, a type of GrALT. We expected CD4 T cell genes would be highly expressed in asymptomatic lung infection. However, the significantly different, highly expressed genes in lungs of asymptomatically infected Diversity Outbred mice corresponded to B-cell activation, proliferation, and antigen-receptor signaling, including Fcrl1, Cd79, Pax5, Cr2, and Ms4a1. Overall, our results suggest that genetically controlled B-cell responses are important for establishing asymptomatic M. tuberculosis lung infection.

Project description:Mycobacterium tuberculosis infects two billion people across the globe, and results in 8-9 million new tuberculosis (TB) cases and 1-1.5 million deaths each year. Most patients have no known genetic basis that predisposes them to disease. Here, we investigate the complex genetic basis of pulmonary TB by modelling human genetic diversity with the Diversity Outbred mouse population. When infected with M. tuberculosis, one-third develop early onset, rapidly progressive, necrotizing granulomas and succumb within 60 days. The remaining develop non-necrotizing granulomas and survive longer than 60 days. Genetic mapping using immune and inflammatory mediators; and clinical, microbiological, and granuloma correlates of disease identified five new loci on mouse chromosomes 1, 2, 4, 16; and three known loci on chromosomes 3 and 17. Further, multiple positively correlated traits shared loci on chromosomes 1, 16, and 17 and had similar patterns of allele effects, suggesting these loci contain critical genetic regulators of inflammatory responses to M. tuberculosis. To narrow the list of candidate genes, we used a machine learning strategy that integrated gene expression signatures from lungs of M. tuberculosis-infected Diversity Outbred mice with gene interaction networks to generate scores representing functional relationships. The scores were used to rank candidates for each mapped trait, resulting in 11 candidate genes: Ncf2, Fam20b, S100a8, S100a9, Itgb5, Fstl1, Zbtb20, Ddr1, Ier3, Vegfa, and Zfp318. Although all candidates have roles in infection, inflammation, cell migration, extracellular matrix remodeling, or intracellular signaling, and all contain single nucleotide polymorphisms (SNPs), SNPs in only four genes (S100a8, Itgb5, Fstl1, Zfp318) are predicted to have deleterious effects on protein functions. We performed methodological and candidate validations to (i) assess biological relevance of predicted allele effects by showing that Diversity Outbred mice carrying PWH/PhJ alleles at the H-2 locus on chromosome 17 QTL have shorter survival; (ii) confirm accuracy of predicted allele effects by quantifying S100A8 protein in inbred founder strains; and (iii) infection of C57BL/6 mice deficient for the S100a8 gene. Overall, this body of work demonstrates that systems genetics using Diversity Outbred mice can identify new (and known) QTLs and functionally relevant gene candidates that may be major regulators of complex host-pathogens interactions contributing to granuloma necrosis and acute inflammation in pulmonary TB.

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.

Project description:Increasing evidence suggests that antibodies (Abs) can have protective roles in M. tuberculosis (Mtb) infection but knowledge of the most relevant protective antigens and epitopes in humans is limited. Using novel glycan arrays, we establish that human serum IgG induced against the M. tuberculosis (Mtb) capsular polysacharide arabinomannan (AM) in natural Mtb infection is highly heterogeneous in its binding specificity and differs in both its reactivity to oligosaccharide (OS) motifs within AM and its functions between BCG vaccination and/or controlled (latent) versus uncontrolled (TB) M. tuberculosis infection. We show that anti-AM IgG from asymptomatic but not diseased individuals is protective, and provide data suggesting a role of IgG2 and specific AM oligosaccharides. Filling a gap in the current knowledge of protective antigens in humans, our human data support the key role of the M. tuberculosis surface glycan AM and suggest the importance of targeting specific glycan epitopes within AM in antibody-mediated immunity against TB.

Project description:Tuberculosis (TB) is a heterogeneous disease manifesting in a subset of individuals infected with aerosolized Mycobacterium tuberculosis (Mtb). Unlike human TB, murine infection results in uniformly high lung bacterial burdens and poorly organized granulomas.  To develop a TB model that more closely resembles human disease, we infected mice with an ultra-low dose (ULD) of between 1-3 founding bacteria, reflecting a physiologic inoculum. ULD-infected mice exhibited highly heterogeneous bacterial burdens, well-circumscribed granulomas that shared features with human granulomas, and prolonged Mtb containment with unilateral pulmonary infection in some mice. We identified blood RNA signatures in mice infected with an ULD or a conventional Mtb dose (50-100 CFU) that correlated with lung bacterial burdens and predicted Mtb infection outcomes across species, including risk of progression to active TB in humans. Overall, these findings highlight the potential of the mouse TB model and show that ULD infection recapitulates key features of human TB.

Project description:Induced lymphoid structures associated with pulmonary granulomas have been observed during TB in both humans and mice and could orchestrate host defense. In order to determine whether granulomas perform lymphoid functions, mice lacking secondary lymphoid organs (SLOs) were infected with Mycobacterium tuberculosis (MTB). As in wild type mice (WT), granulomas developed, MTB was controlled, and antigen-specific T cell responses including T central memory (TCM) cells were generated in the complete absence of SLOs. Moreover, T cell activation correlated with granuloma formation in these mice and TCM cells accumulated in lungs and participated in protection against secondary MTB infection. Lung granulomas may therefore represent tertiary lymphoid organs (TLOs) capable of priming robust T cell responses and mediating host defense during chronic MTB at the site of infection.

Project description:We sought to develop and characterize a novel paucibacillary model in mice, which develop necrotic lung granulomas following infection with Mycobacterium tuberculosis. Paucibacillary infection was established, recapitulating the sterilizing activities of human LTBI regimens. TNF neutralization led to increased lung bacillary load, disrupted granuloma architecture with expanded necrotic foci and reduced tissue hypoxia, and accelerated animal mortality. TNF-neutralized mouse lungs and sera showed significant upregulation of IFN?, IL-1?, IL-6, IL-10, CCL2, CCL3, and matrix metalloproteinase genes Six weeks after aerosol-immunization with recombinant M. bovis BCG overexpressing the 30-kilodalton antigen, C3HeB/FeJ mice were aerosol-infected with M. tuberculosis H37Rv. Six weeks later, mice were treated with one of three standard regimens for latent TB infection (LTBI) or TNF-neutralizing antibody. Mouse lungs were analyzed by histology, positron emission tomography/computed tomography, whole-genome microarrays, and RT-PCR. Lungs and sera were studied by multiplex enzyme-linked immunosorbent assays

Project description:Tuberculosis (TB), caused by the bacterium Mycobacterium tuberculosis (Mtb), infects approximately one-fourth of the world’s population. The majority of infected persons are asymptomatic, but latent TB infection (LTBI) can progress to active clinical disease in 5-10% of infected individuals. The immune mechanisms that govern progression from latent to active pulmonary TB (PTB) remain poorly defined. An in-depth understanding of immune factors correlating with TB disease, as well as protection during TB, is necessary for developing new immunotherapies to promote immune control of Mtb. Experimentally Mtb-infected non-human primates (NHP) mirror the disease progression and pathology observed in humans and can recapitulate both PTB and LTBI. In the present study, we have characterized the lung immune landscape in NHPs with LTBI and PTB using high-throughput technologies including single-cell RNA sequencing (scRNA-seq) and Time of flight cytometry (CyTOF). We show that the three defining features of PTB in macaque lungs are the influx of plasmacytoid DCs (pDCs), an Interferon (IFN)-exhibiting alveolar macrophage population and predominant activated T cell responses. These features contribute to uncontrolled inflammation and disease without mediating Mtb control. In contrast, a CD27+ Natural killer (NK) cell subset accumulated in the lungs of LTBI macaques and in circulation in individuals with LTBI, thus providing novel insights into the protective lung landscape that functions during TB latency. A comprehensive understanding of the lung immune landscape as described here will improve our overall understanding of TB disease immunopathogenesis and provide novel targets for design of new therapies and vaccines for TB control.

Project description:Tuberculosis (TB), caused by infection with Mycobacterium tuberculosis (M. tuberculosis), is a major cause of morbidity and mortality worldwide and efforts to control TB are hampered by difficulties with diagnosis, prevention and treatment. Most people infected with M. tuberculosis remain asymptomatic, termed latent TB, with a 10% lifetime risk of developing active TB disease, but current tests cannot identify which individuals will develop disease. The immune response to M. tuberculosis is complex and incompletely characterized, hindering development of new diagnostics, therapies and vaccines. The goals of this study include: 1. Identify a transcript signature for active TB in intermediate and high burden settings, correlating with radiological extent of disease and reverting to that of healthy controls following treatment; 2. Identify a specific transcript signature that discriminated active TB from other inflammatory and infectious diseases; 3. Classify TB signature using modular and pathway analysis tools.