Inactivation of the transcriptional regulator PhoP results in Mycobacterium tuberculosis attenuation. Preclinical testing has shown that attenuated M. tuberculosis phoP mutants hold promise as safe and effective live vaccine candidates. We focused this study to decipher the virulence networks regulated by PhoP. A combined transcriptomic and proteomic analysis revealed that PhoP controls a variety of functions including: hypoxia response through DosR crosstalking, respiratory metabolism, secretion of the major T-cell antigen ESAT-6, stress response, synthesis of pathogenic lipids and the M. tuberculosis persistence through transcriptional regulation of the enzyme isocitrate lyase. We also demonstrate that the M. tuberculosis phoP mutant SO2 exhibits an antigenic capacity similar to that of the BCG vaccine. Finally, we provide evidence that the SO2 mutant persists better in mouse organs than BCG. Altogether, these findings indicate that PhoP orchestrates a variety of functions implicated in M. tuberculosis virulence and persistence, making phoP mutants promising vaccine candidates.
In response to recommendations from the Steering Committees responsible for co-ordination of World Health Organization programmes for research on the immunology of leprosy (IMMLEP) and tuberculosis (IMMTUB), a list was prepared summarizing the properties of mycobacterial proteins currently under investigation with respect to their immunological activities. After consultation with more than 40 laboratories world-wide this list was extended to form the compilation shown below and is intended to provide a comprehensive and convenient reference for future studies in this field.
Protein glycosylation has an important influence on a broad range of molecular interactions in eukaryotes, but is comparatively rare in bacteria. Several antigens from Mycobacterium tuberculosis, the causative agent of human tuberculosis, have been identified as glycoproteins on the basis of lectin binding, or by detailed structural analysis. By production of a set of alkaline phosphatase (PhoA) hybrid proteins in a mycobacterial expression system, the peptide region required for glycosylation of the 19 kDa lipoprotein antigen from M.tuberculosis was defined. Mutagenesis of two threonine clusters within this region abolished lectin binding by PhoA hybrids and by the 19 kDa protein itself. Substitution of the threonine residues also resulted in generation of a series of smaller forms of the protein as a result of proteolysis. In a working model to account for these observations, we propose that the role of glycosylation is to regulate cleavage of a proteolytically sensitive linker region close to the acylated N‐terminus of the protein.
The major goal of the present study was to develop a limiting dilution system for the enumeration of T cells which respond to mycobacterial antigens. Purified T cells from M. tuberculosis-immune mice were restimulated with mycobacterial antigens and accessory cells, and after 4 days expanded with antigen, accessory cells and T cell growth factor. After another 3 days, proliferative responses were determined. Similar cultures performed without antigen served as controls. Limiting dilution analysis revealed that approximately 1/2000 to 1/3000 T cells from M. tuberculosis-immune mice responded to whole M. tuberculosis organisms while T cells from normal mice did not respond. Similar T cell numbers reacted with several mycobacterial strains indicating expression of shared T cell antigens. Using a semi-purified recombinant 64-kDa protein from M. bovis the frequency of T cells generated after immunization with M. tuberculosis which reacted with a single mycobacterial protein could be estimated. We found that approximately 1/5 of the M. tuberculosis-reactive T cells recognized this particular antigen. Immunization with the recombinant 64-kDa protein in an adjuvant containing trehalose dimycolate, monophosphoryl lipid A and mycobacterial cell wall skeleton stimulated an equally high number of M. tuberculosis-reactive T cells (1/2000). These findings demonstrate that a high proportion of tuberculosis-responsive T cells are directed against the 64-kDa protein and that immunization with this antigen in an appropriate adjuvant system is capable of stimulating high numbers of M. tuberculosis-reactive T cells. Limiting dilution analysis with a panel of mycobacterial proteins or peptides may allow their ranking from immunodominant to immunosilent and facilitate identification of antigens or epitopes relevant to protection.
Following uptake by macrophages, live mycobacteria initially reside within an immature phagosome that resists acidification and retains access to recycling endosomes. Glycolipids are exported from the mycobacterial phagosome and become available for immune recognition by CD1-restricted T cells. The aim of this study was to explore the possibility that lipoproteins might similarly escape from the phagosome and act as immune targets in cells infected with live mycobacteria. We have focused on a 19-kDa lipoprotein from Mycobacterium tuberculosis that was previously shown to be recognized by CD8+ T cells. The 19-kDa Ag was found to traffic separately from live mycobacteria within infected macrophages by a pathway that was dependent on acylation of the protein. When expressed as a recombinant protein in rapid-growing mycobacteria, the 19-kDa Ag was able to deliver peptides for recognition by MHC class I-restricted T cells by a TAP-independent mechanism. Entry into the class I pathway was rapid, dependent on acylation, and could be blocked by killing the mycobacteria by heating before infection. Although the pattern of 19-kDa trafficking was similar with different mycobacterial species, preliminary experiments suggest that class I presentation is more efficient during infection with rapid-growing mycobacteria than with the slow-growing bacillus Calmette-Guérin vaccine strain.
Protective immunity against mycobacteria is dependent on antigen-specific Th lymphocytes. It has been assumed that these Th upon recognition of antigen/MHC secrete macrophage-activating factors that enable effector macrophages to eliminate the intracellular organism (1).Recently, however, we have found that mycobacteria are very potent inducers of antigen-specific CD4+ and CD8+ cytotoxic T (Tc) cells as well as antigen-nonspecific killer cells that lyse human monocytes (2). Also, in experimental animal models, evidence has recently accumulated in favor of an important role for Tc cells in the immune response to mycobacteria (reviewed in reference 3). In addition, Mycobacterium bovis Bacillus Calmette-Guerin (BCG)-reactive human CD4+ T cell clones have been reported to lyse PPD-pulsed target (antigen-presenting) cells (4). The identification ofthe cytotoxic effector cells as well as the antigens that they recognize are of obvious importance for the design of mycobacterial subunit vaccines .Here we report that the recombinant 65-kD heat shock protein (HSP) (5) ofM. bovis BCG, which is identical to the 65-kD protein ofM. tuberculosis, shares >95% sequence homology with the M. leprae 65-kD gene (6) and shows extensive crossreactivity with the latter (reference 7) is an immunodominant antigen for CD4+ BCG-specific Tc cells in a significant number (t 20%) of BCG-responsive individuals. In addition, recombinant 65-kD HSP-stimulated effector cells also efficiently lysed autologous monocytes in the absence of antigen. This observation may shed new light on the role of the 65-kD HSP in autoimmunity.
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