Regulation of virulence genes in Mycobacterium tuberculosis.

Mycobacterium tuberculosis has demonstrated remarkable ability to survive in diverse conditions encountered during the infection process. These involve surviving the bactericidal stresses within the macrophage, the anaerobic and nutritionally altered environment of the granuloma, and the metabolically inactive latent state. Understanding the molecular basis of this adaptive behavior lies in the identification of genes (or virulence determinants) specifically expressed under these varied conditions. Transcriptional control plays a key role in regulating gene expression in response to environmental signals. However, even after decades of investigation our knowledge about the function of these regulatory mechanisms in mycobacteria remains meagre. But the elucidation of the genome sequence and implementation of sophisticated molecular genetic approaches to this organism have made a revolutionary impact on the study of mycobacterial pathogenesis. Deletion and complementation of individual genes can be done at will facilitating the comparative analysis of mutants and wild-type strains. Novel and powerful technologies such as DNA microarrays, fluorescent beacons and proteomics have made possible the analysis of the expression levels of multiple genes in in vitro systems. More technically challenging uses of these techniques is being undertaken to explore pathogen gene expression within the host. This will lead to the identification of virulence factors and give definitive insight into their regulatory signals.

Antigenic definition of plasma membrane proteins of Bacillus Calmette-Guérin: predominant activation of human T cells by low-molecular-mass integral proteins.

Mycobacterial plasma membrane proteins, in particular the detergent-soluble or 'integral' ones, comprise a class of mostly unexplored antigens capable of inducing potent activation of human T cells. Plasma membrane isolated from culture-grown Bacillus Calmette-Guérin (BCG; Indian vaccine; Danish strain) was subjected to a Triton X-114-based biphasic extraction procedure for isolation of peripheral (water-soluble) and integral proteins (PMP and IMP). A distinction between the two protein pools was evident from results of SDS-PAGE and immunoblotting using antisera raised in rabbits. An enzyme-linked immunosorbant assay with a panel of WHO-IMMYC monoclonal antibodies against various mycobacterial antigens revealed that three well-known antigens, 19 kDa, 33/36 kDa (proline rich) and 38 kDa (PstS homologue), were part of the IMP pool; and another such antigen, 14/16 kDa alpha-crystallin homologue, partly constituted the PMP pool. Apparently, antigenically distinct species of the immunomodulatory moiety lipoarabinomannan partitioned in aqueous and detergent phases. Human T-cell proliferation assays in donors comprising tuberculoid leprosy and pulmonary tuberculosis patients and healthy BCG vaccinees showed significantly greater potency of IMP over PMP and this immunodominance appeared to be directed towards CD4+ cells. IMP of < 56 kDa were resolved by 'continuous elution SDS-PAGE' into 15 fractions which, after extraction of SDS, were used in T-cell proliferation assays for the identification of immunodominant constituents. Proteins falling within three low-molecular-mass zones (all < 35 kDa) performed better than the rest, particularly a approximately 22 kDa fraction, which strongly stimulated T cells from all five donors. Partial overlap between IMP and secreted proteins, as noticed in this study, could provide clues to immunodominance of the latter. The apparent uniqueness and a high T-cell activating potency make mycobacterial IMP attractive candidates for designing future vaccines or immunotherapeutic agents.

Picroliv, the iridoid glycoside fraction of Picrorhiza kurroa, selectively augments human T cell response to mycobacterial protein antigens.

Mycobacterial and other intracellular parasitic diseases are characterised by a deficiency in antigen specific host T cell responses. We have studied the effect of Picroliv, a standardised fraction of root and rhizome of Picrorhiza kurroa, on proliferative T cell response to the mycobacterial 'Purified Protein Derivative (PPD)' antigen in subjects infected with or exposed to mycobacteria (tuberculoid leprosy patients and endemic normals). Coculture of their peripheral blood mononuclear cells with the optimal concentration of Picroliv (0.5 microgram/ml) significantly enhanced the proliferative response to 1/10 optimal PPD dose, as determined by [3H] thymidine incorporation, in the group of 'low' responders. The response to PPD of cells from 'high responders' and to PHA (phytohaëmagglutinin, a non-specific T cell mitogen) remained unaffected by Picroliv which did also not induce cell proliferation on its own. The selective, antigen specific augmentation of human T cell response suggests that Picroliv could be useful as an adjunct to chemotherapy or as a short term prophylactic agent.

Fractionation of mycobacterial integral membrane proteins by continuous elution SDS-PAGE reveals the immunodominance of low molecular weight subunits for human T cells.

Integral membrane proteins (IMP) represent a serologically distinct class of mycobacterial antigens which are potent stimulators of human T cells (Mehrotra et al., Clin Exp Immunol 1995; 102:626). The range of IMP from Mycobacterium fortuitum was resolved by continuous elution SDS-PAGE to recover 31 discrete fractions covering bands up to approximately 58 kD. The fractions, after removal of SDS, were subjected to human T cell proliferation assays for the identification of immunodominant molecule(s). A low molecular weight (<20kD) fraction was able to stimulate T cells from 11 out of 12 donors comprising mainly tuberculoid leprosy patients. The described protocol is well suited to situations where large quantities of antigenic protein mixtures must be processed in order to get the purified molecules/fractions in amounts required for immunoepidemiological studies.

Serological distinction of integral plasma membrane proteins as a class of mycobacterial antigens and their relevance for human T cell activation.

This study pertains to classification and antigenic analysis of mycobacterial plasma membrane proteins in relation to human T cell proliferative responses, using a 'fast grower' Mycobacterium fortuitum as model. Membrane vesicles, prepared by sonication and differential centrifugation, were subjected to biphasic Triton X-114 extraction for isolation of integral peripheral (aqueous phase) proteins. Neither protein pool showed any appreciable overlap serologically. SDS-PAGE showed five prominent bands in peripheral and three in the integral protein pool, whereas immunoblotting with rabbit antisera identified only two major antigens (60 and 67 kD) in the former and five (24, 34, 42, 51 and 54 kD) in the latter. ELISA with a panel of anti-mycobacterial MoAbs revealed that nine out of 12 previously known antigens were present in the peripheral protein pool. Only two of them (33 and 40 kD) were additionally detected amongst integral proteins. The membrane-associated immunosuppressive moiety lipoarabinomannan was semiquantitatively located in aqueous phase. In bulk T cell proliferation assays, seven out of 10 subjects belonging to a 'responder' background (BT-BB leprosy patients and healthy contacts) showed high responses for Myco. fortuitum antigens. Proliferative response with integral proteins was comparable to that with whole membrane, but it was significantly higher (P < 0.0005) than the response with peripheral proteins. The distinction and relevance of integral membrane proteins as a class of mycobacterial antigens make them worthy of consideration in a subunit vaccine design.