Predominant recognition of species-specific determinants of the GroES homologues from Mycobacterium leprae and M. tuberculosis.

The Mycobacterium leprae and M. tuberculosis 10,000 MW heat-shock protein homologues of GroES have previously been identified as major immunogens for human T cells. We used synthetic peptides to characterize the determinants recognized by murine T cells. The findings suggest that, despite 90% sequence identity between these two proteins, T cells recognize prominently the species-specific determinants localized within amino acid residues 21-40 and 49-72. Analysis of the molecular determinants of species-specificity for the M. leprae GroES sequence 25-40, using T-cell hybridomas and major histocompatibility complex (MHC)-binding assays, led to the identification of epitope cores and critical residues. Interestingly, closely overlapping epitope cores were found to be restricted by either H-2Ad (24-34) or H-2Ed (28-34). Furthermore, the site recognized by the M. leprae-specific monoclonal antibodies ML06 and ML10 was also localized in the overlapping sequences 25-31 and 25-29. In conclusion, we demonstrated that immunodominant species-specific T- and B-cell epitopes can be found in a mycobacterial heat-shock protein despite its highly conserved amino acid sequence. This finding suggests the feasibility of identifying a sufficient number of M. leprae-specific determinants for a composite T-cell immunodiagnostic reagent for tuberculoid leprosy.

Identification of a Mycobacterium leprae-specific T cell epitope on the 70 kDa heat shock protein.

A major antigen of the leprosy bacillus, Mycobacterium leprae, is the 70 kDa heat shock protein (Hsp70), which has significant sequence homology with Hsp70 from other mycobacterial species as well as Hsp70 from eukaryotes. A unique region of 70 amino acids at the C-terminus of the M. leprae Hsp70 has been previously identified. This study investigated whether mice immunized with the C-terminal fragment of M. leprae Hsp70 recognize T cell epitopes in this species-specific portion of the molecule. Murine lymphoproliferative responses to overlapping peptides spanning the C-terminal 70 amino acids were restricted to mice of an H-2b haplotype and identified the presence of a determinant in sequence 567-591. Lymph node cells from mice immunized with this peptide recognized both the C-terminal fragment and the whole Hsp70 molecule. Moreover, mice immunized with the same peptide responded to the whole Hsp70 molecule in a delayed-type hypersensitivity reaction. The significance of M. leprae-specific T cell epitopes in the host response to mycobacterial infection is discussed.

Correlation between CD8 dependency and determinant density using peptide-induced, Ld-restricted cytotoxic T lymphocytes.

We have taken advantage of some unique properties of H-2Ld to investigate the determinant density requirements for cytotoxic T lymphocyte (CTL) priming versus effector function and to correlate the determinant density requirements with CD8 dependency. In a previous study (Lie, W.-R., N. B. Myers, J. Gorka, R. J. Rubocki, J. M. Connolly, and T. H. Hansen. 1990. Nature [Lond.]. 344:439), we demonstrated that culturing normal cells with peptides known to be restricted by H-2Ld led to a two- to fourfold increase in surface Ld expression. In the present study, we demonstrate the generation of Ld-restricted, peptide-specific in vitro primary CTL by culturing spleen cells with murine cytomegalovirus or tum- peptide at concentrations previously shown to result in maximum induction of Ld expression. Target cells can be sensitized for recognition by these CTL with lower dose of peptide than are required for the primary sensitization. This demonstrates differences in the determinant density requirements for priming versus effector function. The in vitro primary CTL generated with peptide can weakly lyse target cells that express the determinant endogenously, and CTL lines and clones capable of strong lysis of endogenous expressors are easily obtained. In both cases, target cells treated with exogenous peptide are lysed better than target cells expressing antigen endogenously. This suggested that there are differences in the determinant density of peptide-fed versus endogenous targets. This interpretation was substantiated when it was observed that the level of lysis of target cells expressing endogenous determinants correlated inversely with the amount of peptide required to sensitize targets for recognition by various tum- -specific CTL clones. Furthermore, simultaneous titration of both the peptide used to treat target cells and the antibody to CD8 revealed that the various CTL clones analyzed displayed widely disparate CD8 dependencies. In each case, the CD8 dependency correlated inversely with the determinant density requirement. Therefore, CD8 dependency of CTL is relative, but shows an absolute and quantitative correlation with their dependency on determinant density. These findings suggest that under physiologic conditions, where only low determinant densities are likely to be encountered, all CTL clones will show at least partial CD8 dependency.

Mycobacterium leprae-specific Lyt-2+ T lymphocytes with cytolytic activity.

Mice were immunized intradermally with 10(7) irradiated Mycobacterium leprae organisms, and draining lymph nodes were collected after 4 weeks. Lymph node cells were restimulated in vitro with soluble M. leprae antigen and accessory cells. The resulting T-cell line was propagated in vitro in the presence of M. leprae antigen, accessory cells, and interleukin-2-containing supernatants from concanavalin A-stimulated rat spleen cells. Long-term cultured T cells were Thy-1+ L3T4- Lyt-2+ as revealed by analysis with the fluorescence-activated cell sorter. From this line, T-cell clones with the same phenotype were established. The T-cell clone A4 failed to secret interleukin-2 after stimulation with antigen and accessory cells, and its growth depended on exogeneous interleukin-2. A4 T cells produced gamma interferon in an antigen-specific, H-2-restricted, and interleukin-2-dependent way. Importantly, this T-cell clone was capable of lysing bone marrow macrophages presenting M. leprae antigen. Other T-cell clones as well as native Lyt-2+ T cells from M. leprae-immunized mice were also capable of lysing bone marrow macrophages expressing M. leprae antigens. These findings suggest that specific Lyt-2+ T cells participate in the immune response to M. leprae. It is postulated that cytolysis of M. leprae-infected macrophages or Schwann cells contributes to protection against and pathogenesis of leprosy.

Immunity to leprosy. II. Genetic control of murine T cell proliferative responses to Mycobacterium leprae.

T cell proliferative responses to Mycobacterium leprae were measured after immunization of mice at the base of the tail with antigen and challenging lymphocytes from draining lymph nodes in culture with M. leprae. This T cell response to M. leprae has been compared in 18 inbred strains of mice. C57BL/10J mice were identified as low responder mice. The congenic strains B10.M and B10.Q were found to be high responders, whereas B10.BR and B10.P were low responders. F1 (B10.M X C57BL/10J) and F1 (B10.Q X C57BL/10J) hybrid mice were found to be low responders, similar to the C57BL/10J parent, indicating that the low responsive trait is dominant. Whereas B10.BR mice were shown to be low responders to M. leprae, B10.AKM and B10.A(2R) were clearly high responders, indicating that the H-2D region influences the magnitude of the T cell proliferative response. Gene complementation within the H-2 region was evident. Genes outside the H-2 region were also shown to influence the response to M. leprae. C3H/HeN were shown to be high responder mice, whereas other H-2k strains, BALB.K, CBA/N, and B10.BR, were low responders. Gene loci that influence the T cell proliferation assay have been discussed and were compared to known background genes which may be important for the growth of intracellular parasites. Because mycobacteria are intracellular parasites for antigen-presenting cells, genes that affect bacterial growth in these cells will also influence subsequent immune responses of the host.