Highly focused T cell responses in latent human pulmonary Mycobacterium tuberculosis infection.

The elucidation of the molecular and immunological mechanisms mediating maintenance of latency in human tuberculosis aids to develop more effective vaccines and to define biologically meaningful markers for immune protection. We analyzed granuloma-associated lymphocytes (GALs) from human lung biopsies of five patients with latent Mycobacterium tuberculosis (MTB) infection. MTB CD4+ and CD8+ T cell response was highly focused in the lung, distinct from PBL, as assessed by TCR-CDR3 spectratyping coupled with a quantitative analysis of TCR VB frequencies. GALs produced IFN-gamma in response to autologous macrophages infected with MTB and to defined MTB-derived HLA-A2-presented peptides Ag85a242-250, Ag85b199-207, early secreted antigenic target 6 (ESAT-6)28-36, 19-kDa Ag88-97, or the HLA-DR-presented ESAT-6(1-20) epitope. Immune recognition of naturally processed and presented MTB epitopes or the peptide ESAT-6(1-20) could be linked to specific TCR VB families, and in two patients to unique T cell clones that constituted 19 and 27%, respectively, of the CD4+ and 17% of the CD8+ GAL population. In situ examination of MTB-reactive GALs by tetramer in situ staining and confocal laser-scanning microscopy consolidates the presence of MHC class I-restricted CD8+ T cells in MTB granuloma lesions and supports the notion that clonally expanded T cells are crucial in immune surveillance against MTB.

Longitudinal analysis of Mycobacterium tuberculosis 19-kDa antigen-specific T cells in patients with pulmonary tuberculosis: association with disease activity and cross-reactivity to a peptide from HIVenv gp120.

CD8(+) T cells play a central role in immune protection against infection with Mycobacterium tuberculosis. One of the target epitopes for anti-M. tuberculosis directed CD8(+) T cells is the HLA-A2-restricted 19-kDa lipoprotein peptide VLTDGNPPEV. T cell clones directed against this epitope recognized not only the nominal peptide ligand, but also a closely related peptide (VPTDPNPPEV) from the HIV envelope gp120 (HIV(env) gp120) protein characterized by IFN-gamma release. This cross-reactivity was confirmed in ex vivo in M. tuberculosis 19-kDa tetramer-sorted T cells from patients with tuberculosis and in HIVgp120 tetramer-reactive T cells sorted from HIV(+) patients. M. tuberculosis 19-kDa antigen-reactive T cells were present in HLA-A2(+) patients (10/10) with HIV infection with no evidence of M. tuberculosis infection, but they are absent in peripheral blood lymphocytes from healthy HLA-A2(+) individuals (10/10). M. tuberculosis 19-kDa antigen-reactive T cells were elevated in acute pulmonary tuberculosis, declined with response to therapy (7/10 patients) and resided in the terminally differentiated CD8(+) T cell subset. CD8(+) cross-reactive T cells recognizing HIV(env) or M. tuberculosis 19-kDa antigens may contribute to pathogenesis in individuals co-infected with both pathogens and may also present a marker for active tuberculosis.

Immunotherapy of melanoma.

The rationale for immunotherapy of human melanoma is based on the knowledge acquired in the molecular characterization of T cell defined antigens which are recognized in vitro by patients' lymphocytes. Based on this information, active immunotherapy (vaccination) and adoptive immunotherapy trials were conducted in metastatic melanoma patients. This review highlights the most important clinical studies and discuss their limits, in terms of both immune and clinical response considering the formulation of the vaccine (cellular, peptide/protein; DNA, etc.) or the features of immune cells used in adoptive immunotherapy. This new knowledge, along with that of escape mechanisms, should allow to improve significantly the clinical response rate in the immunotherapy of melanoma.