Prospects for a better vaccine against tuberculosis.

There have been many new promising approaches to developing human vaccines against tuberculosis (TB). Advances in gene and antigen identification, availability of genome sequences, a greater understanding of immune mechanisms in resistance to TB, the development of adjuvants and delivery systems to stimulate T-cell immunity, and increased funding from public and private agencies are some of the reasons for progress in this area. Dozens of vaccine candidates have been tested in animal models in recent years, and several of these are poised to move into clinical trials in the next several years. Thus, there is renewed optimism for the potential of developing new and improved TB vaccines.

Tracking antigen-specific CD8 T lymphocytes in the lungs of mice vaccinated with the Mtb72F polyprotein.

This study used a major histocompatibility complex class I tetramer reagent to track antigen-specific CD8 T cells in the lungs of mice immunized with the tuberculosis vaccine candidate Mtb72F. The results show that CD8 T cells recognizing an immunodominant Mtb32-specific epitope could be detected in significant numbers over the course of infection in mice exposed to low-dose aerosol challenge with Mycobacterium tuberculosis and that prior vaccination substantially increased the numbers of these cells early in the lungs. The effector phenotype of the cells was shown by the demonstration that many secreted gamma interferon, but very few contained granzyme B. As the course of the infection progressed, many activated CD8 T cells down-regulated expression of CD45RB and upregulated expression of the interleukin-7 receptor alpha chain, indicating a transition of these cells to a state of memory. These data support the hypothesis that M. tuberculosis-specific CD8 T cells can be targeted by vaccination with the Mtb72F polyprotein.

Chlamydial antigens colocalize within IncA-laden fibers extending from the inclusion membrane into the host cytosol.

Chlamydial IncA localizes to the inclusion membrane and to vesicular fibers extending away from the inclusion. Chlamydial outer membrane components, in the absence of developmental forms, are found within these fibers. This colocalization may explain how chlamydial developmental form antigens are localized outside of the inclusion within infected cells.

Vaccination with plasmid DNA encoding TSA/LmSTI1 leishmanial fusion proteins confers protection against Leishmania major infection in susceptible BALB/c mice.

We have recently shown that a cocktail containing two leishmanial recombinant antigens (LmSTI1 and TSA) and interleukin-12 (IL-12) as an adjuvant induces solid protection in both a murine and a nonhuman primate model of cutaneous leishmaniasis. However, because IL-12 is difficult to prepare, is expensive, and does not have the stability required for a vaccine product, we have investigated the possibility of using DNA as an alternative means of inducing protective immunity. Here, we present evidence that the antigens TSA and LmSTI1 delivered in a plasmid DNA format either as single genes or in a tandem digene construct induce equally solid protection against Leishmania major infection in susceptible BALB/c mice. Immunization of mice with either TSA DNA or LmSTI1 DNA induced specific CD4(+)-T-cell responses of the Th1 phenotype without a requirement for specific adjuvant. CD8 responses, as measured by cytotoxic-T-lymphocyte activity, were generated after immunization with TSA DNA but not LmSTI1 DNA. Interestingly, vaccination of mice with TSA DNA consistently induced protection to a much greater extent than LmSTI1 DNA, thus supporting the notion that CD8 responses might be an important accessory arm of the immune response for acquired resistance against leishmaniasis. Moreover, the protection induced by DNA immunization was specific for infection with Leishmania, i.e., the immunization had no effect on the course of infection of the mice challenged with an unrelated intracellular pathogen such as Mycobacterium tuberculosis. Conversely, immunization of BALB/c mice with a plasmid DNA that is protective against challenge with M. tuberculosis had no effect on the course of infection of these mice with L. major. Together, these results indicate that the protection observed with the leishmanial DNA is mediated by acquired specific immune response rather than by the activation of nonspecific innate immune mechanisms. In addition, a plasmid DNA containing a fusion construct of the two genes was also tested. Similarly to the plasmids encoding individual proteins, the fusion construct induced both specific immune responses to the individual antigens and protection against challenge with L. major. These results confirm previous observations about the possibility of DNA immunization against leishmaniasis and lend support to the idea of using a single polygenic plasmid DNA construct to achieve polyspecific immune responses to several distinct parasite antigens.

In vitro cellular immune responses to complex and newly defined recombinant antigens of Mycobacterium tuberculosis.

The immunological diagnosis and development of new antituberculosis vaccines require the characterization of Mycobacterium tuberculosis antigens inducing cell-mediated immune responses. In this study, we have tested peripheral blood mononuclear cells (PBMC) from tuberculosis (TB) patients (n = 43) and Bacille Calmette-Guérin (BCG)-vaccinated healthy subjects (n = 24) for in vitro cellular immune responses, as indicated by antigen-induced proliferation and interferon (IFN)-gamma secretion, in response to a panel of complex (culture filtrate and cell wall preparations) and single recombinant antigens (Mtb8.4, Mtb9.8, Mtb9.9, Mtb32A, Mtb39A, Mtb40, Mtb41 and Ag85B) of M. tuberculosis. The results of cellular responses showed that the majority (ranging from 70 to 98%) of TB patients and healthy donors responded to the complex antigens in antigen-induced proliferation and IFN-gamma secretion assays. However, when PBMC from the same groups of patients and healthy donors were tested with the recombinant antigens, TB patients showed strong recognition (>50% responders) of Mtb9.8 and Mtb39A in proliferation assays (median SI = 6.2 and 6.4, respectively) and of Mtb9.8, Mtb39A, Mtb40 and Ag85B in IFN-gamma assays (median delta IFN-gamma= 15.5, 10.8, 7.8 and 8.1 U/ml, respectively). BCG-vaccinated healthy donors showed weak (<30% responders) to moderate (31-50% responders) responses to all of the recombinant antigens in both assays. When PBMC of a subset of TB patients (n = 11) were tested for secretion of protective Th1 cytokines [IFN-gamma, tumour necrosis factor (TNF)-alpha and interleukin (IL)-12] and the immunosuppressive cytokine IL-10, the complex CF and CW antigens as well as the recombinant Mtb9.8, Mtb9.9, Mtb40 and Ag85B induced the secretion of both types of cytokines. On the other hand, Mtb41 induced only IL-10, while Mtb8.4, Mtb32Aand Mtb39A induced the secretion of one or more of Th1 cytokines, but not IL-10. In conclusion, the recombinant antigens inducing the secretion of Th1 cytokines could be useful as subunit vaccine candidates against TB.