Improved Immunogenicity and Protective Efficacy of a Tuberculosis DNA Vaccine Encoding Ag85 by Protein Boosting

Tanghe, Audrey; D’Souza, Sushila; Rosseels, Valérie; Denis, Olivier; Ottenhoff, T.H.M.; Dalemans, Wilfried; Wheeler, Carl J.; Huygen, Kris

doi:10.1128/iai.69.5.3041-3047.2001

Cited by 214 publications

(201 citation statements)

References 39 publications

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“…Therefore, various approaches were tested that sought to take advantage of combining the ability of DNA to prime Ab responses with the ability of recombinant proteins to boost them. DNA-protein primeboost regimens have been studied extensively in HIV (58), providing partial protection from simian-human immunodeficiency virus challenge (59) and also have been studied in anthrax (60), tuberculosis (61), and in transmission-blocking vaccines for both vivax and falciparium malaria (62).…”

Section: Mixed Modality Vaccinesmentioning

confidence: 99%

DNA Vaccines: Progress and Challenges

Donnelly

Wahrén²,

Liu³

2005

The Journal of Immunology

402

242

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In the years following the publication of the initial in vivo demonstration of the ability of plasmid DNA to generate protective immune responses, DNA vaccines have entered into a variety of human clinical trials for vaccines against various infectious diseases and for therapies against cancer, and are in development for therapies against autoimmune diseases and allergy. They also have become a widely used laboratory tool for a variety of applications ranging from proteomics to understanding Ag presentation and cross-priming. Despite their rapid and widespread development and the commonplace usage of the term “DNA vaccines,” however, the disappointing potency of the DNA vaccines in humans underscores the challenges encountered in the efforts to translate efficacy in preclinical models into clinical realities. This review will provide a brief background of DNA vaccines including the insights gained about the varied immunological mechanisms that play a role in their ability to generate immune responses.

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Section: Mixed Modality Vaccinesmentioning

confidence: 99%

DNA Vaccines: Progress and Challenges

Donnelly

Wahrén²,

Liu³

2005

The Journal of Immunology

402

242

View full text Add to dashboard Cite

show abstract

“…Prophylactic DNA vaccines expressing M. tuberculosis antigens or cytokines are of particular interest, because of their efficiency and long-lasting effect in animal TB models. For example, prophylactic DNA vaccines expressing various M. tuberculosis antigens, including Ag85A, [15][16][17] Ag85B, 17,18 65 kDa heat shock protein, 19,20 and PstS-3 21 , were found to be effective at limiting the growth of M. tuberculosis in mice. In contrast, there has been little evidence that DNA vaccines are useful as therapeutic vaccines against TB.…”

Section: Introductionmentioning

confidence: 99%

Therapeutic effect of DNA vaccines combined with chemotherapy in a latent infection model after aerosol infection of mice with Mycobacterium tuberculosis

Jeon

Kim

et al. 2003

Gene Ther

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“…In prophylactic settings, there are several reports that DNA vaccines expressing M. tuberculosis antigens are effective for limiting the bacterial growth in mice. [10][11][12][13] However, it is still controversial whether DNA vaccines work against TB reactivation in postexposure models. [14][15][16] For example, the vaccination of plasmid DNA expressing hsp65 after completion of chemotherapy was shown to be effective in preventing the reactivation of intravenously infected M. tuberculosis.…”

mentioning

confidence: 99%

“…Firstly, it has been reported that the Ag85A epitopes are frequently expressed on the surface of the infected macrophages during early phase, but downregulated at the late phase, while PstS-3-specific epitopes are more abundantly expressed during late phase. 13 Thus, DNA immunization with combination of these two genes might induce both Ag85A-and PstS-3-specific immune responses required for suppressing bacterial growth during both early and late phases. Secondly, it has also been known that CD4 + T cells play an important role in the protection for the acute Figure 2 Preventive effect of DNA vaccines given during chemotherapy on reinfection of M. tuberculosis.…”

mentioning

confidence: 99%

Protective effect of DNA vaccine during chemotherapy on reactivation and reinfection of Mycobacterium tuberculosis

Jeon

Youn

et al. 2005

Gene Ther

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Active disease of tuberculosis (TB) can be developed decades later by either a relapse of the initial infection (endogenous reactivation) or by an entrance of the secondary infection (exogenous reinfection), since the current chemotherapy cannot lead to complete elimination of tuberculosis. Although the immunotherapeutic approaches in conjunction with conventional chemotherapy were tried to prevent TB growth via boosting the immune system, their therapeutic effects are still controversial. Here, we found that TB DNA vaccination completely blocked tuberculosis reactivation and significantly prevented from the secondary infection when chemotherapy was combined simultaneously.In particular, double-gene DNA vaccine composed of Ag85A and PstS-3 genes could reduce bacteria growth better than single-gene DNA vaccine after a secondary reinfection, indicating a correlation between the breadth of Th1 IFN-g response and the efficacy of the protection from reinfection. Thus, we propose that multigene TB DNA immunotherapy including Ag85A and PstS-3 genes during the period of chemotherapy could benefit patients undergoing TB chemotherapy in prevention from exogenous reinfection as well as endogenous reactivation. Gene Therapy (2005) Tuberculosis (TB) holds the dubious honor of being the leading single-agent infectious disease killer in the world 1,2 and the situation is worsened by the increasing incidence of both multidrug resistant (MDR) stains and combination with AIDS. 1,3 After Mycobacterium tuberculosis infection, active disease arises in about 5% of exposed individuals and most of the others will develop a latent infection in which the tubercle bacilli can persist in vivo without causing any clinical symptoms. However, active disease may also develop decades later either as a relapse of the initial infection or because of a secondary infection. Although most cases of tuberculosis were once believed to result from a endogenous reactivation acquired in the past, 4 recent studies indicate that onethird of tuberculosis cases are due to recent transmission by exogenous reinfection of multiple M. tuberculosis strains, [5][6][7][8][9] implicating that the exogenous reinfection significantly contributes to disease transmission. Therefore, novel immunotherapeutic approaches will be required to prevent reinfection as well as reactivation of M. tuberculosis in individuals with latent tuberculosis.DNA vaccination has become a promising strategy for developing an effective vaccine against TB, since it efficiently induces Th1 immunity, an essential arm of immune system to clear the bacteria. In prophylactic settings, there are several reports that DNA vaccines expressing M. tuberculosis antigens are effective for limiting the bacterial growth in mice. 10-13 However, it is still controversial whether DNA vaccines work against TB reactivation in postexposure models. 14-16 For example, the vaccination of plasmid DNA expressing hsp65 after completion of chemotherapy was shown to be effective in preventing the reactivation of intravenou...

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Improved Immunogenicity and Protective Efficacy of a Tuberculosis DNA Vaccine Encoding Ag85 by Protein Boosting

Cited by 214 publications

References 39 publications

DNA Vaccines: Progress and Challenges

DNA Vaccines: Progress and Challenges

Therapeutic effect of DNA vaccines combined with chemotherapy in a latent infection model after aerosol infection of mice with Mycobacterium tuberculosis

Protective effect of DNA vaccine during chemotherapy on reactivation and reinfection of Mycobacterium tuberculosis

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