Without close supervision,

many patients with TB are unable to complete a full course of medication, which results in relapse and acquired drug resistance [17]. China has the second highest burden of TB. The challenge we are facing for the control of TB is a dilemma because of the high incidence of MDR-TB and the lack of funding for the treatment with second-line anti-TB drugs. Previous studies demonstrate that DNA vaccine has a pronounced therapeutic action on TB in mice [8, 9]. In addition, immunotherapy with plasmid DNA encoding mycobacterial antigen in association with conventional chemotherapy is a more rapid and effective form of treatment on reactivation and reinfection of M. tb [10, 11]. In the present study, we test whether immunotherapy with DNA vaccine in combination with RFP or PZA result in effective treatment Ku-0059436 in vivo of MDR-TB in infected mice. Mycobacterium tuberculosis Ag85A DNA vaccine is a strong immunotherapeutic agent for MDR-TB [14] and TB [8–11]. Th2 response is abundant during M. tb infection; therefore, the therapeutic effect is associated with not only prompt Th1 response but also switching from an improper status to a protective one. In the current study, significantly Navitoclax in vivo more T cells that secrete IFN-γ are elicited by Ag85A DNA vaccination, and lower

amount of IL-4 are observed in Ag85A DNA vaccine immunized mice, suggesting a predominant Th1 immune response. RFP alone fails to kill the bacteria, but PZA alone is able to kill the bacteria, which suggest that MDR-TB model has been developed successfully. Vaccination with Ag85A DNA vaccine

associated with RFP reduces the pulmonary and splenic bacterial loads by 1.34 and 1.28 logs, respectively, compared with those of the RFP groups, which proves again that Ag85A DNA vaccine is the most efficient immunotherapy for MDR-TB in mice. This is consistent with our previous study [14]. Although Ag85A DNA vaccine associated with PZA treatment reduces the splenic infectious bacterial loads, it fails to reduce the pulmonary infectious bacterial loads when compared with the PZA alone groups. These results suggest that Ag85A DNA selleck inhibitor vaccine fails to strengthen the drug effect of PZA in killing infectious bacteria in lungs, but prevents haematogenous dissemination of M. tb to the spleens. Cai et al. [12] demonstrate that combined DNA vaccine may be a valuable adjunct to shorten the duration of antibacterial chemotherapy. The data of this study indicate that immunotherapy with RFP or PZA results in effective treatment of MDR-TB in infected mice. In conclusion, M. tb Ag85A DNA vaccine has obvious immunotherapeutic effect on TB and MDR-TB in mice. DNA vaccination associated with conventional chemotherapy may have synergistic effect for this treatment. The therapeutic Ag85A DNA vaccine and its combination with anti-TB drugs may be promising and affordable strategies for the treatment of MDR-TB disease in developing countries.