Anti-retroviral therapy does not reduce tuberculosis reactivation in a tuberculosis-HIV co-infection model.

While the advent of combination antiretroviral therapy (ART) has significantly improved survival, tuberculosis (TB) remains the leading cause of death in the HIV-infected population. We employed Mtb/Simian Immunodeficiency Virus (SIV) co-infected macaques to model Mtb/HIV co-infection and study the impact of ART on TB reactivation due to HIV-infection. While ART significantly reduced viral loads and increased CD4+ T cell counts in whole blood and BAL samples, it did not reduce the relative risk of SIV- induced TB reactivation in ART treated macaques in the early phase of treatment. CD4+ T cells were poorly restored specifically in the lung interstitium, despite their significant restoration in the alveolar compartment of the lung as well as in the periphery. IDO1 induction on myeloid cells in the iBALT likely contributed to dysregulated T cell homing and impaired lung immunity. Thus, while ART is indispensable in controlling viral replication, CD4+ T cells restoration and preventing opportunistic infection, it appears inadequate in reversing clinical signs of TB reactivation during the relatively short duration of ART and follow-up during this study. This warrants modeling concurrent treatment of TB and HIV to potentially reduce the risk of reactivation of TB due to HIV. The current and future studies like this have the potential to inform treatment strategies in patients with Mtb/HIV co-infection.

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