Indoleamine-2,3-dioxygenase inhibition improves immunity and is safe for concurrent use with cART during Mtb/SIV coinfection
Bindu Singh, … , Deepak Kaushal, Smriti Mehra
Bindu Singh, … , Deepak Kaushal, Smriti Mehra
Published August 8, 2024
Citation Information: JCI Insight. 2024;9(15):e179317. https://doi.org/10.1172/jci.insight.179317.
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Research Article Immunology Infectious disease

Indoleamine-2,3-dioxygenase inhibition improves immunity and is safe for concurrent use with cART during Mtb/SIV coinfection

Abstract

Chronic immune activation promotes tuberculosis (TB) reactivation in the macaque Mycobacterium tuberculosis (M. tuberculosis)/SIV coinfection model. Initiating combinatorial antiretroviral therapy (cART) early lowers the risk of TB reactivation, but immune activation persists. Studies of host-directed therapeutics (HDTs) that mitigate immune activation are, therefore, required. Indoleamine 2,3, dioxygenase (IDO), a potent immunosuppressor, is one of the most abundantly induced proteins in NHP and human TB granulomas. Inhibition of IDO improves immune responses in the lung, leading to better control of TB, including adjunctive to TB chemotherapy. The IDO inhibitor D-1 methyl tryptophan (D1MT) is, therefore, a bona fide TB HDT candidate. Since HDTs against TB are likely to be deployed in an HIV coinfection setting, we studied the effect of IDO inhibition in M. tuberculosis/SIV coinfection, adjunctive to cART. D1MT is safe in this setting, does not interfere with viral suppression, and improves the quality of CD4+ and CD8+ T cell responses, including reconstitution, activation and M. tuberculosis–specific cytokine production, and access of CD8+ T cells to the lung granulomas; it reduces granuloma size and necrosis, type I IFN expression, and the recruitment of inflammatory IDO+ interstitial macrophages (IMs). Thus, trials evaluating the potential of IDO inhibition as HDT in the setting of cART in M. tuberculosis/HIV coinfected individuals are warranted.

Authors

Bindu Singh, Riti Sharan, Gayathri Ravichandran, Ruby Escobedo, Vinay Shivanna, Edward J. Dick Jr., Shannan Hall-Ursone, Garima Arora, Xavier Alvarez, Dhiraj K. Singh, Deepak Kaushal, Smriti Mehra

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Figure 3

Bacterial burdens in D1MT+cART-treated RMs relative to other groups of coinfected RMs.

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Bacterial burdens in D1MT+cART-treated RMs relative to other groups of c...
M. tuberculosis burdens were assessed in BAL collected biweekly and tissues at endpoint. (A) Graph shows Log M. tuberculosis CFU/mL of BAL in the 3 study groups at different time points over the course ranging from preinfection to the end of treatment. Burgundy dotted line marks SIV infection, gray area represents the treatment phase, and black dotted line represents the end of D1MT treatment. (B and C) Graphical representations of Log10 CFU/gram of lung (B) and Log10 CFU/gram of granulomas (C) obtained from the lungs. (DF) Individual lung lobes obtained from each RM were assessed for sterility using Fischer’s sterility test to determine the sterile and nonsterile lung lobes between D1MT+cART and untreated (D), cART and untreated (E), and D1MT+cART and cART (F). (GJ) Log CFU/gram of spleen (G), liver (H), kidney (I), and BrLN (J) obtained at necropsy. P values are indicated above the plots as obtained from 2-way ANOVA (A); 1-way ANOVA (B, C, and H–J); contingency χ2 (and Fisher’s exact) test (DF). Data are represented as mean ± SEM.