Actionable mechanisms of drug tolerance and resistance in <i>Mycobacterium tuberculosis</i>

Mycobacterium tuberculosis(Mtb) infection of the lungs, besides producing prolonged cough with mucus, also causes progressive fatigue and cachexia with debilitating loss of muscle mass. While anti-tuberculosis (TB) drug therapy is directed towards eliminating bacilli, the treatment regimen ignores the systemic pathogenic derailments that probably dictate TB-associated mortality and morbidity. Presently, it is not understood whether the spread of infection to other metabolic organs brings about these impairments. Here, we show that Mtb, during the chronic phase utilizes hepatocytes as a replicative niche and shields itself against the common anti-TB drugs by inducing drug-metabolizing enzymes. Mtb creates a replication-conducive milieu of lipid droplets in hepatocytes by upregulating transcription factor PPARγ. In the classical murine-TB aerosol infection model hepatocyte infection can be consistently observed post-week 4 along with enhanced expression of PPARγ and drug-metabolizing enzymes. Histopathological analysis and fluorescence in situ hybridization with Mtb-specific primers of human autopsy liver specimens, indeed show the presence of Mtb in hepatocytes along with granuloma-like structures. Hepatotropism of Mtb during the chronic infectious cycle results in immuno-metabolic dysregulation that could magnify local and systemic pathogenicity, altering clinical presentations

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A clinical mutation inuvrA, a DNA repair gene, confers survival advantage toMycobacterium tuberculosisin the host

Naz,

Datta,

Khan

et al. 2024

Preprint

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DNA repair pathways play an essential role in maintaining the genomic integrity of bacteria, and a perturbation in their biological activity helps bacteria survive under duress. In drug-resistant clinical strains, we identified a Q135K mutation in the uvrA gene, a DNA repair pathway gene. To delineate the role of uvrA and the Q135K mutation, we generated the gene replacement mutant of UvrA (RvΔuvrA) in Mycobacterium tuberculosis H37Rv (Mtb-Rv). While the lack of UvrA function in RvΔuvrA could be restored upon complementation with uvrA, the uvrA-Q135K mutant identified in clinical drug-resistant strains failed to do so. This was reflected in higher mutation rates in RvΔuvrA and RvΔuvrA::uvrAQ135A, compared with wild-type Rv or RvΔuvrA::uvrA complemented strains in the presence and absence of oxidative stress. Killing kinetics experiments with anti-TB drugs showed increased survival of RvΔuvrA and RvΔuvrA::uvrAQ135K, strains compared with Rv or RvΔuvrA::uvrA. Importantly, RvΔuvrA and RvΔuvrA::uvrAQ135K showed enhanced survival in peritoneal macrophages and murine infection model of infection. Together, data suggests that acquiring Q135K mutation benefits the pathogen, which helps enhance the host's survival adaptability.

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Actionable mechanisms of drug tolerance and resistance in Mycobacterium tuberculosis

Cited by 4 publications

References 145 publications

Key challenges in TB drug discovery: A perspective

Key challenges in TB drug discovery: A perspective

PPARγ mediated enhanced lipid biogenesis fuelsMycobacterium tuberculosisgrowth in a drug-tolerant hepatocyte environment

A clinical mutation inuvrA, a DNA repair gene, confers survival advantage toMycobacterium tuberculosisin the host

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