Environment pollutants exposure affects the endogenous activation of within-host Mycobacterium tuberculosis.

Epidemiological studies have linked ambient pollutants with tuberculosis (TB) risk, but the association has not been fully understood. Here, for the first time, we applied whole-genome sequencing (WGS) to assess the reproductive state of Mycobacterium tuberculosis (MTB) by profiling the mutation rate of MTB (MTBMR) during within-host endogenous reactivated progression, intending to dissect the actual effects of ambient pollutants on the endogenous reactivation. We conducted a retrospective cohort study on bacteriologically confirmed TB patients and followed them for relapse in Jiangsu and Sichuan Province, China. Endogenous and exogenous activation were distinguished by WGS of the pathogen. The average concentration of air pollution was estimated by considering a lag of 0–1 to 0–12 months. We applied a generalized additive model with a Poisson function to evaluate the relationships between ambient pollutants exposure and MTBMR. In the single-pollutant adjusted models, the maximum effect for PM 10 (MTBMR increase: 81.87%, 95% CI: 38.38, 139.03) and PM 2.5 (MTBMR increase: 73.91%, 95% CI: 22.17, 147.55) was observed at a lag of 0–12 months for every 10 μg/m³ increase. For SO 2 , the maximum effect was observed at lag 0–8 months, with MTBMR increasing by 128.06% (95% CI: 45.92, 256.44); and for NO 2 , the maximum effect was observed at lag 0–9 months, with MTBMR increasing by 124.02% (95% CI: 34.5, 273.14). In contrast, the O 3 concentration was inversely associated with MTBMR, and the maximum reduction of MTBMR was 6.18% (95% CI: −9.24, −3.02) at a lag of 0–9 months. Similar results were observed for multi-pollutant models. Increased exposure to ambient pollutants (PM 10 , PM 2.5 , SO 2 , and NO 2) contributed to a faster MTBMR, indicating that MTB exhibits increased reproductive activity, thus accelerating within-host endogenous reactivation. O 3 exposure could decrease the MTBMR, suggesting that MTB exerts low reproductive activity by inhibiting within-host endogenous activation. [Display omitted] [ABSTRACT FROM AUTHOR]