Exploring the potential of Lactocaseibacillus rhamnosus PMC203 in inducing autophagy to reduce the burden of Mycobacterium tuberculosis.

Mycobacterium tuberculosis, a lethal pathogen in human history, causes millions of deaths annually, which demands the development of new concepts of drugs. Considering this fact, earlier research has explored the anti-tuberculosis potential of a probiotic strain, Lactocaseibacillus rhamnosus PMC203, leading to a subsequent focus on the molecular mechanism involved in its effect, particularly on autophagy. In this current study, immunoblotting-based assay exhibited a remarkable expression of autophagy marker LC3-II in the PMC203 treated group compared to an untreated group. A remarkable degradation of p62 was also noticed within treated cells compared to control. Furthermore, the immunofluorescence-based assay showed significant fold change in fluorescence intensity for alexa-647-LC3 and alexa-488-LC3, whereas p62 was degraded noticeably. Moreover, lysosomal biogenesis generation was elevated significantly in terms of LAMP1 and acidic vesicular organelles. As a result, PMC203-induced autophagy played a vital role in reducing M. tuberculosis burden within the macrophages in treated groups compared to untreated group. A colony -forming unit assay also revealed a significant reduction in M. tuberculosis in the treated cells over time. Additionally, the candidate strain significantly upregulated the expression of autophagy induction and lysosomal biogenesis genes. Together, these results could enrich our current knowledge of probiotics-mediated autophagy in tuberculosis and suggest its implications for innovatively managing tuberculosis.

Anti-tuberculosis effect of microbiome therapeutic PMC205 in extensively drug-resistant pulmonary tuberculosis in vivo.

BACKGROUND: Tuberculosis is a highly contagious disease caused by Mycobacterium tuberculosis, and the increase in antibiotic resistance threatens humankind. Therefore, there is an urgent need to develop new anti-tuberculosis drugs that can overcome the limitations of existing drugs. Here, we report the anti-tuberculosis effect of microbiome therapeutic PMC205, a strain of Bacillus subtilis. METHODS: The anti-tuberculosis activity of probiotics was evaluated in mouse models of lethal and latent pulmonary tuberculosis induced by high or low-dose infection of the extensively drug-resistant (XDR) strain. Probiotics were administered by inhalation, and the burden of M. tuberculosis in the lungs, along with mortality and clinical observations, were monitored for 12 weeks and 8 months, respectively. For an in-depth understanding, analysis of the microbiome and inflammatory profile of the lung microenvironment and induction of autophagy in vitro were explored. RESULTS: After inhalation administration of PMC205 for 3 months, the survival rate was 100%, unlike all deaths in the saline-treated group, and the burden of M. tuberculosis in the lungs was reduced by log 1.3 in the 8-month latent tuberculosis model. Moreover, PMC205 induced recovery of disrupted lung microflora, increased butyric acid, and suppressed excessive inflammation. It also promoted autophagy. CONCLUSIONS: These results confirm PMC205's anti-tuberculosis effect, suggesting that it can be developed as an adjuvant to current antibiotic therapy to solve the drug-resistant tuberculosis problem.