Gut-lung axis and microbiome alterations in mycobacterial infections: from pathogenesis to therapeutic potential.

Mycobacterial lung diseases, including tuberculosis (TB) and nontuberculous mycobacterial pulmonary disease (NTM-PD), are increasingly recognized as disorders influenced not only by host immunity but also by microbiota. Emerging evidence identifies the gut-lung axis (GLA) as a key bidirectional communication network linking intestinal and pulmonary homeostasis. Mycobacterial infection itself induces airway and gut dysbiosis through immune and metabolic disturbances, which is further exacerbated by prolonged antibiotic therapy. Dysbiosis within either site reciprocally affects the other via GLA, leading to reduced microbial diversity, impaired epithelial integrity, and systemic inflammation. These alterations disrupt metabolite-mediated immunoregulation and attenuate IL-22-driven epithelial defense, thereby weakening bacterial clearance and promoting chronic inflammation. Distinct microbial features, such as the depletion of beneficial SCFA-producing taxa and enrichment of pro-inflammatory anaerobes, are observed in both TB and NTM-PD. Moreover, therapy-induced microbiome remodeling influences treatment response and disease relapse. Restoring microbial balance through probiotics, prebiotics, postbiotics, dietary modulation, or fecal microbiota transplantation offers a promising adjunctive strategy. This review integrates current evidence linking microbiome dysbiosis to mycobacterial pathogenesis and highlights microbiome-targeted interventions as an emerging therapeutic frontier in pulmonary mycobacterial diseases.