Exploiting Vitamin B6 Dependency: BVL3572S Inhibits HisC and AlaA to Kill Mycobacterium tuberculosis

Tuberculosis remains the leading cause of death from a single infectious agent worldwide, and the growing prevalence of multi-drug resistant Mycobacterium tuberculosis ( Mtb ) underscores the urgent need for antibiotics with novel mechanisms of action. Here, we characterize BVL3572S, a hydroxamic acid-containing compound that is bactericidal and potently inhibits the growth of both extracellular and intracellular Mtb . Integrated transcriptomic, genetic, and biochemical analyses identified the pyridoxal phosphate (PLP)-dependent aminotransferases HisC (Rv1600) and AlaA (Rv0337c; formerly AspC) as the primary molecular targets of BVL3572S, thereby simultaneously impacting L-histidine and L-alanine biosynthesis. Spontaneous resistance mutants harbored mutations in hisC or alaA . Target engagement was further supported by overexpression studies: AlaA overexpression increased resistance in the presence of L-His whereas HisC overexpression paradoxically increased susceptibility. X-ray crystallography revealed a covalent adduct between PLP and BVL3572S within the HisC active site. The short occupancy of this adduct suggests a futile cycle that sequesters PLP. Isotopic labeling revealed widespread perturbation of amino acid biosynthesis, consistent with PLP starvation. The stepwise resistance observed upon supplementation with L-His and L-Ala together or with PLP alone suggests inhibition of multiple targets. Genome-scale CRISPRi and Tn-seq analyses additionally indicated disruptions in central metabolism, cell envelope integrity, and redox balance, possibly due to PLP depletion cascades. Consistent with its inhibition of AlaA, BVL3572S displayed strong synergy with D-cycloserine, a second-line antitubercular drug targeting D-alanine synthesis and impacting peptidoglycan synthesis, highlighting the potential of this compound in combination therapy. Collectively, our findings establish BVL3572S as a promising lead compound acting through a previously unexploited, multitarget mechanism that induces broad metabolic stress in Mtb , offering a novel therapeutic strategy against drug-resistant tuberculosis.