Mycobacterial infectious diseases, including tuberculosis (TB), severely threaten global public health. Nonreplicating Mycobacterium tuberculosis (Mtb) is extremely difficult to eradicate using current TB drugs that primarily act on replicating cells.… Click to show full abstract
Mycobacterial infectious diseases, including tuberculosis (TB), severely threaten global public health. Nonreplicating Mycobacterium tuberculosis (Mtb) is extremely difficult to eradicate using current TB drugs that primarily act on replicating cells. Novel TB drugs acting on unconventional targets are needed to combat TB efficiently. Although membrane-disrupting antimicrobial peptides and their synthetic mimics exhibit the potential to kill persisters, the lack of microbe selectivity, especially toward mycobacteria, has been a concern. Here, we report that the recently developed poly(guanylurea)-piperazine (PGU-P) shows fast and selective mycobactericidal effects. Using a nonpathogenic model organism, Mycobacterium smegmatis (Msm), we have found that the mycobactericidal effects of PGU-P are correlated to the disruption of the mycobacterial membrane potential and bioenergetics. Accordingly, PGU-P also potentiates bedaquiline, an oxidative phosphorylation-targeting TB drug disturbing mycobacterial bioenergetics. Importantly, PGU-P also exhibits a promising activity against pathogenic Mtb with a minimum inhibitory concentration of 37 μg/mL. Our results support that PGU-P is a novel class of antimycobacterial biomaterial, and the unique structural feature can contribute to developing novel antimycobacterial drugs.
               
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