Abstract
Mycobacterium tuberculosis and pathogenic nontuberculous mycobacteria pose a growing challenge to human health, and new antibiotics that target new pathways with novel mechanisms of action are urgently needed. Acylaminooxadiazole derivatives have previously been shown to inhibit the trans-translation ribosome rescue pathway and kill M. tuberculosis. Here, we show that modifications to the acylaminooxadiazole scaffold can improve potency and tune mycobacterial species specificity, resulting in molecules that kill M. avium, M. abscessus, and M. tuberculosis clinical isolates. Free iron was previously shown to antagonize antibacterial activity and decrease the inhibition of trans-translation by acylaminooxadiazoles, but we found that biologically relevant iron sources such as hemin and transferrin do not affect activity. Mutants depleted for tmRNA and mutants defective in siderophore-mediated iron utilization are both hypersusceptible to acylaminooxadiazole-based trans-translation inhibitors, indicating a dual mechanism of action involving both direct inhibition of trans-translation and metal starvation. These findings establish acylaminooxadiazoles as dual-mechanism antimycobacterial agents that couple inhibition of trans-translation with disruption of iron homeostasis.