A Novel Small-Molecule Inhibitor of the Demethylmenaquinone Methyltransferase MenG Is Bactericidal to Both Growing and Nutritionally Deprived Persister Cells

Overview

Journal mBio

Publisher American Society for Microbiology

Specialty Microbiology

Date 2017 Feb 16

PMID 28196957

Citations 37

Authors

Paridhi Sukheja

Pradeep Kumar

Nisha Mittal

Shao-Gang Li

Eric Singleton

Riccardo Russo

Alexander L Perryman

Riju Shrestha

Divya Awasthi

Seema Husain

Patricia Soteropoulos

Roman Brukh

Nancy Connell

Joel S Freundlich

David Alland

Affiliations

Soon will be listed here.

Abstract

Active tuberculosis (TB) and latent infection both require lengthy treatments to achieve durable cures. This problem has partly been attributable to the existence of nonreplicating "persisters" that are difficult to kill using conventional anti-TB treatments. Compounds that target the respiratory pathway have the potential to kill both replicating and persistent and shorten TB treatment, as this pathway is essential in both metabolic states. We developed a novel respiratory pathway-specific whole-cell screen to identify new respiration inhibitors. This screen identified the biphenyl amide GSK1733953A (DG70) as a likely respiration inhibitor. DG70 inhibited both clinical drug-susceptible and drug-resistant strains. Whole-genome sequencing of DG70-resistant colonies identified mutations in (), which is responsible for the final step in menaquinone biosynthesis and required for respiration. Overexpression of from wild-type and DG70-resistant isolates increased the DG70 MIC by 4× and 8× to 30×, respectively. Radiolabeling and high-resolution mass spectrometry studies confirmed that DG70 inhibited the final step in menaquinone biosynthesis. DG70 also inhibited oxygen utilization and ATP biosynthesis, which was reversed by external menaquinone supplementation. DG70 was bactericidal in actively replicating cultures and in a nutritionally deprived persistence model. DG70 was synergistic with the first-line TB drugs isoniazid, rifampin, and the respiratory inhibitor bedaquiline. The combination of DG70 and isoniazid completely sterilized cultures in the persistence model by day 10. These results suggest that MenG is a good therapeutic target and that compounds targeting MenG along with standard TB therapy have the potential to shorten TB treatment duration. This study shows that MenG, which is responsible for the last enzymatic step in menaquinone biosynthesis, may be a good drug target for improving TB treatments. We describe the first small-molecule inhibitor (DG70) of MenG and show that DG70 has characteristics that are highly desirable for a new antitubercular agent, including bactericidality against both actively growing and nonreplicating mycobacteria and synergy with several first-line drugs that are currently used to treat TB.

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