Discovery and Characterization of the Antimetabolite Action of Thioacetamide-Linked 1,2,3-Triazoles As Disruptors of Cysteine Biosynthesis in Gram-Negative Bacteria

Overview

Journal ACS Infect Dis

Specialties Infectious Diseases
Microbiology
Pharmacology

Date 2019 Dec 31

PMID 31887254

Citations 9

Authors

Miranda J Wallace

Suresh Dharuman

Dinesh M Fernando

Stephanie M Reeve

Clifford T Gee

Jiangwei Yao

Elizabeth C Griffith

Gregory A Phelps

William C Wright

John M Elmore

Robin B Lee

Taosheng Chen

Richard E Lee

Affiliations

Soon will be listed here.

Abstract

Increasing rates of drug-resistant Gram-negative (GN) infections, combined with a lack of new GN-effective antibiotic classes, are driving the need for the discovery of new agents. Bacterial metabolism represents an underutilized mechanism of action in current antimicrobial therapies. Therefore, we sought to identify novel antimetabolites that disrupt key metabolic pathways and explore the specific impacts of these agents on bacterial metabolism. This study describes the successful application of this approach to discover a new series of chemical probes, -(phenyl)thioacetamide-linked 1,2,3-triazoles (TAT), that target cysteine synthase A (CysK), an enzyme unique to bacteria that is positioned at a key juncture between several fundamental pathways. The TAT class was identified using a high-throughput screen against designed to identify modulators of pathways related to folate biosynthesis. TAT analog synthesis demonstrated a clear structure-activity relationship, and activity was confirmed against GN antifolate-resistant clinical isolates. Spontaneous TAT resistance mutations were tracked to CysK, and mode of action studies led to the identification of a false product formation mechanism between the CysK substrate -acetyl-l-serine and the TATs. Global transcriptional responses to TAT treatment revealed that these antimetabolites impose substantial disruption of key metabolic networks beyond cysteine biosynthesis. This study highlights the potential of antimetabolite drug discovery as a promising approach to the discovery of novel GN antibiotics and the pharmacological promise of TAT CysK probes.

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