Alkyl Gallates Inhibit Serine -acetyltransferase in Bacteria and Enhance Susceptibility of Drug-resistant Gram-negative Bacteria to Antibiotics

Overview

Journal Front Microbiol

Specialty Microbiology

Date 2023 Nov 15

PMID 37965540

Authors

Touya Toyomoto

Katsuhiko Ono

Tomoo Shiba

Kenta Momitani

Tianli Zhang

Hiroyasu Tsutsuki

Takeshi Ishikawa

Kanae Hoso

Koma Hamada

Azizur Rahman

Liping Wen

Yosuke Maeda

Keiichi Yamamoto

Masao Matsuoka

Kenjiro Hanaoka

Takuro Niidome

Takaaki Akaike

Tomohiro Sawa

Affiliations

Soon will be listed here.

Abstract

A principal concept in developing antibacterial agents with selective toxicity is blocking metabolic pathways that are critical for bacterial growth but that mammalian cells lack. Serine -acetyltransferase (CysE) is an enzyme in many bacteria that catalyzes the first step in l-cysteine biosynthesis by transferring an acetyl group from acetyl coenzyme A (acetyl-CoA) to l-serine to form -acetylserine. Because mammalian cells lack this l-cysteine biosynthesis pathway, developing an inhibitor of CysE has been thought to be a way to establish a new class of antibacterial agents. Here, we demonstrated that alkyl gallates such as octyl gallate (OGA) could act as potent CysE inhibitors and in bacteria. Mass spectrometry analyses indicated that OGA treatment markedly reduced intrabacterial levels of l-cysteine and its metabolites including glutathione and glutathione persulfide in to a level similar to that found in lacking the gene. Consistent with the reduction of those antioxidant molecules in bacteria, became vulnerable to hydrogen peroxide-mediated bacterial killing in the presence of OGA. More important, OGA treatment intensified susceptibilities of metallo-β-lactamase-expressing Gram-negative bacteria ( and ) to carbapenem. Structural analyses showed that alkyl gallate bound to the binding site for acetyl-CoA that limits access of acetyl-CoA to the active site. Our data thus suggest that CysE inhibitors may be used to treat infectious diseases caused by drug-resistant Gram-negative bacteria not only via direct antibacterial activity but also by enhancing therapeutic potentials of existing antibiotics.

Citing Articles

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Identification of Fungal Metabolite Gliotoxin as a Potent Inhibitor Against Bacterial -Acetylserine Sulfhydrylase CysK and CysM.

Rahman A, Ono K, Toyomoto T, Hanaoka K, Sawa T Int J Mol Sci. 2025; 26(3).

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