Xiang‐Yang Ye scite author profile

Ramoplanin is a lipglycodepsipeptide antibiotic that inhibits peptidoglycan biosynthesis. Its mechanism of action has been the subject of debate. It was originally proposed to inhibit the MurG step of peptidoglycan synthesis by binding Lipid I. In this paper, we report that ramoplanin inhibits bacterial transglycosylases by binding to Lipid II, the substrate for these enzymes. The inhibition curves reveal that the inhibitory species has a stoichiometry of 2:1 ramoplanin:Lipid II. A Job titration confirms that ramoplanin binds as a dimer to Lipid II. The apparent dissociation constant is in the nanomolar range, which is unusually low given the nature of the interacting species. We show that Lipid II binding is coupled to the formation of a higher order species, which may explain the tight binding. We also present a testable model for the binding-competent dimeric conformation of ramoplanin.

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Oxidative stress: The core pathogenesis and mechanism of Alzheimer’s disease

Bai

Guo

et al. 2022

Ageing Research Reviews

300

102

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Intrinsic Lipid Preferences and Kinetic Mechanism of Escherichia coli MurG

Chen

Men

et al. 2002

Biochemistry

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MurG, the last enzyme involved in the intracellular phase of peptidoglycan synthesis, is a membrane-associated glycosyltransferase that couples N-acetyl glucosamine to the C4 hydroxyl of a lipid-linked N-acetyl muramic acid derivative (lipid I) to form the beta-linked disaccharide (lipid II) that is the minimal subunit of peptidoglycan. Lipid I is anchored to the bacterial membrane by a 55 carbon undecaprenyl chain. Because this long lipid chain impedes kinetic analysis of MurG, we have been investigating alternative substrates containing shortened lipid chains. We now describe the intrinsic lipid preferences of MurG and show that the optimal substrate for MurG in the absence of membranes is not the natural substrate. Thus, while the undecaprenyl carrier lipid may be critical for certain steps in the biosynthetic pathway to peptidoglycan, it is not required-in fact, is not preferred-by MurG. Using synthetic substrate analogues and products containing different length lipid chains, as well as a synthetic dead-end acceptor analogue, we have also shown that MurG follows a compulsory ordered Bi Bi mechanism in which the donor sugar binds first. This information should facilitate obtaining crystals of MurG with substrates bound, an important goal because MurG belongs to a major superfamily of NDP-glycosyltransferases for which no structures containing intact substrates have yet been solved.

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Selective Tyk2 inhibitors as potential therapeutic agents: a patent review (2015–2018)

Chen

Zhang³

et al. 2019

Expert Opinion on Therapeutic Patents

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Xiang‐Yang Ye

Better Substrates for Bacterial Transglycosylases

Ramoplanin Inhibits Bacterial Transglycosylases by Binding as a Dimer to Lipid II

Oxidative stress: The core pathogenesis and mechanism of Alzheimer’s disease

Intrinsic Lipid Preferences and Kinetic Mechanism of Escherichia coli MurG

Selective Tyk2 inhibitors as potential therapeutic agents: a patent review (2015–2018)

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