Rational Prioritization Strategy Allows the Design of Macrolide Derivatives That Overcome Antibiotic Resistance

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2021 Nov 9

PMID 34750269

Citations 2

Authors

Gerhard Konig

Pandian Sokkar

Niclas Pryk

Sascha Heinrich

David Moller

Giuseppe Cimicata

Donna Matzov

Pascal Dietze

Walter Thiel

Anat Bashan

Julia Elisabeth Bandow

Johannes Zuegg

Ada Yonath

Frank Schulz

Elsa Sanchez-Garcia

Affiliations

Soon will be listed here.

Abstract

Antibiotic resistance is a major threat to global health; this problem can be addressed by the development of new antibacterial agents to keep pace with the evolutionary adaptation of pathogens. Computational approaches are essential tools to this end since their application enables fast and early strategical decisions in the drug development process. We present a rational design approach, in which acylide antibiotics were screened based on computational predictions of solubility, membrane permeability, and binding affinity toward the ribosome. To assess our design strategy, we tested all candidates for in vitro inhibitory activity and then evaluated them in vivo with several antibiotic-resistant strains to determine minimal inhibitory concentrations. The predicted best candidate is synthetically more accessible, exhibits higher solubility and binding affinity to the ribosome, and is up to 56 times more active against resistant pathogens than telithromycin. Notably, the best compounds designed by us show activity, especially when combined with the membrane-weakening drug colistin, against , , and , which are the three most critical targets from the priority list of pathogens of the World Health Organization.

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