Combined Structural Analysis and Molecular Dynamics Reveal Penicillin-Binding Protein Inhibition Mode with β‑Lactones

β-Lactam antibiotics comprise one of the most widely used therapeutic classes to combat bacterial infections. This general scaffold has long been known to inhibit bacterial cell wall biosynthesis by inactivating penicillin-binding proteins (PBPs); however, bacterial resistance to β-lactams is now wi...

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Published inACS chemical biology Vol. 17; no. 11; pp. 3110 - 3120
Main Authors Flanders, Parker L., Contreras-Martel, Carlos, Brown, Nathaniel W., Shirley, Joshua D., Martins, Alexandre, Nauta, Kelsie N., Dessen, Andréa, Carlson, Erin E., Ambrose, Elizabeth A.
Format Journal Article
LanguageEnglish
Published United States American Chemical Society 18.11.2022
Subjects
Anti-Bacterial Agents
Anti-Bacterial Agents - chemistry
Anti-Bacterial Agents - pharmacology
Bacterial Proteins
Bacterial Proteins - metabolism
beta-Lactams
beta-Lactams - metabolism
Biochemistry, Molecular Biology
Lactones
Lactones - pharmacology
Life Sciences
Ligands
Molecular Dynamics Simulation
Penicillin-Binding Proteins
Penicillin-Binding Proteins - metabolism
Pharmaceutical sciences
Pharmacology
Streptococcus pneumoniae
Streptococcus pneumoniae - chemistry
Structural Biology
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Summary:β-Lactam antibiotics comprise one of the most widely used therapeutic classes to combat bacterial infections. This general scaffold has long been known to inhibit bacterial cell wall biosynthesis by inactivating penicillin-binding proteins (PBPs); however, bacterial resistance to β-lactams is now widespread, and new strategies are urgently needed to target PBPs and other proteins involved in bacterial cell wall formation. A key requirement in the identification of strategies to overcome resistance is a deeper understanding of the roles of the PBPs and their associated proteins during cell growth and division, such as can be obtained with the use of selective chemical probes. Probe development has typically depended upon known PBP inhibitors, which have historically been thought to require a negatively charged moiety that mimics the C-terminus of the PBP natural peptidoglycan substrate, d-Ala-d-Ala. However, we have identified a new class of β-lactone-containing molecules that interact with PBPs, often in an isoform-specific manner, and do not incorporate this C-terminal mimetic. Here, we report a series of structural biology experiments and molecular dynamics simulations that we utilized to evaluate specific binding modes of this novel PBP inhibitor class. In this work, we obtained <2 Å resolution X-ray structures of four β-lactone probes bound to PBP1b from Streptococcus pneumoniae. Despite their diverging recognition modes beyond the site of covalent modification, these four probes all efficiently labeled PBP1b, as well as other PBPs from S. pneumoniae. From these structures, we analyzed protein–ligand interactions and characterized the β-lactone-bound active sites using in silico mutagenesis and molecular dynamics. Our approach has clarified the dynamic interaction profile in this series of ligands, expanding the understanding of PBP inhibitor binding.
Bibliography:N.W.B., J.D.S.: These authors contributed equally.
Author Contributions
E.A.A. contributed to the design and completion of this project, especially related to molecular modeling and structural analysis, and assisted with manuscript editing. N.W.B. initiated this project, including design and analysis of bioorthogonal lactone-based probes, and assisted with manuscript editing. E.E.C. contributed to the design and completion of this project, especially related to probe design and use, and assisted with manuscript editing. C.C-M. performed crystal soaking experiments, data collection, solution, and refinement of all crystal structures and prepared all crystallography-related figures. A.D. contributed to the design and completion of this project, especially related to protein crystallography, and assisted with manuscript editing. P.L.F. performed molecular modeling, MD simulations, and analysis and prepared the introductory figure as well as all simulation-related figures. A.M. performed expression, purification, and crystallization of PBP1b*. K.N. obtained gel data for probes 5Az and 6Az. J.D.S. initiated this project, including the design and analysis of bioorthogonal lactone-based probes, and assisted with manuscript editing.
ISSN:1554-8929
1554-8937
DOI:10.1021/acschembio.2c00503