Non-β-Lactam Allosteric Inhibitors Target Methicillin-Resistant Staphylococcus aureus: An In Silico Drug Discovery Study.

Mahmoud A A Ibrahim,Mohamed A M Atia,Mahmoud E S Soliman,Esraa Khalaf,Othman R Alzahrani,Khlood A A Abdeljawaad,Fahad M Alshabrmi,Mohamed-Elamir F Hegazy,Paul W Paré,Faris Alrumaihi,Mahmoud F Moustafa,Alaa H M Abdelrahman,Khaled S Allemailem

doi:10.3390/antibiotics10080934

Abstract

Penicillin-binding proteins (PBPs) catalyze the final stages for peptidoglycan cell-wall bio-synthesis. Mutations in the PBP2a subunit can attenuate β-lactam antibiotic activity, resulting in unimpeded cell-wall formation and methicillin-resistant Staphylococcus aureus (MRSA). A double mutation in PBP2a (i.e., N146K and E150K) is resistant to β-lactam inhibitors; however, (E)-3-(2-(4-cyanostyryl)-4-oxoquinazolin-3(4H)-yl) benzoic acid (QNZ), a heterocyclic antibiotic devoid of a β-lactam ring, interacts non-covalently with PBP2a allosteric site and inhibits PBP enzymatic activity. In the search for novel inhibitors that target this PBP2a allosteric site in acidic medium, an in silico screening was performed. Chemical databases including eMolecules, ChEMBL, and ChEBI were virtually screened for candidate inhibitors with a physicochemical similarity to QNZ. PBP2a binding affinities from the screening were calculated based on molecular docking with co-crystallized ligand QNZ serving as a reference. Molecular minimization calculations were performed for inhibitors with docking scores lower than QNZ (calc. −8.3 kcal/mol) followed by combined MD simulations and MM-GBSA binding energy calculations. Compounds eMol26313223 and eMol26314565 exhibited promising inhibitor activities based on binding affinities (ΔGbinding) that were twice that of QNZ (−38.5, −34.5, and −15.4 kcal/mol, respectively). Structural and energetic analyses over a 50 ns MD simulation revealed high stability for the inhibitors when complexed with the double mutated PBP2a. The pharmacokinetic properties of the two inhibitors were predicted using an in silico ADMET analysis. Calculated binding affinities hold promise for eMol26313223 and eMol26314565 as allosteric inhibitors of PBP2a in acidic medium and establish that further in vitro and in vivo inhibition experimentation is warranted.

Highlights

With multidrug-resistant bacteria on the rise and bacterial infections imposing a major threat to public health, there is an imminent need for the development of new antibiotics [1,2]
QNZ was found to be more potent than CFT towards the mutated penicillin-binding protein 2a (PBP2a)
The greatest potency of QNZ against PBP2a could be imputed to its capability of a carboxylic group of QNZ to form two hydrogen bonds with Antibiotics 2021, 10, x FOR PEER REthVeIEWbackbone carbonyl group and ammonium group (NH3+) of ASP295 and L4YoSf32126 with bond lengths of 3.18 and 2.94 Å, respectively (Figure 1)

Summary

Introduction

With multidrug-resistant bacteria on the rise and bacterial infections imposing a major threat to public health, there is an imminent need for the development of new antibiotics [1,2]. While anti-MRSA drugs have been developed, including methicillin, penicillin, cephalosporins, and carbapenems [9,10,11], new MRSA-resistant strains continue to appear, threatening the current repository of antibiotics [12,13,14]. PBP2a inhibition depends on the opening of the active site through a conformational change in the β3–β4 loops to allow drug entry [17,18]. This conformational change is mediated by a small molecule allosteric regulation 60 Å from the active site [18,19]. Communication between these two sites has been characterized by targeted molecular dynamics (TMD) simulations [17]

Methods

Results

Conclusion