Acarbose Potentially Binds to the Type I Peptide Deformylase Catalytic Site and Inhibits Bacterial Growth: An In Silico and In Vitro Study

Abstract

Background: In bacteria, peptide deformylase (PDF), a metalloenzyme, removes N-formyl methio-nine from a nascent protein, which is a critical step in the protein maturation process. The enzyme is ubiqui-tously present in bacteria and possesses therapeutic target potential. Acarbose, an FDA-approved antidiabetic drug, is an alpha-glucosidase inhibitor of microbial origin. Clinical studies indicate that acarbose administration in humans can alter gut microbiota. As per the best of our knowledge, the antibacterial potential of acarbose has not been reported. Objective: The present study aimed to check the binding ability of acarbose to the catalytic site of E. coli PDF and assess its in vitro antibacterial activity. Methods: Molecular docking, molecular dynamic (MD) simulation, and MM-PBSA experiments were per-formed to study the binding potential of the catalytic site, and a disc diffusion assay was also employed to assess the antibacterial potential of acarbose. Results: Acarbose was found to form a hydrogen bond and interact with the metal ion present at the catalytic site. The test compound showed a better docking score in comparison to the standard inhibitor of PDF. MD simulation results showed energetically stable acarbose-PDF complex formation in terms of RMSD, RMSF, Rg, SASA, and hydrogen bond formation throughout the simulation period compared to the actinonin-PDF complex. Furthermore, MM-PBSA calculations showed better binding free energy (?G) of acarbose PDF than the actinonin-PDF complex. Moreover, acarbose showed in vitro antibacterial activity. Conclusion: Acarbose forms conformational and thermodynamically stable interaction with the E. coli peptide deformylase catalytic site. Results of the present work necessitate in-depth antimicrobial potential studies on the effect of acarbose on drug resistance and nonresistant bacteria. � 2022 Bentham Science Publishers.