Targeting the Protein Tunnels of the Urease Accessory Complex: A Theoretical Investigation.

Matteo Masetti,Stefano Ciurli,Maurizio Recanatini,Francesco Musiani,Dario Gioia,Federico Falchi

doi:10.3390/molecules25122911

Matteo Masetti, Stefano Ciurli + Show 4 more

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https://doi.org/10.3390/molecules25122911

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Abstract

Urease is a nickel-containing enzyme that is essential for the survival of several and often deadly pathogenic bacterial strains, including Helicobacter pylori. Notwithstanding several attempts, the development of direct urease inhibitors without side effects for the human host remains, to date, elusive. The recently solved X-ray structure of the HpUreDFG accessory complex involved in the activation of urease opens new perspectives for structure-based drug discovery. In particular, the quaternary assembly and the presence of internal tunnels for nickel translocation offer an intriguing possibility to target the HpUreDFG complex in the search of indirect urease inhibitors. In this work, we adopted a theoretical framework to investigate such a hypothesis. Specifically, we searched for putative binding sites located at the protein–protein interfaces on the HpUreDFG complex, and we challenged their druggability through structure-based virtual screening. We show that, by virtue of the presence of tunnels, some protein–protein interfaces on the HpUreDFG complex are intrinsically well suited for hosting small molecules, and, as such, they possess good potential for future drug design endeavors.

Highlights

All living organisms require transition metal ions as indispensable micronutrients [1,2]
We show that small molecules identified through a structure-based virtual screening (SBVS) approach might act as indirect urease inhibitors by either disrupting protein–protein interactions within the HpUreDFG
We explored the feasibility of using Structure-Based Virtual Screening to identify potential molecules able to interfere with the functionality of the (HpUreDFG)2 complex

Summary

Introduction

All living organisms require transition metal ions as indispensable micronutrients [1,2]. The low environmental availability coupled with their toxicity obliged all life forms to develop mechanisms for selective metal ion import, trafficking, accumulation, concentration regulation, and export [3,4,5,6,7]. Eight out of twelve dangerous microorganisms recently identified by the World Health Organization for their antibiotic resistance use urease for their survival [16] To this aim, if one considers that Ni(II) ions are not essential for higher animal species, nickel metabolism is an ideal candidate for the development of new specific therapeutics to tackle bacterial pathogens [17]. The nutritional effect of nickel in humans has not yet been studied sufficiently [20]

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