Water Will Find Its Way: Transport Through Narrow Tunnels in Hydrolases

Overview

Journal J Chem Inf Model

Publisher American Chemical Society

Specialties Chemistry
Medical Informatics

Date 2024 Apr 26

PMID 38669675

Authors

Carlos Sequeiros-Borja

Bartlomiej Surpeta

Aravind Selvaram Thirunavukarasu

Cedrix J Dongmo Foumthuim

Igor Marchlewski

Jan Brezovsky

Affiliations

Soon will be listed here.

Abstract

An aqueous environment is vital for life as we know it, and water is essential for nearly all biochemical processes at the molecular level. Proteins utilize water molecules in various ways. Consequently, proteins must transport water molecules across their internal network of tunnels to reach the desired action sites, either within them or by functioning as molecular pipes to control cellular osmotic pressure. Despite water playing a crucial role in enzymatic activity and stability, its transport has been largely overlooked, with studies primarily focusing on water transport across membrane proteins. The transport of molecules through a protein's tunnel network is challenging to study experimentally, making molecular dynamics simulations the most popular approach for investigating such events. In this study, we focused on the transport of water molecules across three different α/β-hydrolases: haloalkane dehalogenase, epoxide hydrolase, and lipase. Using a 5 μs adaptive simulation per system, we observed that only a few tunnels were responsible for the majority of water transport in dehalogenase, in contrast to a higher diversity of tunnels in other enzymes. Interestingly, water molecules could traverse narrow tunnels with subangstrom bottlenecks, which is surprising given the commonly accepted water molecule radius of 1.4 Å. Our analysis of the transport events in such narrow tunnels revealed a markedly increased number of hydrogen bonds formed between the water molecules and protein, likely compensating for the steric penalty of the process. Overall, these commonly disregarded narrow tunnels accounted for ∼20% of the total water transport observed, emphasizing the need to surpass the standard geometrical limits on the functional tunnels to properly account for the relevant transport processes. Finally, we demonstrated how the obtained insights could be applied to explain the differences in a mutant of the human soluble epoxide hydrolase associated with a higher incidence of ischemic stroke.

Citing Articles

Water Migration through Enzyme Tunnels Is Sensitive to the Choice of Explicit Water Model.

Thirunavukarasu A, Szleper K, Tanriver G, Marchlewski I, Mitusinska K, Gora A J Chem Inf Model. 2024; 65(1):326-337.

PMID: 39680044 PMC: 11733929. DOI: 10.1021/acs.jcim.4c01177.

Impact of water models on the structure and dynamics of enzyme tunnels.

Sethi A, Agrawal N, Brezovsky J Comput Struct Biotechnol J. 2024; 23:3946-3954.

PMID: 39582894 PMC: 11584523. DOI: 10.1016/j.csbj.2024.10.051.

Reinforcing Tunnel Network Exploration in Proteins Using Gaussian Accelerated Molecular Dynamics.

Mandal N, Surpeta B, Brezovsky J J Chem Inf Model. 2024; 64(16):6623-6635.

PMID: 39143923 PMC: 11351021. DOI: 10.1021/acs.jcim.4c00966.

Incorporating Prior Knowledge in the Seeds of Adaptive Sampling Molecular Dynamics Simulations of Ligand Transport in Enzymes with Buried Active Sites.

Sarkar D, Surpeta B, Brezovsky J J Chem Theory Comput. 2024; 20(14):5807-5819.

PMID: 38978395 PMC: 11270739. DOI: 10.1021/acs.jctc.4c00452.

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