Predictions of the poses and affinity of a ligand over the entire surface of a NEET protein: the case of human mitoNEET

10 October 2022, Version 1
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

Human NEET proteins contain two [2Fe–2S] iron-sulfur clusters, bound to three Cys and one His residue. They exist in two redox states. Recently, these proteins have revealed themselves as attractive drug targets for mitochondrial dysfunction-related diseases, such as type 2 diabetes, Wolfram syndrome 2, and cancers. Unfortunately, the lack of information and mechanistic understanding on ligands binding to the whole functional, cytoplasmatic domain has limited rational drug design approaches. Here we use an enhanced sampling technique, volume-based metadynamics, recently developed by a team involving some of us, to predict the poses and affinity of 2-benzamido-4-(1,2,3,4-tetrahydronaphthalen-2-yl)-thiophene-3-carboxylate ligand to the entire surface of the cytoplasmatic domain of the human NEET protein mitoNEET (mNT) in an aqueous solution. The calculations, based on the recently published X-ray structure of the complex, are consistent with the measured affinity. The calculated free energy landscape revealed that the ligand can bind in multiple sites and with poses other than the one found in the X-ray. This difference is likely to be caused by crystal packing effects that allow the ligand to interact with multiple adjacent NEET protein copies. Such extra-contacts are of course absent in solution, therefore the X-ray pose is only transient in our calculations, where the binding free energy correlate with the number of contacts. We further evaluated how the reduction and protonation of the Fe-bound histidine, as well as temperature, can affect ligand binding. Both such modifications introduce the possibility for the ligand to bind in area of the protein other than the one observed in the X-ray, with no or little impact on affinity. Overall, our study can provide insights on the molecular recognition mechanisms of ligand binding to mNT in different oxidative conditions, possibly helping rational drug design of NEET ligands.

Keywords

NEET proteins
mitoNEET
binding poses
binding free energy
molecular dynamics
metadynamics

Supplementary materials

Title
Description
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Title
Supporting information of Predictions of the poses and affinity of a ligand over the entire surface of a NEET protein: the case of human mitoNEET
Description
Details on settings of molecular docking; force field and parameters of ligand A; convergence of MD simulations and metadynamics of A·mNT; ligand/protein interactions for I–IV complexes
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