Thermal Titration Molecular Dynamics: The Revenge of the Fragments

Overview

Journal J Chem Inf Model

Publisher American Chemical Society

Date 2025 Jan 21

PMID 39835670

Authors

Matteo Pavan

Silvia Menin

Andrea Dodaro

Gianluca Novello

Chiara Cavastracci Strascia

Mattia Sturlese

Veronica Salmaso

Stefano Moro

Affiliations

Soon will be listed here.

Abstract

During the last 20 years, the fragment-based drug discovery approach gained popularity in both industrial and academic settings due to its efficient exploration of the chemical space. This bottom-up approach relies on identifying high-efficiency small ligands (fragments) that bind to a target binding site and then rationally evolve them into mature druglike compounds. To achieve such a task, researchers rely on accurate information about the ligand binding mode, usually obtained through experimental techniques, such as X-ray crystallography or computer simulations. However, the physicochemical characteristics of fragments limit the accuracy and reliability of computational predictions of their binding mode. This article presents a new Thermal Titration Molecular Dynamics (TTMD) protocol, a recently developed enhanced sampling method for qualitatively estimating protein-ligand-binding stability, specifically tuned for the refinement of fragment docking results. The protocol has been applied to eight pharmaceutically relevant targets on 12 different test cases, including ligands with very low molecular weight and structural complexity (MiniFrag/FragLites). In more than 80% of cases, TTMD successfully identified the native fragment binding mode among a set of docking poses, outperforming docking alone and proving to be a useful tool to assist the fragment screening and optimization process.

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