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Main Authors: Carvalho, Felipe Silva, Ramsey, Steven, Kurtzman, Tom, Luchko, Tyler
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.26140
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author Carvalho, Felipe Silva
Ramsey, Steven
Kurtzman, Tom
Luchko, Tyler
author_facet Carvalho, Felipe Silva
Ramsey, Steven
Kurtzman, Tom
Luchko, Tyler
contents Molecular dynamics (MD) simulations are widely used to study biological systems, where water molecules often play a critical role in protein-ligand interactions. In conventional MD preparation protocols, water molecules are typically added from a pre-equilibrated solvent box and removed using conservative steric cutoffs, an approach that can eliminate important interfacial waters that are often not recovered during equilibration due to kinetic barriers limiting exchange with bulk solvent. In this work, we present an automated and computationally efficient method for placing water molecules around biomolecular solutes using three-dimensional reference interaction site model (3D-RISM) solvent density distributions. By identifying regions of high solvent probability, the method generates physically meaningful initial hydration structures without requiring extended sampling or specialized techniques such as grand canonical Monte Carlo (MC) or hybrid MC/MD approaches, and will be released as an update to AmberTools 26, enabling seamless integration into standard MD preparation pipelines. We validate the approach on a diverse set of protein-ligand complexes with crystallographically resolved bridging waters, showing that 3D-RISM-based placement reproduces a large fraction of these experimentally observed waters, while subsequent minimization further improves agreement as crystallographic waters relax toward positions consistent with those predicted by our approach. Overall, this method enables more accurate and practical initialization of interfacial hydration, improving the reliability of MD simulations with modest computational cost relative to routine system preparation.
format Preprint
id arxiv_https___arxiv_org_abs_2604_26140
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Solv-eze: Automated Placement of Explicit Water Molecules Using 3D-RISM
Carvalho, Felipe Silva
Ramsey, Steven
Kurtzman, Tom
Luchko, Tyler
Chemical Physics
Molecular dynamics (MD) simulations are widely used to study biological systems, where water molecules often play a critical role in protein-ligand interactions. In conventional MD preparation protocols, water molecules are typically added from a pre-equilibrated solvent box and removed using conservative steric cutoffs, an approach that can eliminate important interfacial waters that are often not recovered during equilibration due to kinetic barriers limiting exchange with bulk solvent. In this work, we present an automated and computationally efficient method for placing water molecules around biomolecular solutes using three-dimensional reference interaction site model (3D-RISM) solvent density distributions. By identifying regions of high solvent probability, the method generates physically meaningful initial hydration structures without requiring extended sampling or specialized techniques such as grand canonical Monte Carlo (MC) or hybrid MC/MD approaches, and will be released as an update to AmberTools 26, enabling seamless integration into standard MD preparation pipelines. We validate the approach on a diverse set of protein-ligand complexes with crystallographically resolved bridging waters, showing that 3D-RISM-based placement reproduces a large fraction of these experimentally observed waters, while subsequent minimization further improves agreement as crystallographic waters relax toward positions consistent with those predicted by our approach. Overall, this method enables more accurate and practical initialization of interfacial hydration, improving the reliability of MD simulations with modest computational cost relative to routine system preparation.
title Solv-eze: Automated Placement of Explicit Water Molecules Using 3D-RISM
topic Chemical Physics
url https://arxiv.org/abs/2604.26140