Litcius/Paper detail

Convergent Protocols for Computing Protein–Ligand Interaction Energies Using Fragment-Based Quantum Chemistry

Paige Bowling, Dustin Broderick, John M. Herbert

2025Journal of Chemical Theory and Computation15 citationsDOIOpen Access PDF

Abstract

Fragment-based quantum chemistry methods offer a means to sidestep the steep nonlinear scaling of electronic structure calculations so that large molecular systems can be investigated using high-level methods. Here, we use fragmentation to compute protein–ligand interaction energies in systems with several thousand atoms, using a new software platform for managing fragment-based calculations that implements a screened many-body expansion. Convergence tests using a minimal-basis semiempirical method (HF-3c) indicate that two-body calculations, with single-residue fragments and simple hydrogen caps, are sufficient to reproduce interaction energies obtained using conventional supramolecular electronic structure calculations, to within 1 kcal/mol at about 1% of the computational cost. We also demonstrate that the HF-3c results are illustrative of trends obtained with density functional theory in basis sets up to augmented quadruple-ζ quality. Strategic deployment of fragmentation facilitates the use of converged biomolecular model systems alongside high-quality electronic structure methods and basis sets, bringing ab initio quantum chemistry to systems of hitherto unimaginable size. This will be useful for generation of high-quality training data for machine learning applications.

Topics & Concepts

Fragment (logic)Quantum chemistryElectronic structureComputer scienceDensity functional theoryFragmentation (computing)Supramolecular chemistryQuantumAb initioChemistryTheoretical chemistryComputational scienceComputational chemistryProtein ligandStatistical physicsPhysicsQuantum mechanicsAlgorithmMoleculeOperating systemOrganic chemistryGreen chemistryProtein Structure and DynamicsMachine Learning in Materials ScienceComputational Drug Discovery Methods