Litcius/Paper detail

Correlating enzymatic reactivity for different substrates using transferable data-driven collective variables

Sudip Das, Umberto Raucci, Rui P. P. Neves, Maria J. Ramos, Michele Parrinello

2024Proceedings of the National Academy of Sciences12 citationsDOIOpen Access PDF

Abstract

Machine learning (ML) is transforming the investigation of complex biological processes. In enzymatic catalysis, one significant challenge is identifying the reactive conformations (RC) of the enzyme:substrate complex where the substrate assumes a precise arrangement in the active site necessary to initiate a reaction. Traditional methods are hindered by the complexity of the multidimensional free energy landscape involved in the transition from nonreactive to reactive conformations. Here, we applied ML techniques to address this challenge, focusing on human pancreatic α-amylase, a crucial enzyme in type-II diabetes treatment. Using ML-based collective variables (CVs), we correlated the probability of being in a RC with the experimental catalytic activity of several malto-oligosaccharide substrates. Our findings demonstrate a remarkable transferability of these CVs across various compounds, significantly streamlining the modeling process and reducing both computational demand and manual intervention in setting up simulations for new substrates. This approach not only advances our understanding of enzymatic processes but also holds substantial potential for accelerating drug discovery by enabling rapid and accurate evaluation of drug efficacy across different generations of inhibitors.

Topics & Concepts

TransferabilitySubstrate (aquarium)Enzyme catalysisEnzymeChemistryComputer scienceProcess (computing)Combinatorial chemistryReactivity (psychology)Computational biologyBiological systemBiochemical engineeringComputational chemistryMachine learningBiochemistryBiologyEngineeringMedicineLogitOperating systemEcologyPathologyAlternative medicineProtein Structure and DynamicsComputational Drug Discovery MethodsEnzyme Catalysis and Immobilization