Quantum neural networks can predict binding free energies for enzymatic inhibitors

Quantum mechanical molecular electrostatic potential surfaces and neural networks are combined to predict the binding energy for bioactive molecules with enzyme targets. Computational neural networks are employed to identify the quantum mechanical features of inhibitory molecules that contribute to binding. This approach generates relationships between the quantum mechanical structure of inhibitory molecules and the strength of binding. Feed-forward neural networks with back-propagation of error are trained to recognize the quantum mechanical electrostatic potential at the entire van der Waals surface of a group of training molecules and to predict the strength of interactions between the enzyme and novel inhibitors. Three enzyme systems are used as examples in this work: AMP (adenosine mono phosphate) nucleosidase, adenosine deaminase, and cytidine deaminase. Quantum neural networks identify critical areas on inhibitor potential surfaces involved in binding and predict with quantitative accuracy the binding strength of new inhibitors. The method is able to predict the binding free energy of the transition state, when trained with less tightly bound inhibitors. The application of this approach to the study of enzyme inhibitors and receptor agonists would permit evaluation of chemical libraries of potential bioactive agents.