AI Article Synopsis
- Understanding protein dynamics is crucial for deciphering how their structure relates to their function in biological processes, but it's a complex problem that remains unsolved.
- This study develops simplified molecular models using artificial neural networks, derived from extensive simulations (9 ms of data) of twelve different proteins, to accelerate simulations while maintaining accurate thermodynamics.
- The findings suggest that these machine learning models can effectively represent multiple proteins and their mutations, offering a promising method to enhance the simulation and understanding of protein dynamics.
Article Abstract
A generalized understanding of protein dynamics is an unsolved scientific problem, the solution of which is critical to the interpretation of the structure-function relationships that govern essential biological processes. Here, we approach this problem by constructing coarse-grained molecular potentials based on artificial neural networks and grounded in statistical mechanics. For training, we build a unique dataset of unbiased all-atom molecular dynamics simulations of approximately 9 ms for twelve different proteins with multiple secondary structure arrangements. The coarse-grained models are capable of accelerating the dynamics by more than three orders of magnitude while preserving the thermodynamics of the systems. Coarse-grained simulations identify relevant structural states in the ensemble with comparable energetics to the all-atom systems. Furthermore, we show that a single coarse-grained potential can integrate all twelve proteins and can capture experimental structural features of mutated proteins. These results indicate that machine learning coarse-grained potentials could provide a feasible approach to simulate and understand protein dynamics.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10504246 | PMC |
| http://dx.doi.org/10.1038/s41467-023-41343-1 | DOI Listing |
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