AI Article Synopsis
- RNA-protein interactions are essential for biological processes like protein translation and gene expression regulation, making accurate models of these interactions vital.
- Advances in modeling RNA-protein binding affinities have been achieved by integrating a free energy function, automated mutation modeling, and secondary structure energetic calculations.
- The new Rosetta-Vienna RNP-ΔΔG method shows improved accuracy in predicting binding affinities, outperforming previous approaches and laying groundwork for future advancements in RNA-protein interaction modeling.
Article Abstract
Interactions between RNA and proteins are pervasive in biology, driving fundamental processes such as protein translation and participating in the regulation of gene expression. Modeling the energies of RNA-protein interactions is therefore critical for understanding and repurposing living systems but has been hindered by complexities unique to RNA-protein binding. Here, we bring together several advances to complete a calculation framework for RNA-protein binding affinities, including a unified free energy function for bound complexes, automated Rosetta modeling of mutations, and use of secondary structure-based energetic calculations to model unbound RNA states. The resulting Rosetta-Vienna RNP-ΔΔG method achieves root-mean-squared errors (RMSEs) of 1.3 kcal/mol on high-throughput MS2 coat protein-RNA measurements and 1.5 kcal/mol on an independent test set involving the signal recognition particle, human U1A, PUM1, and FOX-1. As a stringent test, the method achieves RMSE accuracy of 1.4 kcal/mol in blind predictions of hundreds of human PUM2-RNA relative binding affinities. Overall, these RMSE accuracies are significantly better than those attained by prior structure-based approaches applied to the same systems. Importantly, Rosetta-Vienna RNP-ΔΔG establishes a framework for further improvements in modeling RNA-protein binding that can be tested by prospective high-throughput measurements on new systems.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6486753 | PMC |
| http://dx.doi.org/10.1073/pnas.1819047116 | DOI Listing |
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