Abstract
Protein–RNA interactions (PRIs) are essential for many biological processes, so understanding aspects of the sequences and structures involved in PRIs is important for unraveling such processes. Because of the expensive and time-consuming techniques required for experimental determination of complex protein–RNA structures, various computational methods have been developed to predict PRIs. However, most of these methods focus on predicting only RNA-binding regions in proteins or only protein-binding motifs in RNA. Methods for predicting entire residue–base contacts in PRIs have not yet achieved sufficient accuracy. Furthermore, some of these methods require the identification of 3D structures or homologous sequences, which are not available for all protein and RNA sequences. Here, we propose a prediction method for predicting residue–base contacts between proteins and RNAs using only sequence information and structural information predicted from sequences. The method can be applied to any protein–RNA pair, even when rich information such as its 3D structure, is not available. In this method, residue–base contact prediction is formalized as an integer programming problem. We predict a residue–base contact map that maximizes a scoring function based on sequence-based features such as k-mers of sequences and the predicted secondary structure. The scoring function is trained using a max-margin framework from known PRIs with 3D structures. To verify our method, we conducted several computational experiments. The results suggest that our method, which is based on only sequence information, is comparable with RNA-binding residue prediction methods based on known binding data.
Highlights
The results suggest that our method, which is based on only sequence information, is comparable with RNA-binding residue prediction methods based on known binding data
We propose a prediction method for residue–base contacts between proteins and RNAs based only on sequence information and structural information predicted from sequences
The results suggest that our method based on only sequence information is comparable with RNA-binding residue prediction methods based on actual known binding data
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Recent studies have begun unraveling the mechanisms of biological processes involving functional non-coding RNAs, most of which interact with RNA-binding proteins (RBPs) in essential roles, such as splicing, transport, localization, and translation. These interactions involve sequence- and structure-specific recognition between proteins and RNAs. understanding aspects of sequences and structures involved in protein–RNA interactions (PRIs) is important for understanding many biological processes. Several studies have focused on the analysis and discussion of PRIs [1,2,3]
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