AI Article Synopsis
- DNA-binding proteins play key roles in genetic processes like alternative splicing and methylation, but identifying them with current methods is resource-intensive.
- The novel predictor MsDBP uses a deep neural network with multiscale sequence features, focusing on sequence data rather than structure, and encodes protein subsequences for better analysis.
- MsDBP achieved an accuracy of 66.99% in identifying DNA-binding proteins on a test dataset, showing promise as an efficient tool for researchers, and is available online for use.
Article Abstract
DNA-binding proteins are crucial to alternative splicing, methylation, and the structural composition of the DNA. The existing experimental methods for identifying DNA-binding proteins are expensive and time-consuming; thus, it is necessary to develop a fast and accurate computational method to address the problem. In this Article, we report a novel predictor MsDBP, a DNA-binding protein prediction method that combines the multiscale sequence feature into a deep neural network. First of all, instead of developing a narrow-application structured-based method, we are committed to a sequenced-based predictor. Second, instead of characterizing the whole protein directly, we divide the protein into subsequences with different lengths and then encode them into a vector based on composition information. In this way, the multiscale sequence feature can be obtained. Finally, a branch of dense layers is applied for learning multilevel abstract features to discriminate DNA-binding proteins. When MsDBP is tested on the independent data set PDB2272, it achieves an overall accuracy of 66.99% with the SE of 70.69%. In addition, we also perform extensive experiments to compare the proposed method with other existing methods. The results indicate that MsDBP would be a useful tool for the identification of DNA-binding proteins. MsDBP is freely available at a web server on http://47.100.203.218/MsDBP/ .
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| http://dx.doi.org/10.1021/acs.jproteome.9b00226 | DOI Listing |
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