Zhenkun Gou scite author profile

Proteins that interact with DNA are involved in a number of fundamental biological activities such as DNA replication, transcription, and repair. A reliable identification of DNA-binding sites in DNA-binding proteins is important for functional annotation, site-directed mutagenesis, and modeling protein-DNA interactions. We apply Support Vector Machine (SVM), a supervised pattern recognition method, to predict DNA-binding sites in DNA-binding proteins using the following features: amino acid sequence, profile of evolutionary conservation of sequence positions, and low-resolution structural information. We use a rigorous statistical approach to study the performance of predictors that utilize different combinations of features and how this performance is affected by structural and sequence properties of proteins. Our results indicate that an SVM predictor based on a properly scaled profile of evolutionary conservation in the form of a position specific scoring matrix (PSSM) significantly outperforms a PSSM-based neural network predictor. The highest accuracy is achieved by SVM predictor that combines the profile of evolutionary conservation with low-resolution structural information. Our results also show that knowledge-based predictors of DNA-binding sites perform significantly better on proteins from mainly-alpha structural class and that the performance of these predictors is significantly correlated with certain structural and sequence properties of proteins. These observations suggest that it may be possible to assign a reliability index to the overall accuracy of the prediction of DNA-binding sites in any given protein using its sequence and structural properties. A web-server implementation of the predictors is freely available online at http://lcg.rit.albany.edu/dp-bind/.

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Scintillation properties of selected oxide monocrystals activated with Ce and Pr

Wojtowicz

Drozdowski

Wiśniewski

et al. 2006

Optical Materials

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VUV spectroscopy and low temperature thermoluminescence of LSO:Ce and YSO:Ce

Drozdowski

Wojtowicz

Wiśniewski

et al. 2004

Journal of Alloys and Compounds

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A canonical correlation neural network for multicollinearity and functional data

Gou

Fyfe

2004

Neural Networks

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Zhenkun Gou

DP-Bind: a web server for sequence-based prediction of DNA-binding residues in DNA-binding proteins

Using evolutionary and structural information to predict DNA‐binding sites on DNA‐binding proteins

Scintillation properties of selected oxide monocrystals activated with Ce and Pr

VUV spectroscopy and low temperature thermoluminescence of LSO:Ce and YSO:Ce

A canonical correlation neural network for multicollinearity and functional data

Contact Info

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