Abstract
BackgroundGuanosine triphosphate (GTP)-binding proteins play an important role in regulation of G-protein. Thus prediction of GTP interacting residues in a protein is one of the major challenges in the field of the computational biology. In this study, an attempt has been made to develop a computational method for predicting GTP interacting residues in a protein with high accuracy (Acc), precision (Prec) and recall (Rc).ResultAll the models developed in this study have been trained and tested on a non-redundant (40% similarity) dataset using five-fold cross-validation. Firstly, we have developed neural network based models using single sequence and PSSM profile and achieved maximum Matthews Correlation Coefficient (MCC) 0.24 (Acc 61.30%) and 0.39 (Acc 68.88%) respectively. Secondly, we have developed a support vector machine (SVM) based models using single sequence and PSSM profile and achieved maximum MCC 0.37 (Prec 0.73, Rc 0.57, Acc 67.98%) and 0.55 (Prec 0.80, Rc 0.73, Acc 77.17%) respectively. In this work, we have introduced a new concept of predicting GTP interacting dipeptide (two consecutive GTP interacting residues) and tripeptide (three consecutive GTP interacting residues) for the first time. We have developed SVM based model for predicting GTP interacting dipeptides using PSSM profile and achieved MCC 0.64 with precision 0.87, recall 0.74 and accuracy 81.37%. Similarly, SVM based model have been developed for predicting GTP interacting tripeptides using PSSM profile and achieved MCC 0.70 with precision 0.93, recall 0.73 and accuracy 83.98%.ConclusionThese results show that PSSM based method performs better than single sequence based method. The prediction models based on dipeptides or tripeptides are more accurate than the traditional model based on single residue. A web server "GTPBinder" http://www.imtech.res.in/raghava/gtpbinder/ based on above models has been developed for predicting GTP interacting residues in a protein.
Highlights
Guanosine triphosphate (GTP)-binding proteins play an important role in regulation of G-protein
Composition analysis We have analyzed the composition of GTP interacting and non-interacting residues in GTP binding proteins and observed that certain types of residues are preferred in GTP interaction
We have introduced two new concepts for predicting GTP interacting residues using dipeptide based technique (DPT) and tripeptides based technique (TPT)
Summary
Guanosine triphosphate (GTP)-binding proteins play an important role in regulation of G-protein. An attempt has been made to develop a computational method for predicting GTP interacting residues in a protein with high accuracy (Acc), precision (Prec) and recall (Rc). Many proteins such as protein kinase, G-protein, dehydrogenase enzymes, Ras group of proteins and Src group proteins bind to nucleotide (adenine and guanine) for their function [1,2]. We have used the second approach for predicting GTP interacting residues in a protein from its amino acid sequence. Many nucleotides (GTP) binding proteins have been discovered due to advancement in sequence technology. To the best of our knowledge, no sequenced based method has been developed so far for predicting GTP interacting residue in a protein
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