Abstract
Identifying the drug-target interactions (DTIs) plays an essential role in new drug development. However, there still has the limited knowledge of DTIs and a significant number of unknown DTI pairs. Moreover, the traditional experimental methods have inevitable disadvantages such as high cost and time-consuming. Therefore, developing computational methods for predicting DTIs is attracting more and more attention. In this study, we report a novel computational approach for predicting DTI using GIST feature, position-specific scoring matrix (PSSM), and rotation forest (RF). Specifically, each target protein is first converted into a PSSM for retaining evolutionary information. Then, the GIST feature is extracted from PSSM and substructure fingerprint information is adopted to extract the feature of the drug. Finally, combining each protein and drug features to form a new drug-target pair, which is employed as input feature for RF classifier. In the experiment, the proposed method achieves high average accuracies of 89.25%, 85.93%, 82.36%, and 73.89% on enzyme, ion channel, G protein-coupled receptors (GPCRs), and nuclear receptor, respectively. For further evaluating the prediction performance of the proposed method, we compare it with the state-of-the-art support vector machine (SVM) classifier on the same golden standard dataset. These promising results illustrate that the proposed method is more effective and stable than other methods. We expect the proposed method to be a useful tool for predicting large-scale DTIs.
Highlights
Identification of drug-target interaction (DTI) plays a vital role in researching and developing new drugs
Where true negative (TN) represents the number of drugtarget pairs that are classified as noninteracting pairs correctly, true positive (TP) denotes the count of drug-target pairs that are classified as interacting pairs correctly, false negative (FN) represents the number of samples that are classified as noninteracting pairs incorrectly, and false positive (FP) is the count of samples that are classified as interacting
We reported a novel computational approach combines GIST feature, position-specific scoring matrix (PSSM), and rotation forest (RF) based classification to infer unknown DTIs on a large-scale
Summary
Identification of drug-target interaction (DTI) plays a vital role in researching and developing new drugs. Many researchers have conducted extensive research into the DTI due to its essential role in seeking new protein to the target for drug development and promoting the emergence of new drug candidates [1, 2]. Researchers have carried out a large number of experimental methods to identify drug-target interactions, but these experimental methods have inevitable shortcomings such as time-consuming and high cost. It is becoming increasingly urgent to identify drug-target interactions by developing effective new computational methods [5] which can reduce the cost and time of the experimental approach. The reliable computational method could accelerate drug discovery and potentially find some better drug candidates [6]
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