Abstract
BackgroundElectron transport chain is a series of protein complexes embedded in the process of cellular respiration, which is an important process to transfer electrons and other macromolecules throughout the cell. It is also the major process to extract energy via redox reactions in the case of oxidation of sugars. Many studies have determined that the electron transport protein has been implicated in a variety of human diseases, i.e. diabetes, Parkinson, Alzheimer’s disease and so on. Few bioinformatics studies have been conducted to identify the electron transport proteins with high accuracy, however, their performance results require a lot of improvements. Here, we present a novel deep neural network architecture to address this problem.ResultsMost of the previous studies could not use the original position specific scoring matrix (PSSM) profiles to feed into neural networks, leading to a lack of information and the neural networks consequently could not achieve the best results. In this paper, we present a novel approach by using deep gated recurrent units (GRU) on full PSSMs to resolve this problem. Our approach can precisely predict the electron transporters with the cross-validation and independent test accuracy of 93.5 and 92.3%, respectively. Our approach demonstrates superior performance to all of the state-of-the-art predictors on electron transport proteins.ConclusionsThrough the proposed study, we provide ET-GRU, a web server for discriminating electron transport proteins in particular and other protein functions in general. Also, our achievement could promote the use of GRU in computational biology, especially in protein function prediction.
Highlights
Proteins accomplish a large diversity of functions inside the various compartments of eukaryotic cells
This is the first study that has applied this method to protein function prediction
We are able to preserve all of the position specific scoring matrix (PSSM) information which is fed into the deep neural networks
Summary
Proteins accomplish a large diversity of functions inside the various compartments of eukaryotic cells. It is not surprising that protein function prediction is one of the well-studied topics in computational biology and it attracts the attention of numerous researchers conducting their works. There has been a lot of attention given to enhancing the predictive performance of protein functions using a variety of computational techniques. We applied our techniques in the prediction of the function of electron transport protein, which is one of the most essential molecule functions in cellular respiration. Many studies have determined that the electron transport protein has been implicated in a variety of human diseases, i.e. diabetes, Parkinson, Alzheimer’s disease and so on. Few bioinformatics studies have been conducted to identify the electron transport proteins with high accuracy, their performance results require a lot of improvements.
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