Lei Wang scite author profile

Protein-protein interactions (PPIs) play an important role in most of the biological processes. How to correctly and efficiently detect protein interaction is a problem that is worth studying. Although high-throughput technologies provide the possibility to detect large-scale PPIs, these cannot be used to detect whole PPIs, and unreliable data may be generated. To solve this problem, in this study, a novel computational method was proposed to effectively predict the PPIs using the information of a protein sequence. The present method adopts Zernike moments to extract the protein sequence feature from a position specific scoring matrix (PSSM). Then, these extracted features were reconstructed using the stacked autoencoder. Finally, a novel probabilistic classification vector machine (PCVM) classifier was employed to predict the protein-protein interactions. When performed on the PPIs datasets of Yeast and H. pylori, the proposed method could achieve average accuracies of 96.60% and 91.19%, respectively. The promising result shows that the proposed method has a better ability to detect PPIs than other detection methods. The proposed method was also applied to predict PPIs on other species, and promising results were obtained. To evaluate the ability of our method, we compared it with the-state-of-the-art support vector machine (SVM) classifier for the Yeast dataset. The results obtained via multiple experiments prove that our method is powerful, efficient, feasible, and make a great contribution to proteomics research.

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Study on bending damage and failure of basalt fiber reinforced concrete under freeze-thaw cycles

Zhao

Wang

Lei

et al. 2018

Construction and Building Materials

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Hopf bifurcation in Cohen–Grossberg neural network with distributed delays

Zhao

Wang

2007

Nonlinear Analysis: Real World Applications

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Determining the transport mechanism of an enzyme-catalytic complex metabolic network based on biological robustness

Wang

2012

Bioprocess Biosyst Eng

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Understanding the transport mechanism of 1,3-propanediol (1,3-PD) is of critical importance to do further research on gene regulation. Due to the lack of intracellular information, on the basis of enzyme-catalytic system, using biological robustness as performance index, we present a system identification model to infer the most possible transport mechanism of 1,3-PD, in which the performance index consists of the relative error of the extracellular substance concentrations and biological robustness of the intracellular substance concentrations. We will not use a Boolean framework but prefer a model description based on ordinary differential equations. Among other advantages, this also facilitates the robustness analysis, which is the main goal of this paper. An algorithm is constructed to seek the solution of the identification model. Numerical results show that the most possible transport way is active transport coupled with passive diffusion.

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Lei Wang

Predicting protein–protein interactions from protein sequences by a stacked sparse autoencoder deep neural network

Study on bending damage and failure of basalt fiber reinforced concrete under freeze-thaw cycles

Hopf bifurcation in Cohen–Grossberg neural network with distributed delays

Determining the transport mechanism of an enzyme-catalytic complex metabolic network based on biological robustness

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