Abstract
Z-coordinate is an important structural feature of $\alpha $ -helical transmembrane proteins ( $\alpha $ -TMPs), which is defined as the distance from a residue to the center of the biological membrane. Since the $\alpha $ -TMP structures from both experimental solved and computational predicted approaches still cannot cover the requirements in relevant research fields, z-coordinate prediction provides an opportunity to partly descript $\alpha $ -TMP structures based on their sequences, further contributes to function annotation and drug target discovery. For the purpose of improving the prediction accuracy and providing a convenient tool, we proposed a deep learning-based predictor (TM-ZC) for the z-coordinate of residues in $\alpha $ -TMPs. TM-ZC used the one-hot code and the PSSM as input features for a convolutional neural network (CNN) regression model. The experimental results demonstrated that TM-ZC was a powerful predictor, which is simple and fast, and achieved a considerable performance: the average error was 1.958, the percent of prediction error within 3A was 77.461%, and the correlation coefficient (CC) was 0.922. We further discussed the usefulness of TM-ZC predicted z-coordinate and found its high consistency with topology structure and the enhancement of the surface accessibility prediction.
Highlights
We proposed a deep learning-based predictor (TM-ZC) for the z-coordinate of residues in α-helical transmembrane proteins (α-transmembrane proteins (TMPs))
The model using one-hot code alone performed poorly, it complemented the PSSM feature that the model achieved the best performance while using two features together
The z-coordinate of a residue in α-TMPs is defined as the distance between the residue and the membrane center
Summary
Of known drugs, the detailed structure of them would be paramount to the success of drug discovery [12], [13] Despite their important biological functions, determination of high-resolution structures of α-TMPs persist technical difficulties, only approximately 5% of them are determined. Beyond high-resolution structural information, some low-resolution structural descriptors, such as topology structure, surface accessibility, and z-coordinate, can provide valuable information about α-TMPs. In recent years, a lot of illuminating methods have been proposed and accessed great achievements. C. Lu et al.: TM-ZC: Deep Learning-Based Predictor for the Z-Coordinate of Residues in α-TMPs topology structure prediction methods of α-TMPs [14], [15], especially, S.
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