Weighted-support vector machines for predicting membrane protein types based on pseudo-amino acid composition

doi:10.1093/protein/gzh061

PEDS Advance Access originally published online on August 16, 2004
Protein Engineering Design and Selection 2004 17(6):509-516; doi:10.1093/protein/gzh061

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Weighted-support vector machines for predicting membrane protein types based on pseudo-amino acid composition

Meng Wang¹^,2, Jie Yang¹, Guo-Ping Liu¹, Zhi-Jie Xu¹ and Kuo-Chen Chou¹^,2^,3^,4^,5^,6

¹Institute of Image Processing and Pattern Recognition, Shanghai Jiaotong University, Shanghai 200030, ³Bioinformatics Research Centre, Donghau University, Shanghai 200050, ⁴Department of Biomedical Engineering, Shanghai Jiaotong University, Shanghai 200030, ⁵Tianjin Institute of Bioinformatics and Drug Discovery, Tianjin, China and ⁶Gordon Life Science Institute, San Diego, CA 92130, USA

² To whom correspondence should be addressed. E-mail: mengking{at}sjtu.edu.cn; kchou{at}san.rr.com

Membrane proteins are generally classified into the followingfive types: (1) type I membrane proteins, (2) type II membraneproteins, (3) multipass transmembrane proteins, (4) lipid chain-anchoredmembrane proteins and (5) GPI-anchored membrane proteins. Predictionof membrane protein types has become one of the growing hottopics in bioinformatics. Currently, we are facing two criticalchallenges in this area: first, how to take into account theextremely complicated sequence-order effects, and second, howto deal with the highly uneven sizes of the subsets in a trainingdataset. In this paper, stimulated by the concept of using thepseudo-amino acid composition to incorporate the sequence-ordereffects, the spectral analysis technique is introduced to representthe statistical sample of a protein. Based on such a framework,the weighted support vector machine (SVM) algorithm is applied.The new approach has remarkable power in dealing with the biascaused by the situation when one subset in the training datasetcontains many more samples than the other. The new method isparticularly useful when our focus is aimed at proteins belongingto small subsets. The results obtained by the self-consistencytest, jackknife test and independent dataset test are encouraging,indicating that the current approach may serve as a powerfulcomplementary tool to other existing methods for predictingthe types of membrane proteins.

Received May 10, 2004; revised July 23, 2004; accepted July 26, 2004.

Edited by Alan Fersht

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