Mining viral protease data to extract cleavage knowledge

doi:10.1093/bioinformatics/18.suppl_1.S5

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Bioinformatics Vol. 18 no. 90001 2002
Pages S5-S13
© 2002 Oxford University Press

Mining viral protease data to extract cleavage knowledge

Ajit Narayanan , Xikun Wu and Z. Rong Yang

School of Engineering and Computer Sciences (Bioinformatics Laboratory), Old Library, University of Exeter, Exeter EX4 4PT, UK

Received on January 19, 2002 ; revised on March 28, 2002 ; accepted on March 28, 2002

Motivation: The motivation is to identify, through machine learningtechniques, specific patterns in HIV and HCV viral polyproteinamino acid residues where viral protease cleaves the polyproteinas it leaves the ribosome. An understanding of viral proteasespecificity may help the development of future anti-viral drugsinvolving protease inhibitors by identifying specific featuresof protease activity for further experimental investigation.While viral sequence information is growing at a fast rate,there is still comparatively little understanding of how viralpolyproteins are cut into their functional unit lengths. Theaim of the work reported here is to investigate whether it is possible to generalise from known cleavage sites to unknowncleavage sites for two specific viruses—HIV and HCV.An understanding of proteolytic activity for specific viruseswill contribute to our understanding of viral protease functionin general, thereby leading to a greater understanding of proteasefamilies and their substrate characteristics.

Results: Our results show that artificial neural networks andsymbolic learning techniques (See5) capture some fundamentaland new substrate attributes, but neural networks outperformtheir symbolic counterpart.

Availability: Publicly available software was used (Stuttgart NeuralNetwork Simulator—http://www-ra.informatik.uni-tuebingen.de/SNNS/ andSee5—http://www.rulequest.com. The datasets used (HIV,HCV) for See5 are available at: http://www.dcs.ex.ac.uk/~anarayan/bioinf/ismbdatasets/

Keywords: protase cleavage; protease inhibitors; machine learning;neural networks; decision trees.

Contact: a.narayanan{at}ex.ac.uk; wuxikun{at}yahoo.com; z.r.yang{at}ex.ac.uk

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