Improving position-specific predictions of protein functional sites using phylogenetic motifs

doi:10.1093/bioinformatics/btn454

Bioinformatics Advance Access originally published online on August 21, 2008
Bioinformatics 2008 24(20):2308-2316; doi:10.1093/bioinformatics/btn454

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Improving position-specific predictions of protein functional sites using phylogenetic motifs

K. C. Dukka Bahadur and Dennis R. Livesay ^*

Department of Computer Science and Bioinformatics Research Center, University of North Carolina at Charlotte, Charlotte, NC 28223, USA

*To whom correspondence should be addressed.

Abstract

Motivation: Accurate computational prediction of protein functionalsites is critical to maximizing the utility of recent high-throughputsequencing efforts. Among the available approaches, position-specificconservation scores remain among the most popular due to theiraccuracy and ease of computation. Unfortunately, high falsepositive rates remain a limiting factor. Using phylogeneticmotifs (PMs), we have developed two combined (conservation +PMs) prediction schemes that significantly improve predictionaccuracy.

Results: Our first approach, called position-specific MINER(psMINER), rank orders alignment columns by conservation. Subsequently,positions that are also not identified as PMs are excluded fromthe prediction set. This approach improves prediction accuracy,in a statistically significant way, compared to the underlyingconservation scores. Increased accuracy is a general result,meaning improvement is observed over several different conservationscores that span a continuum of complexity. In addition, a hybridMINER (hMINER) that quantitatively considers both scoring regimesprovides further improvement. More importantly, it providescritical insight into the relative importance of phylogeny versusalignment conservation. Both methods outperform other commonprediction algorithms that also utilize phylogenetic concepts.Finally, we demonstrate that the presented results are criticallysensitive to functional site definition, thus highlighting theneed for more complete benchmarks within the prediction community.

Availability: Our benchmark datasets are available for downloadat http://www.cs.uncc.edu/~drlivesa/dataset.html.

Contact: drlivesa{at}uncc.edu

Supplementary information: Supplementary data is available atBioinformatics online.

Associate Editor: Burkhard Rost

Received on May 20, 2008; revised on August 14, 2008; accepted on August 20, 2008

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