A Comparison Study for DNA Motif Modeling on Protein Binding Microarray

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13 Scopus Citations
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Detail(s)

Original languageEnglish
Article number7122289
Pages (from-to)261-271
Journal / PublicationIEEE/ACM Transactions on Computational Biology and Bioinformatics
Volume13
Issue number2
Publication statusPublished - 1 Mar 2016

Abstract

Transcription factor binding sites (TFBSs) are relatively short (5-15 bp) and degenerate. Identifying them is a computationally challenging task. In particular, protein binding microarray (PBM) is a high-throughput platform that can measure the DNA binding preference of a protein in a comprehensive and unbiased manner; for instance, a typical PBM experiment can measure binding signal intensities of a protein to all possible DNA k-mers (k = 8∼10). Since proteins can often bind to DNA with different binding intensities, one of the major challenges is to build TFBS (also known as DNA motif) models which can fully capture the quantitative binding affinity data. To learn DNA motif models from the non-convex objective function landscape, several optimization methods are compared and applied to the PBM motif model building problem. In particular, representative methods from different optimization paradigms have been chosen for modeling performance comparison on hundreds of PBM datasets. The results suggest that the multimodal optimization methods are very effective for capturing the binding preference information from PBM data. In particular, we observe a general performance improvement if choosing di-nucleotide modeling over mono-nucleotide modeling. In addition, the models learned by the best-performing method are applied to two independent applications: PBM probe rotation testing and ChIP-Seq peak sequence prediction, demonstrating its biological applicability.

Research Area(s)

  • differential evolution, DNA motif, Gene regulation, genetic algorithm, multimodal optimization, protein binding microarray, ranking