LocalAli: an evolutionary-based local alignment approach to identify functionally conserved modules in multiple networks

Motivation: Sequences and protein interaction data are of significance to understand the underlying molecular mechanism of organisms. Local network alignment is one of key systematic ways for predicting protein functions, identifying functional modules and understanding the phylogeny from these data...

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Vydáno v:Bioinformatics Ročník 31; číslo 3; s. 363 - 372
Hlavní autoři: Hu, Jialu, Reinert, Knut
Médium: Journal Article
Jazyk:angličtina
Vydáno: England 01.02.2015
Témata:
Algorithms
Alignment
Bioinformatics
Biological Evolution
Computational Biology
Databases, Protein
Evolution
Evolutionary
Gene Regulatory Networks
Humans
Mathematical models
Modules
Networks
Phylogeny
Protein Interaction Mapping - methods
Proteins
Sequence Alignment - methods
Software
ISSN:1367-4803, 1367-4811, 1367-4811, 1460-2059
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Shrnutí:Motivation: Sequences and protein interaction data are of significance to understand the underlying molecular mechanism of organisms. Local network alignment is one of key systematic ways for predicting protein functions, identifying functional modules and understanding the phylogeny from these data. Most of currently existing tools, however, encounter their limitations, which are mainly concerned with scoring scheme, speed and scalability. Therefore, there are growing demands for sophisticated network evolution models and efficient local alignment algorithms. Results: We developed a fast and scalable local network alignment tool called LocalAli for the identification of functionally conserved modules in multiple networks. In this algorithm, we firstly proposed a new framework to reconstruct the evolution history of conserved modules based on a maximum-parsimony evolutionary model. By relying on this model, LocalAli facilitates interpretation of resulting local alignments in terms of conserved modules, which have been evolved from a common ancestral module through a series of evolutionary events. A meta-heuristic method simulated annealing was used to search for the optimal or near-optimal inner nodes (i.e. ancestral modules) of the evolutionary tree. To evaluate the performance and the statistical significance, LocalAli were tested on 26 real datasets and 1040 randomly generated datasets. The results suggest that LocalAli outperforms all existing algorithms in terms of coverage, consistency and scalability, meanwhile retains a high precision in the identification of functionally coherent subnetworks. Availability: The source code and test datasets are freely available for download under the GNU GPL v3 license at https://code.google.com/p/localali/ . Contact:  jialu.hu@fu-berlin.de or knut.reinert@fu-berlin.de . Supplementary information:  Supplementary data are available at Bioinformatics online.
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ISSN:1367-4803
1367-4811
1367-4811
1460-2059
DOI:10.1093/bioinformatics/btu652