Metabolic PathFinding: inferring relevant pathways in biochemical networks

Metabolic PathFinding: inferring relevant pathways in biochemical networks

Our knowledge of metabolism can be represented as a network comprising several thousands of nodes (compounds and reactions). Several groups applied graph theory to analyse the topological properties of this network and to infer metabolic pathways by path finding. This is, however, not straightforwar...

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Bibliographic Details
Published in:Nucleic acids research Vol. 33; no. suppl-2; pp. W326 - W330
Main Authors: Croes, Didier, Couche, Fabian, Wodak, Shoshana J., van Helden, Jacques
Format: Journal Article
Language:English
Published: England Oxford University Press 01-07-2005
Oxford Publishing Limited (England)
Subjects:
Algorithms
Bioinformatics
Computer Graphics
Computer Science
Internet
Life Sciences
Metabolism
Software
Tryptophan - biosynthesis
User-Computer Interface
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Summary:Our knowledge of metabolism can be represented as a network comprising several thousands of nodes (compounds and reactions). Several groups applied graph theory to analyse the topological properties of this network and to infer metabolic pathways by path finding. This is, however, not straightforward, with a major problem caused by traversing irrelevant shortcuts through highly connected nodes, which correspond to pool metabolites and co-factors (e.g. H2O, NADP and H+). In this study, we present a web server implementing two simple approaches, which circumvent this problem, thereby improving the relevance of the inferred pathways. In the simplest approach, the shortest path is computed, while filtering out the selection of highly connected compounds. In the second approach, the shortest path is computed on the weighted metabolic graph where each compound is assigned a weight equal to its connectivity in the network. This approach significantly increases the accuracy of the inferred pathways, enabling the correct inference of relatively long pathways (e.g. with as many as eight intermediate reactions). Available options include the calculation of the k-shortest paths between two specified seed nodes (either compounds or reactions). Multiple requests can be submitted in a queue. Results are returned by email, in textual as well as graphical formats (available in http://www.scmbb.ulb.ac.be/pathfinding/).
Bibliography:istex:4ABC16F67CA0987792C2A85F5870717724050801
local:gki437
To whom correspondence should be addressed. Tel: +32 2 650 5466; Fax: +32 2 650 5425; Email: jvanheld@scmbb.ulb.ac.be
ark:/67375/HXZ-D4BDTQ02-K
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ISSN:0305-1048
1362-4962
DOI:10.1093/nar/gki437