On the use of qualitative reasoning to simulate and identify metabolic pathways

doi:10.1093/bioinformatics/bti255

Bioinformatics Advance Access originally published online on January 12, 2005
Bioinformatics 2005 21(9):2017-2026; doi:10.1093/bioinformatics/bti255

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On the use of qualitative reasoning to simulate and identify metabolic pathways

Ross D. King ¹^,*, Simon M. Garrett ¹ and George M. Coghill ²

¹Department of Computer Science, University of Wales Aberystwyth, Wales, SY23 3DB, UK
²Department of Computing Science, University of Aberdeen Aberdeen, ABD24 3UE, UK

^*To whom correspondence should be addressed.

Motivation: Perhaps the greatest challenge of modern biologyis to develop accurate in silico models of cells. To do thiswe require computational formalisms for both simulation (howaccording to the model the state of the cell evolves over time)and identification (learning a model cell from observation ofstates). We propose the use of qualitative reasoning (QR) asa unified formalism for both tasks. The two most commonly usedalternative methods of modelling biochemical pathways are ordinarydifferential equations (ODEs), and logical/graph-based (LG)models.

Results: The QR formalism we use is an abstraction of ODEs.It enables the behaviour of many ODEs, with different functionalforms and parameters, to be captured in a single QR model. QRhas the advantage over LG models of explicitly including dynamics.To simulate biochemical pathways we have developed ‘enzyme’and ‘metabolite’ QR building blocks that fit togetherto form models. These models are finite, directly executable,easy to interpret and robust. To identify QR models we havedeveloped heuristic chemoinformatics graph analysis and machinelearning procedures. The graph analysis procedure is a seriesof constraints and heuristics that limit the number of waysmetabolites can combine to form pathways. The machine learningprocedure is generate-and-test inductive logic programming.We illustrate the use of QR for modelling and simulation usingthe example of glycolysis.

Availability: All data and programs used are available on request.

Contact: rdk{at}aber.ac.uk

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