Theoretical analysis of alternative splice forms using computational methods

doi:10.1093/bioinformatics/18.suppl_2.S65

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Bioinformatics Vol. 18 no. 90002 2002
Pages S65-S73
© 2002 Oxford University Press

Theoretical analysis of alternative splice forms using computational methods

Stéphanie Boué ¹, Martin Vingron ¹, Evgenia Kriventseva ² and Ina Koch ¹^,3

¹ Max-Planck-Institute for Molecular Genetics, Department Computational Molecular Biology, Ihnestr.73, Berlin, 14195, Germany
² EMBL Outstation - Hinxton, European Bioinformatics Institute, European Bioinformatics Institute, Hinxton, Cambridge CB10 1SD, UK
³ University of Applied Sciences Berlin - TFH, Computational Biology, Seestr. 64, Berlin, 13347, Germany

Nowadays understanding alternative splicing is one of the greatestchallenges in biology, because it is a genetic process muchmore important than thought at the time of its discovery. Inthis paper, we explain the approach of using the different availabledatabases and software tools to start a large scale investigationof alternative splice forms. To collect information about alternative splicingwe investigated known data in the databases using differentcomputational methods. The investigations proceeded from thegenomic sequence data to structural protein data. Then, we interpretedthose data to find the relationship between alternative spliceforms and protein function and structure. We found some interesting featuresof alternative splicing which are presented here. We discussthe results of one chosen example. They concern the coveragequality of the protein sequence of a known structure, an ESTanalysis, the validation of splice variants, the determinationof the alternative splice type, and finally the link betweenalternative splicing and disease.

Contact: ina.koch{at}molgen.mpg.de

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