Evidence for a subpopulation of conserved alternative splicing events under selection pressure for protein reading frame preservation

doi:10.1093/nar/gkh284

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Published online 24 February 2004

Nucleic Acids Research, 2004, Vol. 32, No. 4 1261-1269
© 2004 Oxford University Press

Evidence for a subpopulation of conserved alternative splicing events under selection pressure for protein reading frame preservation

Alissa Resch, Yi Xing, Alexander Alekseyenko, Barmak Modrek and Christopher Lee^*

Molecular Biology Institute, Institute for Genomics and Proteomics, and Department of Chemistry and Biochemistry, University of California, Los Angeles, Los Angeles, CA 90095-1570, USA

*To whom correspondence should be addressed. Tel: +1 310 825 7374; Fax: +1 310 267 0248; Email: leec{at}mbi.ucla.edu

Recently there has been much interest in assessing the roleof alternative splicing in evolution. We have sought to measurefunctional selection pressure on alternatively spliced single-exonskips, by calculating the fraction that are an exact multipleof 3 nt in length and therefore preserve protein reading-framein both the exon-inclusion and exon-skip splice forms. The frame-preservationratio (defined as the number of exons that are an exact multipleof three in length, divided by the number of exons that arenot) was slightly above random for both constitutive exons andalternatively spliced exons as a whole in human and mouse. However,orthologous exons that were observed to be alternatively splicedin the expressed sequence tag data from two or more organismsshowed a substantially increased bias to be frame-preserving.This effect held true only for exons within the protein codingregion, and not the untranslated region. In five animal genomes(human, mouse, rat, zebrafish, Drosophila), we observed anassociation between these conserved alternative splicing eventsand increased selection pressure for frame-preservation. Surprisingly,this effect became stronger as a function of decreasing exoninclusion level: for alternatively spliced exons that were includedin a majority of the gene’s transcripts, the frame-preservationbias was no higher than that of constitutive exons, whereasfor alternatively spliced exons that were included in only aminority of the gene’s transcripts, the frame-preservationbias increased nearly 20-fold. These data indicate that a subpopulationof modern alternative splicing events was present in the commonancestors of these genomes, and was under functional selectionpressure to preserve the protein reading frame.

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