Analysis of evolution of exon-intron structure of eukaryotic genes

doi:10.1093/bib/6.2.118

Briefings in Bioinformatics 2005 6(2):118-134; doi:10.1093/bib/6.2.118

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Analysis of evolution of exon-intron structure of eukaryotic genes

Igor B. Rogozin
Staff scientist at the National Center for Biotechnology Information NLM/NIH (Bethesda, MD, USA).

Alexander V. Sverdlov
visiting fellow at the National Center for Biotechnology Information NLM/NIH.

Vladimir N. Babenko
Research fellow at the National Center for Biotechnology Information NLM/NIH.

Eugene V. Koonin
Senior investigator at the National Center for Biotechnology Information NLM/NIH.

Igor B. Rogozin, NCBI/NLM/NIH, 8600 Rockville Pike, Bldg. 38A, Bethesda, MD 20894, USA Tel: +1 301 594 4271 Fax: +1 301 435 7794 E-mail: rogozin{at}ncbi.nlm.nih.gov

The availability of multiple, complete eukaryotic genome sequencesallows one to address many fundamental evolutionary questionson genome scale. One such important, long-standing problem isevolution of exon—intron structure of eukaryotic genes.Analysis of orthologous genes from completely sequenced genomesrevealed numerous shared intron positions in orthologous genesfrom animals and plants and even between animals, plants andprotists. The data on shared and lineage-specific intron positionswere used as the starting point for evolutionary reconstructionwith parsimony and maximum-likelihood approaches. Parsimonymethods produce reconstructions with intron-rich ancestors butalso infer lineage-specific, in many cases, high levels of intronloss and gain. Different probabilistic models gave oppositeresults, apparently depending on model parameters and assumptions,from domination of intron loss, with extremely intron-rich ancestors,to dramatic excess of gains, to the point of denying any trueconservation of intron positions among deep eukaryotic lineages.Development of models with adequate, realistic parameters andassumptions seems to be crucial for obtaining more definitiveestimates of intron gain and loss in different eukaryotic lineages.Many shared intron positions were detected in ancestral eukaryoticparalogues which evolved by duplication prior to the divergenceof extant eukaryotic lineages. These findings indicate thatnumerous introns were present in eukaryotic genes already atthe earliest stages of evolution of eukaryotes and are compatiblewith the hypothesis that the original, catastrophic intron invasionaccompanied the emergence of the eukaryotic cells. Comparisonof various features of old and younger introns starts sheddinglight on probable mechanisms of intron insertion, indicatingthat propagation of old introns is unlikely to be a major mechanismfor origin of new ones. The existence and structure of ancestralprotosplice sites were addressed by examining the context ofintrons inserted within codons that encode amino acids conservedin all eukaryotes and, accordingly, are not subject to selectionfor splicing efficiency. It was shown that introns indeed predominantlyinsert into or are fixed in specific protosplice sites whichhave the consensus sequence (A/C)AG|Gt.

Keywords: intron evolution, intron gain, intron loss, protosplice site, exon shuffling, early eukaryotes

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