Messenger RNA Surveillance and the Evolutionary Proliferation of Introns

doi:10.1093/molbev/msg068

MBE Advance Access published online on March 5, 2003
Molecular Biology and Evolution, doi:10.1093/molbev/msg068
Molecular Biology and Evolution © Society for Molecular Biology and Evolution 2003; all rights reserved

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Accepted November 22, 2002
© 2003 Society for Molecular Biology and Evolution

Original Articles

Messenger RNA Surveillance and the Evolutionary Proliferation of Introns

Michael Lynch ¹^* Avinash Kewalramani ¹

¹ Department of Biology, Indiana University, Bloomington, Indiana 47405

^* To whom correspondence should be addressed. E-mail: mlynch{at}bio.indiana.edu.

Abstract

The mechanisms responsible for the proliferation and subsequentstabilization of introns within the eukaryotic lineage haveremained elusive. In the early stages of eukaryotic evolution,most introns may have been mildly deleterious at the time ofinsertion, but enough of them eventually acquired integral rolesin transcript processing that few eukaryotic species can anylonger survive without them. We suggest that the proliferationof spliceosomal introns was facilitated by the evolution ofnonsense-mediated decay, an ancient and (in many cases) intron-dependentmechanism for eliminating aberrant mRNA molecules resultingfrom errors in transcription and splicing and from mutationsat the DNA level. The spatial distribution of introns, as revealedby whole-genome analysis, is consistent with expectations fora model in which maximum protective coverage of a gene stochasticallyevolves over time.

Key Words: genome complexity, genome evolution, introns, mRNA processing, mRNA surveillance, nonsense-mediated decay, null alleles, splicing

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