High Intron Sequence Conservation Across Three Mammalian Orders Suggests Functional Constraints

doi:10.1093/molbev/msg111

MBE Advance Access originally published online on April 25, 2003

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Mol. Biol. Evol. 20(6):969-978. 2003
DOI: 10.1093/molbev/msg111
© 2003 by the Society for Molecular Biology and Evolution. ISSN: 0737-4038

High Intron Sequence Conservation Across Three Mammalian Orders Suggests Functional Constraints

Matthew P. Hare^*^, and Stephen R. Palumbi^,1

^* Biology Department, University of Maryland, College Park
Department of Organismic and Evolutionary Biology, Harvard University

Several studies have demonstrated high levels of sequence conservationin noncoding DNA compared between two species (e.g., human andmouse), and interpreted this conservation as evidence for functionalconstraints. If this interpretation is correct, it suggeststhe existence of a hidden class of abundant regulatory elements.However, much of the noncoding sequence conserved between twospecies may result from chance or from small-scale heterogeneityin mutation rates. Stronger inferences are expected from sequencecomparisons using more than two taxa, and by testing for spatialpatterns of conservation in addition to primary sequence similarity.We used a Bayesian local alignment method to compare approximately10 kb of intron sequence from nine genes in a pairwise mannerbetween human, whale, and seal to test whether the degree andpattern of conservation is consistent with neutral divergence.Comparison of the three sets of conserved gapless pairwise blocksrevealed the following patterns: The proportion of identicalintron nucleotides averaged 47% in pairwise comparisons and28% across the three taxa. Proportions of conserved sequencewere similar in unique sequence and general mammalian repetitiveelements. We simulated sequence evolution under a neutral modelusing published estimates of substitution rate heterogeneityfor noncoding DNA and found pairwise identity at 33% and three-taxonidentity at 16% of nucleotide sites. Spatial patterns of primarysequence conservation were also nonrandomly distributed withinintrons. Overall, segments of intron sequence closer to flankingexons were significantly more conserved than interior intronsequence. This level of intron sequence conservation is abovethat expected by chance and strongly suggests that intron sequencesare playing a larger functional role in gene regulation thanpreviously realized.

Key Words: phylogenetic footprinting • intron • noncoding sequence conservation • gene regulation • interspersed repeats

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