Patterns of intron sequence evolution in Drosophila are dependent upon length and GC content

Penelope R Haddrill, Brian Charlesworth, Daniel L Halligan, Peter Andolfatto

Research output: Contribution to journalArticle

136 Citations (Scopus)

Abstract

Introns comprise a large fraction of eukaryotic genomes, yet little is known about their functional significance. Regulatory elements have been mapped to some introns, though these are believed to account for only a small fraction of genome wide intronic DNA. No consistent patterns have emerged from studies that have investigated general levels of evolutionary constraint in introns.
We examine the relationship between intron length and levels of evolutionary constraint by analyzing inter-specific divergence at 225 intron fragments in Drosophila melanogaster and Drosophila simulans, sampled from a broad distribution of intron lengths. We document a strongly negative correlation between intron length and divergence. Interestingly, we also find that divergence in introns is negatively correlated with GC content. This relationship does not account for the correlation between intron length and divergence, however, and may simply reflect local variation in mutational rates or biases.
Short introns make up only a small fraction of total intronic DNA in the genome. Our finding that long introns evolve more slowly than average implies that, while the majority of introns in the Drosophila genome may experience little or no selective constraint, most intronic DNA in the genome is likely to be evolving under considerable constraint. Our results suggest that functional elements may be ubiquitous within longer introns and that these introns may have a more general role in regulating gene expression than previously appreciated. Our finding that GC content and divergence are negatively correlated in introns has important implications for the interpretation of the correlation between divergence and levels of codon bias observed in Drosophila.

LanguageEnglish
Article numberR67
Number of pages8
JournalGenome Biology
Volume6
Issue number8
DOIs
Publication statusPublished - 27 Jul 2005

Fingerprint

Base Composition
Introns
Drosophila
Genes
Genome
DNA
Drosophila melanogaster
Gene expression
Codon

Keywords

  • animals
  • base composition
  • base pairing
  • base sequence
  • DNA
  • drosophila melanogaster
  • evolution, molecular
  • introns
  • patterns
  • length and GC content
  • intron sequence evolution

Cite this

Haddrill, Penelope R ; Charlesworth, Brian ; Halligan, Daniel L ; Andolfatto, Peter. / Patterns of intron sequence evolution in Drosophila are dependent upon length and GC content. In: Genome Biology. 2005 ; Vol. 6, No. 8.
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Patterns of intron sequence evolution in Drosophila are dependent upon length and GC content. / Haddrill, Penelope R; Charlesworth, Brian; Halligan, Daniel L; Andolfatto, Peter.

In: Genome Biology, Vol. 6, No. 8, R67, 27.07.2005.

Research output: Contribution to journalArticle

TY - JOUR

T1 - Patterns of intron sequence evolution in Drosophila are dependent upon length and GC content

AU - Haddrill, Penelope R

AU - Charlesworth, Brian

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