Evolution of Developmental Genes: Molecular Microevolution of Enhancer Sequences at the Ubx Locus in Drosophila and Its Impact on Developmental Phenotypes

doi:10.1093/molbev/msh025

MBE Advance Access originally published online on December 5, 2003

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Mol. Biol. Evol. 21(2):348-363. 2004
DOI: 10.1093/molbev/msh025
© 2004 by the Society for Molecular Biology and Evolution. ISSN: 0737-4038

Evolution of Developmental Genes: Molecular Microevolution of Enhancer Sequences at the Ubx Locus in Drosophila and Its Impact on Developmental Phenotypes

Jaros Phinchongsakuldit, Stewart MacArthur and John F. Y. Brookfield

Institute of Genetics, University of Nottingham, Queens Medical Centre, Nottingham, United Kingdom

E-mail: john.brookfield{at}nottingham.ac.uk.

Homeotic genes, which function to specify segment identity alongthe anterior-posterior axis of embryos, are controlled by extensivebatteries of enhancer sequences. We have investigated patternsof interspecific and intraspecific molecular variation in threeenhancers of the Ultrabithorax (Ubx) locus, which are bx-32.8,pbx32.7, and bxd4.1, from the Drosophila melanogaster speciesgroup. These enhancer sequences control Ubx expression by bindingto multiple transcription factors encoded by gap, pair-rule,and dorsoventrally expressed genes. Sequence comparisons revealpurifying selection acting on all three enhancers, both in basesbinding transcription factors and in bases whose functions areas yet unknown. Neutrality tests largely fail to reject a neutralevolution model. However, using a matrix similarity value toreflect the binding affinity of the protein-binding sites, interspecificand intraspecific variation that may have potential to affectthe binding affinity of the sequences homologous to those bindingtranscription factors in D. melanogaster are discovered, suggestingevolutionary flexibility in the way in which these sequencesfunction in the control of development. As a means of measuringthe impact of intraspecific variation on observable phenotypes,we have induced Ubx mutant phenocopies with embryonic ethertreatment, and find strong and highly significant variationbetween D. melanogaster strains in their phenocopy frequencies.This variation shows no significant correlation with the strengthsof the mutant phenotypes when the strains are heterozygous witha Ubx null mutation. Estimated phylogenetic trees have beenconstructed for the three enhancer regions investigated. Neitherof the two phenotypic traits investigated shows any significantassociations with the phylogeny of any of the three enhancers.

Key Words: Drosophila • Ultrabithorax • phenocopy • developmental evolution • molecular evolution • enhancer sequences

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