Evidence for a High Ancestral GC Content in Drosophila

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Molecular Biology and Evolution 17:1710-1717 (2000)
© 2000 Society for Molecular Biology and Evolution

ARTICLE

Evidence for a High Ancestral GC Content in Drosophila

Francisco Rodríguez-Trelles^*, Rosa Tarrío^* and Francisco J. Ayala^*

*Department of Ecology and Evolutionary Biology, University of California at Irvine; and
${dagger}$ Instituto de Investigaciones Agrobiológicas de Galicia (CSIC), Santiago de Compostela, Spain

Study of the nucleotide composition in Drosophila, focusingon the saltans and willistoni groups, has revealed unanticipateddifferences in nucleotide composition among lineages. Compositionaldifferences are associated with an accelerated rate of nucleotidesubstitution in functionally less constrained regions. Theseobservations have been set forth against the extended opinionthat the pattern of point mutation has remained constant duringthe evolution of the genus. A crucial assumption has been thatthe most recent common ancestor of the subgenus Sophophora hadan elevated GC content. Until now, this assumption has beensupported by indirect arguments, consisting of extrapolationsfrom closely related outgroups and limited by the robustnessof mathematical descriptions concerning the extensive nucleotidecomposition differences among sequences. The present study seeksto test the assumption of a high ancestral GC content usingrealistic representations of the nucleotide substitution processto account for potential biases induced by the heterogeneousGC content of the taxa. The analysis of eight nuclear genesunambiguously corroborates that the common ancestor of Sophophorahad an elevated GC content.

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