Mitochondrial Genomes and Avian Phylogeny: Complex Characters and Resolvability without Explosive Radiations

doi:10.1093/molbev/msl158

MBE Advance Access originally published online on October 24, 2006
Molecular Biology and Evolution 2007 24(1):269-280; doi:10.1093/molbev/msl158

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© The Author 2006. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oxfordjournals.org

Research Articles

Mitochondrial Genomes and Avian Phylogeny: Complex Characters and Resolvability without Explosive Radiations

Gillian C. Gibb^*, Olga Kardailsky^*, Rebecca T. Kimball, Edward L. Braun and David Penny^*

^* Allan Wilson Centre for Molecular Ecology and Evolution, Massey University, Palmerston North, New Zealand
Department of Zoology, University of Florida

E-mail: g.c.gibb{at}massey.ac.nz.

Accepted for publication October 11, 2006.

We improve the taxon sampling for avian phylogeny by analyzing7 new mitochondrial genomes (a toucan, woodpecker, osprey, forestfalcon, American kestrel, heron, and a pelican). This improvesinference of the avian tree, and it supports 3 major conclusions.The first is that some birds (including a parrot, a toucan,and an osprey) exhibit a complete duplication of the controlregion (CR) meaning that there are at least 4 distinct geneorders within birds. However, it appears that there are regionsof continued gene conversion between the duplicate CRs, resultingin duplications that can be stable for long evolutionary periods.Because of this stable duplicated state, gene order can eventuallyeither revert to the original order or change to the new geneorder. The existence of this stable duplicate state explainshow an apparently unlikely event (finding the same novel geneorder) can arise multiple times. Although rare genomic changeshave theoretical advantages for tree reconstruction, they canbe compromised if these apparently rare events have a stableintermediate state. Secondly, the toucan and woodpecker improvethe resolution of the 6-way split within Neoaves that has beencalled an "explosive radiation." An explosive radiation impliesthat normal microevolutionary events are insufficient to explainthe observed macroevolution. By showing the avian tree is, inprinciple, resolvable, we demonstrate that the radiation ofbirds is amenable to standard evolutionary analysis. Thirdly,and as expected from theory, additional taxa breaking up longbranches stabilize the position of some problematic taxa (likethe falcon). In addition, we report that within the birds ofprey and allies, we did not find evidence pairing New Worldvultures with storks or accipitrids (hawks, eagles, and osprey)with Falconids.

Key Words: gene order • forest falcon • osprey • kestrel • woodpecker • heron • toucan • pelican • explosive radiation • avian phylogeny • complex characters • adaptive radiations

Naoko Takezaki, Associate Editor

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