High population connectivity across the Indo-Pacific: Congruent lack of phylogeographic structure in three reef fish congeners

We used the mitochondrial control region and a comparative approach to study the genetic population structure of two surgeonfishes, Naso brevirostris and Naso unicornis, across their Indo-central Pacific ranges. Our purpose was to compare our results with those of a previous study of Naso vlamingii...

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Bibliographic Details
Published in:Molecular phylogenetics and evolution 2008-11, Vol.49 (2), p.629-638
Main Authors: Horne, John B., van Herwerden, Lynne, Choat, J. Howard, Robertson, D.R.
Format: Article
Language:English
Subjects:
Acanthuridae
Animals
Bayes Theorem
Comparative phylogeography
Coral reef fish
DNA, Mitochondrial - genetics
Female
Gene Flow
Genetic Speciation
Genetic Variation
Genetics, Population
Geography
Likelihood Functions
Marine
Markov Chains
Mitochondria - genetics
Mitochondrial control region
Models, Genetic
Monte Carlo Method
Naso
Naso brevirostris
Naso unicornis
Pacific Ocean
Perciformes - classification
Perciformes - genetics
Phylogeny
Sequence Alignment
Sequence Analysis, DNA
Species Specificity
Stochastic variation
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Summary:We used the mitochondrial control region and a comparative approach to study the genetic population structure of two surgeonfishes, Naso brevirostris and Naso unicornis, across their Indo-central Pacific ranges. Our purpose was to compare our results with those of a previous study of Naso vlamingii [Klanten, S.O., van Herwerden, L., Choat J.H., 2007. Extreme genetic diversity and temporal rather than spatial partitioning in a widely distributed coral reef fish. Mar. Biol. 150, 659–670] another widely distributed Indo-central Pacific Naso species. We found no evidence of a barrier to gene flow between the Indian and Pacific Oceans for either species, consistent with what was shown for N. vlamingii. Overall, both target species lacked spatial population partitions and probably have complex patterns of gene flow on several spatial scales. Despite the lack of geographic population structure distinct clades were observed in N. brevirostris, similar to those found in N. vlamingii. Coalescence times for intraspecific clades of N. brevirostris and N. vlamingii approximate each other, suggesting parallel evolutionary histories. A bimodal mismatch distribution in N. brevirostris indicates that a biogeographic barrier separated N. brevirostris populations sometime during its species history. Naso unicornis, in contrast, lacked genetic structure of any kind, although it has what could represent a single surviving clade. Congruent lack of spatial population structure among all three species suggest that such patterns are not due to stochastic processes of DNA mutation and are most likely driven by ecological and environmental factors.
ISSN:1055-7903
1095-9513
DOI:10.1016/j.ympev.2008.08.023