1. Cryptic species and independent origins of allochronic populations within a seabird species complex (Hydrobates spp.).
- Author
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Taylor RS, Bolton M, Beard A, Birt T, Deane-Coe P, Raine AF, González-Solís J, Lougheed SC, and Friesen VL
- Subjects
- Animals, Atlantic Ocean, Bayes Theorem, Biodiversity, Breeding, Charadriiformes genetics, DNA, Mitochondrial genetics, Gene Flow, Genetics, Population, Geography, Likelihood Functions, Mitochondria genetics, Pacific Ocean, Principal Component Analysis, Species Specificity, Charadriiformes classification, Phylogeny
- Abstract
Humans are inherently biased towards naming species based on morphological differences, which can lead to reproductively isolated species being mistakenly classified as one if they are morphologically similar. Recognising cryptic diversity is needed to understand drivers of speciation fully, and for accurate estimates of global biodiversity and assessments for conservation. We investigated cryptic species across the range of band-rumped storm-petrels (Hydrobates spp.): highly pelagic, nocturnal seabirds that breed on tropical and sub-tropical islands in the Atlantic and Pacific Oceans. In many breeding colonies, band-rumped storm-petrels have sympatric but temporally isolated (allochronic) populations; we sampled all breeding locations and allochronic populations. Using mitochondrial control region sequences from 754 birds, cytochrome b sequences from 69 birds, and reduced representation sequencing of the nuclear genomes of 133 birds, we uncovered high levels of genetic structuring. Population genomic analyses revealed up to seven unique clusters, and phylogenomic reconstruction showed that these represent seven monophyletic groups. We uncovered up to six independent breeding season switches across the phylogeny, spanning the continuum from genetically undifferentiated temporal populations to full allochronic species. Thus, band-rumped storm-petrels encompass multiple cryptic species, with non-geographic barriers potentially comprising strong barriers to gene flow., (Copyright © 2019 Elsevier Inc. All rights reserved.)
- Published
- 2019
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