Abstract
Investigations of the genetic structure of populations over the entire range of a species yield valuable information about connectivity among populations. Seabirds are an intriguing taxon in this regard because they move extensively when not breeding, facilitating intermixing of populations, but breed consistently on the same isolated islands, restricting gene flow among populations. The degree of genetic structuring of populations varies extensively among seabird species but they have been understudied in their tropical ranges. Here, we address this across a broad spatial scale by using microsatellite and mitochondrial data to explore the population connectivity of 13 breeding populations representing the six subspecies of the white‐tailed tropicbird (Phaethon lepturus) in the Atlantic, Indian, and Pacific Oceans. Our primary aim was to identify appropriate conservation units for this little known species. Three morphometric characters were also examined in the subspecies. We found a clear pattern of population structuring with four genetic groups. The most ancient and the most isolated group was in the northwestern Atlantic Ocean. The South Atlantic populations and South Mozambique Channel population on Europa were genetically isolated and may have had a common ancestor. Birds from the Indo‐Pacific region showed unclear and weak genetic differentiation. This structuring was most well defined from nuclear and mtDNA markers but was less well resolved by morphological data. The validity of classifying white‐tailed tropicbirds into six distinct subspecies is discussed in light of our new findings. From a conservation standpoint our results highlight that the three most threatened conservation units for this species are the two subspecies of the tropical North and South Atlantic Oceans and that of Europa Island in the Indian Ocean.
Highlights
Distributed species consist of distinct populations that are variously connected to each other though current and historic overlaps in ranges, resulting in different patterns of genetic structuring at global and local scales (Avise & Ball, 1990; Frankham, Ballou, & Briscoe, 2004)
The present study has provided data on genetic and morphological differences among putative white-tailed tropicbird subspecies
Our results showed clear morphological and genetic differentiation in some subspecies such as P. l. catesbyi, represented by the Bermuda population, in which birds are larger and display a genetic clade potentially isolated from the Middle Pleistocene
Summary
Distributed species consist of distinct populations that are variously connected to each other though current and historic overlaps in ranges, resulting in different patterns of genetic structuring at global and local scales (Avise & Ball, 1990; Frankham, Ballou, & Briscoe, 2004). Of the three species of tropicbird (Phaethontidae), the whitetailed tropicbird Phaethon lepturus is the most common (Lee & Walsh-McGehee, 1998) This pantropical seabird is widely distributed in the Atlantic, Pacific, and Indian Oceans between 30°N and 30°S (del Hoyo, Elliott, Sargatal, & Christie, 1992). The aim of the present study was to explore genetic diversity and population genetic structuring across the entire range of the white-tailed tropicbird and to infer genetic relationships among populations Both microsatellite and mtDNA markers were used to investigate genetic structure of 13 breeding populations of the Atlantic, Indian, and Pacific Oceans, including birds from all of the six recognized subspecies. Our findings allow us to discuss subspecies validity and appropriate units for effective conservation strategies
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