Your search keyword '"Clucas, Gemma"' showing total 4 results

1. Limited genetic differentiation among chinstrap penguin (Pygoscelis antarctica) colonies in the Scotia Arc and Western Antarctic Peninsula

Author

Freer, Jennifer J., Mable, Barbara K., Clucas, Gemma, Rogers, Alex D., Polito, Michael J., Dunn, Michael, Naveen, Ron, Levy, Hila, and Hart, Tom

Published

2015

2. Novel signals of adaptive genetic variation in northwestern Atlantic cod revealed by whole‐genome sequencing.

Author

Clucas, Gemma V., Lou, R. Nicolas, Therkildsen, Nina O., and Kovach, Adrienne I.

Subjects

*ATLANTIC cod, *MORPHOLOGY, *CHROMOSOME inversions, *HEAT shock proteins, *HAPLOTYPES, *FISHERY management, *POPULATION genetics

Abstract

Selection can create complex patterns of adaptive differentiation among populations in the wild that may be relevant to management. Atlantic cod in the Northwest Atlantic are at a fraction of their historical abundance and a lack of recovery within the Gulf of Maine has created concern regarding the misalignment of fisheries management structures with biological population structure. To address this and investigate genome‐wide patterns of variation, we used low‐coverage sequencing to perform a region‐wide, whole‐genome analysis of fine‐scale population structure. We sequenced 306 individuals from 20 sampling locations in U.S. and Canadian waters, including the major spawning aggregations in the Gulf of Maine in addition to spawning aggregations from Georges Bank, southern New England, the eastern Scotian Shelf, and St. Pierre Bank. With genotype likelihoods estimated at almost 11 million loci, we found large differences in haplotype frequencies of previously described chromosomal inversions between Canadian and U.S. sampling locations and also among U.S. sampling locations. Our whole‐genome resolution also revealed novel outlier peaks, some of which showed significant genetic differentiation among sampling locations. Comparisons between allochronic winter‐ and spring‐spawning populations revealed highly elevated relative (FST) and absolute (dxy) genetic differentiation near genes involved in reproduction, particularly genes associated with the brain‐pituitary‐gonadal axis, which likely control timing of spawning, contributing to prezygotic isolation. We also found genetic differentiation associated with heat shock proteins and other genes of functional relevance, with complex patterns that may point to multifaceted selection pressures and local adaptation among spawning populations. We provide a high‐resolution picture of U.S. Atlantic cod population structure, revealing greater complexity than is currently recognized in management. Our genome‐scan approach likely underestimates the full suite of adaptive differentiation among sampling locations. Nevertheless, it should inform the revision of stock boundaries to preserve adaptive genetic diversity and evolutionary potential of cod populations. [ABSTRACT FROM AUTHOR]

Published

2019

3. Comparative population genomics reveals key barriers to dispersal in Southern Ocean penguins.

Author

Clucas, Gemma V., Younger, Jane L., Kao, Damian, Emmerson, Louise, Southwell, Colin, Wienecke, Barbara, Rogers, Alex D., Bost, Charles‐André, Miller, Gary D., Polito, Michael J., Lelliott, Patrick, Handley, Jonathan, Crofts, Sarah, Phillips, Richard A., Dunn, Michael J., Miller, Karen J., and Hart, Tom

Subjects

*POPULATION genetics, *DISPERSAL (Ecology), *PENGUINS, *SPECIES distribution, *MARINE species diversity

Abstract

The mechanisms that determine patterns of species dispersal are important factors in the production and maintenance of biodiversity. Understanding these mechanisms helps to forecast the responses of species to environmental change. Here, we used a comparative framework and genomewide data obtained through RAD‐Seq to compare the patterns of connectivity among breeding colonies for five penguin species with shared ancestry, overlapping distributions and differing ecological niches, allowing an examination of the intrinsic and extrinsic barriers governing dispersal patterns. Our findings show that at‐sea range and oceanography underlie patterns of dispersal in these penguins. The pelagic niche of emperor (Aptenodytes forsteri), king (A. patagonicus), Adélie (Pygoscelis adeliae) and chinstrap (P. antarctica) penguins facilitates gene flow over thousands of kilometres. In contrast, the coastal niche of gentoo penguins (P. papua) limits dispersal, resulting in population divergences. Oceanographic fronts also act as dispersal barriers to some extent. We recommend that forecasts of extinction risk incorporate dispersal and that management units are defined by at‐sea range and oceanography in species lacking genetic data. [ABSTRACT FROM AUTHOR]

Published

2018

4. Population structure and phylogeography of the Gentoo Penguin ( Pygoscelis papua) across the Scotia Arc.

Author

Levy, Hila, Clucas, Gemma V., Rogers, Alex D., Leaché, Adam D., Ciborowski, Kate L., Polito, Michael J., Lynch, Heather J., Dunn, Michael J., and Hart, Tom

Subjects

*GENTOO penguin, *EFFECT of climate on animal behavior, *PHYLOGEOGRAPHY, *COLONIZATION (Ecology), *SEA bird behavior, *SEA bird ecology, *MICROSATELLITE repeats

Abstract

Climate change, fisheries' pressure on penguin prey, and direct human disturbance of wildlife have all been implicated in causing large shifts in the abundance and distribution of penguins in the Southern Ocean. Without mark-recapture studies, understanding how colonies form and, by extension, how ranges shift is challenging. Genetic studies, particularly focused on newly established colonies, provide a snapshot of colonization and can reveal the extent to which shifts in abundance and occupancy result from changes in demographic rates (e.g., reproduction and survival) or migration among suitable patches of habitat. Here, we describe the population structure of a colonial seabird breeding across a large latitudinal range in the Southern Ocean. Using multilocus microsatellite genotype data from 510 Gentoo penguin ( Pygoscelis papua) individuals from 14 colonies along the Scotia Arc and Antarctic Peninsula, together with mitochondrial DNA data, we find strong genetic differentiation between colonies north and south of the Polar Front, that coincides geographically with the taxonomic boundary separating the subspecies P. p. papua and P. p. ellsworthii. Using a discrete Bayesian phylogeographic approach, we show that southern Gentoos expanded from a possible glacial refuge in the center of their current range, colonizing regions to the north and south through rare, long-distance dispersal. Our findings show that this dispersal is important for new colony foundation and range expansion in a seabird species that ordinarily exhibits high levels of natal philopatry, though persistent oceanographic features serve as barriers to movement. [ABSTRACT FROM AUTHOR]

Published

2016