2 research outputs found

    Perturbation drives changing metapopulation dynamics in a top marine predator

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    Funding: O.E.G. was supported by the Marine Alliance for Science and Technology for Scotland, funded by the Scottish Funding Council (grant no. HR09011). E.L.C. was supported by a Newton Fellowship (Royal Society of London), Marie Curie Fellowship (EU Horizon2020) and a Rutherford Discovery Fellowship (Royal Society of New Zealand). A.J.H. and D.J.F.R. were supportedby NERC (grant no. SMRU 10/001).Metapopulation theory assumes a balance between local decays/extinctions and local growth/new colonisations. Here we investigate whether recent population declines across part of the UK harbour seal range represent normal metapopulation dynamics or are indicative of perturbations potentially threatening the metapopulation viability, using 20 years of population trends, location tracking data (n = 380), and UK-wide, multi-generational population genetic data (n = 269). First, we use microsatellite data to show that two genetic groups previously identified are distinct metapopulations: northern and southern. Then, we characterize the northern metapopulation dynamics in two different periods, before and after the start of regional declines (pre-/peri-perturbation). We identify source-sink dynamics across the northern metapopulation, with two putative source populations apparently supporting three likely sink populations, and a recent metapopulation-wide disruption of migration coincident with the perturbation. The northern metapopulation appears to be in decay, highlighting that changes in local populations can lead to radical alterations in the overall metapopulation's persistence and dynamics.PostprintPeer reviewe

    DNA in the deep : comparative molecular ecology for the conservation of beaked whales

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    Beaked whales (Ziphiidae) are an incredibly diverse and elusive family, and behavioural responses linked to certain anthropogenic sounds have resulted in mass stranding events. The substantial knowledge gaps regarding abundance and population structure for most ziphiids highlight that more information is required for their effective management and conservation. To this end, next-generation DNA sequencing was used to investigate beaked whale ecology and evolution, showcasing the utility of reduced representation sequencing in non-model organisms. Single nucleotide polymorphisms (SNPs) were derived using double-digest restriction site associated DNA sequencing (ddRAD) from a newly established international beaked whale tissue and DNA archive. Globally, hierarchical genetic structure and diversity of cosmopolitan Cuvierā€™s and Blainvilleā€™s beaked whales (Ziphius cavirostris and Mesoplodon densirostris, ā€œCuvierā€™sā€ and ā€œBlainvilleā€™sā€) were investigated. Biogeographic barriers and differing life and evolutionary histories have contributed to the observed patterns, and the findings are evaluated in the context of management units for conservation. Regionally, population structure and demographic history were characterised for four North Atlantic beaked whales: Cuvierā€™s, Blainvilleā€™s, Sowerbyā€™s beaked whales (M. bidens) and northern bottlenose whales (Hyperoodon ampullatus). Fluctuations in effective population size (Ne) were likely responses to climatic change. With these findings, potential responses of beaked whale populations to future climate change are discussed. Locally, genetic Essential Biodiversity Variables (EBVs) were calculated for paired ā€˜disturbedā€™ and ā€˜semi-pristineā€™ populations of Cuvierā€™s and Blainvilleā€™s in three well studied populations: the Bahamas, Canary Islands and Mediterranean Sea (Cuvierā€™s only). At least one ā€˜disturbedā€™ site was found in each region with reduced genetic variation and at risk of genetic erosion. In summary, genetic population structure has been identified in many ziphiids. These populations have different levels of genetic diversity, different demographic responses to historic climatic change and it is likely that they have different abilities to adapt to future anthropogenic and climate impacts and should be managed on a population level
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