Conservation status of polar bears (<i>Ursus maritimus</i>) in relation to projected sea-ice declines

Regehr, Eric V.; Laidre, Kristin L.; Akçakaya, H. Reşi̇t; Amstrup, Steven C.; Atwood, Todd C.; Lunn, Nicholas J.; Obbard, Martyn E.; Stern, Harry L.; Thiemann, Gregory W.; Wiig, Øystein

doi:10.1098/rsbl.2016.0556

Cited by 121 publications

(95 citation statements)

References 22 publications

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“…Genetic variation in polar bears is relatively low, and genetics is a relatively insensitive means of identifying, defining, or detecting change in subpopulation structure, especially when compared to individual‐based telemetry and tag recoveries. Time‐lag effects in genetic composition are influenced by the relatively long generation length for polar bears (~11.5 years; Regehr et al., 2016), and several generations may be needed to demonstrate increased genetic isolation as a consequence of climate‐induced range contraction.…”

Section: Discussionmentioning

confidence: 99%

Range contraction and increasing isolation of a polar bear subpopulation in an era of sea‐ice loss

Laidre

Born

Atkinson

et al. 2018

Ecology and Evolution

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Climate change is expected to result in range shifts and habitat fragmentation for many species. In the Arctic, loss of sea ice will reduce barriers to dispersal or eliminate movement corridors, resulting in increased connectivity or geographic isolation with sweeping implications for conservation. We used satellite telemetry, data from individually marked animals (research and harvest), and microsatellite genetic data to examine changes in geographic range, emigration, and interpopulation connectivity of the Baffin Bay (BB) polar bear (Ursus maritimus) subpopulation over a 25‐year period of sea‐ice loss. Satellite telemetry collected from n = 43 (1991–1995) and 38 (2009–2015) adult females revealed a significant contraction in subpopulation range size (95% bivariate normal kernel range) in most months and seasons, with the most marked reduction being a 70% decline in summer from 716,000 km2 (SE 58,000) to 211,000 km2 (SE 23,000) (p < .001). Between the 1990s and 2000s, there was a significant shift northward during the on‐ice seasons (2.6° shift in winter median latitude, 1.1° shift in spring median latitude) and a significant range contraction in the ice‐free summers. Bears in the 2000s were less likely to leave BB, with significant reductions in the numbers of bears moving into Davis Strait (DS) in winter and Lancaster Sound (LS) in summer. Harvest recoveries suggested both short and long‐term fidelity to BB remained high over both periods (83–99% of marked bears remained in BB). Genetic analyses using eight polymorphic microsatellites confirmed a previously documented differentiation between BB, DS, and LS; yet weakly differentiated BB from Kane Basin (KB) for the first time. Our results provide the first multiple lines of evidence for an increasingly geographically and functionally isolated subpopulation of polar bears in the context of long‐term sea‐ice loss. This may be indicative of future patterns for other polar bear subpopulations under climate change.

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Section: Discussionmentioning

confidence: 99%

Range contraction and increasing isolation of a polar bear subpopulation in an era of sea‐ice loss

Laidre

Born

Atkinson

et al. 2018

Ecology and Evolution

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“…Ice-obligate species that use ice as a platform for raising young (e.g., ringed seal pupping lairs) (NOAA, 2012) or for hunting (e.g., for polar bears, Ursus maritimus), or whose prey species are closely or directly linked to ice [e.g., Antarctic fur seals (Arctocephalus gazella) (Forcada et al, 2008)] may be particularly vulnerable to declines in the extent of seasonal and multi-year ice. While some forecasting work has already been done for polar bears, ice seals, and walruses (Odobenus rosmarus) in the context of endangered species determinations under the ESA (Jay et al, 2011;Regehr et al, 2016), additional work is required to develop and refine models for species residing or occurring seasonally in high latitudes.…”

Section: Priority Actions and Exemplar Speciesmentioning

confidence: 99%

Projecting Marine Mammal Distribution in a Changing Climate

et al. 2017

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Climate-related shifts in marine mammal range and distribution have been observed in some populations; however, the nature and magnitude of future responses are uncertain in novel environments projected under climate change. This poses a challenge for agencies charged with management and conservation of these species. Specialized diets, restricted ranges, or reliance on specific substrates or sites (e.g., for pupping) make many marine mammal populations particularly vulnerable to climate change. High-latitude, predominantly ice-obligate, species have experienced some of the largest changes in habitat and distribution and these are expected to continue. Efforts to predict and project marine mammal distributions to date have emphasized data-driven statistical habitat models. These have proven successful for short time-scale (e.g., seasonal) management activities, but confidence that such relationships will hold for multi-decade projections and novel environments is limited. Recent advances in mechanistic modeling of marine mammals (i.e., models that rely on robust physiological and ecological principles expected to hold under climate change) may address this limitation. The success of such approaches rests on continued advances in marine mammal ecology, behavior, and physiology together with improved regional climate projections. The broad scope of this challenge suggests initial priorities be placed on vulnerable species or populations (those already experiencing declines or projected to undergo ecological shifts resulting from climate Silber et al.Projecting Marine Mammal Distributions changes that are consistent across climate projections) and species or populations for which ample data already exist (with the hope that these may inform climate change sensitivities in less well observed species or populations elsewhere). The sustained monitoring networks, novel observations, and modeling advances required to more confidently project marine mammal distributions in a changing climate will ultimately benefit management decisions across time-scales, further promoting the resilience of marine mammal populations.

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“…The ice-free season within the SH subpopulation boundaries increased by about 30 days from 1980 to 2012 (Obbard et al 2016). Concurrently, body condition declined in all age and sex classes, though the decline was less for cubs than for other social classes.…”

Section: Southern Hudson Bay (Sh)mentioning

confidence: 97%

“…There is uncertainty about the discreteness of the less studied subpopulations, particularly in the Russian Arctic and neighbouring areas, due to a lack of capture and genetic data. The total number of polar bears worldwide is estimated to be 26,000 (95% CI=22,000-31,000; Regehr et al 2016). The following subpopulation summaries are the result of discussions of the 18 th Working Meeting of the IUCN/SSC Polar Bear Specialist Group held in Anchorage, Alaska, 7-11 June, 2016.…”

Section: Status and Distributionmentioning

confidence: 99%

Polar bears: proceedings of the 18th working meeting of the IUCN/SSC Polar Bear Specialist Group, Anchorage, Alaska, 7-11 June 2016

Durner¹,

Laidre²,

York³

2018

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Conservation status of polar bears (Ursus maritimus) in relation to projected sea-ice declines

Cited by 121 publications

References 22 publications

Range contraction and increasing isolation of a polar bear subpopulation in an era of sea‐ice loss

Range contraction and increasing isolation of a polar bear subpopulation in an era of sea‐ice loss

Projecting Marine Mammal Distribution in a Changing Climate

Polar bears: proceedings of the 18th working meeting of the IUCN/SSC Polar Bear Specialist Group, Anchorage, Alaska, 7-11 June 2016

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