Abstract
Caribou and reindeer migrations are the tip of the iceberg when one considers migration among the 70 species of Arctic terrestrial mammals. About 26% of species indeed have migratory individuals, while 33% are non-migratory and 41% are data deficient. Such figures demonstrate the need to both better document and better understand seasonal movements in these vertebrates. Whereas spatiotemporal variations in resources are key drivers of Arctic terrestrial mammal migrations, the changes of water phase around 0°C, from liquid to solid and vice versa, have considerable impacts given that liquid water, snow, and ice differ so strongly in their physical properties. We explore how the interplay between resources and water phase shape Arctic terrestrial mammal migrations, demonstrate that a rich set of research questions emerges from this interaction, and introduce new concepts such as the micro-migrations of small mammals. We also list key questions about the migrations of Arctic terrestrial mammals, with emphasis on the impacts of climate change. We conclude by arguing that the strong exposure of the Arctic to climate change, combined with the quick development of biologging techniques, rapidly increase both the need and the capacity to enhance our knowledge of migration in Arctic terrestrial mammals.
References
[1] CAFF, Arctic Biodiversity Assessment. Status and trends in Arctic biodiversity, Conservation of Arctic Flora and Fauna, Akureyri, Iceland, 2013Search in Google Scholar
[2] Gaston A.J., Gavrilo M., Eberl C., Ice bridging as a dispersal mechanism for Arctic terrestrial vertebrates and the possible consequences of reduced sea ice cover, Biodiversity, 2012, 13, 182–19010.1080/14888386.2012.719177Search in Google Scholar
[3] Reid D.G., Berteaux D., Laidre K.L., (Lead authors), and 32 Contributing Authors, Chapter 3 - Mammals, In: Arctic Biodiversity Assessment: Status and Trends in Arctic Biodiversity, Conservation of Arctic Flora and Fauna (CAAF), Arctic Council, Iceland, 2013, 78–141Search in Google Scholar
[4] Dickman A.J., Macdonald E.A., Macdonald D.W., Biodiversity Conservation and Poverty Traps Special Feature: A review of financial instruments to pay for predator conservation and encourage human-carnivore coexistence, Proc. Natl. Acad. Sci., 2011, 108, 13937–1394410.1073/pnas.1012972108Search in Google Scholar PubMed PubMed Central
[5] Berteaux D., Gauthier G., Dominé F., Ims R.A., Lamoureux S.F., Lévesque E., et al., Effects of changing permafrost and snow conditions on tundra wildlife: critical places and times, Arct. Sci., 2017, 3, 65–9010.1139/as-2016-0023Search in Google Scholar
[6] Lai S., Bêty J., Berteaux D., Spatio–temporal hotspots of satellite–tracked arctic foxes reveal a large detection range in a mammalian predator, Mov. Ecol., 2015, 3, 3710.1186/s40462-015-0065-2Search in Google Scholar PubMed PubMed Central
[7] Poole K.G., Gunn A., Patterson B.R., Dumond M., Sea ice and migration of the Dolphin and Union caribou herd in the Canadian Arctic: an uncertain future, Arctic, 2010, 63, 414–42810.14430/arctic3331Search in Google Scholar
[8] Abrahms B., Seidel D.P., Dougherty E., Hazen E.L., Bograd S.J., Wilson A.M., et al., Suite of simple metrics reveals common movement syndromes across vertebrate taxa, Mov. Ecol., 2017, 510.1186/s40462-017-0104-2Search in Google Scholar PubMed PubMed Central
[9] Gnanadesikan G.E., Pearse W.D., Shaw A.K., Evolution of mammalian migrations for refuge, breeding, and food, Ecol. Evol., 2017, 7, 5891–590010.1002/ece3.3120Search in Google Scholar PubMed PubMed Central
[10] Meltofte A., Barry T., Berteaux D., et al, Arctic Biodiversity Assessment: Status and Trends in Arctic Biodiversity – Full Report, Conservation of Arctic Flora and Fauna (CAAF), Arctic Council, Iceland, 2013Search in Google Scholar
[11] Walker D.A., Raynolds M.K., Daniëls F.J.A., Einarsson E., Elvebakk A., Gould W.A., et al., The Circumpolar Arctic vegetation map, J. Veg. Sci., 2005, 16, 267–28210.1111/j.1654-1103.2005.tb02365.xSearch in Google Scholar
[12] Fancy S.G., Pank L.F., Whitten K.R., Regelin W.L., Seasonal movements of caribou in arctic Alaska as determined by satellite, Can. J. Zool., 1989, 67, 644–65010.1139/z89-093Search in Google Scholar
[13] Gurarie E., Hebblewhite M., Joly K., Kelly A.P., Adamczewski J., Davidson S.C., et al., Tactical departures and strategic arrivals: Divergent effects of climate and weather on caribou spring migrations, Ecosphere, 2019, 10, e0297110.1002/ecs2.2971Search in Google Scholar
[14] Whitman J.S., Ballard W.B., Gardner C.L., Home range and habitat use by wolverines in Southcentral Alaska, J. Wildl. Manag., 1986, 50, 460–46310.2307/3801105Search in Google Scholar
[15] Landa A., Strand O., Linnell J.D.C., Skogland T., Home-range sizes and altitude selection for arctic foxes and wolverines in an alpine environment, Can. J. Zool., 1998, 76, 448–45710.1139/z97-209Search in Google Scholar
[16] Walton L.R., Cluff H.D., Paquet P.C., Ramsay M.A., Movement patterns of barren-ground wolves in the Central Canadian Arctic, J. Mammal., 2001, 82, 867–87610.1093/jmammal/82.3.867Search in Google Scholar
[17] Lai S., Bêty J., Berteaux D., Movement tactics of a mobile predator in a meta-ecosystem with fluctuating resources: the arctic fox in the High Arctic, Oikos, 2017, 126, 937-94710.1111/oik.03948Search in Google Scholar
[18] Tast J., Will the Norwegian lemming become endangered if climate becomes warmer?, Arct. Alp. Res., 1991, 23, 53–6010.2307/1551437Search in Google Scholar
[19] Henttonen H., Kaikusalo A., Lemming movements, Biol. Lemmings, 1993, 157–186Search in Google Scholar
[20] Duchesne D., Gauthier G., Berteaux D., Habitat selection, reproduction and predation of wintering lemmings in the Arctic, Oecologia, 2011, 167, 967–98010.1007/s00442-011-2045-6Search in Google Scholar PubMed
[21] Avgar T., Street G., Fryxell J.M., On the adaptive benefits of mammal migration, Can. J. Zool., 2014, 92, 481–49010.1139/cjz-2013-0076Search in Google Scholar
[22] Berg J.E., Hebblewhite M., St. Clair C.C., Merrill E.H., Prevalence and mechanisms of partial migration in ungulates, Front. Ecol. Evol., 2019, 7, 32510.3389/fevo.2019.00325Search in Google Scholar
[23] Singh N.J., Börger L., Dettki H., Bunnefeld N., Ericsson G., From migration to nomadism: movement variability in a northern ungulate across its latitudinal range, Ecol. Appl., 2012, 22, 2007–202010.1890/12-0245.1Search in Google Scholar PubMed
[24] Loe L.E., Hansen B.B., Stien A., D. Albon S., Bischof R., Carlsson A., et al., Behavioral buffering of extreme weather events in a high-Arctic herbivore, Ecosphere, 2016, 7, e0137410.1002/ecs2.1374Search in Google Scholar
[25] Lack D., The significance of migration, In: The Natural Regulation of Animal Numbers, Oxford University Press, Oxford, 1954, 243–254Search in Google Scholar
[26] MacArthur R.H., On the breeding distribution pattern of North American migrant birds, The Auk, 1959, 76, 318–32510.2307/4081809Search in Google Scholar
[27] Alerstam T., Hedenström A., Åkesson S., Long-distance migration: evolution and determinants, Oikos, 2003, 103, 247-26010.1034/j.1600-0706.2003.12559.xSearch in Google Scholar
[28] Holt R.D., Fryxell J.M., Theoretical reflections on the evolution of migration, In: Animal Migration, E.J. Milner-Gulland, J.M. Fryxell, and A.R.E. Sinclair, Oxford University Press, New York, 2011, 17–3210.1093/acprof:oso/9780199568994.003.0003Search in Google Scholar
[29] Fryxell J.M., Holt R.D., Environmental change and the evolution of migration, Ecology, 2013, 94, 1274–127910.1890/12-0668.1Search in Google Scholar PubMed
[30] Nathan R., Getz W.M., Revilla E., Holyoak M., Kadmon R., Saltz D., et al., A movement ecology paradigm for unifying organismal movement research, Proc. Natl. Acad. Sci., 2008, 105, 19052–1905910.1073/pnas.0800375105Search in Google Scholar PubMed PubMed Central
[31] Boelman N.T., Liston G.E., Gurarie E., Meddens A.J.H., Mahoney P.J., Kirchner P.B., et al., Integrating snow science and wildlife ecology in Arctic-boreal North America, Environ. Res. Lett., 2019, 14, 01040110.1088/1748-9326/aaeec1Search in Google Scholar
[32] Slatyer R.A., Umbers K.D.L., Arnold P.A., Ecological responses to variation in seasonal snow cover, Conserv. Biol., 202110.1111/cobi.13727Search in Google Scholar PubMed
[33] Reid D.G., Bilodeau F., Krebs C.J., Gauthier G., Kenney A.J., Gilbert B.S., et al., Lemming winter habitat choice: a snow-fencing experiment, Oecologia, 2012, 168, 935–94610.1007/s00442-011-2167-xSearch in Google Scholar PubMed
[34] Laforge M.P., Bonar M., Vander Wal E., Tracking snowmelt to jump the green wave: phenological drivers of migration in a northern ungulate, Ecology, 2021, 102, e0326810.1002/ecy.3268Search in Google Scholar PubMed
[35] Leblond M., St-Laurent M.-H., Côté S.D., Caribou, water, and ice - fine-scale movements of a migratory arctic ungulate in the context of climate change, Mov. Ecol., 2016, 4, article 1410.1186/s40462-016-0079-4Search in Google Scholar PubMed PubMed Central
[36] Poirier M., Gauthier G., Domine F., What guides lemmings movements through the snowpack?, J. Mammal., 2019, 100, 1416–142610.1093/jmammal/gyz129Search in Google Scholar
[37] Vaughan D.G., Comiso J.C., Allison I., Carrasco J., Kaser G., Kwok R., et al., Observations: cryosphere, Clim. Change 2013 Phys. Sci. Basis Contrib. Work. Group Fifth Assess. Rep. Intergov. Panel Clim. Change Stock. TF Qin G-K Plattner M Tignor SK Allen J Boschung Nauels Xia V Bex PM Midgley Eds Camb. Univ. Press Camb. U. K. N. Y. NY USA, 2013, 317–38210.1017/CBO9781107415324.012Search in Google Scholar
[38] Post E., Forchhammer M.C., Bret-Harte M.S., Callaghan T.V., Christensen T.R., Elberling B., et al., Ecological dynamics across the Arctic associated with recent climate change, Science, 2009, 325, 1355–135810.1126/science.1173113Search in Google Scholar PubMed
[39] Hansen B.B., Aanes R., Herfindal I., Kohler J., Sæther B.-E., Climate, icing, and wild arctic reindeer: past relationships and future prospects, Ecology, 2011, 92, 1917-192310.1890/11-0095.1Search in Google Scholar PubMed
[40] Gauthier G., Bêty J., Cadieux M.C., Legagneux P., Doiron M., Chevallier C., et al., Long-term monitoring at multiple trophic levels suggests heterogeneity in responses to climate change in the Canadian Arctic tundra, Phil Trans R Soc B, 2013, 368, 2012048210.1098/rstb.2012.0482Search in Google Scholar PubMed PubMed Central
[41] Berger J., The last mile: How to sustain long-distance migration in mammals, Conserv. Biol., 2004, 18, 320–33110.1111/j.1523-1739.2004.00548.xSearch in Google Scholar
[42] Kauffman M.J., Cagnacci F., Chamaillé-Jammes S., Hebblewhite M., Hopcraft J.G.C., Merkle J.A., et al., Mapping out a future for ungulate migrations, Science, 2021, 372, 566–56910.1126/science.abf0998Search in Google Scholar PubMed
[43] Berteaux D., Humphries M.M., Krebs C.J., Lima M., McAdam A.G., Pettorelli N., et al., Constraints to projecting the effects of climate change on mammals, Clim. Res., 2006, 32, 151–15810.3354/cr032151Search in Google Scholar
[44] Davidson S.C., Bohrer G., Gurarie E., LaPoint S., Boelman N.T., Eitel J.U.H., et al., Ecological insights from three decades of animal movement tracking across a changing Arctic, Science, 2020, 370, 712–715Search in Google Scholar
[45] Morelle K., Lehaire F., Lejeune P., Is wild boar heading towards movement ecology? A review of trends and gaps, Wildl. Biol., 2014, 20, 196–20510.2981/wlb.00017Search in Google Scholar
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