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The effects of climate change on avian migratory patterns and the dispersal of commercial poultry diseases in Canada - Part I

Published online by Cambridge University Press:  25 February 2013

C.D. PATTERSON*
Affiliation:
Department of Population Medicine, Ontario Veterinary College, University of Guelph, 50 Stone Rd E, Guelph ON, N1G 2W1, Canada
M.T. GUERIN
Affiliation:
Department of Population Medicine, Ontario Veterinary College, University of Guelph, 50 Stone Rd E, Guelph ON, N1G 2W1, Canada
*
Corresponding author: [email protected]
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Abstract

Many birds are able to modify migratory strategies when selection favours an adjustment. Climate change is provoking a range of responses from avian migrants and affecting their relationship with other biological systems. This is the first part of a two-part review that aims to summarise the available literature on the impact of climate change on migratory birds and how those changes will subsequently affect the spread of poultry diseases. Part I reviews the effects of climate change on the ecology of avian migrants; it was found that climate change has evoked several changes in birds, including changes in avian phenology, poleward shifts in avian distributions, modification of migratory distances, direction and activity, and alterations to movement patterns and destinations. Based on predictions for future climatic trends, climate change will continue to favour changes in avian migratory strategies and behaviour, emphasising the importance of investigating how these adjustments will affect the relationship between avian migrants and bird-borne pathogens.

Type
Reviews
Copyright
Copyright © World's Poultry Science Association 2013

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References

ABLE, K.P. and BELTHOFF, J.R. (1998) Rapid ‘evolution’ of migratory behaviour in the introduced house finch of eastern North America. Proceedings of the Royal Society of London. Series B: Biological Sciences 265: 2063-2071.Google Scholar
ALERSTAM, T. and HEDENSTROM, A. (1998) The Development of Bird Migration Theory. Journal of Avian Biology 29: 343-369.Google Scholar
AUSTIN, G.E. and REHFISCH, M.M. (2005) Shifting nonbreeding distributions of migratory fauna in relation to climatic change. Global Change Biology 11: 31-38.Google Scholar
BAIRLEIN, F. and HÜPPOP, O. (2004) Migratory Fuelling and Global Climate Change, in: MOLLER, A., FIEDLER,AND, W. & BERTHOLD, P. (Eds) Advances in Ecological Research, Vol. Volume 35, pp. 33-47 ( Academic Press).Google Scholar
BATES, B.C., KUNDZEWICZ, Z.W., WU, S. and PALUTIKOF, J.P. (2008) Climate Change and Water (Geneva, Switzerland, IPCC Secretariat).Google Scholar
BATT, B.D.J., ANDERSON, M.G., ANDERSON, C.D. and CASWELL, F.D. (1989) The use of prairie potholes by North American ducks, in: VALK, A.V.D. (Ed.) Northern prairie wetlands, pp. 204-227 (Ames, IA, Iowa State University Press).Google Scholar
BAUER, S., VAN DINTHER, M., HOGDA, K.A., KLAASSEN, M. and MADSEN, J. (2008) The consequences of climate-driven stop-over sites changes on migration schedules and fitness of Arctic geese. Journal of Animal Ecology 77: 654-660.Google Scholar
BERTHOLD, P. (2001) Bird Migration: A general Survey (Oxford, Oxford University Press).Google Scholar
BERTHOLD, P. (1999) Towards a comprehensive theory of the evolution, control and adaptability of avian migration. Ostrich 70: 1-11.Google Scholar
BERTHOLD, P. (1996) Control of Bird Migration (London, U.K, Chapman and Hall).Google Scholar
BERTHOLD, P. (1990) Genetics of migration, in: GWINNER, E. (Ed.) Bird migration: The physiology and ecophysiology, pp. 429 (Berlin, Germany, Springer).Google Scholar
BERTHOLD, P., WILTSCHKO, W., MILTENBERGER, H. and QUERNER, U. (1990) Genetic transmission of migratory behavior into a nonmigratory bird population. Cellular and Molecular Life Sciences 46: 107-108.Google Scholar
BETHKE, R.W. and NUDDS, T.D. (1995) Effects of Climate Change and Land Use on Duck Abundance in Canadian Prairie-Parklands. Ecological Applications 5: 588-600.Google Scholar
BOTH, C., ARTEMYEV, A.V., BLAAUW, B., COWIE, R.J., DEKHUIJZEN, A.J., EEVA, T., ENEMAR, A., GUSTAFSSON, L., IVANKINA, E.V., JÄRVINEN, A., METCALFE, N.B., NYHOLM, N.E.I., POTTI, J., RAVUSSIN, P.A., SANZ, J.J., SILVERIN, B., SLATER, F.M., SOKOLOV, L.V., TÖRÖK, J., WINKEL, W., WRIGHT, J., ZANG, H. and VISSER, M.E. (2004) Large-scale geographical variation confirms that climate change causes birds to lay earlier. Proceedings of the Royal Society of London. Series B: Biological Sciences 271: 1657-1662.Google Scholar
BOTH, C., VAN TURNHOUT, C.A.M., BIJLSMA, R.G., SIEPEL, H., VAN STRIEN, A.J. and FOPPEN, R.P.B. (2010) Avian population consequences of climate change are most severe for long-distance migrants in seasonal habitats. Proceedings of the Royal Society B: Biological Sciences 277: 1259-1266.Google Scholar
BOTH, C. and VISSER, M.E. (2001) Adjustment to climate change is constrained by arrival date in a long-distance migrant bird. Nature 411: 296-298.Google Scholar
BRADSHAW, W.E. and HOLZAPFEL, C.M. (2008) Genetic response to rapid climate change: it's seasonal timing that matters. Molecular ecology 17: 157-166.Google Scholar
BROMMER, J.E. (2004) The range margins of northern birds shift polewards. Annales Zoologici Fennici 41: 391-397.Google Scholar
BROWN, J.L., LI, S.H. and BHAGABATI, N. (1999) Long-term trend toward earlier breeding in an American bird: A response to global warming?. Proceedings of the National Academy of Sciences of the United States of America 96: 5565-5569.Google Scholar
BUTLER, C.J. (2003) The disproportionate effect of global warming on the arrival dates of short-distance migratory birds in North America. Ibis 145: 484-495.Google Scholar
CHAMBERS, L.E., HUGHES, L. and WESTON, M.A. (2005) Climate change and its impact on Australia's avifauna. Emu 105: 1-20.Google Scholar
CITY OF BANKSTOWN, (2004) management plan for Australian white ibis (Threskiornis molucca) in the Bankstown local government area (Bankstown, Australia, City of Bankstown).Google Scholar
COTTON, P.A. (2003) Avian migration phenology and global climate change. Proceedings of the National Academy of Sciences of the United States of America 100: 12219-12222.CrossRefGoogle ScholarPubMed
CRICK, H.Q.P. (2004) The impact of climate change on birds. Ibis 146: 48-56.Google Scholar
CRICK, H.Q.P. and SPARKS, T.H. (1999) Climate change related to egg-laying trends. Nature 399: 423-424.CrossRefGoogle Scholar
DAVIS, M.B., SHAW, R.G. and ETTERSON, J.R. (2005) Evolutionary Responses to Changing Climate. Ecology 86: 1704-1714.Google Scholar
DESANTE, D.F. (1973) An analysis of the fall occurrences and nocturnal orientations of vagrant wood warblers (Parulidae) in California (Unpublished Ph.D. thesis, Stanford University).Google Scholar
DOSWALD, N., WILLIS, S.G., COLLINGHAM, Y.C., PAIN, D.J., GREEN, R.E. and HUNTLEY, B. (2009) Potential impacts of climatic change on the breeding and non-breeding ranges and migration distance of European Sylvia warblers. Journal of Biogeography 36: 1194-1208.Google Scholar
EPSTEIN, J., MCKEE, J., SHAW, P., HICKS, V., MICALIZZI, G., DASZAK, P., KILPATRICK, A. and KAUFMAN, G. (2006) The Australian White Ibis (Threskiornis molucca) as a Reservoir of Zoonotic and Livestock Pathogens. EcoHealth 3: 290-298.Google Scholar
FIEDLER, W. (2003) Recent changes in migratory behaviour of birds: a compilation of field observations and ringing data, in: BERTHOLD, P., GWINNER, E. & SONNENSCHEIN, E. (Eds) Avian Migration, pp. 21-38 (Berlin, Springer).Google Scholar
FORCHHAMMER, M.C., POST, E. and STENSETH, N.C. (1998) Breeding phenology and climate. Nature 391: 29-30.Google Scholar
FRANSSON, T. and STOLT, B.O. (2005) Migration routes of North European reed warblers Acrocephalus scirpaceus 15: 153-160.Google Scholar
GIENAPP, P., TEPLITSKY, C., ALHO, J.S., MILLS, J.A. and MERILÄ, J. (2008) Climate change and evolution: disentangling environmental and genetic responses. Molecular ecology 17: 167-178.CrossRefGoogle ScholarPubMed
HANSEN, J., SATO, M., RUEDY, R., LO, K., LEA, D.W. and MEDINA-ELIZADE, M. (2006) Global temperature change. Proceedings of the National Academy of Sciences 103: 14288-14293.Google Scholar
HELBIG, A. (1991) Inheritance of migratory direction in a bird species: a cross-breeding experiment with SE- and SW-migrating blackcaps (Sylvia atricapilla). Behavioral Ecology and Sociobiology 28: 9-12.Google Scholar
HITCH, A.T. and LEBERG, P.L. (2007) Breeding distributions of north American bird species moving north as a result of climate change. Conservation Biology 21: 534-539.CrossRefGoogle Scholar
HOUGHTON, J. (2005) Global warming. Reports on Progress in Physics 68: 1343-1403.Google Scholar
HUNTLEY, B., COLLINGHAM, Y.C., GREEN, R.E., HILTON, G.M., RAHBEK, C. and WILLIS, S.G. (2006) Potential impacts of climatic change upon geographical distributions of birds. Ibis 148: 8-28.CrossRefGoogle Scholar
IPCC, (2007) Climate change 2007: synthesis report (Intergovernmental Panel on Climate Change).CrossRefGoogle Scholar
JOHNSON, D.H. and GRIER, J.W. (1988) Determinants of Breeding Distributions of Ducks. Wildlife Monographs 100: 3-37.Google Scholar
JOHNSON, W.C., MILLETT, B.V., GILMANOV, T., VOLDSETH, R.A., GUNTENSPERGEN, G.R. and NAUGLE, D.E. (2005) Vulnerability of Northern Prairie Wetlands to Climate Change. Bioscience 55: 863-872.Google Scholar
JONZEN, N., LINDEN, A., ERGON, T., KNUDSEN, E., VIK, J.O., RUBOLINI, D., PIACENTINI, D., BRINCH, C., SPINA, F., KARLSSON, L., STERVANDER, M., ANDERSSON, A., WALDENSTROM, J., LEHIKOINEN, A., EDVARDSEN, E., SOLVANG, R. and STENSETH, N.C. (2006) Rapid Advance of Spring Arrival Dates in Long-Distance Migratory Birds. Science 312: 1959-1961.CrossRefGoogle ScholarPubMed
JOSEPH, L. and STOCKWELL, D. (2000) Temperature-Based Models of the Migration of Swainson's Flycatcher (Myiarchus swainsoni) across South America: A New Use for Museum Specimens of Migratory Birds. Proceedings of the Academy of Natural Sciences of Philadelphia 150: 293-300.Google Scholar
LA SORTE, F.A. and THOMPSON, F.R. (2007) Poleward shifts in winter ranges of North American birds. 88: 1803-1812.Google Scholar
MARTIN, J., FRENCH, K. and MAJOR, R. (2010) Population and breeding trends of an urban coloniser: the Australian white ibis. Wildlife Research 37: 230-239.Google Scholar
MCCLEERY, R.H. and PERRINS, C.M. (1998) Temperature and Egg-Laying Trends. Nature 391: 30-31.Google Scholar
MEHLMAN, D.W., MABEY, S.E., EWERT, D.N., DUNCAN, C., ABEL, B., CIMPRICH, D., SUTTER, R.D. and WOODREY, M. (2005) Conserving Stopover Sites for Forest-Dwelling Migratory Landbirds. The Auk 122: 1281-1290.Google Scholar
MØLLER, A.P. (2008) Climate change and micro-geographic variation in laying date. Oecologia 155: 845-857.Google Scholar
MØLLER, A.P., RUBOLINI, D. and LEHIKOINEN, E. (2008) Populations of migratory bird species that did not show a phenological response to climate change are declining. Proceedings of the National Academy of Sciences 105: 16195-16200.Google Scholar
MUELLER, J.C., PULIDO, F. and KEMPENAERS, B. (2011) Identification of a gene associated with avian migratory behaviour (published online).CrossRefGoogle Scholar
MURKIN, H.R., MURKIN, E.J. and BALL, J.P. (1997) Avian habitat selection and prairie wetland dynamics: a 10-year experiment. Ecological Applications 7: 1144-1159.Google Scholar
PALMER, T.N. and RAISANEN, J. (2002) Quantifying the risk of extreme seasonal precipitation events in a changing climate. Nature 415: 512-514.Google Scholar
PARMESAN, C. and YOHE, G. (2003) A globally coherent fingerprint of climate change impacts across natural systems. Nature 421: 37-42.Google Scholar
POIANI, K.A. and JOHNSON, W.C. (1991) Global Warming and Prairie Wetlands. Bioscience 41: 611-618.Google Scholar
PULIDO, F. (2007) The Genetics and Evolution of Avian Migration. Bioscience 57: 165-174.Google Scholar
PULIDO, F. and BERTHOLD, P. (2010) Current selection for lower migratory activity will drive the evolution of residency in a migratory bird population. Proceedings of the National Academy of Sciences 107: 7341-7346.CrossRefGoogle Scholar
PULIDO, F. and BERTHOLD, P. (2004) Microevolutionary Response to Climatic Change. Advances in Ecological Research 35: 151-183.Google Scholar
RAINIO, K. (2008) Climate Change Effects on Avian Migration. Ph.D Thesis, University of Turku.Google Scholar
REID, J. (2003) What's the link, if any, between recent changes in distribution of Australian birds and greenhouse climate change? (Canberra, Commonwealth of Australia).Google Scholar
ROBINSON, R.A., CRICK, H.Q.P., LEARMONTH, J.A., MACLEAN, I.M.D., THOMAS, C.D., BAIRLEIN, F., FORCHHAMMER, M.C., FRANCIS, C.M., GILL, J.A., GODLEY, B.J., HARWOOD, J., HAYS, G.C., HUNTLEY, B., HUTSON, A.M., PIERCE, G.J., REHFISCH, M.M., SIMS, D.W., SANTOS, B.M., SPARKS, T.H., STROUD, D.A. and VISSER, M.E. (2009) Travelling through a warming world: climate change and migratory species. Endangered Species Research 7: 87-99.Google Scholar
SALEWSKI, V. and BRUDERER, B. (2007) The evolution of bird migration - a synthesis. Naturwissenschaften 94: 268-279.Google Scholar
SEHGAL, R.N.M. (2010) Deforestation and avian infectious diseases. Journal of Experimental Biology; Journal of Experimental Biology 213: 955-960.CrossRefGoogle ScholarPubMed
SEKERCIOGLU, C.H., SCHNEIDER, S.H., FAY, J.P. and LOARIE, S.R. (2008) Climate change, elevational range shifts, and bird extinctions. Conservation Biology 22: 140-150.Google Scholar
SORENSON, L.G., GOLDBERG, R., ROOT, T.L. and ANDERSON, M.G. (1998) Potential Effects of Global Warming on Waterfowl Populations Breeding in the Northern Great Plains. Climatic Change 40: 343-369.Google Scholar
STENSETH, N.C. and MYSTERUD, A. (2002) Climate, changing phenology, and other life history traits: nonlinearity and match-mismatch to the environment. Proceedings of the National Academy of Sciences of the United States of America 99: 13379-13381.Google Scholar
SUTHERLAND, W.J. (1998) Evidence for Flexibility and Constraint in Migration Systems. Journal of Avian Biology 29: 441-446.Google Scholar
SWANSON, G.A. and DUEBBERT, H.F. (1989) Wetland habitats of waterfowl in the prairie pothole region, in: VAN DER VALK, A. (Ed.) Northern Prairie Wetlands, pp. 228-267 (Ames, IA, USA, Iowa State University Press).Google Scholar
THOMAS, C.D. and LENNON, J.J. (1999) Birds extend their ranges northwards. Nature 399: 213-213.Google Scholar
VÉGVÁRI, Z., BÓKONY, V., BARTA, Z. and KOVÁCS, G. (2010) Life history predicts advancement of avian spring migration in response to climate change. Global Change Biology 16: 1-11.Google Scholar
VISSER, M.E., PERDECK, A.C., VAN BALEN, J.H. and BOTH, C. (2009) Climate change leads to decreasing bird migration distances. Global Change Biology 15: 1859-1865.Google Scholar
VISSER, M., HOLLEMAN, L. and GIENAPP, P. (2006) Shifts in caterpillar biomass phenology due to climate change and its impact on the breeding biology of an insectivorous bird. Oecologia 147: 164-172.Google Scholar
VOSE, R.S., EASTERLING, D.R. and GLEASON, B. (2005) Maximum and minimum temperature trends for the globe: An update through 2004. Geophysical Research Letters 32: L23822.Google Scholar
WALTHER, G.R., POST, E., CONVEY, P., MENZEL, A., PARMESAN, C., BEEBEE, T.J.C., FROMENTIN, J.M., HOEGH-GULDBERG, O. and BAIRLEIN, F. (2002) Ecological responses to recent climate change. Nature 416: 389-395.Google Scholar
WINKLER, D.W., DUNN, P.O. and MCCULLOCH, C.E. (2002) Predicting the effects of climate change on avian life-history traits. Proceedings of the National Academy of Sciences of the United States of America 99: 13595-13599.CrossRefGoogle ScholarPubMed
WOBESER, G. (1992) Avian cholera and waterfowl biology. Journal of Wildlife Diseases 28: 674-682.Google Scholar
ZUCKERBERG, B., WOODS, A.M. and PORTER, W.F. (2009) Poleward shifts in breeding bird distributions in New York State. Global Change Biology 15: 1866-1883.Google Scholar