Hostname: page-component-78c5997874-m6dg7 Total loading time: 0 Render date: 2024-11-05T08:33:34.729Z Has data issue: false hasContentIssue false
  • English
  • Français

Animal health aspects of adaptation to climate change: beating the heat and parasites in a warming Europe

Published online by Cambridge University Press:  06 June 2013

P. J. Skuce ,
E. R. Morgan ,
J. van Dijk  and
M. Mitchell
P. J. Skuce*
Affiliation:
Moredun Research Institute, Pentlands Science Park, Midlothian EH26 0PZ, UK
E. R. Morgan
Affiliation:
School of Biological Sciences, University of Bristol, Langford, Bristol BS40 5DU, UK
J. van Dijk
Affiliation:
Institute of Infection and Global Health, University of Liverpool, Leahurst Campus, CH64 7TE, UK
M. Mitchell
Affiliation:
Scotland's Rural College (SRUC), The Roslin Building, Easter Bush, Midlothian EH25 9RG, UK
*
E-mail: [email protected]
Get access

Abstract

Weather patterns in northern European regions have changed noticeably over the past several decades, featuring warmer, wetter weather with more extreme events. The climate is projected to continue on this trajectory for the foreseeable future, even under the most modest warming scenarios. Such changes will have a significant impact on livestock farming, both directly through effects on the animals themselves, and indirectly through changing exposure to pests and pathogens. Adaptation options aimed at taking advantage of new opportunities and/or minimising the risks of negative impacts will, in themselves, have implications for animal health and welfare. In this review, we consider the potential consequences of future intensification of animal production, challenges associated with indoor and outdoor rearing of animals and aspects of animal transportation as key examples. We investigate the direct and indirect effects of climate change on the epidemiology of important livestock pathogens, with a particular focus on parasitic infections, and the likely animal health consequences associated with selected adaptation options. Finally, we attempt to identify key gaps in our knowledge and suggest future research priorities.

Keywords

climate changelivestockadaptationparasites
Type
Full Paper
Information
animal , Volume 7 , Issue s2: Greenhouse Gases & Animal Agriculture Conference (GGAA 2013), 23rd ‐ 26th June 2013, Dublin, Ireland , June 2013 , pp. 333 - 345
Copyright
Copyright © The Animal Consortium 2013 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Aby, BA, Aass, L, Sehested, E, Vangen, O 2012. Effects of changes in external production conditions on economic values of traits in continental and British beef cattle breeds. Livestock Science 150, 8093.Google Scholar
Aguerre, MJ, Wattiaux, MA, Powell, JM, Broderick, GA, Arndt, C 2011. Effect of forage-to-concentrate ratio in dairy cow diets on emission of methane, carbon dioxide, and ammonia, lactation performance, and manure excretion. Journal of Diary Science 94, 30813093.Google Scholar
Alain, V, Mirabito, L, Arnould, C, Colas, M, Le Bouquin, S, Lupo, C, Michel, V 2009. Skin lesions in broiler chickens measured at the slaughterhouse: relationships between lesions and between their prevalence and rearing factors. British Poultry Science 50, 407417.Google Scholar
Appleby, MC, Lawrence, TL (eds) 1999. Farm animal welfare – who writes the rules? Occasional Publication no. 23. British Society of Animal Production, Edinburgh, pp. 4364.Google Scholar
Baker, RH, Britton, C, Roberts, B, Loer, CM, Matthews, JB, Nisbet, AJ 2012. Melanisation of Teladorsagia circumcincta larvae exposed to sunlight: a role for GTP-cyclohydrolase in nematode survival. International Journal of Parasitology 42, 887891.Google Scholar
Baylis, M 2006. Foresight. Infectious diseases: preparing for the future. T7.3: The effects of climate change on infectious diseases of animals. The Government Office for Science, London. Retrieved from http://www.foresight.gov.ukGoogle Scholar
Beddington, J 2011. Foresight: The future of food and farming. The Government Office for Science, London. Retrieved from http://www.foresight.gov.ukGoogle Scholar
Belay, T, Teeter, RG 1993. Broiler water balance and thermo-balance during thermoneutral and high temperature exposure. Poultry Science 72, 116124.Google Scholar
Bell, MJ, Eckhard, RJ, Cullen, BR 2012. The effect of future climate change scenarios on the balance between productivity and greenhouse gas emissions from sheep grazing systems. Livestock Science 147, 126138.Google Scholar
Bergquist, R, Rinaldi, L 2010. Health research based on geospatial tools: a timely approach in a changing environment. Journal of Helminthology 84, 111.Google Scholar
Bessai, W 2006. Welfare of broilers: a review. Worlds Poultry Science Journal 62, 455466.CrossRefGoogle Scholar
Champion, RA, Rutter, SM, Penning, PD, Rook, AJ 1994. Temporal variation in grazing behaviour of sheep and the reliability of sampling periods. Applied Animal Behaviour Science 42, 99108.Google Scholar
Charlier, J, Claerebout, E, De Muelenaere, E, Vercruysse, J 2005. Associations between dairy herd management factors and bulk tank milk antibody levels against Ostertagia ostertagi. Veterinary Parasitology 133, 91100.Google Scholar
Cockram, MS, Mitchell, MA 1999. Role of research in the formulation of ‘rules’ to protect the welfare of farm animals during road transportation. In EC Climate Change Policy (ed. AJ Russel, CA Morgan, CJ Savory), pp. 4364. British Association for Animal Science, Edinburgh, UK. Retrieved from http://ec.europa.eu/clima/policies/adaptation/index_en.htmGoogle Scholar
Cornell, S 2005. Modelling nematode populations: 20 years of progress. Trends Parasitol 21, 542545.Google Scholar
Defra 2013. Adapting to climate change. Retrieved April 24, 2013, from http://www.gov.uk/government/policies/adapting-to-climate-changeGoogle Scholar
de Rancourt, M, Fois, N, Lavin, M, Tchakerian, E, Vallerand, F 2006. Mediterranean sheep and goats production: an uncertain future. Small Ruminant Research 62, 167179.Google Scholar
Dobson, ADM, Finnie, TJR, Randolph, SE 2011. A modified matrix model to describe the seasonal population ecology of the European tick Ixodes ricinus. Journal of Applied Ecology 48, 10171028.Google Scholar
Dobson, RJ, Barnes, EH, Tyrrell, KL, Hosking, BC, Larsen, JWA, Besier, RB, Love, S, Rolfe, PF, Bailey, JN 2011. A multi-species model to assess the effect of refugia on worm control and anthelmintic resistance in sheep grazing systems. Australian Veterinary Journal 89, 200208.Google Scholar
Eckard, RJ, Cullen, BR 2011. Impacts of future climate scenarios on nitrous oxide emissions from pasture based dairy systems in south eastern Australia. Animal Feed Science and Technology 166–167, 736748.CrossRefGoogle Scholar
Ford, SE, Chintala, MM 2006. Northward expansion of a marine parasite: testing the role of temperature adaptation. Journal of Experimental Marine Biology and Ecology 339, 226235.CrossRefGoogle Scholar
EU 2009. Agriculture and Rural Development. Retrieved January 22, 2013, from http://ec.europa.eu/agriculture/climate-change/pdf/sum2009_en.pdfGoogle Scholar
Europa 2012. Climate action: forests and agriculture. Retrieved January 22, 2013, from http://ec.europa.eu/clima/policies/adaptation/index_en.htmGoogle Scholar
Fox, NJ, Marion, G, Davidson, RS, White, PCL, Hutchings, MR 2012. Livestock helminths in a changing climate: approaches and restrictions to meaningful predictions (Review). Animals 2, 93107.Google Scholar
Fox, NJ, White, PCL, McClean, CJ, Marion, G, Evans, A, and Hutchings, M 2011. Predicting impacts of climate change on Fasciola hepatica risk. PLoS One 6, e16126. doi:10.1371/journal.pone.0016126.Google Scholar
Garnett, T 2013. Food sustainability: problems, perspectives and solutions. Proceedings of the Nutrition Society 72, 2939.Google Scholar
Gaughan, JB, Lacetera, N, Valtorta, SE, Khalifa, HH, Hahn, L, Mader, T 2009. Response of domestic animals to climate challenges. In Biometeorology for adaption to climate variability and change (ed. KL Ebi, I Burton, GR McGregor), vol. 1, pp. 131170. Springer.Google Scholar
Gauly, M, Bollwein, H, Breves, G, Brugemann, K, Danicke, S, Das, G, Demeler, J, Hansen, H, Isselstein, J, Konig, S, Loholter, M, Martinsohn, M, Meyer, U, Potthoff, M, Sanker, C, Schroder, B, Wrage, N, Meibaum, B, von Samson-Himmelstjerna, G, Stinshoff, H, Wrenzycki, C 2013. Future consequences and challenges for dairy cow production systems arising from climate change in Central Europe – a review. Animal 7, 843859.Google Scholar
Gill, M, Smith, P, Wilkinson, JM 2010. Mitigating climate change: the role of domestic livestock. Animal 4, 323333.Google Scholar
Gray, J, Dautel, H, Estrada-Pena, A, Kahl, O, Lindgren, E 2009. Effects of climate change on ticks and tick-borne diseases in Europe. Invited Review. Interdisciplinary perspectives on infectious diseases 2009, article ID 593232, 12pp., doi:10.1155/2009/593232.Google Scholar
González-Warleta, M, Lladosa, S, Castro-Hermida, JA, Martínez-Ibeas, AM, Conesa, D, Munoz, F, López-Quílez, A, Manga-González, Y, Mezo, M 2013. Bovine paramphistomosis in Galicia (Spain): prevalence, intensity, aetiology and geospatial distribution of the infection. Veterinary Parasitology 191, 252263.Google Scholar
Haskell, M, Kettlewell, P, McCloskey, E, Wall, E, Hutchings, Mand Mitchell, M 2011. Animal Welfare and Climate Change: Impacts, Adaptations, Mitigation and Risks. Defra Project Report AW0513. Retrieved from http://www.defra.gov.uk/Google Scholar
Houdijk, JGM 2008. Influence of periparturient nutritional demand on resistance to parasites in livestock. Parasite Immunology 30, 113121.Google Scholar
Hudson, PJ, Cattadori, IM, Boag, B, Dobson, AP 2006. Climate disruption and parasite-host dynamics: patterns and processes associated with warming and the frequency of extreme climatic events. Journal of Helminthology 80, 175182.Google Scholar
IFAD 2010. Livestock and Climate Change – Livestock Thematic Papers – Retrieved from http://www.ifad.org/climate/Google Scholar
Kanneganti, VR, Kaffka, SR 1995. Forage availability from a temperate pasture managed with intensive rotational grazing. Grass and Forage Science 50, 5562.Google Scholar
Kaplan, RM 2004. Drug resistance in nematodes of veterinary importance: a status report. Trends in Parasitology 20, 477481.Google Scholar
Kenyon, F, Jackson, F 2012. Targeted flock/herd and individual ruminant treatment approaches. Veterinary Parasitology 186, 1017.Google Scholar
Kettlewell, PJ, Hampson, CJ, Green, NR, Teer, NJ, Veale, BM, Mitchell, MA 2001a. Heat and moisture generation of livestock during transportation. In Proceedings of 6th International livestock environment symposium, 21–23 May, Louisville, Kentucky (ed. RR Stowell, R Bucklin, RW Bottcher), pp. 519526. American Society of Agricultural Engineers, St Joseph, Missouri.Google Scholar
Kettlewell, PJ, Mitchell, MA 2001b. Mechanical ventilation, improving the welfare of boiler chickens in transit. Journal of the Royal Agricultural Society 162, 175184.Google Scholar
Kettlewell, PJ, Hoxey, RP, Hampson, CJ, Green, NR, Veale, BM, Mitchell, MA 2001c. Design and operation of a prototype mechanical ventilation system for livestock transport vehicles. Journal of Agricultural Engineering Research 79, 429439.Google Scholar
Knox, JW, Hurford, A, Hargreaves, LWall, E 2012. Climate Change Risk Assessment for the Agriculture Sector – (Defra Project Code–GA0204) January 2012.Google Scholar
Kyvsgaard, N-C, Jensen, HB, Ambrosen, T, Toft, N 2013. Temporal changes and risk factors for foot-pad dermatitis in Danish broilers. Poultry Science 92, 2632.Google Scholar
Leathwick, DM, Hosking, BC, Bisset, SA, McKay, CH 2009. Managing anthelmintic resistance: is it feasible in New Zealand to delay the emergence of resistance to a new anthelmintic class? New Zealand Veterinary Journal 57, 181192.Google Scholar
Leathwick, DM, Waghorn, TS, Miller, CM, Candy, PM, Oliver, AMB 2012. Managing anthelmintic resistance – use of a combination anthelmintic and leaving some lambs untreated to slow the development of resistance to ivermectin. Veterinary Parasitology 187, 285294.Google Scholar
Manning, L, Chadd, SA, Baines, RN 2007. Water consumption in broiler chicken: a welfare indicator. Worlds Poultry Science Journal 63, 6371.Google Scholar
Mason, C, Stevenson, H, Cox, A, Dick, I, Rodger, C 2012. Disease associated with immature paramphistome infection in sheep. Veterinary Record 170, 343344.Google Scholar
Maurer, V, Baumgärtner, J 1992. Temperature influence on life table statistics of the chicken mite Dermanyssus gallinae (Acari: Dermanyssidae). Experimental and Applied Acarology 15, 2740.Google Scholar
May, JD, Lott, BD 1992. Feed and water consumption patterns of broilers at high environmental temperatures. Poultry Science 71, 331336.Google Scholar
McGlone, J, Pond, WG 2003. Pig production: biological principles and applications. Delmar Publishers, Clifton Park, NY.Google Scholar
Meluzzi, A, Fabbri, C, Folegatti, E, Sirri, F 2008. Survey of chicken rearing conditions: effects of litter quality and stocking density on productivity, foot dermatitis and carcase injuries. British Poultry Science 49, 257264.Google Scholar
Millar, M, Colloff, A, Scholes, S 2012. Disease associated with immature paramphistome infection. Veterinary Record 171, 509510.Google Scholar
Mitchell, MA 2006. Using physiological models to define environmental control strategies. In Mechanistic modelling in pig and poultry production (ed. RM Gous, TR Morris, C Fisher), pp. 209228. CABI International, Wallingford, Oxfordshire, UK.Google Scholar
Mitchell, MA, Kettlewell, PJ 1998. Physiological stress and welfare of broiler chickens in transit, solutions not problems!. Poultry Science 77, 18031814.Google Scholar
Mitchell, MAKettlewell, PJ 2006. Minimización del stress en el transporte de ganado porcino. Plenary Lecture, Proceedings of the III Congresso Mundial de Jamon, Sobre Ciencia, Technología y Commercialization, Teruel, Spain, May 17–20, 2005, 11pp.Google Scholar
Mitchell, MA, Kettlewell, PJ 2008. Engineering and design of vehicles for long distance road transport of livestock (ruminants, pigs and poultry). An invited review. Veterinaria Italiana 44, 213225.Google Scholar
Moran, D, Topp, K, Wall, E, Wreford, AMitchell, M. 2009. Climate change impacts on the livestock sector. Defra Project Report AC0307. Retrieved from http://www.defra.gov.uk/Google Scholar
Morgan, ER, Wall, R 2009. Climate change and parasitic disease: farmer mitigation? Trends in Parasitology 25, 308313.Google Scholar
Morgan, ER, van Dijk, J 2012. Climate and the epidemiology of gastrointestinal nematode infections of sheep in Europe. Veterinary Parasitology 189, 814.Google Scholar
Nieuwhof, GJ, Bishop, SC 2005. Costs of the major endemic diseases in Great Britain and the potential benefits of reduction in disease impact. Animal Science 81, 2329.Google Scholar
Novak, SM, Fiorelli, JL 2011. Greenhouse gases and ammonia emissions from organic mixed crop-dairy systems: a critical review of mitigation options. Sustainable Agriculture 2, 529556.Google Scholar
O'Connor, LJ, Walkden-Brown, SW, Kahn, LP 2006. Ecology of the free-living stages of major trichostrongylid parasites of sheep. Veterinary Parasitology 142, 115.Google Scholar
O'Mara, FP 2012. The role of grasslands in food security and climate change. Annals of Botany 6, 12631270.Google Scholar
Papadopoulos, E, Himonas, C, Coles, GC 2001. Drought and flock isolation may enhance the development of anthelmintic resistance in nematodes. Veterinary Parasitology 97, 253259.CrossRefGoogle ScholarPubMed
Polley, L, Thompson, RCA 2009. Parasite zoonoses and climate change: molecular tools for tracking shifting boundaries. Trends in Parasitology 25, 285291.Google Scholar
Rivington, M, Matthews, KB, Buchan, K, Miller, DG, Bellocchi, G, Russel, G 2013. Climate change impacts and adaptation, scope for agriculture indicated by ago-meteorologicalmetrics. Agricultural Sytems 114, 1531.Google Scholar
Roca-Fernandez, AI, O'Donovan, MA, Curran, J, Gonzalez-Rodriguez, A 2011. Effect of pre-grazing herbage mass and daily herbage allowance on perennial ryegrass swards structure, pasture dry matter intake and milk performance of Holstein-Friesian dairy cows. Spanish Journal of Agricultural Research 9, 8699.Google Scholar
Rodriquez, D, de Voil, P, Power, B, Cox, H, Crimp, S, Meinke, H 2011. The intrinsic plasticity of farm businesses and their resilience to change. An Australian example. Field Crop Research 124, 157170.Google Scholar
Sargison, ND, Scott, PR 2011. Diagnosis and economic consequences of triclabendazole resistance in Fasciola hepatica in a sheep flock in south-east Scotland. Veterinary Record 168, 159.Google Scholar
Sargison, ND, Scott, PR, Jackson, F 2002. Teladorsagiosis in young lambs and extended periparturient susceptibility in moxidectin-treated ewes grazing heavily contaminated pastures. Veterinary Record 151, 353355.Google Scholar
Sargison, ND, Jackson, F, Bartley, DJ, Moir, A 2005. Failure of moxidectin to control benzimidazole-, levamisole- and ivermectin-resistant teladorsagia circumcincta in a sheep flock. Veterinary Record 156, 105109.Google Scholar
Schonbach, P, Wolf, B, Dickhofer, U, Wiesmeier, M, Chen, W, Hongwei, W, Gierus, M, Butterbach-Bahl, K, Kogel-Knabner, I, Susenbeth, A, Zheng, X, Taube, F 2012. Grazing effects on the greenhouse gas balance of a temperate steppe ecosystem. Nutrient Cycling in Agroecosystems 93, 357371.Google Scholar
Schweizer, G, Braun, W, Deplazes, D, Torgerson, P 2005. The economic effects of bovine fasciolosis in Switzerland. Veterinary Record 157, 188193.Google Scholar
Singh, A, Casey, KD, King, WD, Pescatore, AJ, Gates, RS, Ford, MJ 2009. Efficacy of urease inhibitor to reduce ammonia emission form poultry houses. Journal of Applied Poultry Science 18, 3442.Google Scholar
Smith, P, Gregory, PJ 2013. Climate change and sustainable food production. Proceedings of the Nutrition Society 72, 2128.Google Scholar
Sturaro, E, Cocca, G, Gallo, L, Mrad, M, Ramanzin, M 2009. Livestock systems and farming styles in Eastern Italian Alps: an on-farm survey. Italian Journal of Animal Science 8, 541554.Google Scholar
Thornton, PK 2010. Livestock production: recent trends, future prospects. Philosophical Transactions of the Royal Society B 365, 28532867.Google Scholar
Tiley, GED 2010. Biological flora of the British Isles: Cirsium arvense (L.). Journal of Ecology 98, 938983.Google Scholar
Topper, PA, Wheeler, EF, Zajaczkowski, JS, Gates, RS, Xin, H, Liang, Y, Casey, KD 2008. Ammonia emissions from two empty broiler houses with built up litter. Transactions of the ASABE 51, 219225.Google Scholar
Troell, K, Waller, P, Hoglund, J 2005. The development and overwintering survival of free-living larvae of Haemonchus contortus in Sweden. Journal of Helminthology 79, 373379.Google Scholar
Troell, K, Tingstedt, C, Hoglund, J 2006. Phenotypic characterization of Haemonchus contortus: a study of isolates from Sweden and Kenya in experimentally infected sheep. Parasitology 132, 403409.Google Scholar
Turnpenny, JR, Parsons, DJ, Armstrong, AC, Clark, JA, Cooper, K, Matthews, AM 2001. Integrated models of livestock systems for climate change studies. 2. Intensive systems. Global Change Biology 7, 163170.Google Scholar
van Dijk, J 2008. Climate change and the epidemiology of gastrointestinal nematodes of sheep. Unpublished PhD thesis, University of Bristol, UK.Google Scholar
van Dijk, J, Morgan, ER 2008. The influence of temperature on the development, hatching and survival of Nematodirus battus larvae. Parasitology 135, 269283.Google Scholar
van Dijk, J, Morgan, ER 2010. Variation in the hatching behavior of Nematodirus battus: polymorphic bet hedging? International Journal for Parasitology 40, 675681.Google Scholar
van Dijk, J, Morgan, ER 2011. The influence of water on the migration of infective trichostrongyloid larvae onto grass. Parasitology 138, 780788.Google Scholar
van Dijk, J, David, GP, Baird, G, Morgan, ER 2008. Back to the future: developing hypotheses on the effects of climate change on ovine parasitic gastroenteritis from historical data. Veterinary Parasitology 158, 7384.Google Scholar
van Dijk, J, De Louw, MDE, Kalis, LPA, Morgan, ER 2009. Ultraviolet light increases mortality of nematode larvae and can explain patterns of larval availability at pasture. International Journal for Parasitology 39, 11511156.CrossRefGoogle ScholarPubMed
van Dijk, J, Sargison, ND, Kenyon, F, Skuce, PJ 2010. Climate change and infectious disease: helminthological challenges to farmed ruminants in temperate regions. Animal 4, 377392.CrossRefGoogle ScholarPubMed
Van Wyk, JA 2001. Refugia – overlooked as perhaps the most potent factor concerning the development of anthelmintic resistance. Onderestepoort Journal of Veterinary Research 68, 5567.Google Scholar
Waghorn, TS, Leathwick, DM, Miller, CM, Atkinson, DS 2008. Brave or gullible: testing the concept that leaving susceptible parasites in refugia will slow the development of anthelmintic resistance. New Zealand Veterinary Journal 56, 158163.Google Scholar
Waghorn, TS, Miller, CM, Oliver, AM, Leathwick, DM 2009. Drench-and-shift is a high risk practice in the absence of refugia. New Zealand Veterinary Journal 57, 359363.CrossRefGoogle ScholarPubMed
Wall, R, Rose, H, Ellse, L, Morgan, E 2011. Livestock ectoparasites: integrated management in a changing climate. Veterinary Parasitology 180, 8289.Google Scholar
White, N, Sutherst, RW, Hall, N, Whish-Wilson, P 2003. The vulnerability of the Australian beef industry to impacts of the cattle tick (Boophilus microplus) under climate change. Climatic Change 61, 157190.CrossRefGoogle Scholar
Vercruysse, J, Schetters, T, Knox, DP, Willadsen, P, Claerebout, E 2007. Control of parasitic disease by vaccination – an answer to drug resistance? Reviews in Science and Technology 26, 105115.Google Scholar
Wolstenholme, AJ, Fairweather, I, Prichard, RK, von Samson-Himmelstjerna, G, Sangster, NC 2004. Drug resistance in veterinary helminths. Trends in Parasitology 20, 469476.Google Scholar