Abstract
The aim of the present study was to assess the heat tolerance of animals of two Portuguese (Alentejana and Mertolenga) and two exotic (Frisian and Limousine) cattle breeds, through the monitoring of physiological acclimatization reactions in different thermal situations characterized by alternate periods of thermoneutrality and heat stress simulated in climatic chambers. In the experiment, six heifers of the Alentejana, Frisian and Mertolenga breeds and four heifers of the Limousine breed were used. The increase in chamber temperatures had different consequences on the animals of each breed. When submitted to heat stress, the Frisian animals developed high thermal polypnea (more than 105 breath movements per minute), which did not prevent an increase in the rectal temperature (from 38.7°C to 40.0°C). However, only a slight depression in food intake and in blood thyroid hormone concentrations was observed under thermal stressful conditions. Under the thermal stressful conditions, Limousine animals decreased food intake by 11.4% and blood triiodothyronine (T3) hormone concentration decreased to 76% of the level observed in thermoneutral conditions. Alentejana animals had similar reactions. The Mertolenga cattle exhibited the highest capacity for maintaining homeothermy: under heat stressful conditions, the mean thermal polypnea increased twofold, but mean rectal temperature did not increase. Mean food intake decreased by only 2% and mean T3 blood concentration was lowered to 85,6% of the concentration observed under thermoneutral conditions. These results lead to the conclusion that the Frisian animals had more difficulty in tolerating high temperatures, the Limousine and Alentejana ones had an intermediate difficulty, and the Mertolenga animals were by far the most heat tolerant.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aganga AA, Umunna NN, Oyedipe EO, Okoh PN, Aduku AO (1990) Response to water deprivation by Yankasa Ewes under different physiological states. Small Rumin Res 3:109–115
Alba J de, Sampaio JMC (1957) Climatic stress on tropically reared breeds of cattle. J Anim Sci 16:725–731
Alnaimy A, Habbeb M, Fayaz M, Marai M, Kamal TH (1992) Heat stress. In: Phillpis C, Piggins D (eds) Farm animals and the environment. CAB International, Oxfordshire, pp 27–47
Alvarez MB, Johnson HD (1971) Environmental heat exposure on cattle plasma catecholamine and glucocorticoids. J Dairy Sci 56:189–201
Amakiri SF, Funsho ON (1979) Studies of rectal temperature, respiratory rates and heat tolerance in cattle in the humid tropics. Anim Prod 28:329–335
Baccari F Jr, Johnson HD, Hahn GL (1983) Environmental heat effects on growth, plasma T3, and postheat compensatory effects on Holstein calves. Proc Soc Exp Biol Med 173:312–318
Baccari F Jr, Blasi AC, Muniz LMR, Fre CA (1988) Effect of thermal stress on feed intake and serum triiodothyronine in young buffalo bulls. Proceedings of II World Buffalo Congress, New Delhi, India vol 3:139–143
Beede DK, Collier RJ (1986) Potential nutritional strategies for intensively managed cattle during thermal stress. J Anim Sci 62:543–554
Berbigier P (1983) Tolérance au climat tropical des taurillons Frisons et Créoles soumis à plusieurs régimes alimentaires. Détérmination d’un indice climatique. Ann Zootech 32:383–396
Berman A (1968) Nychthemeral and seasonal patterns of thermoregulation in cattle. Aust J Agric Res 19:181–189
Berman A (2005) Estimates of heat stress relief needs for Holstein dairy cows. J Anim Sci 83:1377–1384
Bianca W (1965) Reviews of the progress of dairy science. Cattle in a hot environment. J Dairy Res 32:291-345
Blackshaw JK, Blachshaw AW (1994) Heat stress in cattle and the effect of shade on production and behaviour: a review. Aust J Exp Agric 34:285–295
Bligh J, Harthoorn AM (1965) Continuous radiotelemetric records of the deep body temperature of some unrestrained african mammals under near-natural conditions. J Physiol 176:145–162
Blincoe C (1958) Environmental physiology and shelter engineering with special reference to domestic animals. XLVII. The influence of constant ambient temperature on the thyroid activity and iodide metabolism of Shorthorn, Santa Gertrudis and Brahman calves during growth. University of Missouri College of Agriculture, Agricultural Experiment Station Research Bulletin 649:3–25
Boissy A (1998) Fear and fearfulness in determing behavior. In: Grandin T (ed) Genetics and the behavior of domestic animals. Academic Press, San Diego, pp 67–111
Boissy A, Bouissou M-F (1991) L’influence des réactions de peur sur les capacités d’adaptation des bovins a leurs conditions d’élevage - Anxiété. Conférence APRIA-CNEVA sur “bien-être des animaux d’élevage”, vol 93-3-B-427:59–68
Brown-Brandl TM, Eigenberg R, Hahn GL, Nienaber JA (2001) Correlations of respiration rate, core body temperatures, and ambient temperatures for shaded and non-shaded cattle. VI International Symposium Livestock Environment, Louisville, Kentucky, pp 448–454
Burns B, Vercoe JE, Holmes CR (1988) Productive and adaptative trait differences of Simmental, Hereford and Africander * Hereford cattle. J Agric Sci 111:475–480
Cabanac M (1972) Thermoregulatory behavior. In: Bligh J, Moore RE (eds) Essays on temperature regulation. North Holland, Amsterdam, pp 19–36
Cabello G, Wrutniak C (1989) Thyroid hormone and growth: relationships with growth hormone effects and regulation - review. Reprod Nutr Develop:387–402
Christopherson RJ, Gonyou HW, Thompson JR (1979) Effects of temperature and feed intake on plasma concentration of thyroid hormones in beef cattle. Can J Anim Sci 59:655–661
Colditz PJ, Kellaway RC (1972) The effect of diet and heat stress on feed intake, growth, and nitrogen metabolism in Friesian, F1 Brahman * Friesian, and Brahman heifers. Aust J Agric Res 23:717–725
Collier RJ, Eley RM, Sharma AK, Pereira RM, Buffington DE (1981) Shade management in subtropical environment for milk yield and composition in Holstein and Jersey cows. J Dairy Sci 64:844–849
Degen AA, Young BA (1984) Effects of ingestion of warm, cold and frozen water on heat balance in cattle. Can J Anim Sci 64:73–80
Eckert, Randall D, Burggren W, French K (1997) Eckert animal physiology - mechanisms and adaptation, 4th edn. Freeman, New York
El-Nouty FD, Elbanna IM, Davis TP, Johnson HD (1980) Aldosterone and ADH response to heat and dehydration in cattle. J Appl Physiol: Respir, Environ Exercise Physiol 48:249–255
Faure JM, Mills AD (1998) Improving the adaptability of Animals by selection. In: Grandin T (ed) Genetics and the behavior of domestic animals. Academic Press, San Diego, pp 235–264
Finch VA (1985) Comparison of non-evaporative heat transfer in different cattle breeds. Aust J Agric Res 36:497–508
Finch VA (1986) Body temperature in beef cattle: its control and relevance to production in the tropics. J Anim Sci 62:531–542
Finch VA, Bennett IL, Holmes CR (1982) Sweating response in cattle and its relation to rectal temperature, tolerance of sun and metabolic rate. J Agric Sci 99:479–487
Forbes JM (1993) Voluntary feed intake. In: Forbes JM, France J (eds) Quantitative aspects of ruminant digestion and metabolism. CAB International, Devon, pp 479–494
Frisch JE, Vercoe JE (1984) An analysis of growth of different cattle genotypes reared in different environments. J Agric Sci 103:137–153
Fulkerson WJ, Sawyer GJ, Gow CB (1980) Investigations of ultradian and circadian rhythms in the concentration of cortisol and prolactin in the plasma of dairy cattle. Aust J Biol Sci 33:557–561
Grandin T, Deesing M (1998) Genetics and behavior during handling, restraint and herding. In: Grandin T (ed) Genetics and the behavior of domestic animals. Academic Press, San Diego, pp 113–144
Hahn GL (1989) Body temperature rhythms in farm animals - A review and reassessment relative to environmental influences. Proc 11th Int Soc Biometeorol Congr, SPB Academic, The Hague, The Netherlands, pp 325−337
Hahn GL, Parkhurst AM, Gaughan JB (1997) Cattle respiration rate as function of ambient temperature. In: ASAE Meeting Presentation. ASAE, Missouri, pp 1–21
Ingraham RH, Stanley RW, Wagner WC (1976) Seasonal effects of tropical climate on shaded and nonshaded cows as measured by rectal temperature, adrenal cortex hormones, thyriod hormone, and milk production. Am J Vet Res 40:1792–1797
Johnson HD, Hahn I, Kibler HH, Shanklin MK, Edmondson JE (1967) Environmental physiology and shelter engineering with special reference to domestic animals. Heat and aclimation influences on lactation of Holstein cattle. University of Missouri College of Agriculture, Agricultural Experiment Station Research Bulletin 916:3–32
Kamal TH (1992) Indices of heat tolerance and amelioration of heat stress. In: Shafie MM, Barkawi AH, Ibrahim SA, Sadek RR (eds) Prospects of buffalo production in the Mediterranean and the Middle East, no 62. EAAP Publication, International Center for Agriculture, Doki (Cairo) Egypt, pp 198–200
Kamal TH, Shebaita MK, Ibrahim II (1992) Seasonal variations in different physiological parametres in water buffaloes and friesians. In: Publication E (ed) Prospects of buffalo production in the Mediterranean and the Middle East, no62. EAAP Publication, International Center for Agriculture, Doki (Cairo) Egypt, pp 201–204
Kibler HH, Brody S, Worstell DM (1949) Environmental physiology with special reference to domestic animals. Influence of temperature, 50° to 105°F, on heat production and cardiorespiratory activities in dairy cattle. University of Missouri College of Agriculture, Agricultural Experiment Station Research Bulletin 435:3–31
Lawrence TLJ, Fower VR (1997) Growth of farm animals. CAB International, Cambridge
Lofgreen GP, Givens RL, Morrison SR, Bond TE (1975) Effect of drinking water temperature on beef cattle performance. J Anim Sci 40:223–229
Magdub A, Johnson HD, Belyea RL (1982) Effect of environmental heat and dietary fiber on thyroid physiology of lactating cows. J Dairy Sci 65:2323–2331
McDowell RE, Moody EG, Van Soest PJ, Lehmann RP, Ford GL (1968) Effect of heat stress on energy and water utilization of lactating cows. J Dairy Sci 52:188–194
Muller CJC, Botha JA, Coetzer WA, Smith WA (1994) Effect of shade on various parameters of Friesian cows in a Mediterranean climate in South Africa. II. Physiological responses. S Afr J Anim Sci 24:56–60
O’Kelly JC (1987) Influence of dietary fat on some metabolic responses of cattle to hyperthermia induced by heat exposure. Comp Biochem Physiol 87A, 677–682
Pratt BR (1986) The effect of environmental temperature on concentrations of thyroxine and triiodothyronine after tirotropin releasing hormone in steers. J Anim Sci 62:1346–1352
Riis PM (1983) Adaptation of metabolism to various conditions: nutritional and other environmental conditions. In: Riis PM (ed) Dynamic biochemistry of animal production, vol A3, World Animal Science. Elsevier, Amsterdan, pp 319–358
Robertshaw D (1986) Physical and physiological principles of adaptation of animals to the tropics. Simposio de bioclimatologia animal nos trópicos, Fortaleza, pp 87–94
Roman-Ponce H, Thatcher WW, Buffington DE, Wilcox CJ, Van Horn HH (1976) Physiological and production responses of dairy cattle to a shade structure in a subtropical environment. J Dairy Sci 60:424–430
Rosenberg LJ, Blad BL, Verma SB (1983) Human and animal biometeorology. In: Rosenberg LJ, Blad BL, Verma SB (eds) Microclimate - the biological environment. Wiley, New York, pp 425–467
Silanikove N (2000) Effects of heat stress on the welfare of extensively managed domestic ruminants - a review. Livest Prod Sci 67:1–18
Silva RG (2000) Introdução à bioclimatologia animal. Nobel, São Paulo
Singh K, Bhattacharyya NK (1991) Thermosensitivity of Bos Indicus cattle and their F1 crosses with three breeds of Bos Taurus. Anim Prod 52:57–65
Singh SP, Newton WM (1978) Acclimation of young calves to high temperatures: composition of blood and skin secretions. Am J Vet Res 39:799–801
Spiers DE, Vogt DW, Johnson HD, Garner GB, Murphy CN (1994) Heat-stress responses of temperate and tropical breeds of Bos Taurus cattle. Arch Latinoam Prod Anim 2:41–52
Thompson JA, Brimacombe M, Calvin JA, Tomaszewski MA, Davidson TJ, Magee DD (1999) Effects of environmental management on seasonal decrease in milk production in dairy cattle. J Am Vet Med Assoc 24:85–88
Titto EAL, Pereira AF, Passini R, Balieiro Neto G, Fagundes ACA, Lima CG (1998) Estudo da tolerância ao calor de tourinhos das raças Marchigiana, Nelore e Simental. In: SBBiomet (ed) II Congresso Brasileiro de Biometeorologia. Goiânia-DF, Brasil, pp 361–366
Webster AJF (1988) Comparative aspects of the energy exchange. In: Blaxter K, Mcdonald I (eds) Comparative nutrition. Libby, London, pp 37–54
Wise ME, Armstrong DV, Huber JT, Hunter R, Wiersma F (1988) Hormonal alterations in the lactating dairy cow in response to thermal stress. J Dairy Sci 71:2480–2485
Yousef MK, Johnson HD (1966) Calorigenesis of dairy cattle as influenced by thyroxine and environmental temperature. J Anim Sci 25:150–156
Yousef MK, Johnson HD (1984) Body fluids and thermal environments. In: Yousef MK (ed) Stress physiology in livestock. Basic principles, vol 1. CRC Press, Las Vegas, pp 189–201
Yousef MK, Robertson WD, Johnson HD, Hahn L (1988) Effect of ruminal heating on thyroid function and heat production of cattle. J Anim Sci 28:677–683
Zia-Ur-Rehman, Gilani AH, Ahmad M-U-D, Ali CS (1982) Adaptability of cross-bred dairy heifers to summer season measured by rectal temperature, pulse rate and respiration rate. Rev Elev Méd Vét Pays Trop 35:63–68
Acknowledgements
This study was supported by PRAXIS XXI research programme (FCT, Lisboa) and by ICAM (Évora, Portugal).
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Pereira, A.M.F., Baccari, F., Titto, E.A.L. et al. Effect of thermal stress on physiological parameters, feed intake and plasma thyroid hormones concentration in Alentejana, Mertolenga, Frisian and Limousine cattle breeds. Int J Biometeorol 52, 199–208 (2008). https://doi.org/10.1007/s00484-007-0111-x
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00484-007-0111-x