Hostname: page-component-cd9895bd7-8ctnn Total loading time: 0 Render date: 2024-12-26T17:02:45.041Z Has data issue: false hasContentIssue false

Alleviating heat stress in domestic fowl: different strategies

Published online by Cambridge University Press:  23 December 2009

S. YAHAV*
Affiliation:
Institute of Animal Science, ARO, the Volcani Center, Bet Dagan 50250, Israel
*
Corresponding author: yahavs@agri.huji.ac.il
Get access

Abstract

During recent decades there has been significant improvement in genetic selection of broilers and turkeys for growth rate, which has coincided with dramatic increases in metabolic rate. A similar pattern is observed in the rate of egg production by laying hens. However, this selection has not been accompanied by comparable development of visceral systems, causing inferior thermotolerance response. In parallel, scientists expect that the average global surface temperature will rise by 0.6-2.5°C during the next 50 years. This situation, in which, from year to year, growth rate especially, but also egg production, improve (accompanied by increased heat production), and global surface temperature increases, demands an efficient means to improve the acquisition of thermotolerance by domestic fowl exposed to hot climatic conditions, and to do so economically. To develop thermotolerance three direct responses are employed: the rapid thermal stress response (RTSR), acclimation/acclimatization, and epigenetic temperature adaptation. This review will focus on the advantages and disadvantages of the different strategies used to reach the conflicting goals of production on the one hand and thermotolerance on the other hand.

Type
Review Article
Copyright
Copyright © World's Poultry Science Association 2009

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

ARAD, Z. and ITSAKI-GLUCKLISH, S. (1991) Ontogeny of brain temperature in quail chicks (Coturnix coturnix japonica ). Physiological Zoology 64: 1356-1370.CrossRefGoogle Scholar
BOGIN, E., PEH, H.C., AVIDAR, Y., ISRAELI, B.A. and CAHANER, A. (1996) The effects of long term high environmental temperature on cellular enzyme activities from different organs. European Journal of Clinical Chemistry and Clinical Biochemistry 34: 625-629.Google ScholarPubMed
BOGIN, E., PEH, H.C., AVIDAR, Y., ISRAELI, B.A., KEVKHAYE, E., LOMBARDI, P. and CAHANER, A. (1997) Sex and genotype dependence on the effects of long term high environmental temperatures on cellular enzymes activities from chickens organs. Avian Pathology 26: 511-524.CrossRefGoogle ScholarPubMed
BOULANT, J.A. (1996) Hypothalamic neurons regulating body temperature, in: FREGLY, M.J., & BLATTEIS, C.M. (Eds) Handbook of physiology. Section 4: Environmental physiology, pp. 105-126 (APS, Oxford University Press, New York).Google Scholar
BUYS, J., SCHEELE, C.W., KWAKERNAAK, C. and DECUYPERE, E. (1999) Performance and physiological variables in broiler chicken lines differing in susceptibility to the ascites syndrome: 2. Effect of ambient temperature on partial efficiencies of protein and fat retention and plasma hormone concentrations. British Poultry Science 40: 140-144.CrossRefGoogle Scholar
CAREW, L.B., EVARTS, K.G. and ALSTER, F.A. (1998) Growth, feed intake, and plasma thyroid hormone levels in chicks fed dietary excesses of essential amino acids. Poultry Science 77: 295-298.CrossRefGoogle ScholarPubMed
CHRISTENSEN, V.L., WINELAND, M.J., FASENKO, G.M. and DONALDSON, E. (2001) Egg storage effects on plasma glucose and supply and demand tissue glycogen concentrations of broiler embryos. Poultry Science 80: 1729-1735.CrossRefGoogle ScholarPubMed
COLLIN, A., BERRI, C., TESSERAUD, S., REQUENA, F., CASSY, S., CROCHET, S., DUCLOS, M.J., RIDEAU, N., TONA, K., BUYSE, J., BRUGGEMANN, V., DECUYPERE, E., PICARD, M. and YAHAV, S. (2007) Effects of thermal manipulation during early and late embryogenesis on thermotolerance and breast muscle characteristics in broiler chickens. Poultry Science 86: 795-800.CrossRefGoogle ScholarPubMed
DARRE, M.J. and HARRISON, P.C. (1987) Heart rate, blood pressure, cardiac output and total peripheral resistance of single comb white leghorn hens during an acute exposure to 35C ambient temperature. Poultry Science 66: 541-547.CrossRefGoogle Scholar
DÖRNER, G. (1974) Environment-dependent brain differentiation and fundamental processes of life. Acta Biologica et Medica Germanica 33: 129-148.Google ScholarPubMed
ETCHES, R.J., JOHN, T.M. and VERRINDER-GIBBINS, G.A.M. (1995) Behavioral, physiological, neuroendocrine and molecular responses to heat stress, in: DAGHIR, N.J. (Ed.) Poultry production in hot climate, pp. 31-66, (Cambridge, UK, CAB International).Google Scholar
FEIGE, U. and POLLA, B.S. (1994) HSP70: multi gene, multi structure, multi function family with potential clinical applications. Experientia 50: 979-986.CrossRefGoogle ScholarPubMed
FORREST, J.C., WILL, J.A., SCHMIDT, G.R., JUDGE, M.D. and BRISKEY, E.J. (1968) Homeostasis in animals (Sus domesticus) during exposure to warm environment. Journal of Applied Physiology 24: 33-39.CrossRefGoogle ScholarPubMed
FREEMAN, B.M. (1964) The emergence of the homeothermic-metabolic response in the fowl (Gallus domesticus). Comparative Biochemistry and Physiology 13: 413-422.CrossRefGoogle ScholarPubMed
FRIEDMAN-EINAT, M., HABERFELD, A., SHAMAI, A., HOREV, G., HURWITZ, S. and YAHAV, S. (1996) A novel 29-kDa chicken heat shock protein. Poultry Science 75: 1528-1530.CrossRefGoogle Scholar
GABARROU, J.F., DUCHAMP, C., WILLIAMS, J. and GĖRAERT, P.A. (1997) A role for thyroid hormones in the regulation of diet-induced thermogenesis in birds. British Journal of Nutrition 78: 963-973.CrossRefGoogle ScholarPubMed
GETHING, M.J. and SAMBROOK, J. (1992) Protein folding in cells. Nature 355: 33-45.CrossRefGoogle Scholar
GONZALES, E., BUYSE, J., SARTORI, J.R., LODDI, M. and DECUYPERE, E. (1999) Metabolic disturbances in male broilers of different strains. 2. Relationship between the thyroid and somatotropic axes with growth and mortality. Poultry Science 78: 516-521.CrossRefGoogle Scholar
HALES, J.R.S., HUBBARD, R.W. and GAFFIN, S.L. (1996) Limitation of heat tolerance, in: FREGLY, M.J. & BLATTRIS, C.M. (Eds) Handbook of physiology, section 4, environmental physiology, Vol. 1. (Chapter 15), pp. 285-359 (Oxford, Oxford University Press).Google Scholar
HALEVY, O., KRISPIN, A., LESHEM, Y., MCMURTRY, J.F. and YAHAV, S. (2001) Early age heat stress accelerates skeletal muscle satellite cell proliferation and differentiation in chicks. American Journal of Physiology 281: R302-R317.Google ScholarPubMed
HARRIS, K. and KOIKE, T.I. (1977) The effect of dietary sodium restriction on fluid and electrolytes metabolism in the chicken (Gallus domesticus). Comparative Physiology and Biochemistry 59A: 311-317.CrossRefGoogle Scholar
HAUSENLOY, D.J. and YELLON, D.M. (2006) Survival kinases in ischemic preconditioning and postconditioning. Cardiovascular Research 70: 240-53.CrossRefGoogle ScholarPubMed
HAVENSTEIN, G.B., FERKET, P.R., SCHIEDELER, S.E. and LARSON, B.T. (1994) Growth, livability and feed conversion of 1991 vs 1957 broilers when fed typical 1957 and 1991 broiler diets. Poultry Science 73: 1785-1794.CrossRefGoogle ScholarPubMed
HAVENSTEIN, G.B., FERKET, P.R. and QURESHI, M.A. (2003a) Growth, livability, and feed conversion of 1957 versus 2001 broilers when fed representative 1957 and 2001 broiler diets. Poultry Science 82: 1500-1508.CrossRefGoogle ScholarPubMed
HAVENSTEIN, G.B., FERKET, P.R. and and QURESHI, M.A. (2003b) Carcass composition and yield of 1957 versus 2001 broilers when fed representative 1957 and 2001 broiler diets. Poultry Science 82: 1509-1518.CrossRefGoogle ScholarPubMed
HAVENSTEIN, G.B., FERKET, P.R., GRIMES, J.L., QURESHI, M.A. and NESTOR, K.E. (2007) Comparison of the performance of 1966- versus 2003-type turkeys when fed representative 1966 and 2003 turkey diet: growth rate, livability, and feed conversion. Poultry Science 86: 232-240.CrossRefGoogle ScholarPubMed
HILLMAN, P.E., SCOTT, N.R. and VAN TIENHOVEN, A. (1985) Physiological responses and adaptations to hot and cold environments, in: YOUSEF, M.K. (Ed.) Stress physiology in livestock (vol. 3, Poultry), pp. 27-71 (Boca Raton, FL, CRC Press, Inc).Google Scholar
HOROWITZ, M. (1998) Do cellular heat acclimation responses modulate central thermoregulatory activity? News in Physiological Science 13: 218-225.Google ScholarPubMed
HOROWITZ, M. (2002) From molecular and cellular to integrative heat defense during exposure to chronic heat. Comparative Physiology and Biochemistry 131: 475-483.CrossRefGoogle ScholarPubMed
IUPS THERMAL COMMISSION, (2001) Glossary of terms for thermal physiology. The Japanese Journal of Physiology 51: 245-280.Google Scholar
JAATTELA, M. and WISSING, D. (1992) Emerging role of heat shock proteins in biology and medicine. Annual Medicine 24: 249-258.CrossRefGoogle ScholarPubMed
JANKE, O., TZSCHENTKE, B. and BOERJAN, B. (2004) Comparative investigations of heat production and body temperature in modern chicken breeds. Avian and Poultry Biological Reviews 15: 191-196.CrossRefGoogle Scholar
KATZ, A. and MEIRI, N. (2006) Brain-derived neurotrophic factor is critically involved in thermal-experience-dependent developmental plasticity. Journal of Neuroscience 12: 3899-3907.CrossRefGoogle Scholar
KOIKE, T.I., PRYOR, L.R. and NELDON, H.L. (1983) Plasma volume and electrolytes during progressive water deprivation in chickens (Gallus domesticus). Comparative Biochemistry and Physiology 74A: 83-87.CrossRefGoogle Scholar
KOVACH, A.G.B., SZASZ, E. and PILMAYER, N. (1969) Mortality of various avian and mammalian species following blood loss. Acta Physiologica Hungary 35: 109-116.Google ScholarPubMed
KÜHN, E.R., DECUYPERE, E. and RUDAS P., (1984) Hormonal and environmental interactions on thyroid function in the chick embryo and post-hatching chickens. Journal of Experimental Zoology 232: 653-658.CrossRefGoogle Scholar
LABUNSKAY, G. and MEIRI, N. (2006) R-Ras3/(M-Ras) is involved in thermal adaptation in the critical period of thermal control establishment. Journal of Neurobiology 66: 56-70.CrossRefGoogle ScholarPubMed
LI, G.C. and LASZLO, A. (1985) Thermotolerance in mammalian cells: a possible role for heat shock proteins, in: ATKINSON, B.G. & WALDEN, D.B. (Eds) Changes in eukaryotic gene expression in response to environmental stress, pp. 227-254 (Orlando FL USA, Academic Press Inc).Google Scholar
LINDQUIST, S. and CRAIG, A. (1988) The heat shock proteins. Annual Review of Genetics 22: 631-677.CrossRefGoogle ScholarPubMed
MARDER, J. and ARAD, Z. (1989) Panting and acid base regulations in heat stressed birds. Comparative Biochemistry and Physiology 94A: 395-400.CrossRefGoogle Scholar
MAY, J.D., DEATON, J.W., REECE, F.N., MITLIN, N. and KUBENA, L.F. (1971) The effect of environmental temperature on blood volume. Poultry Science 50: 1867-1870.CrossRefGoogle ScholarPubMed
MCNABB, F. and KING, D.B. (1993) Thyroid hormones effects on growth development and metabolism, in: SCHREIBMAN, M.P., SCANES, C.G. & PANG, P.K.T. (Eds) The endocrinology of growth development and metabolism in vertebrates, pp. 393-417 (New York, Academic Press).Google Scholar
MEIRI, N. (2008) 14-3-3epsilon expression is induced during the critical period of thermal control establishment. Developmental Neurobiology 68: 62-72.CrossRefGoogle ScholarPubMed
MORAES, V.M.B., MALEHIROS, D., BRUGGEMANN, V., COLLIN, A., TONA, K., VAN AS P., , ONAGBESAN, O.M., BUYSE, J., DECUYPERE, E. and MACARI, M. (2003) Effect of thermal conditioning during embryonic development on aspects of physiological responses of broilers to heat stress. Journal of Thermal Biology 28: 133-140.CrossRefGoogle Scholar
MORIMOTO, R.I. (1998) Regulation of the heat shock transcriptional response: cross talk between a family of heat shock factors, molecular chaperons and negative regulators. Genes and Development 12: 3788-3796.CrossRefGoogle ScholarPubMed
NAKI, A. (1999) New aspects in the vertebrate heat shock factor system: HSF3 and HSF4. Cell Stress Chaperones 4: 86-93.2.3.CO;2>CrossRefGoogle Scholar
NICHELMANN, M. and TZSCHENTKE, B. (2002) Ontogeny of thermoregulation in precocial birds. Comparative Biochemistry and Physiology 131(A): 751-763.CrossRefGoogle ScholarPubMed
NICHELMANN, M., LANGE, B., PIROW, R., LANGBEIN, J. and HERRMANN, S. (1994) Thermal balance in health and disease. Advances in pharmacological science. Birkhäuser Verlag, Basel.Google Scholar
NICHELMANN, M., HÖCHEL, J. and TZSCHENTKE, B. (1999) Biological rhythms in birds – development, insights and perspectives. Comparative Biochemistry and Physiology 124A: 437-439.Google Scholar
OPHIR, E., ARIELI, Y., MARDER, J. and HOROWITZ, M. (2002) Cutaneous blood flow in the pigeon Columba livia: its possible relevance to cutaneous water evaporation. Journal of Experimental Biology 205: 2627-2636.CrossRefGoogle ScholarPubMed
PARSELL, D.A. and LINDQUIST, S. (1994) Heat shock proteins and stress tolerance, in: MORIMOTO, R.I., TISSIERES, A., & GEORGOPOULOS, C. (Eds) Biology of heat shock proteins and molecular chaperones, pp. 457-494 (Cold Spring Harbor, NY, Cold Spring Harbor Laboratory Press).Google Scholar
PIESTUN, Y., SHINDER, D., HALEVY, O. and YAHAV, S. (2008a) The effect of thermal manipulations during development of the thyroid and adrenal axes on in-hatch and post-hatch thermoregulation. Journal of Thermal Biology 33: 413-418.CrossRefGoogle Scholar
PIESTUN, Y., SHINDER, D., RUZAL, M., HALEVY, O., BRAKE, J. and YAHAV, S. (2008b) The effect of thermal manipulations during development of the thyroid and adrenal axes on in-hatch and post-hatch thermoregulation. Poultry Science 87: 1516-1525.CrossRefGoogle Scholar
RICHARDS, S.A. (1968) Vagal control of thermal panting in mammals and birds. Journal of Physiology 199: 89-101.CrossRefGoogle ScholarPubMed
RICHARDS, S.A. (1970) The biology and comparative physiology of thermal panting. Biological Review 45: 223-264.CrossRefGoogle ScholarPubMed
RICHARDS, S.A. (1976) Evaporative water loss in domestic fowls and its partition in relation to ambient temperature. Journal of Agricultural Sciences 87: 527-532.Google Scholar
SENAY, L.C., MITCHELL, D. and WYNDHAM, C.H. (1976) Acclimatization in a hot humid environment: body fluid adjustment. Journal of Applied Physiology 40: 786-796.CrossRefGoogle Scholar
SEYMOUR, S.R. (1972) Convective heat transfer in the respiratory systems of panting animals. Comparative Biochemistry and Physiology 35: 119-127.Google ScholarPubMed
SHABTAY, A. and ARAD, Z. (2006) Reciprocal activation of HSF1 and HSF3 in brain and blood tissues: is redundancy developmentally related? American Journal of Physiology, Regular Integration Comparative Physiology 291: R566-R572.CrossRefGoogle ScholarPubMed
SILVA, J.E. (2006) Thermogenic mechanisms and their hormonal regulation. Physiological Reviews 86: 435-464.CrossRefGoogle ScholarPubMed
STURKIE, P.D. (1967) Cardiovascular effects of acclimatization to heat and cold in chickens. Journal of Applied Physiology 22: 13-15.CrossRefGoogle ScholarPubMed
STURKIE, P.D., LIN, Y.C. and OSSORIO, N. (1970) Effects of acclimatization to heat and cold on heart rate in chickens. American Journal of Physiology 219: 34-36.CrossRefGoogle ScholarPubMed
TONA, K., ONAGBESAN, O., BRUGGMANN, V., COLLIN, A., BERRI, C., DUCLOS, M.J., TESSERAUD, S., BUYSE, J., DECUYPERE, E. and YAHAV, S. (2008) Effects of heat conditioning at d 16 to 18 of incubation or during early broiler rearing on embryo physiology, post-hatch growth performance and heat tolerance. Archive für Geflügelkunde 72: 75-83.Google Scholar
TZSCHENTKE, B. and BASTA, D. (2002) Early development of neuronal hypothalamic sensitivity in birds: influence of epigenetic temperature adaptation. Comparative Biochemistry and Physiology A 131: 825-832.CrossRefGoogle ScholarPubMed
TZSCHENTKE, B., BASTA, D. and NICHELMANN, M. (2001) Epigenetic temperature adaptation in birds: peculiarities and similarities in comparison to acclimation. News in Biomedical Sciences 1: 26-31.Google Scholar
TZSCHENTKE, B., BASTA, D., JANKE, O. and MAIER, I. (2004) Characteristics of early development of body functions and epigenetic adaptation to the environment in poultry: focused on development of central nervous mechanisms. Avian and Poultry Biology Reviews 15: 107-118.CrossRefGoogle Scholar
TZSCHENTKE, B. and and PLAGEMANN, A. (2006) Imprinting and critical periods in early development. World's Poultry Science Journal 4: 626-637.CrossRefGoogle Scholar
UNI, Z., GAL-GARBER, O., GEYRA, A., SKLAN, D. and YAHAV, S. (2001) Changes in growth and function of chick small intestine epithelium due to early thermal conditioning. Poultry Science 80: 438-445.CrossRefGoogle ScholarPubMed
VOLLOCH, V. and RITS, S. (1999) A natural extracellular factor that induces HSP72, inhibits apoptosis and restores stress resistance in aged human cells. Experimental Cellular Research 253: 483-492.CrossRefGoogle ScholarPubMed
WANG, S. and EDENS, F.W. (1998) Heat conditioning induces heat shock proteins in broiler chickens and turkey poults. Poultry Science 77: 1636-1645.CrossRefGoogle ScholarPubMed
WEBB, D.R. (1987) Thermal tolerance of avian embryos: a review. The Condor 89: 874-898.CrossRefGoogle Scholar
WEBSTER, M.D. and KING, J.R. (1987) Temperature and humidity dynamics of cutaneous and respiratory evaporation in pigeons, Columba livia. Journal of Comparative Physiology 157: 253-260.CrossRefGoogle ScholarPubMed
WELCH, W.J. (1993) How cells respond to stress. Scientific American 268: 34-41.CrossRefGoogle ScholarPubMed
WHITTOW, G.C., STURKIE, P.D. and STEIN, G. Jr. (1964) Cardiovascular changes associated with thermal polypnea in the chicken. American Journal of Physiology 207: 1349-1353.CrossRefGoogle ScholarPubMed
WOLFENSON, D. (1986) The effect of acclimatization on blood flow and its distribution in normothermic and hyperthermic domestic fowl. Comparative Biochemistry and Physiology A 85: 739-742.CrossRefGoogle ScholarPubMed
WOLFENSON, D., FREI, Y.F., SNAPIR, N. and BERMAN, A. (1981) Heat stress effects on capillary blood flow and its redistribution in the laying hen. Pflugers Archives 390: 86-93.CrossRefGoogle ScholarPubMed
WOLFENSON, D., BACHRACH, D., MAMAN, M., GRABER, Y. and ROZENBOIM, I. (2001) Evaporative cooling of ventral regions of the skin in heat-stressed laying hens. Poultry Science 80: 958-964.CrossRefGoogle ScholarPubMed
WYSE, D.G. and NICKERSON, M. (1971) Studies on hemorrhagic hypotension in domestic fowl. Canadian Journal of Physiology and Pharmacology 49: 919-926.CrossRefGoogle ScholarPubMed
YAHAV, S. (1999) The effect of constant and diurnal cyclic temperatures on performance and blood system of young turkeys. Journal of Thermal Biology 24: 71-78.CrossRefGoogle Scholar
YAHAV, S. (2000) Domestic fowl — strategies to confront environmental conditions. Poultry and Avian Biology Reviews 11: 81-95.Google Scholar
YAHAV, S., COLLIN, A., SHINDER, D. and PICARD, M. (2004a) Thermal manipulations during broiler chick's embryogenesis – the effect of timing and temperature. Poultry Science 83: 1959-1963.CrossRefGoogle ScholarPubMed
YAHAV, S., GOLDFELD, S., PLAVNIK, I. and HURWITZ, S. (1995) Physiological responses of chickens and turkeys to relative humidity during exposure to high ambient temperature. Journal of Thermal Biology 20: 245-253.CrossRefGoogle Scholar
YAHAV, S. and HURWITZ, S. (1996) Induction of thermotolerance in male broiler chickens by temperature conditioning at an early age. Poultry Science 75: 402-406.CrossRefGoogle ScholarPubMed
YAHAV, S., LUGER, D., CAHANER, A., DOTAN, M., RUZAL, M. and HURWITZ, S. (1998) Thermoregulation in naked neck chickens subjected to different ambient temperatures. British Poultry Science 39: 133-138.CrossRefGoogle ScholarPubMed
YAHAV, S., RUZAL, M. and SHINDER, D. (2007) The effect of ventilation on performance, body and surface temperature of young turkeys. Poultry Science 87: 133-137.CrossRefGoogle Scholar
YAHAV, S. SHAMAY, A., , HOREV, G., BAR-ILAN, D., GENINA, O. and FRIEDMAN-EINAT, M. (1997b) Effect of acquisition of improved thermotolerance on the induction of heat shock proteins in broiler chickens. Poultry Science 76: 1428-1434.CrossRefGoogle ScholarPubMed
YAHAV, S., SHINDER, D., RAZPAKOVSKI, V., RUSAL, M. and BAR, A. (2000) Lack of response of laying hens to relative humidity at high ambient temperature. British Poultry Science 41: 660-663.CrossRefGoogle ScholarPubMed
YAHAV, S., SHINDER, D. TANNY, J., and COHEN, S. (2005) Sensible heat loss – the broiler's paradox. World's Poultry Science Journal 61: 419-435.CrossRefGoogle Scholar
YAHAV, S., STRASCHNOW, A. LUGER, D., , SHINDER, D., TANNY, J. and COHEN, S. (2004b) Ventilation, sensible heat loss, broiler energy, and water balance under harsh environmental conditions. Poultry Science 83: 253-258.CrossRefGoogle ScholarPubMed
YAHAV, S., STRASCHNOW, A., PLAVNIK, I. and HURWITZ, S. (1996) Effect of diurnal cyclic versus constant temperatures on chicken growth and food intake. British Poultry Science 37: 43-54.CrossRefGoogle Scholar
YAHAV, S., STRASCHNOW, A., PLAVNIK, I. and HURWITZ, S. (1997a) Blood system response of chickens to changes in environmental temperature. Poultry Science 76: 627-633.CrossRefGoogle ScholarPubMed
ZHOU, W. (2000) Physiological significance of the change in blood viscosity of broiler chickens under high ambient temperature. Japanese Poultry Science 37: 201-211.CrossRefGoogle Scholar