Hostname: page-component-cd9895bd7-jkksz Total loading time: 0 Render date: 2024-12-23T18:29:41.206Z Has data issue: false hasContentIssue false

Heat stress: effects on productive and reproductive performance of quail

Published online by Cambridge University Press:  24 October 2017

M. ALAGAWANY*
Affiliation:
Poultry Department, Faculty of Agriculture, Zagazig University, Zagazig 44511, Egypt
M.R. FARAG
Affiliation:
Department of Forensic Medicine and Toxicology, Veterinary Medicine, Zagazig University, Zagazig, 44511, Egypt
M.E. ABD EL-HACK
Affiliation:
Poultry Department, Faculty of Agriculture, Zagazig University, Zagazig 44511, Egypt
A. PATRA
Affiliation:
Department of Animal Nutrition, West Bengal University of Animal and Fishery Sciences, Belgachia, Kolkata, India
*
Corresponding author: [email protected]
Get access

Abstract

Animals experiencing thermal stress tend to reduce heat production by limiting feed intake, with subsequent detrimental impacts on productive performance and health status. Heat stress as an environmental stressor has been an important concern among researchers, poultry producers and scientists for many decades, especially in tropical (wet and hot round the year) and arid (dry and hot round the year) regions of the world. It has been implicated in adverse marked impacts on productive and reproductive performance of quail. Several studies have investigated the negative impacts of heat stress on quail production and it has been shown that heat stress adversely affects both productivity and welfare of birds. The deleterious impacts of heat stress on different quail breeds such as Japanese quail (Coturnix coturnix japonica), bobwhite quail (Colinus virginianus), scaled quail (Callipepla californica) and Gambel's quail (Colinus gambelii) range from decreased body weight (7.7 to 13.2%), growth rate (11.0 to 14.5%), feed intake (6.1 to 21.6%), feed efficiency (4.3 to 8.6%), egg production (6.6 to 23.3%) and egg mass. Furthermore, the detrimental effects of heat stress on reproductive performance and welfare of quail have recently attracted awareness. However, further studies are required to increase the levels of information into basic mechanisms associated with the consequences of heat stress on quail. This review covers the published evidence available on the negative role of heat stress on growth performance, feed utilisation, egg production and mass, meat and egg quality and carcass traits as well as reproductive performance of quail.

Type
Reviews
Copyright
Copyright © World's Poultry Science Association 2017 

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

ALTAN, Ö., ALTAN, A., OĞUZ, I., PABUCCUOĞLU, A. and KONYALIOĞLU, S. (2000) Effects of heat stress on growth, some blood variables and lipid oxidation in broilers exposed to high temperature at an early age. British Poultry Science 41: 489-493.Google Scholar
AYO, J.O., OBIDI, J.A. and REKWOT, P.I. (2011) Effects of heat stress on the well-being, fertility, and hatchability of chickens in the northern guinea savannah zone of Nigeria: A Review. ISRN Veterinary Science 2011: 1-10.CrossRefGoogle ScholarPubMed
BARTLETT, J.R. and SMITH, M.O. (2003) Effects of different levels of zinc on the performance and immunocompetence of broilers under heat stress. Poultry Science 82: 1580-1588.CrossRefGoogle ScholarPubMed
BONFIM, D.S., DE SIQUEIRA, J.C., BOMFIM, M.A.D., RIBEIRO, F.B., DE OLIVEIRA, F.L., NASCIMENTO, D.C.N. and DE ARAUJO MELO, S. (2016) Productive characteristics of meat quail reared in different environments. Ciências Agrárias, Londrina 37: 4313-4326.Google Scholar
CHEN, Z., WANG, B., XIE, J. and TANG, J. (2014) Effect of γ-aminobutyric acid on digestive enzymes, absorption function, and immune function of intestinal mucosa in heat-stressed chicken. Poultry Science 93: 2490-2500.Google Scholar
CHENG, C.Y., TU, W.L., WANG, S.H., TANG, P.C., CHEN, C.F., CHEN, H.H. and HUANG, S.Y. (2015) Annotation of differential gene expression in small yellow follicles of a broiler-type strain of Taiwan country chickens in response to acute heat stress. PloS One 10: e0143418.Google Scholar
CLARK, C.E. and SARAKOON, K. (1967) Influence of ambient temperature on reproductive traits of male and female chicken. Poultry Science 46: 1093-1098.Google Scholar
DENG, W., DONG, X.F., TONG, J.M. and ZHANG, Q. (2012) The probiotic Bacillus licheniformis ameliorates heat stress-induced impairment of egg production, gut morphology, and intestinal mucosal immunity in laying hens. Poultry Science 91: 575-582.Google Scholar
EL-KHOLY, M.S., EL-HINDAWY, M.M., ALAGAWANY, M., ABD EL-HACK, M.E. and EL-SAYED, S.A.A. (2017) Dietary supplementation of chromium can alleviate negative impacts of heat stress on performance, carcass yield, and some blood hematology and chemistry indices of growing Japanese quail. Biological Trace Element Research DOI 10.1007/s12011-017-0936-z.CrossRefGoogle Scholar
ENSMINGER, M.E., OLDFIELD, J.E. and HEINEMANN, W.W. (1990) Feeds and nutrition, Ensiminger publishing, Colvis, Ca., pp. 108-110.Google Scholar
FOUAD, A.M., CHEN, W., RUAN, D., WANG, S., XIA, W.G. and ZHENG, C.T. (2016) Impact of heat stress on meat, egg quality, immunity and fertility in poultry and nutritional factors that overcome these effects: A Review. International Journal of Poultry Science 15: 81-95.CrossRefGoogle Scholar
GUTHERY, F.S., LAND, C.L. and HALL, B.W. (2001) Heat loads on reproducing bobwhites in the semiarid subtropics. The Journal of Wildlife Management 65: 111-117.Google Scholar
GERAERT, P.A., PADILHA, J.C.F. and GUILLAUMIN, S. (1996) Metabolic and endocrine changes induced by chronic heat exposure in broiler chickens: growth performance, body composition and energy retention. British Journal of Nutrition 75: 195-204.Google Scholar
HABIBIAN, M., GHAZI, S. and MOEINI, M.M. (2016) Effects of dietary selenium and vitamin E on growth performance, meat yield and selenium content and lipid oxidation of breast meat of broilers reared under heat stress. Biological Trace Element Research 169: 142-152.Google Scholar
KILIC, I. and SIMSEK, E. (2013) The effects of heat stress on egg production and quality of laying hens. Journal of Animal and Veterinary Advances 12: 42-47.Google Scholar
LARA, L.J. and ROSTAGNO, M.H. (2013) Impact of heat stress on poultry production. Animals 3: 356-369.Google Scholar
LOYAU, T., BEDRANI, L., BERRI, C., MÉTAYER-COUSTARD, S., PRAUD, C. and COUSTHAM, V. (2015) Cyclic variations in incubation conditions induce adaptive responses to later heat exposure in chickens: a review. Animal 9: 76-85.Google Scholar
MA, X., LIN, Y., ZHANG, H., CHEN, W., WANG, S., RUAN, D. and JIANG, Z. (2014) Heat stress impairs the nutritional metabolism and reduces the productivity of egg-laying ducks. Animal Reproduction Science 145: 182-190.Google Scholar
MILLER, P.C. and SUNDE, L.M. (1975) The effect of precise constant and cyclic environments on shell quality and other lay performance factors with Leghorn pullets. Poultry Science 51: 36-46.Google Scholar
NORDSTROM, J.O. (1973) Duration of egg formation in chickens during heat stress. Poultry Science 52: 1687-1690.CrossRefGoogle ScholarPubMed
ONDERIC, M., SAHIN, K., SAHIN, N., CIKIM, G., VIJAYA, J. and KUCUK, O. (2005) Effects of dietary combination of chromium and biotin on growth performance, carcass characteristics and oxidative stress markers in heat-distressed Japanese quail. Biological Trace Element Research 106: 165-176.CrossRefGoogle Scholar
OZBEY, O. and OZCELIK, M. (2004) The effect of high environmental temperature on growth performance of Japanese quail with different body weights. Journal of Poultry Science 3: 468-470.Google Scholar
RENAUDEAU, D., COLLIN, A., YAHAV, S., DE BASILIO, V., GOURDINE, J.L. and COLLIER, R.J. (2012) Adaptation to hot climate and strategies to alleviate heat stress in livestock production. Animal 6: 707-728.Google Scholar
SAHIN, K. and KUCUK, O. (2001) Effects of vitamin C and vitamin E on performance digestion of nutrients, and carcass characteristics of Japanese quail reared under chronic heat stress (34°C). Journal of Animal Physiology and Animal Nutrition 85: 335-342.Google Scholar
SAHIN, K. and KUCUK, O. (2003) Heat stress and dietary vitamin supplementation of poultry diets. Nutrition Abstract and Review Series B, Livestock Feeds and Feeding 73: 41-50.Google Scholar
SAHIN, K., ONDERIC, M., SAHI, N., GURSU, M.F., VIJAYA, J. and KUCUK, O. (2004) Effects of dietary combination of chromium and biotin on egg production, serum metabolites and egg yolk mineral and cholesterol concentrations in heat-distressed laying quail. Biological Trace Element Research 101: 181-192.Google Scholar
SAHIN, K., ONDERIC, M., SAHI, N., GURSU, M.F., VIJAYA, J. and KUCUK, O. (2005) Chromium picolinate, rather than biotin, alleviates performance and metabolic parameters in heat-stressed quail. British Poultry Science 46: 457-463.Google Scholar
SANTOS, R.R., AWATI, A., ROUBOS-VAN DEN HIL, P.J., TERSTEEG-ZIJDERVELD, M.H., KOOLMEES, P.A. and FINK-GREMMELS, J. (2015) Quantitative histo-morphometric analysis of heat-stress-related damage in the small intestines of broiler chickens. Avian Pathology 44: 19-22.Google Scholar
SATO, K., OTA, K. and KAWAMOTO, Y. (1974) Influence of environmental temperature on growth of Japanese quail. Scientific Reports of the Faculty of Agriculture, Okayama University.Google Scholar
SHANAWAY, M.M. (1984) Food and agriculture organisation of the United Nations, Rome.Google Scholar
SOHAIL, M.U., IJAZ, A., YOUNUS, M., SHABBIR, M.Z., KAMRAN, Z., AHMAD, S., ANWAR, H., YOUSAF, M.S., ASHRAF, K., SHAHZAD, A.H. and REHMAN, H. (2013) Effect of supplementation of mannan oligosaccharide and probiotic on growth performance, relative weights of viscera, and population of selected intestinal bacteria in cyclic heat-stressed broilers. The Journal of Applied Poultry Research 22: 485-491.CrossRefGoogle Scholar
SOHAIL, M.U., IJAZ, A., YOUSAF, M.S., ASHRAF, K., ZANEB, H., ALEEM, M. and REHMAN, H. (2010) Alleviation of cyclic heat stress in broilers by dietary supplementation of mannan-oligosaccharide and Lactobacillus-based probiotic: Dynamics of cortisol, thyroid hormones, cholesterol, C-reactive protein, and humoral immunity. Poultry Science 89: 1934-1938.Google Scholar
SONG, J., XIAO, K., KE, Y.L., JIAO, L.F., HU, C.H., DIAO, Q.Y., SHI, B. and ZOU, X.T. (2014) Effect of a probiotic mixture on intestinal microflora, morphology, and barrier integrity of broilers subjected to heat stress . Poultry Science 93: 581-588.Google Scholar
SOUSA, M.S., TINÔCO, I.F.F., BARRETO, S.L.T., AMARAL, A.G., PIRES, L.C. and FERREIRA, A.S. (2014) Determinação de limites superiores da zona de conforto térmico para codornas de corte aclimatizadas no Brasil de 22 a 35 dias de idade. Revista Brasileira de Saúde e Produção. Animal 15: 350-360.Google Scholar
SYAFWAN, S., KWAKKEL, R.P. and VERSTEGEN, M.W.A. (2011) Heat stress and feeding strategies in meat-type chickens. World's Poultry Science Journal 67: 653-673.Google Scholar
TEMIM, S., CHAGNEAU, A.M., GUILLAUMIN, S., MICHEL, J., PERESSON, R. and TESSEARAUD, S. (2000) Dose excess dietary protein improve growth performance and carcass characteristics in heat exposed chickens. Poultry Science 79: 312-317.CrossRefGoogle Scholar
THOMPSON, J.B., WILSON, H.R. and VOITLE, R.A. (1976) Influence of high ambient temperature stress of 16 day old embryos on subsequent hatchability. Poultry Science 55: 892-894.CrossRefGoogle Scholar
TURK, G., CERIBASI, A.O., SIMSEK, U.G., CERIBASI, S. and GUVENC, M. (2016) Dietary rosemary oil alleviates heat stress-induced structural and functional damage through lipid peroxidation in the testes of growing Japanese quail. Animal Reproduction Science 164: 133-143.Google Scholar
TURK, G., SIMSEK, U.G., CERIBASI, A.O., CERIBASI, S. and KAYA, S.O. (2015) Effect of cinnamon (Cinnamomum zeylanicum) bark oil on heat stress-induced changes in sperm production, testicular lipid peroxidation, testicular apoptosis and androgenic receptor density in developing Japanese quail. Theriogenology 84: 365-376.CrossRefGoogle Scholar
VERCESE, F., GARCIA, E.A., SARTORI, J.R., SILVA, A. DE P., FAITARONE, A.B.G., BERTO, D.A., MOLINO, A. DE B. and PELÍCIA, K. (2012) Performance and egg quality of Japanese quail submitted to cyclic heat stress. Brazilian Journal of Poultry Science 14: 37-41.CrossRefGoogle Scholar
YALCIN, S., OZKAN, S., ACIKGOZ, Z. and OZKAN, K. (1998) Influence of dietary energy in poultry performance, carcass parts yields and nutrient composition of breast meat of heterozygous naked neck broilers reared at natural optimum and summer temperature. British Poultry Science 39: 633-638.Google Scholar
ZEFERINO, C.P., KOMIYAMA, C.M., PELICIA, V.C., FASCINA, V.B. and AOYAGI, M.M. (2016) Carcass and meat quality traits of chickens fed diets concurrently supplemented with vitamins C and E under constant heat stress. Animal 10: 163-171.Google Scholar