Physiological adaptability of livestock to heat stress: an updated review
Veettiparambil Pandarathil Rashamol, Veerasamy Sejian, Madiajagan Bagath, Govindan Krishnan, Payyanakkal Ravindranathan Archana, Raghavendra Bhatta
Abstract
Climate change associated heat stress was established to be the crucial factor, which negatively influences animal production. The animals possess several adaptive mechanisms which are helpful for their survival in harsh environmental conditions, but while doing so their productive performances are compromised. Among the various mechanisms, which helps to maintain homeostasis in animals, Physiological adaptability was considered one of the primary response mechanisms by which the heat stressed animals survive the heat stress. This review is therefore an attempt to provide the audience an updated review on the subject to signify the importance of physiological responses in animals and their role in surviving the stressful environment. Respiration rate (RR), pulse rate (PR), rectal temperature (RT), sweating rate (SR) and skin temperature (ST) are the cardinal physiological variables which helps to maintain the heat balance and homeostasis in the stressed animals. Among the various physiological variables, RR, RT and ST were established to be ideal indicators for quantifying heat stress in several farm animals. Therefore, these variables can be effectively used to assess the severity of heat stress in livestock. Although these variables are considered significant in establishing the heat stress impact in animals, a wide genetic variation was also established in these response mechanisms. Further, variations in physiological adaptability were also established between indigenous, cross bred and pure bred animals. The indigenous livestock breeds were tipped to be exhibiting less physiological variability as compared to their counterparts. These discussions vividly indicate the importance of studying in detail the physiological adaptive mechanisms in different farm animals and these efforts can help the farming community to identify the suitable agro-climatic zone specific livestock breeds which can go in long way to help to ensure climate resilient livestock production.
Keywords
References
Alameen AO, Abdelatif AM (2012) Metabolic and endocrine responses of crossbred dairy cows in relation to pregnancy and season under tropical conditions. American-Eurasian Journal of Agricoltural & Environmental Science 12:1065-1074.
Alamer M (2011) Water requirements and body water distribution in Awassi sheep and Aardi goats during winter and summer seasons. The Journal of Agricultural Science 149:227-234.
Aleena J, Pragna P, Archana PR, Sejian V, Bagath M, Krishnan G, Manimaran A, Beena V, Kurien EK, Varma G, Bhatta R (2017) Significance of Metabolic Response in Livestock for Adapting to Heat Stress Challenges. Asian Journal of Animal Science 10:9-16.
Al-Haidary AA (2004) Physiological responses of Naimey sheep to heat stress challenge under semi-arid environments. International Journal of Agriculture and Biology 2:307-309.
Al-Haidary AA, Aljumaah RS, Alshaikh MA, Abdoun KA, Samara EM, Okab AB, Alfuraiji MM (2012) Thermoregulatory and physiological responses of Najdi sheep exposed to environmental heat load prevailing in Saudi Arabia. Pakistan Veterinary Journal 32:515-519.
Amundson JL, Mader TL, Rasby RJ, Hu QS (2006) Environmental effects on pregnancy rate in beef cattle. Journal of Animal Science 84:3415-3420.
Aritonang SB, Yuniati R, Abinawanto, Imron M, Bowolaksono A (2017) Physiology Response of the Indigenous Cattle Breeds to the Environment in West Sumbawa, Indonesia. AIP Conference Proceedings 1862, 030098. doi: 10.1063/1.4991202
Ashutosh A, Dhanda O, Kunou R (2000) Physiological responses of native and crossbred sheep to climatic stress under semi-arid conditions. Indian Journal of Animal Science 8:857–861.
Aziz MA (2010) Present status of the goat populations and their productivity. Lohmann Information 45:42-52.
Berman A (2005) Estimates of heat stress relief needs for Holstein dairy cows. Journal of Animal Science 83:1377-1384.
Bhakat M, Mohanty TK, Gupta AK, Abdullah M (2014) Effect of season on semen quality of crossbred (Karan Fries) bulls. Advances in Animal and Veterinary Sciences 2:632-637.
Cardoso CC, Peripolli V, Amador SA, Brandão EG, Esteves GI, Sousa CM, França MF, Gonçalves FG, Barbosa FA, Montalvão TC, Martins CF (2015) Physiological and thermographic response to heat stress in zebu cattle. Livestock Science 182:83-92.
Chakravarthi K, Bidarkar DK, Ramesh Gupta B, Rao GN, Sudhakar K, Babu Rao K (2004) Drought performance of Ongole bulls under thermal stress conditions. Indian Journal of Animal Science 74:119-121.
Chandra Bhan, Singh SV, Hooda OK, Upadhyay RC, Beenam, Mangesh V (2012) Influence of temperature variability on Physiological, hematological and biochemical Profile of growing and Adult Sahiwal cattle. Journal of Environmental Research and Development 7:986-994.
Chandra Bhan, Singh SV, Upadhyay RC, Hooda OK, Baliyan Beenam (2013) Impact of temperature variability on physiological, hematological and biochemical profile of growing and adult Murrah buffaloes. Journal of Agrometeorology 15:146-152.
da Silva RG, La Scala Jr N, Tonhati H (2003) Radiative properties of the skin and haircoat of cattle and other animals. Transactions of the ASAE 46:913.
da Silva WE, Leite JHGM, de Sousa JER, Costa WP, da Silva WST, Guilhermino MM, Façanha DAE (2017) Daily rhythmicity of the thermoregulatory responses of locally adapted Brazilian sheep in a semiarid environment. International Journal of Biometerology 61:1221-1231.
Dalcin VC, Fischer V, Daltro DD, Alfonzo EP, Stumpf MT, Kolling GJ, Silva MV, McManus C (2016) Physiological parameters for thermal stress in dairy cattle. Revista Brasileira de Zootecnia 45:458-465.
Das MR, Sarma RK, Saikia R, Kale VS, Shelke MV, Sengupta P (2011) Synthesis of silver nanoparticles in an aqueous suspension of graphene oxide sheets and its antimicrobial activity. Colloids and Surfaces B: Biointerfaces 83:16-22.
Das R, Sailo L, Verma N, Bharti P, Saikia J (2016) Impact of heat stress on health and performance of dairy animals: A review. Veterinary World 9:260.
Delgado C (2005) Rising demand for meat and milk in developing countries: implications for grasslands-based livestock production. In: McGilloway DA (Ed.) Grassland: a global resource. The Netherlands: Wageningen Academic Publishers 29–39.
El-Tarabany MS, El-Tarabany AA, Atta MA (2017) Physiological and lactation responses of Egyptian dairy Baladi goats to natural thermal stress under subtropical environmental conditions. International Journal of Biometeorology 61:61-68.
FAO (Food and Agriculture Organization), IFAD (International Fund for Agriculture Development) and WFP (world Food Programme) (2015). The State of Food Insecurity in the World 2015. Meeting the 2015 international hunger targets: taking stock of uneven progress. Rome, FAO.
Garnett T (2009) Livestock-related greenhouse gas emissions: impacts and options for policymakers. Environmental Science & Policy 12:491–503.
Gebremedhin KG, Hillman PE, Lee CN, Collier RJ, Willard ST, Arthington JD, Brown-Brandl TM (2008) Sweating rates of dairy cows and beef heifers in hot conditions. Transactions of the ASABE 51:2167-2178.
Gebremedhin KG, Wu B (2001) A model of evaporative cooling of wet skin surface and fur layer. Journal of Thermal Biology 26:537-545.
Gesualdi Júnior A, Sales ÉS, Freitas RS, Henry FD, Oliveira VD, Gesualdi AC (2014) Effects of heat stress on the physiological parameters and productivity of hair sheep in tropical and coastal environments. Revista Brasileira de Zootecnia 43:556-560.
Gupta M, Kumar S, Dangi SS, Jangir BL (2013) Physiological, biochemical and molecular responses to thermal stress in goats. International Journal of Livestock Research 3:27-38.
Henry B, Charmley E, Eckard R, Gaughan JB, Hegarty R (2012) Livestock production in a changing climate: adaptation and mitigation research in Australia. Crop and Pasture Science 63:191–202.
Hillman PE, Gebremedhin KG, Brown-Brandl TM, Lee CN (2005) Thermal analysis and behavioral activity of heifers in shade or sunlight. In: Livestock Environment VII, Beijing, China. American Society of Agricultural and Biological Engineers. 151.
Hillman PE, Lee CN, Carpenter JR, Baek KS, Parkhurst A (2001) Impact of hair color on thermoregulation of dairy cows to direct sunlight. In: ASAE Annual Meeting 1998. American Society of Agricultural and Biological Engineers.
Hooda OK, Upadhyay RC (2014) Physiological responses, growth rate and blood metabolites under feed restriction and thermal exposure in kids. Journal of Stress Physiology & Biochemistry. 10:214-227.
Indu S, Pareek A (2015) A Review: Growth and Physiological Adaptability of Sheep to Heat Stress under Semi–Arid Environment. International Journal of Emerging Trends in Science and Technology. doi 10.18535/ijetst/v2i9.09
IPCC (Intergovermental Panel on Climate Change) (2013) The physical science basis. In: Stocker TF, Qin D, Plattner GK, Tignor M, Allen SK, Boschung J, Nauels A, Xia Y, Bex V, Midgley PM (Eds.) Contribution of Working Group I to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA. 1535.
IPCC (Intergovernmental Panel on Climate Change) (2007) Fourth Assessment Report: Climate Change, Working Group I: The Physical Science Basisrect Global Warming Potentials. Solomon S, Qin D, Manning M, Chen Z, Marquis M, Averyt KB, Tignor M, Miller HL (eds.). Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp 996 .
Jiang M, Gebremedhin KG, Albright LD (2005) Simulation of skin temperature and sensible and latent heat losses through fur layers. Transactions of the ASAE 48:767–775.
Kadzere CT, Murphy MR, Silanikove N, Maltz E (2002) Heat stress in lactating dairy cows: a review. Livestock Production Science 77:59-91.
Katiyatiya CLF, Bradley G, Muchenje V (2017) Thermotolerance, health profile and cellular expression of HSP90AB1 in Nguni and Boran cows raised on natural pastures under tropical conditions. Journal of Thermal Biology 69:85-94.
Koga A, Kuhara T, Kanai Y (2004) Comparison of body water retention during water deprivation between swamp buffaloes and Friesian cattle. Journal of Agricultural Science 138:435-440.
Koubkova, M., Kuizkova I., Kunc P., Hartlova H., Flusser Jersey, Dolezal O (2002) Influence of high environmental temperature and evaporative cooling on some physiological, haemamtological and biochemical parameters in high yielding dairy cows. Journal of Animal Science 47:309-318.
Kumar D, Yadav B, Choudhury S, Kumari P, Madan AK, Singh SP, Rout PK, Ramchandran N, Yadav S (2017) Evaluation of adaptability to different seasons in goat breeds of semi-arid region in India through differential expression pattern of heat shock protein genes. Biological Rhythm Research 15:1-3.
Kumar V, Ravikumar RK (2016) Indigenous innovations in livestock production systems: NIF initiatives. In: Invited Papers: Innovative Designs and Implements for Global Environment and Entrepreneurial Needs Optimizing Utilitarian Sources, Indigenous, International Livestock Conference and Expo, 23rd Annual Convention, ISAPM, Hyderabad, India. 28-31.
Lamy E, van Harten S, Sales-Baptista E, Guerra MM, de Almeida AM (2012) Factors influencing livestock productivity. In: Environmental stress and amelioration in livestock production. Springer Berlin Heidelberg, pp 19-51.
Mader TL (2003) Environmental stress in confined beef cattle. Journal of Animal Science 81:110-119.
Marai IF, El-Darawany AA, Fadiel A, Abdel-Hafez MA (2007) Physiological traits as affected by heat stress in sheep—a review. Small Ruminant Research 71:1-2.
Marai IF, Haeeb AA (2010) Buffalo's biological functions as affected by heat stress—A review. Livestock Science 127:89-109.
Marai IFM, Bhagat LB, Shalaby TH, Abdel-Hafez MA (2000) Fattening performances, some behavioral traits and physiological reactions of male lambs fed concentrates mixture alone with or without natural clay, under hot summer of Egyptian. Annals of Arid Zone 39:449–460.
McManus CM, Paludo GR, Louvandini H, Gugel R, Sasaki LCB, Paiva SR (2009) Heat tolerance in Brazilian sheep: physiological and blood parameters. Tropical Animal Health Production 41:95–101.
Nardone A, Ronchi B, Lacetera N, Ranieri MS, Bernabucci U (2010) Effects of climate change on animal production and sustainability of livestock systems. Livestock Science 130:57–69.
Nienaber JA, Hahn GL (2007) Livestock production system management responses to thermal challenges. International Journal of Biometeorology 52:149–157.
Nwosu CC, Ogbu CC. 2011. Climate change and livestock production in nigeria: issues and concerns. Agro-Science J Trop Agri, Food, Environ Extension 10:41-60.
Paulo JLA, Lopes FA (2014) Daily activity patterns of Saanen goats in the semi-arid northeast of Brazil. Revista Brasileira de Zootecnia 43:464–470.
Popoola MA, Bolarinwa MO, Yahaya MO, Adebisi GL, Saka AA (2014) Thermal comfort effects on physiological adaptations and growth performance of West African dwarf goats raised in Nigeria. European Scientific Journal 10:275-281.
Pragnna P, Sejian V, Soren NM, Bagath M, Krishnan G, Beena V, Indira Devi P, Bhatta R (2017) Summer season induced rhythmic alterations in metabolic activities to adapt to heat stress in three indigenous (Osmanabadi, Malabari and Salem Black) goat breeds. Biological Rhythm Research. doi 10.1080/09291016.2017.1386891
Renaudeau D, Huc E, Noblet J (2007) Acclimation to high ambient temperature in Large White and Caribbean Creole growing pigs. Journal of Animal Science 85:779-790.
Reynolds C, Crompton L, Mills J (2010) Livestock and climate change impacts in the developing world. Outlook Agriculture 39:245–248.
Rosegrant MW, Fernandez M, Sinha A (2009) Looking into the future for agriculture and AKST. In: McIntyre BD, Herren HR, Wakhungu J, Watson RT (Ed), International Assessment of Agricultural Knowledge, Science and Technology for Development (IAASTD). Agriculture at a crossroads, Island Press, Washington, DC, pp 307–376.
Sailo L, Gupta ID, Das R, Chaudhari MV (2017) Physiological Response to Thermal Stress in Sahiwal and Karan Fries Cows. International Journal of Livestock Research 7:275-83.
Sejian V, Maurya VP, Naqvi SM (2010) Adaptability and growth of Malpura ewes subjected to thermal and nutritional stress. Tropical Animal Health and Production 42:1763-1770.
Shaji S, Sejian V, Bagath M, Mech A, David ICG, Kurien EK, Varma G, Bhatta R (2016) Adaptive capability as indicated by behavioral and physiological responses, plasma HSP70 level and PBMC HSP70 mRNA expression in Osmanabadi goats subjected to combined (heat and nutritional) stressors. International Journal of Biometeorology 60:1311–1323.
Sharma R, Singh PK, Maitra A, Pandey AK, Mukesh M, Singh SR, Singh B (2013) Molecular characterization, body parameters and management practices of Purnea cattle. Indian Journal of Animal Science 83:536–541.
Silanikove N, Koluman N (2015) Impact of climate change on the dairy industry in temperate zones: predications on the overall negative impact and on the positive role of dairy goats in adaptation to earth warming. Small Ruminant Research 123:27-34.
Singh KM, Singh S, Ganguly I, Ganguly A, Nachiappan RK, Chopra A, Narula HK (2016) Evaluation of Indian sheep breeds of arid zone under heat stress condition. Small Ruminant Research 141:113-117.
Singh R, Singh SV (2005) Variations in cutaneous temperature, physiological responses and blood biochemical in Karan Fries and Sahiwal heifers during solar exposure in summer. Indian Journal of Dairy Science 58:415-419.
Souza PT, Salles MG, da Costa AN, Carneiro HA, de Souza LP, Rondina D, de Araújo AA (2014) Physiological and production response of dairy goats bred in a tropical climate. International Journal of Biometeorology 58:1559-1567.
Sprott LR, Selk GE, Adams DC (2001) Factors affecting decisions on when to calve beef females. The Professional Animal Scientist 17:238-246.
Steinfeld H, Gerber P, Wassenaar TD, Castel V, de Haan C (2006) Livestock's long shadow: environmental issues and options. Food & Agriculture Organisation.
Svotwa E, Makarau A, Hamudikuwanda H (2007) Heat tolerance of Mashona, Brahman and Simmental cattle breeds under warm humid summer conditions of natural region II area of ZImbabew. Electronic Journal of Environmental, Agricultural and Food Chemistry 6:1934 -1944.
Thornton PK (2010) Livestock production: recent trends, future prospects. Philosophical Transactions of the Royal Society of London B: Biological Sciences 365:2853-2867.
UNPD (United Nations Population Division) (2008) World population prospects: the 2006 revision. UNPD. http://esa.un.org/unpp/.
Upadhyay RC, Sirohi S, Ashutosh, Singh SV, Kumar A, Gupta SK (2009) Impact of climate change on milk production in India. In: Aggarwal PK (Ed.) Global climate change and Indian agriculture, Published by ICAR, New Delhi, pp 104-106.
Valente ÉE, Chizzotti ML, de Oliveira CV, Galvão MC, Domingues SS, de Castro Rodrigues A, Ladeira MM (2015) Intake, physiological parameters and behavior of Angus and Nellore bulls subjected to heat stress. Semina: Ciências Agrárias 16:4565-4574.
van Vuuren D, Ochola W, Riha S, Giampietro M, Ginzo H, Henrichs T, Hussain SH, Kok K, Makhura MM, Mirza M, Palanisami KP (2009). Outlook on agricultural changes and its drivers. InAgriculture at a Crossroads-the Global Report of the International Assessment of Agricultural Knowledge, Science, and Technology. Island Press, pp 255-305
Walker B, Carpenter S, Anderies J, Abel N, Cumming G, Janssen M, Lebel L, Norberg J, Peterson G, Pritchard R (2002) Resilience management in social-ecological systems: a working hypothesis for a participatory approach. Conservation ecology. 19. URL: http://www.consecol.org/vol6/iss1/art14
World Bank (2009) Minding the stock: bringing public policy to beasssr on livestock sector development. Washington, Report no. 44010-GLB.
Submitted date:
03/17/2018
Accepted date:
04/17/2018