Respons Fisiologis Ayam KUB (Kampung Unggul Balitbangtan) dan Ayam Walik dengan Haplotipe Gen HSP70 Berbeda yang Terpapar Cekaman Panas Akut

  • Any Aryani Program Studi Biologi, Departemen Pendidikan Biologi, Fakultas Pendidikan Matematika dan Ilmu Pengetahuan Alam Universitas Pendidikan Indonesia, Jl. Dr. Setiabudi No.229, Bandung 40154
  • Dedy Duryadi Solihin Departemen Biologi, Fakultas Matematika dan Ilmu Pengetahuan Alam Institut Pertanian Bogor, Kampus IPB Darmaga, Bogor 16680
  • Cece Sumantri Departemen Ilmu Produksi dan Teknologi Peternakan, Fakultas Peternakan Institut Pertanian Bogor, Kampus IPB Darmaga, Bogor 16680
  • Rudi Afnan Departemen Ilmu Produksi dan Teknologi Peternakan, Fakultas Peternakan Institut Pertanian Bogor, Kampus IPB Darmaga, Bogor 16680
  • Tike Sartika Balai Penelitian Ternak. Jl. Veteran III, PO BOX 221 Ciawi, Bogor 16720


This study was conducted to determine the physiological response of acute heat stress in Kampung Unggul Balitbangtan (KUB) and Walik chickens with four different HSP70 gene haplotypes (H1', H1, H2, and H3). Acute heat stress is carried out at 35°C for one hour. The data was analyzed based on rectal temperature measurements, distribution of body surface temperature (head, neck, body, and leg area), hormone levels (corticosterone and triiodothyronine), and time of panting. Body surface temperature is detected using infrared thermography. The results showed that haplotype H1 Walik chicken is more susceptible to heat stress based on the rectal temperature. In contrast, H1' haplotype Walik chicken released more heat through the body surface in the leg area.

Keywords: heat stress, hormone, KUB chicken, infrared thermography, walik chicken


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Ajakaiye JJ, Pérez AB, Mollineda AT. 2011. Effects of high temperature on production in layer chickens supplemented with vitamins C and E. Revista MVZ Córdoba. 16(1): 22832291.

Archana PR, Aleena I, Pragua P, Vidya MK, Niyas APA, Bagath M, Krishnan G, Manimaran A, Beena V, Kurien EK, Sejian V, Bhatta R. 2017. Role of heat shock proteins in livestock adaptation to heat stress. Journal of Dairy, Veterinary and Animal Research. 5(1): 00127.

Aryani A, Solihin DD, Sumantri C, Afnan R, Sartika T. 2019. Genetic diversity of the structure of HSP70 gene in kampung unggul Balitbangtan (KUB), walik and kate walik chickens. Tropical Animal Science Journal. 42(3):1 80188. tasj.2019.42.3.180.

Barrett NW, Rowland K, Schmidt CJ, Lamont SJ, Rothschild MF, Ashwell CM, Persia ME. 2019. Effects of acute and chronic heat stress on the performance, egg quality, body temperature, and blood gas parameters of laying hens. Poultry Science. 98: 66846692. 10.3382/ps/pez541.

Bogin E, Avidar Y, Pech-Waffenschmidt, Doron Y, Israeli BA, Kevkhayev E. 1996. The relationship between heat stress, survivability and blood composition of the domestic chicken. European Journal of Clinical Chemistry and Clinical Biochemistry. 34(6): 463469. https://doi.10.1515/ cclm.1996.34.6.463.

Chen XY, Wei PP, Xu SH, Geng ZY, Jiang RS. 2013. Rectal temperature as an indicator for heat tolerance in chicken. Animal Science Journal. 84: 737739. https://doi.10.1111/asj.12064.

Cunningham JG, Klein BG. 2007. Textbook of Veterinary Physiology. 4th Ed. St. Louis Missouri (US): WB Saunders Elsevier.

Gerken M, Afnan R, Dörl J. 2006. Adaptive behavior in chickens in relation to thermoregulation. Archiv fur Geflügelkunde. 70(5): 199207.

Giloh M, Shinder D, Yahav S. 2012. Skin surface temperature of broiler chickens is correlated to body core temperature and is indicative of their thermoregulatory status. Poultry Science. 91: 175188. https://doi.10.3382/ps.2011-01497.

Kataria N, Kataria AK, Gahlot AK. 2008. Ambient temperature associated variations in serum hormones and interrelated analytes of broiler chickens in arid tract. Slovenian Veterinary Research. 45(4): 127134.

Komalasari L. 2014. Dampak suhu tinggi terhadap respons fisiologi, profil darah dan performa produksi dua bangsa ayam berbeda [tesis]. Bogor (ID): Institut Pertanian Bogor.

Lamoreux WF, Hutt FB. 1939. Variability of body temperature in the normal chick. Poultry Science. 18: 7075.

Liang HM, Lin DY, Hsuuw YD, Huang TP, Chang HL, Lin CY, Wu HH, Hung KH. 2016. Association of heat shock protein 70 gene polymorphisms with acute thermal tolerance, growth, and egg production traits of native chickens in Taiwan. Archives Animal Breeding. 59: 173181.

Lin H, Jiao HC, Buyse J, Decuypere E. 2006. Strategies for preventing heat stress in poultry. World’s Poultry Science Journal. 62(1): 7186.

Mazzi CM, Ferro JA, Ferro MIT, Savino VJM, Coelho AAD, Macari M. 2003. Polymorphism analysis of the hsp70 stress gene in broiler chickens (Gallus gallus) of different breeds. Genetics and Molecular Biology. 26(3): 275281.

McCafferty DJ. 2013. Applications of thermal imaging in avian science. The International Journal of Avian Science. 155: 415.

Melesse A, Maak S, Schmidt R, Lengerken GV. 2011. Effect of long-term heat stress on key enzyme activities and T3 levels in commercial layer hens. International Journal of Livestock Production. 2(7): 107116.

Nääs IA, Romanini CEB, Neves DP, Nascimento GR, Vercellino RA. 2010. Broiler surface temperature distribution of 42 day old chickens. Scientia Agricola. 67(5): 497502.

Nascimento GR, Nääs IA, Pereira DF, Baracho MS, Garcia R. 2011. Assessment of broiler surface temperature variation when exposed to different air temperatures. Brazilian Journal of Poultry Science. 13(4): 259263.

Osti R, Bhattarai D, Zhou D. 2017. Climatic variation: effects on stress level, feed intake, and body weight of broilers. Brazilian Journal of Poultry Science. 19(3): 489496.

Romanoff AL. 1941. Development of homeothermy in birds. Science. 94(2435):218-219. 10.1126/science.94.2435.218.

Soleimani AF, Zulkifli I, Omar AR, Raha AR. 2011. Physiological responses of 3 chicken breeds to acute heat stress. Poultry Science. 90: 1435–1440.

Sugito, Delima M. 2009. Dampak cekaman panas terhadap pertambahan bobot badan, rasio heterofil:limfosit dan suhu tubuh ayam broiler. Jurnal Kedokteran Hewan. 3(1): 218226.

Tamzil MH, Noor RR, Hardjosworo PS, Manalu W, Sumantri C. 2013a. Keragaman gen heat shock protein 70 pada ayam kampung, ayam arab dan ayam ras. Journal of Veterinary. 14(3): 317326.

Tamzil MH, Noor RR, Hardjosworo PS, Manalu W, Sumantri C. 2013b. Acute heat stress responses of three lines of chickens with different heat shock protein (HSP)-70 genotypes. International Journal of Poultry Science. 12(5): 264272.

Tkáčová J, Angelovičová M. 2012. Heat shock protein (HSPs): a review. Journal of Animal Science and Biotechnology. 45(1): 349353.

Wilson, WO. 1948. Some effects of increasing environmental temperatures on pullets. Poultry Science. 27: 813817.

Yalçin S, Testik A, Ozkan S, Settar P, Çelen F, Cahaner A. 1997. Performance of naked neck and normal broilers in hot, warm, and temperate climates. Poultry Science. 76(7): 930937.

Zhao Y, Xin H, Dong B. 2013. Use of infrared thermography to assess laying-hen feather coverage. Poultry Science. 92: 295302.

How to Cite
AryaniA., SolihinD. D., SumantriC., AfnanR., & SartikaT. (2021). Respons Fisiologis Ayam KUB (Kampung Unggul Balitbangtan) dan Ayam Walik dengan Haplotipe Gen HSP70 Berbeda yang Terpapar Cekaman Panas Akut. Jurnal Ilmu Pertanian Indonesia, 26(2), 276-283.