| Peer-Reviewed

Studying Resistance of Some Dairy Cattle Breeds to Heat Stress in Relation to Milk Yield

Received: 14 April 2021     Accepted: 29 April 2021     Published: 14 May 2021
Views:       Downloads:
Abstract

The objective for our work was to estimate the milk yield and blood biochemical constituents of and weight daily gain of calves recently born from imported cows under hot summer conditions in Egypt. Thirty late- pregnant cows, aged 22-24 months, chosen randomly were used in this study. Experiment was carried out during the period from third stage of pregnancy and continued to 8 weeks postpartum. Imported late-pregnant cows divided into three groups, each group was 10 cows. 1st group was Brown Swiss (BS) cows, 2nd group was Simmental (S) cows and 3rd group was Holstein (H). Results showed that H cows have a lowest rectal temperature (RT) and respiration rate (RR) in compare with BS and S cows. Results showed that H cows have a highest daily milk yield while S cows have lowest values. BS and H cows have significantly higher total protein, albumin and urea concentrations than S cows. While, globulin and glucose concentrations were significantly higher in BS than its concentrations in S and H cows, respectively. Total cholesterol, phospholipids and creatinine concentrations showed the lowest values in BS cows as compare with S and H cows. Otherwise, BS cows have the highest triglycerides concentration as compare with H and S cows. About liver function showed the highest activity for AST in S cows and for ALT in H cows as compared of other groups. BS cows have significantly higher T4 and Estradiol17β levels than its levels in S and H cows, respectively. Birth weight of newborn both male and female calves as well as daily body weight gain of calves produced from the three imported cows were not differs Significantly. Two months weight of calves produced from S cows was significantly higher than BS and H cows, respectively. In conclusion, the three imported breed cows appears good resistance to heat stress effects under hot summer conditions in Egypt with extremely resistance for H cows.

Published in Advances in Applied Physiology (Volume 6, Issue 1)
DOI 10.11648/j.aap.20210601.13
Page(s) 14-22
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

Copyright

Copyright © The Author(s), 2021. Published by Science Publishing Group

Keywords

Imported Cows, Heat Stress, Milk Yield

References
[1] Mahrous, H M (2016). Milk production and its role in food security in Egypt. Int J Chemtech Res CODEN (USA) 9: 329-340 2.
[2] Metwaly YM, Ali AI (2010). An economic study on dairy production and consumption in Egypt. Egypt. J. Agric. Res., 20: 141-150.
[3] Qin D, Chen Z, Averyt KB, Miller, H. L., Solomon, S., Manning, M., Marquis, M. and Tignor, M. (2007). Ipcc, 2007: Summary for policymakers.
[4] Bohmanova J (2006) Studies on genetics of heat stress in US Holsteins. PhD thesis, University of Georgia, Athens, GA, USA.
[5] Collier RJ, Dahl GE, Vanbaale MJ (2006). Major advances associated with environmental effects on dairy cattle. Journal of Dairy Science, 89: 1244-1253.
[6] Aguilar I, Misztal I, Tsuruta S. (2009). Genetic components of heat stress for dairy cattle with multiple lactation. Journal of Dairy Science, 92: 5702-5711.
[7] Aharoni Y, Brosh A, Ezra E (1999). Effect of heat load and photoperiod on milk yield and composition in three dairy herds in Israel. Animal Science, 69: 37-47.
[8] Gantner V, Denis K, Mirna G, Ranko G, Maja G, Tina B, Marcela S, Muhamed B (2019). Persistency of the Effect of Heat Stress in Simmental Cows in Eastern Croatia. Springer Nature Switzerland AG 2020 M. Brka et al. (Eds.): AgriConf 2019, IFMBE Proceedings 78, pp. 163–168, 2020.
[9] NRC (2001). Nutrient requirement of dairy cattle. 7th rev. ed. washington, dC., natl. Acad. Sci., 381 p.
[10] AOAC (2000) Official Methods of Analysis of the Association of Official Analytical Chemists International 17th ed. 2000, Suite 400 2200 Wilson Boulevard, Arlington, Virginia 22201-3301, USA: Association of Official Analytical Chemists International.
[11] Amundson JL, Mader TL, Rasby RG, Rasby QS (2006). Environmental effects on pregnancy rate in beef cattle. J. Anim. Sci., 84: 3415-3420.
[12] Ellefeson RD, Caraway WT (1982). Lipids and Lipoproteins. In Fundamentals of clinical chemistry (ed. N. W. Tietz), P. 474. W. B. Saunders Company, West Wastingtonsqure, Philadelphia, USA.
[13] SAS (2009). SAS Institute Inc., User’s Guide v9.0. Cary, NC, USA.
[14] Duncan DB (1955). Multiple range test and multiple F-test. Biometrics, 11: 1-42.
[15] West JW (1999). Nutritional strategies for managing the heat stresses dairy cow. Journal of Animal Sciences, 77: 21-35.
[16] Srikandakumar A, Riek PM, Horton GM (1993). "The effect of spraying cooling on respiration rate and rectal temperature in Australian Milking Zebu, Jersey and Holstein in a desert environment. Livestock Environment. IV." Proceedings of the 4th International Conference Symposium. ASAE, St Joseph, Mich. 1993.‏
[17] Ganaie AH, Shanker G, Bumla NA, Ghasura RS, Mir NA, Wani, SA, Dudhatra GB (2013). Biochemical and physiological changes during thermal stress in bovines. Journal of Veterinary Science and Technology, 4: 126.
[18] kumar AS, Johnson EH (2004). Effect of Heat Stress on Milk Production, Rectal Temperature, Respiratory Rate and Blood Chemistry in Holstein, Jersey and Australian Milking Zebu Cows. Tropical Animal Health and Production, 36: 685-692.
[19] Leles JS, Rodrigues IC, Vieira MF (2017). Heat Stress and Body Temperature in Brown Swiss Cows Raised in Semi-Arid Climate of Ceará State, Brazil. Acta Scientiae Veterinariae, 45: 1475.
[20] Correa-Calderon A, Armstrong D, Ray D, Denise S, Enns M (2004). Howison Thermoregulatory responses of Holstein and Brown Swiss Heat-Stressed dairy cows to two different cooling systems. Int J. Biometeorol, 48: 142–148.
[21] Dangi SS, Gupta M, Maurya D, Yadav VP, Panda RP, Singh G, Mohan NH, Bhure SK, Das BC, Bag S, Mahapatra RK, Sarkar M (2012). Expression Profile of HSP genes during different seasons in goats (Capra hircus). Tropical Animal Health and Production, 44: 1905–1912.
[22] Helal A, Hashem AL, Abdel-Fattah MS, El-Shaer HM (2010). Effects of heat stress on coat charecteristics and physiological responses of balady and Damascus goat in Sinai Egypt. American Euresian Journal of Agriculture and Environmental Science. 7 (1): 60-69.
[23] Habeeb AA, El-Masry KA, Gad AE, Basuony HA (2019). Milk yield and blood biochemical components in local and crossing bovine cows. J Anim Res Nutr., 4 (2): 5.
[24] Ocak S, Darcan N, Cankaya S, Cinal T (2009). Physiological and biochemical responses in German Fawn kids subjected to cooling treatments under Mediterranean climate conditions. Turkish Jouranl of Veterinary and Animal Science, 33 (6): 455-461.
[25] Bahga CS, Sikka SS, Saijpal S (2009). Effect of seasonal stress on growth rate and serum enzyme levels in young crossbred calves. Indian Journal of Animal Research. 43 (4): 288-290.
[26] Sharma AK, Kataria N (2011). Effects of extreme hot climate on liver and serum enzymes in Marwari goat. Indian Journal of Animal Science. 81 (3): 293-295.
[27] El-Masry K, Nessim M, Gad A (2010). Determination of heat tolerance coefficient in crossbred and Baladi pregnant cows under Egyptian environmental conditions. J. Rad. Res. Applie. Sci., 3 (4): 1399-1409.
[28] Marai IF, Habeeb AA, Daader AH, Yousef HM (1995). Effects of Egyptian subtropical summer conditions and the heat-stress alleviation technique of water spray and a diaphoretic on the growth and physiological functions of Friesian calves. Journal of Arid Environments, 30 (2): 219-225.
[29] Shwartz G, Rhoads ML, Vanbaale MJ, Rhoads RP, Baumgard LH (2009). Effects of a supplemental yeast culture on heat-stressed lactating Holstein cows. Journal of dairy science, 92 (3): 935-942.‏
[30] Montmurro N, Pacelli C, Borghese A (1995) Metabolic profiles in buffalo heifers bred in two farms with different feeding and climatic conditions. J Egyptian J. Anim. Prod., 32 (1): 1-12.
[31] Benedet A, Marco F, Carmen L, Mauro P, Massimo D (2020). Variation of Blood Metabolites of Brown Swiss, Holstein-Friesian, and Simmental Cows. Animals, 10 (2): 271.
[32] Leblanc SJ (2010). Monitoring metabolic health of dairy cattle in the transition period. J. Reprod. Dev., 56: 29–35.
[33] Urdl M, Gruber L, Obritzhauser W, Schauer A (2015). Metabolic parameters and their relationship to energy balance in multiparous Simmental, Brown Swiss and Holstein cows in the periparturient period as influenced by energy supply pre and post-calving. J. Anim. Physiol. Anim. Nutr., 99: 174 -189.
[34] Ocak S, Guey O (2010). Physiological responses and some blood parameters of bucks under Mediterranean climate conditions. Anadolu Journal of Agricultural Science, 25 (2): 113-119.
[35] Alameen AO, Abdelatif AM (2012). Metabolic and endocrine responses of crossbred dairy cows in relation to pregnancy and season under tropical conditions. J American-Eurasian Journal of Agricoltural Environmental Science, 12 (8): 1065-1074.
[36] Qu M, Wei S, Chen Z, Wang G, Zheng Y, Yan P. Differences of hormones involved in adipose metabolism and lactation between high and low producing Holstein cows during heat stress. Anim Nut. 2015; 1: 339-43.
[37] West JW (2003). Effects of heat stress on production in dairy cattle. Journal of Dairy Science, 86: 2131–2144.
[38] Tainturier D, Braun JP, Rico AG, Thouvenot JP (1984). Variation in blood composition in dairy cows during pregnancy and after calving. Res. Vet. Sci., 37: 129-131.
[39] Nazifi S, Saeb M, Ghavami S (2002). Serum lipid profile in iranian fat-tailed sheep in late pregnancy, at parturition and during the post-parturition period. Journal of Veterinary Medicine Series, 49 (1): 9-12.
[40] Kamal TH, Habeeb AA (1999). The effect of sex difference in Friesian calves on heat tolerance using the heat-induced changes in total body water, total body solids and some blood components. Egyptian Journal of Applied Science, 14 (12): 1-15.
[41] Kebede E (2018). Effect of Cattle Breed on Milk Composition in the same Management Conditions. Ethiop. J. Agric. Sci., 28 (2): 53-63.
[42] Ozawa M, Tabayashi D, Latief TA, Shimizu T, Oshima I, Kanai Y (2005) Alterations in follicular dynamics and steroidogenic abilities induced by heat stress during follicular recruitment in goats. Reproduction, 129 (5): 621-630.
[43] Doubek J, Slosarkova S, Fleischer P, Malá G, Skrivanek M (2003). Metabolic and hormonal profiles of potentiated cold stress in lambs during early postnatal period. Czech Journal of Animal Science, 48 (10): 403-412.
[44] Kumar A (2005). Status of oxidative stress markers in erythrocytes of heat exposed cattle and buffaloes. NDRI, Karnal.
[45] Tadesse M, Thiengtham J, Pinyopummin A, Prasanpanich S (2010). Productive and reproductive performance of Holstein Friesian dairy cows in Ethiopia. Livestock Research for Rural Development, 22 (2).
[46] Zaabal MM, Ahmed WM (2008). Monitoring of some reproductive parameters in local Egyptian Friesian cows with emphasis on the use of immunogenetic analysis for evaluation of fertility. Glob. J. Mol. Sci., 3: 21-26.
[47] Usman T, Qureshi MS, Yu Y, Wang Y (2013). Influence of various environmental factors on dairy production and adaptability of Holstein cattle maintained under tropical and subtropical conditions. Advances in Environmental Biology, 7 (2): 366-372.
[48] Usman T, Guo G, Suhail SM, Ahmed S, Qiaoxiang L, Qureshi MS, Wang Y (2011). Performance traits study of Holstein Friesian cattle under subtropical conditions. J. Anim. Plant. Sci., 21 (1): 961-964.
[49] Collier RJ, Collier JL, Rhoads RP, Baumgard LH (2008). Invited review: Gene involved in the bovine heat stress response. J. Dairy Sci., 91: 445-454.
[50] Maia SC, Silva RG, Bertipaglia EC (2003). Holstein cow fur characteristics in a tropical environment: a genetic and adaptive study. Revista Brasileira de Zootecnia. 32 (4): 843-853.
[51] Silva RG, La Scala JN, Tonhati H (2003). Radiative properties of the body surface of cattle and others animals. Transaction of ASAE. 4 (6): 913-918.
[52] Gantner V, Tina B, Maja G, Ranko G, Kresimir K, Klemen P (2017). Heat stress resistance and dairy cattle breed. Mljekarstvo, 67 (2): 112-122.
Cite This Article
  • APA Style

    Ahmed Elsayed Gad, Sana Sayed Emara, Sherif Yousif Eid, Hussein Mustafa El-Zaher. (2021). Studying Resistance of Some Dairy Cattle Breeds to Heat Stress in Relation to Milk Yield. Advances in Applied Physiology, 6(1), 14-22. https://doi.org/10.11648/j.aap.20210601.13

    Copy | Download

    ACS Style

    Ahmed Elsayed Gad; Sana Sayed Emara; Sherif Yousif Eid; Hussein Mustafa El-Zaher. Studying Resistance of Some Dairy Cattle Breeds to Heat Stress in Relation to Milk Yield. Adv. Appl. Physiol. 2021, 6(1), 14-22. doi: 10.11648/j.aap.20210601.13

    Copy | Download

    AMA Style

    Ahmed Elsayed Gad, Sana Sayed Emara, Sherif Yousif Eid, Hussein Mustafa El-Zaher. Studying Resistance of Some Dairy Cattle Breeds to Heat Stress in Relation to Milk Yield. Adv Appl Physiol. 2021;6(1):14-22. doi: 10.11648/j.aap.20210601.13

    Copy | Download

  • @article{10.11648/j.aap.20210601.13,
      author = {Ahmed Elsayed Gad and Sana Sayed Emara and Sherif Yousif Eid and Hussein Mustafa El-Zaher},
      title = {Studying Resistance of Some Dairy Cattle Breeds to Heat Stress in Relation to Milk Yield},
      journal = {Advances in Applied Physiology},
      volume = {6},
      number = {1},
      pages = {14-22},
      doi = {10.11648/j.aap.20210601.13},
      url = {https://doi.org/10.11648/j.aap.20210601.13},
      eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.aap.20210601.13},
      abstract = {The objective for our work was to estimate the milk yield and blood biochemical constituents of and weight daily gain of calves recently born from imported cows under hot summer conditions in Egypt. Thirty late- pregnant cows, aged 22-24 months, chosen randomly were used in this study. Experiment was carried out during the period from third stage of pregnancy and continued to 8 weeks postpartum. Imported late-pregnant cows divided into three groups, each group was 10 cows. 1st group was Brown Swiss (BS) cows, 2nd group was Simmental (S) cows and 3rd group was Holstein (H). Results showed that H cows have a lowest rectal temperature (RT) and respiration rate (RR) in compare with BS and S cows. Results showed that H cows have a highest daily milk yield while S cows have lowest values. BS and H cows have significantly higher total protein, albumin and urea concentrations than S cows. While, globulin and glucose concentrations were significantly higher in BS than its concentrations in S and H cows, respectively. Total cholesterol, phospholipids and creatinine concentrations showed the lowest values in BS cows as compare with S and H cows. Otherwise, BS cows have the highest triglycerides concentration as compare with H and S cows. About liver function showed the highest activity for AST in S cows and for ALT in H cows as compared of other groups. BS cows have significantly higher T4 and Estradiol17β levels than its levels in S and H cows, respectively. Birth weight of newborn both male and female calves as well as daily body weight gain of calves produced from the three imported cows were not differs Significantly. Two months weight of calves produced from S cows was significantly higher than BS and H cows, respectively. In conclusion, the three imported breed cows appears good resistance to heat stress effects under hot summer conditions in Egypt with extremely resistance for H cows.},
     year = {2021}
    }
    

    Copy | Download

  • TY  - JOUR
    T1  - Studying Resistance of Some Dairy Cattle Breeds to Heat Stress in Relation to Milk Yield
    AU  - Ahmed Elsayed Gad
    AU  - Sana Sayed Emara
    AU  - Sherif Yousif Eid
    AU  - Hussein Mustafa El-Zaher
    Y1  - 2021/05/14
    PY  - 2021
    N1  - https://doi.org/10.11648/j.aap.20210601.13
    DO  - 10.11648/j.aap.20210601.13
    T2  - Advances in Applied Physiology
    JF  - Advances in Applied Physiology
    JO  - Advances in Applied Physiology
    SP  - 14
    EP  - 22
    PB  - Science Publishing Group
    SN  - 2471-9714
    UR  - https://doi.org/10.11648/j.aap.20210601.13
    AB  - The objective for our work was to estimate the milk yield and blood biochemical constituents of and weight daily gain of calves recently born from imported cows under hot summer conditions in Egypt. Thirty late- pregnant cows, aged 22-24 months, chosen randomly were used in this study. Experiment was carried out during the period from third stage of pregnancy and continued to 8 weeks postpartum. Imported late-pregnant cows divided into three groups, each group was 10 cows. 1st group was Brown Swiss (BS) cows, 2nd group was Simmental (S) cows and 3rd group was Holstein (H). Results showed that H cows have a lowest rectal temperature (RT) and respiration rate (RR) in compare with BS and S cows. Results showed that H cows have a highest daily milk yield while S cows have lowest values. BS and H cows have significantly higher total protein, albumin and urea concentrations than S cows. While, globulin and glucose concentrations were significantly higher in BS than its concentrations in S and H cows, respectively. Total cholesterol, phospholipids and creatinine concentrations showed the lowest values in BS cows as compare with S and H cows. Otherwise, BS cows have the highest triglycerides concentration as compare with H and S cows. About liver function showed the highest activity for AST in S cows and for ALT in H cows as compared of other groups. BS cows have significantly higher T4 and Estradiol17β levels than its levels in S and H cows, respectively. Birth weight of newborn both male and female calves as well as daily body weight gain of calves produced from the three imported cows were not differs Significantly. Two months weight of calves produced from S cows was significantly higher than BS and H cows, respectively. In conclusion, the three imported breed cows appears good resistance to heat stress effects under hot summer conditions in Egypt with extremely resistance for H cows.
    VL  - 6
    IS  - 1
    ER  - 

    Copy | Download

Author Information
  • Biological Applications Department, Radioisotopes Applications Division, Nuclear Research Center, Egyptian Atomic Energy Authority, Cairo, Egypt

  • Biological Applications Department, Radioisotopes Applications Division, Nuclear Research Center, Egyptian Atomic Energy Authority, Cairo, Egypt

  • Biological Applications Department, Radioisotopes Applications Division, Nuclear Research Center, Egyptian Atomic Energy Authority, Cairo, Egypt

  • Biological Applications Department, Radioisotopes Applications Division, Nuclear Research Center, Egyptian Atomic Energy Authority, Cairo, Egypt

  • Sections