The effect of maternal factors on growth, skeletal growth factors, and serum total protein of Holstein dairy calves

Authors

1 Department of Animal Science , Isfahan (Khorasgan) Branch, Islamic Azad University, Isfahan, Iran.

2 Department of Animal Science , Isfahan (Khorasgan) Branch, Islamic Azad University, Isfahan, Iran

3 Animal Science Research Dep., Isfahan Agricultural and Natural Resources Research and Education Center, AREEO, 8174835117, Isfahan, Iran.

Abstract

Background and objective: The aim of this study was to investigate maternal factors including dry period length, parity, calving type, calf number per calving, and calving body condition score on body weight (BW), serum total protein (STP) concentration, and body structure growth of female Holstein dairy calves.
Materials and methods: 152 Holstein dairy cows and their female calves were studied in this experiment. The calves were weighed at birth and moved to individual pens bedded with sawdust, Fresh colostrum samples were collected from 152 Holstein dairy cows. Maternal effects include: number of births from 2 to 5. Type of childbirth: single or multiple, natural or hard birth. Dry period length which includes: Group 1 - under 45 days. Group 2- 46 to 60 days. Group 3 - 61 to 75 days and group 4- Over 75 days. Calves' BW was also measured on days 30 and 60 of the study.
Results: Birth BW was not affected by the mother's parity. The parity had an effect on the BW of calves at day 30 and 60, whereas, the lowest calves BW at day 30 was revealed in the five lactation cows. Also, the calves that were born to mothers who entered their second lactation were heavier than other calves at day 60 (P <0.05). Calf BW at birth, 30, and 60 days of age was affected by the number of calves at birth and the type of calving (P <0.05) so that singleton calves and normal birth calves had more BW. day 60 (P <0.05) was significant so that the mothers with dry period length less than 45 and more than 75 days had the lowest and highest 60-day calves BW. Serum total protein was affected by parity, calves’ number per calving, type of calving, and calving body condition score (P <0.05). In addition, the effect of calving type on STP concentration at birth and day 10 tended to be significant, while at day 35 normal birth calves had greater STP than dystocia birth calves. Withers height and body length in calves born to five lactations mothers were lower than other parities (P <0.05). Heart girth at birth and hip height at day 60 of age was higher in calves were born to mother with a dry period length more than 75 days (P <0.05). Body structure at birth and day 60 was higher for singleton calves than for twin calves and calves born with normal calving than calves born with dystocia (P <0.05).
Conclusion: The results of the current experiment showed that factors related to the physiological status of dams and calving type affect the immunity status and performance of infant's calves.

Keywords


  1. Beam, A.L., Lombard, J.E., Kopral, C.A., Garber, L.P., Winter, A.L., Hicks, J.A. and Schalter, J.L. 2009. Prevalence of failure of passive transfer of immunity in newborn heifer calves and associated management practices on US dairy operations. Journal of Dairy Science, 92:3973-3980.
  2. Carvalho, M.R, Aboujaoude, C., Penagaricano, F., Santos, J.E.P., Devriese, T.J., McBride, B.W. and Ribeiro, E.S. 2020. Associations between maternal characteristics and health, survival, and performance of dairy heifers from birth through first lactation. Journal of Dairy Science, 103:823-839.
  3. Conneely, M., Berry, D., Sayers, R., Murphy, J., Lorenz, I., Doherty, M. and Kennedy, E. 2013. Factors associated with the concentration of immunoglobulin G in the colostrum of dairy cows. Animal, 7: 1824–1832.
  4. Edmonson, A.J., Lean, I.J., Weaver, L.D., Farver, T. and Webster, G. 1989. A body condition scoring chart for Holstein dairy cows. Journal of Dairy Science, 72: 68-78.
  5. Eley, R.M., Thatcher, W.W., Fuller, W., Bazer, C.J., Wilcox, R.B., Becker, H., Head, H. and Adkinson, R.W. 1978. Development of the Conceptus in the Bovine. Journal of Dairy Science, 61:467-473.
  6. Funston, R.N., Larson, D.M., Vonnahme, K.A. 2010. Effects of maternal nutrition on conceptus growth and offspring performance: Implications for beef cattle production. Journal of Animal Science, 88: 205–215.
  7. Godden, S. 2008. Colostrum management for dairy calves. Veterinary Clinics of North America: Food Animal Practice, 24: 19-39.
  8. Gonzalez-Recio, O., Ugarte, E. and Bach, A. 2012. Trans-generational effect of maternal lactation during pregnancy: A Holstein cow model. PLoS One,7: e51816.
  9. Gulliksen, S.M., Lie, K.I., Solverod, L. and Osteras, O. 2008. Risk factors associated with colostrum quality in Norwegian dairy cows. Journal of Dairy Science, 91: 704–712.
  10. Haskins, S.C. 1977. Sampling and storage of blood for PH and blood gas analysis. Journal of the American Veterinary Medical Association, 170: 423-428.
  11. Hassig, M., Stadler, T. and Lutz, H. 2007. Transition from maternal to endogenous antibodies in newborn calves. Veterinary Record, 160:234–235.
  12. Jensine, W., Joao, H.C.C., Heather, W.N., Daniel, M.W. and Marina, A.G.V. 2018. Technical note: Serum total protein and immunoglobulin G concentrations in neonatal dairy calves over the first 10 days of age. Journal of Dairy Science, 101:1–7.
  13. Larson, L.L., Owens, F.G., Albright, J.L., Appleman, R.D., Lamb, R.C. and Muller, L.D. 1977. Guidelines towards more uniformity in measuring and reporting calf experimental data. Journal of Dairy Science, 60: 989–991.
  14. MacFarlane, J.A., Grove-White, D.H., Royal, M.D. and Smith, R.F. 2015. Identification and quantification of factors affecting neonatal immunological transfer in dairy calves in the UK. Veterinary Record, 176:625-630
  15. Mahnani, A., Sadeghi-Sefi dmazgi, A. and Cabrera, V. 2015. Consequences and economics of metritis in Iranian Holstein dairy farms. Journal of Dairy Science, 98: 6048–6057.
  16. Mehri, M., Seyfi, H. and Mokhber Dezfooli, M. Effects of number of calves, mode of delivery and season on total protein levels and different protein segments of blood serum of colostrum-fed calves. Iranian Journal of Veterinary Research, 2:184-186. (In Persian)
  17. Mohri, M., Sharifi, K. and Eidi, S. 2007. Hematology and serum biochemistry of Holstein dairy calves: Age related changes and comparison with blood composition in adults. Research in Veterinary Science, 83: 30–39.
  18. Morrill, K.M., Conrad, E., Lago, A., Campbell, J., Quigley, J. and Tyler, H. 2012. Nationwide evaluation of quality and composition of colostrums on dairy farms in the United States. Journal of Dairy Science, 95: 3997-4005.
  19. Mulder, R., Fosgate, G.T., Tshuma, T. and Lourens, D.C. 2017. The effect of cow-level factors on colostrum quality, passive immunity and health of neonatal calves in a pasture-based dairy operation. Animal Production Science, 58: 1225-1232.
  20. Nikkhah, A., Sadeghi, A.A. and Shoorang, P. 2005. Development, Nutrition and Management of Milking Calves. 1st ed, Publication of Tehran University. 225-229. (In Persian).
  21. Noya, A., Serrano-Pérez, B., Villalba, D., Casasús, I., Molina, E., López-Helguera, I. and Sanz, A. 2019. Effects of maternal subnutrition during early pregnancy on cow hematological profiles and offspring physiology and vitality in two beef breeds. Animal Science Journal, 90: 857–869.
  22. Olson, K.M., Cassell B.G., McAllister, A.J. and Washburn, S.P. 2009. Dystocia, stillbirth, gestation length, and birth weight in Holstein, Jersey and reciprocal crosses from a planned experiment. Journal of Dairy Science, 92: 6167-6175.
  23. Pritchett, L.C., Gay, C.C., Besser, T.E. and Hancock, D.D. 1991. Management and production factors influencing immunoglobulin G1 concentration in colostrum from Holstein cows. Journal of Dairy Science, 74: 2336–2341.
  24. Quigley, J.D., Lago, A., Chapman, C. and Erickson Polo, J. 2013. Evaluation of the Brix 26-refractometer to estimate immunoglobulin G concentration in bovine colostrum. Journal of Dairy Science, 96:1148-1155.
  25. Rahimi, H., Ariyazand, Y. and Ghorbani, A. 2010. Economic problems caused by twinning in dairy cows are factors influencing it. 16th Iranian Veterinary Congress. https://civilica.com/doc/840121
  26. Reschke, C., Schelling, E., Michel, A., Remy-Wohlfender, F. and Meylan, 2017. Factors associated with colostrum quality and effects on serum gamma globulin concentrations of calves in Swiss dairy herds. Journal of Veterinary Internal Medicine, 31:1563–157.
  27. 2001. SAS User’s Guide, Statistics. Statistical Analysis Systems. Version 9.1 ed. Cary, (NC), USA.
  28. Shamay, A., Werner, D., Moallem, V., Barash, H. and Bruckental, I. 2005. Effect of nursing management and skeletal size weaning on puberty, skeletal growth rate, and milk production during first lactation of dairy heifers. Journal of Dairy Science, 88: 1460-1469.
  29. Sorrells, A.D., Eicher, S.D., Scott, K.A., Harris, M.J., Pajor, E.A. and Lay Richert, B.T. 2006. Postnatal behavioral and physiological responses of piglets from gilts housed individually or in groups during gestation. Journal of Animal Science, 84:757–766.
  30. Swali, A. and Wathes, D.C. 2007. Influence of primiparity on size at birth, growth, the somatotrophic axis and fertility in dairy heifers. Animal Reproduction Science, 10: 0-12.
  31. Thornhill, J.B., Krebs, G.L. and Petzel, C.E. 2015. Evaluation of the Brix refractometer as an on-farm tool for the detection of passive transfer of immunity in dairy calves. Australian Veterinary Journal, 93: 26–30.
  32. Tyler, J.W., Steevens, B.J., Hostetler, D.E., Holle, J.M. and Denbigh, J.L. 1999. Colostral immunoglobulin concentrations in Holstein and Guernsey cows. American Journal of Veterinary Research, 60: 1136–1139.
  33. Wilm, J., Costa, J.H.C., Neave, H.W., Weary, D.M. and von Keyserlingk, M.A.G. 2018. Technical note: Serum total protein and immunoglobulin G concentrations in neonatal dairy calves over the first 10 days of age. Journal of Dairy Science, 101:1–7
  34. Windeyer, M.C., Leslie, K.E., Godden, S.M., Hodgins, D.C., Lissemore, K.D. and LeBlanc, S.J. 2014. Factors associated with morbidity, mortality, and growth of dairy heifer calves up to 3 months of age. Preventive Veterinary Medicine, 113:231–240.
  35. Wu, G., Bazer, F.W., Wallace, J.M. and Spencer, T.E. 2006. Intrauterine growth retardation: Implications for the animal sciences. Journal of Animal Science, 84: 2316–2337.