Efeito do histórico reprodutivo da vaca sobre o desempenho da progênie

John Lenon Klein; Ivan Luiz Brondani; Dari Celestino Alves Filho; Sander Martinho Adams; Joziane Michelon  Cocco; Fabiana Moro Maidana; Ricardo Gonçalves Gindri; Dieson Pansiera Antunes

doi:10.33448/rsd-v10i1.11823

Authors

John Lenon Klein Universidade Federal de Santa Maria https://orcid.org/0000-0001-8337-4152
Ivan Luiz Brondani Universidade Federal de Santa Maria https://orcid.org/0000-0002-6526-3042
Dari Celestino Alves Filho Universidade Federal de Santa Maria https://orcid.org/0000-0003-2559-7504
Sander Martinho Adams Universidade Federal de Santa Maria https://orcid.org/0000-0003-4895-8237
Joziane Michelon Cocco Universidade Federal de Santa Maria https://orcid.org/0000-0001-6617-3076
Fabiana Moro Maidana Universidade Federal de Santa Maria https://orcid.org/0000-0002-9946-5355
Ricardo Gonçalves Gindri Universidade Federal de Santa Maria https://orcid.org/0000-0003-3674-8400
Dieson Pansiera Antunes Universidade Federal de Santa Maria https://orcid.org/0000-0002-9672-8455

DOI:

https://doi.org/10.33448/rsd-v10i1.11823

Keywords:

Body score; Fetal programming; Weight gain; Nutrition.

Abstract

The nutritional and physiological condition of the cow during pregnancy has been associated with fetal formation and future progeny performance. The objective of the work was to evaluate the effects of the history of the pregnant cow on the progeny performance. 343 Charolais and Nellore beef cows were used, divided according to reproductive history: pregnant cows that repeated pregnancy (P); empty cows that have impregnated (V). The data were collected during 5 years in the experimental herd. V cows had a higher body condition score (BCS) (2.83 vs 3.05 points) and body weight at the end of the reproductive season (462.72 vs 478.82 kg), in addition to a lower BCS at calving (2.58 vs 2.64 points) and greater weight loss during pregnancy (-35.17 vs -13.34 kg) compared to P cows. The weight adjusted at 205 days of age was higher in the progeny of P cows (140.54 vs 139.35 kg), with no effects at 365 and 540 days (P>0.05). The performance at 7 months of age was higher in the progeny of P cows (0.517 vs 0.502 kg/day), while the progeny of V cows was superior at 12 and 18 months of age, with values respectively of 0.558 vs 0.397 and 0.397 vs 0.351 kg/day. Calves of P cows showed higher Kleiber value at 7 months, while the progeny of V cows was more efficient at 12 months. The reproductive history of the cow influences the performance of the progeny, where empty cows produce calves with greater productive potential in adulthood.

References

ABIEC – Associação Brasileira de Indústrias Exportadoras de Carne (2020). Perfil da Pecuária no Brasil. São Paulo, Brasil.

ANUALPEC – Anuário Brasileiro da Pecuária (2019). Instituto FNP e Agra FNP Pesquisas LTDA, São Paulo, Brasil.

Bauman, D. E., & Currie, B. (1980). Partitioning of nutrients during pregnancy and lactation: a review of mechanisms involving homeostasis e homeorhesis. Journal of Dairy Science, 63(9), 1514-1529.

Bohnert, D. W., Stalker, L. A., Mills, R. R., Nyman, A., Falck, S. J., & Cooke, R. F. (2013). Late gestation suplementation of beff cows differing in body condition score: Effects on cow and calf performance. Journal of Animal Science, 91(11), 5485-5491.

Camacho, L. E., Lemley, C. O., Dorsam, S. T., Swanson, K. C., & Vonnahme, K. A. (2018). Effects of maternal nutrient restriction followed by realimentation during early and mid-gestation in beef cows. II. Placental development, umbilical blood flow, and uterine blood flow responses to diet alterations. Theriogenology, 116, 1-11.

Du, M., Tong, J., Zhao, J., Underwood, K. R., Zhu, M., Ford, S. P., & Nathanielsz, P. W. (2010). Fetal programming of skeletal muscle development in ruminant animals. Journal Animal Science, 88, 51-60.

Du, M., Huang, Y., Das, A. K., Yang, Q., Duarte, M. S., Modson, M. V., & Zhu, M. J. (2013). Manipulating mesenchymal progenitor cell differentiation to optimize performance and carcass value of beef cattle. Journal Animal Science, 91(3), 1419-1427.

González-Recio, O., Ugarte, E.; & Bach, A. (2012). Trans-Generational Effect of Maternal Lactation during Pregnancy: A Holstein Cow Model. Plos One, 7(12), 1-7.

Klein, J. L., Machado, D. S., Porsch, R. V., Brondani, I. L., Alves Filho, D. C., Moura, A. F., Cardoso, G. S., Silva, A. L., Domingues, C. C., & Silva, M. A., (2018). Eficiência bionutricional e características da carcaça de novilhos confinados recebendo distintas fontes nitrogenadas com milho moído ou inteiro. Semina: Ciências Agrárias, 39(6), 2541-2554.

LeMaster, C. T., Taylor, R. K., Ricks, R. E., & Long, N. M. (2017). The effects of late gestation maternal nutrient restriction whit or without protein supplementation on endocrine regulation of newborn and postnatal beef calves. Theriogenology, 87, 64-71.

Long, N. M., Vonnahme, K. A., Hess, B. W., Nathanielsz, P. W., & Ford, S. P. (2009). Effects of early gestational undernutrition on fetal growth, organ development, and placentomal composition in the bovine. Journal of Animal Science, 87, 1950-1959.

Maresca, S., Lopes Valiente, S., Rodrigues, A. M., Long, N. M., Pavan, E., & Quintans, G. (2018). Effect of protein restriction of bovine dams during late gestation on offspring postnatal growth, glucose-insulin metabolism and IGF-1 concentration. Livestock Science, 212, 120-126.

Marques, R. S., Cooke, R. F., Rodrigues, M. C., Moriel, P., & Bohnert, D. W. (2016). Impacts of cow body condition score during gestation on weaning performance of the offspring. Livestock Science, 191, 174-178.

McCarty, K. J., Washburn, J. L., Taylor, R. K., & Long, N. M. (2020). The effects of early or mid-gestation nutrient restriction on bovine fetal pancreatic development. Domestic Animal Endocrinology, 70, 1-6.

Mohrhauser, D. A., Taylor, A. R., Underwood, K. R., Pritchard, R. H., Wertz-Lutz, A. E., & Blair, D. A. (2015). The influence of maternal energy status during midgestation on beef offspring carcass characteristics and meat quality. Journal of Animal Science, 93, 786-793.

Reynolds, L. P., Borowicz, P. P., Caton, J. S., Crouse, M. S., Dahlen C. R., & Ward, A. K. (2019). Developmental Programming of Fetal Growth and Development. Veterinary Clinics Food Animal, 35(2), 229-247.

Silveira, M. F., Restle, J., Alves Filho, D. C., Missio, R. L., Donicht, P. A. M. M., Segabinazzi, L. R., Callegaro, A. M., & Joner, G. (2014). Suplementação com gordura protegida para vacas de corte desmamadas precocemente mantidas em pastagem natural. Arquivo Brasileiro de Medicina Veterinária e Zootecnia 66(3), 809-817.

Taylor, A. R., Mohrhauser, D. A., Pritchard, R. H., Underwood, K. R., Wertz-Lutz, A. E., & Blair, D. A. (2016). The influence of maternal energy status during mid-gestation on growth, cattle performance, and the immune response in the resultant beef progeny. The Professional Animal Scientist, 32, 389-399.

Torres, H. A. L., Tineo, J. S. A., & Raidan, F. S. S., (2015). Influência da condição corporal na probabilidade de prenhez de bovinos de corte. Archivos de Zootecnia, 64(247), 255-260.

Webb, M. J., Block, J. J., Funstons, R. N., Underwood, K. R., Legako, J. F., Harty, A. A., Slaverson, R. R., Olson, K. C., & Blair, A. D. (2019). Influence of maternal protein restriction in primiparous heifers during mid and/or late-gestation on meat quality and fatty acid profile of progeny. Meat Science, 152, 31-37.

Effect of the cow's reproductive history on the progeny performance

Authors

DOI:

Keywords:

Abstract

References

Downloads

Published

How to Cite

Issue

Section

License

JOURNAL METRICS

Language

Make a Submission