[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.7744/kjoas.20210083

Effects of the crude protein concentration on the growth performance and blood parameters in growing Hanwoo steers (Bos taurus coreanae)

Seoyoung, Jeon (Division of Animal and Dairy Sciences, Chungnam National University)
Hyunjin, Cho (Division of Animal and Dairy Sciences, Chungnam National University)
Hamin, Kang (Division of Animal and Dairy Sciences, Chungnam National University)
Kyewon, Kang (Division of Animal and Dairy Sciences, Chungnam National University)
Mingyung, Lee (Division of Animal and Dairy Sciences, Chungnam National University)
Enkyu, Park (Division of Animal and Dairy Sciences, Chungnam National University)
Seokman, Hong (Woosung Feed Co., Ltd.)
Seongwon, Seo (Division of Animal and Dairy Sciences, Chungnam National University)

Publication Information

Korean Journal of Agricultural Science / v.48, no.4, 2021 , pp. 975-985 More about this Journal

Abstract

The sufficient amount of protein supply is crucial for improving the growth performance of growing beef cattle. In addition, due to the improvement in the genetic potential of the carcass weight of Hanwoo steers, dietary protein requirements may be increased during the rapid growth period. Accordingly, the dietary crude protein (CP) level in growing Hanwoo steers has been increasing in the field. However, little scientific evidence is available in relation to this. Therefore, this study was conducted to test whether a higher dietary CP level than convention would improve the growth performance and body metabolism in growing Hanwoo steers. Fifty growing Hanwoo steers were randomly divided into two groups and fed either a commercial diet (CON) or a higher CP (HCP) concentrate mix, provided with a similar level of dietary energy. Tall fescue hay was provided ad libitum. The dietary CP level did not affect growth performance and blood metabolite. Nitrogen intake, predicted nitrogen excretion, and retained nitrogen were higher in the HCP group than in the CON group (p < 0.01). Although there was no difference in the nitrogen utilization efficiency, the growth efficiency per retained nitrogen decreased in the HCP group (p = 0.02). A higher dietary CP level may increase nitrogen retention in growing Hanwoo steers without improving growth performance, which leads to reduced growth efficiency per retained nitrogen. Furthermore, considering the high price of feed protein and increased nitrogen excretion to the environment, a further increase in the protein level may not be sustainable.

Keywords

blood metabolite; growth performance; Hanwoo; protein; steer;

Citations & Related Records

Times Cited By KSCI : 2 (Citation Analysis)

Reference
Cited By KSCI

1	Anderson P, Bergen W, Merkel R, Hawkins D. 1988. The effects of dietary crude protein level on rate, efficiency and composition of gain of growing beef bulls. Journal of Animal Science 66:1990-1996. DOI
2	Bahrami-Yekdangi H, Khorvash M, Ghorbani G, Alikhani M, Jahanian R, Kamalian E. 2014. Effects of decreasing metabolizable protein and rumen-undegradable protein on milk production and composition and blood metabolites of Holstein dairy cows in early lactation. Journal of Dairy Science 97:3707-3714. DOI
3	Bailey C, Duff G, Sanders S, Treichel J, Baumgard L, Marchello JA, Schafer DW, McMurphy C. 2008. Effects of increasing crude protein concentrations on performance and carcass characteristics of growing and finishing steers and heifers. Animal Feed Science and Technology 142:111-120. DOI
4	Berger L, Pyatt N. 2005. Nutritional and management factors affecting marbling deposition. University of Illionis, Illinois, USA.
5	Broderick G. 2003. Effects of varying dietary protein and energy levels on the production of lactating dairy cows. Journal of Dairy Science 86:1370-1381. DOI
6	Cho HU, Ko WS, Son HW, Lee MJ, Song HJ, Park JH. 2008. Hematological and biochemical analysis of Korean indigenous cattle according to the ages. Korean Journal of Veterinary Service 31:137-147. [in Korean]
7	Chung K, Chang S, Lee E, Kim H, Park H, Kwon E. 2015. Effects of high energy diet on growth performance, carcass characteristics, and blood constituents of final fattening Hanwoo steers. Korean Journal of Agricultural Science 42:261-268. [in Korean] DOI
8	Fox DG, Tedeschi LO, Tylutki TP, Russell JB, Van Amburgh ME, Chase LE, Pell AN, Overton TR. 2004. The Cornell net carbohydrate and protein system model for evaluating herd nutrition and nutrient excretion. Animal Feed Science and Technology 112:29-78. DOI
9	Galyean M. 1996. Protein levels in beef cattle finishing diets: Industry application, university research, and systems results. Journal of Animal Science 74:2860-2870. DOI
10	Gibb D, Hao X, McAllister T. 2008. Effect of dried distillers' grains from wheat on diet digestibility and performance of feedlot cattle. Canadian Journal of Animal Science 88:659-665. DOI
11	Gleghorn J, Elam N, Galyean M, Duff G, Cole N, Rivera J. 2004. Effects of crude protein concentration and degradability on performance, carcass characteristics, and serum urea nitrogen concentrations in finishing beef steers. Journal of Animal Science 82:2705-2717.
12	Hammond AC. 1997. Update on BUN and MUN as a guide for protein supplementation in cattle. pp. 43-52. In Proceeding Florida Ruminant Nutrtion Symposium, University of Florida, Gainesville, USA.
13	Huntington G, Poore M, Hopkins B, Spears J. 2001. Effect of ruminal protein degradability on growth and N metabolism in growing beef steers. Journal of Animal Science 79:533-541. DOI
14	Jeon S, Sohn KN, Seo S. 2016. Evaluation of feed value of a by-product of pickled radish for ruminants: Analyses of nutrient composition, storage stability, and in vitro ruminal fermentation. Journal of Animal Science and Technology 58:34.
15	Kim K, Lee J, Oh Y, Kang S, Lee S, Park W , Ko Y. 2005. The optimal TDN levels of concentrates and slaughter age in Hanwoo steers. Journal of Animal Science and Technology 47:731-744. [in Korean] DOI
16	Martin T, Perry T, Beeson W, Mohler M. 1978. Protein levels for bulls: Comparison of three continuous dietary levels on growth and carcass traits. Journal of Animal Science 47:29-33. DOI
17	Kohn R, Dinneen M, Russek-Cohen E. 2005. Using blood urea nitrogen to predict nitrogen excretion and efficiency of nitrogen utilization in cattle, sheep, goats, horses, pigs, and rats. Journal of Animal Science 83:879-889. DOI
18	Law R, Young F, Patterson D, Kilpatrick D, Wylie A, Mayne C. 2009. Effect of dietary protein content on animal production and blood metabolites of dairy cows during lactation. Journal of Dairy Science 92:1001-1012. DOI
19	MAFRA (Ministry of Agriculture and Forestry). 2007. Development of technology for high quality Hanwoo beef by controlling the nutrient level of protein and ADF in feeds of fattening phases. MAFRA, Sejong, Korea. [in Korean]
20	Martin T, Perry T, Mohler M, Owens F. 1979. Comparison of four levels of protein supplementation with and without oral diethylstilbestrol on daily gain, feed conversion and carcass traits of bulls. Journal of Animal Science 48:1026-1032. DOI
21	McBride K, Greene L, Cole N, McCollum F, Galyean M. 2003. Nitrogen and phosphorus utilization by beef cattle fed three dietary crude protein levels with there levels of supplemental urea. p. 114. In Proceeding Plains Nutrition Council Spring Conference, Texas A&M Research and Extension Center, Amarillo, USA.
22	Menezes ACB, Valadares SC, Pacheco MVC, Pucetti P, Silva BC, Zanetti D, Paulino MF, Silva FF, Neville TL, Caton JS. 2019. Oscillating and static dietary crude protein supply. I. Impacts on intake, digestibility, performance, and nitrogen balance in young Nellore. Bulls Translational Animal Science 3:1205-1215. DOI
23	NASEM (National Academies of Sciences, Engineering, and Medicine). 2016. Nutrient requirements of beef cattle. The National Academies Press, Washington, D.C., USA.
24	Perry T, Shields D, Dunn W, Mohler M. 1983. Protein levels and monensin for growing and finishing steers. Journal of Animal Science 57:1067-1076.
25	Ndlovu T, Chimonyo M, Okoh A, Muchenje V, Dzama K, Raats J. 2007. Assessing the nutritional status of beef cattle: Current practices and future prospects. African Journal of Biotechnology 6:2727-2734. DOI
26	Owens F, Gardner B. 2000. A review of the impact of feedlot management and nutrition on carcass measurements of feedlot cattle. Journal of Animal Science 77:1-18. DOI
27	Owens F, Zinn R, Kim Y. 1986. Limits to starch digestion in the ruminant small intestine. Journal of Animal Science 63:1634-1648.
28	Pethick D, McIntyre B, Tudor G. 2000. The role of dietary protein as a regulator of the expression of marbling in feedlot cattle (WA). Meat and Livestock Australia, Final report of project FLOT 209, North Sydney, Australia.
29	Prado I, Campo M, Muela E, Valero M, Catalan O, Olleta J, Sanudo C. 2014. Effects of castration age, dietary protein level and lysine/methionine ratio on animal performance, carcass and meat quality of Friesian steers intensively reared. Animal 8:1561-1568. DOI
30	Reed K, Moraes L, Casper D, Kebreab E. 2015. Predicting nitrogen excretion from cattle. Journal of Dairy Science 98:3025-3035. DOI
31	Rusche W, Cochran R, Corah L, Stevenson J, Harmon D, Brandt R, Minton J. 1993. Influence of source and amount of dietary protein on performance, blood metabolites, and reproductive function of primiparous beef cows. Journal of Animal Science 71:557-563.
32	SAS (Statistical Analysis System). 2015. Base SAS 9.4 procedures guide. SAS Institute Inc., Cary, NC, USA.
33	Sinclair K, Garnsworthy P, Mann G, Sinclair L. 2014. Reducing dietary protein in dairy cow diets: Implications for nitrogen utilization, milk production, welfare and fertility. Animal 8:262-274. DOI
34	Schroeder G, Titgemeyer E. 2008. Interaction between protein and energy supply on protein utilization in growing cattle: A review. Livestock Science 114:1-10. DOI
35	Seo S, Jeon S, Ha JK. 2018. Guidelines for experimental design and statistical analyses in animal studies submitted for publication in the Asian-Australasian Journal of Animal Sciences. Asian-Australasian Journal of Animal Sciences 31:1381-1386. DOI
36	Shain D, Stock R, Klopfenstein TJ, Herold D. 1998. Effect of degradable intake protein level on finishing cattle performance and ruminal metabolism. Journal of Animal Science 76:242-248. DOI
37	Steen R. 1996. Effects of protein supplementation of grass silage on the performance and carcass quality of beef cattle. The Journal of Agricultural Science 127:403-412. DOI
38	Tritschler J, Shirley R, Bertrand J. 1984. Tissue protein and energy deposition in steers fed isocaloric diets with different levels of nitrogen. Journal of Animal Science 58:444-451. DOI