ADSA 2022 Abstract: Effects of dietary crude protein level and feeding pattern on nitrogen balance and nutrient digestibility

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MaryGrace Erickson1, Geoffrey I. Zanton2, and Michel A. Wattiaux1

1Department of Animal & Dairy Sciences, University of Wisconsin—Madison, Madison, WI, USA

2USDA-Agricultural Research Service, US Dairy Forage Research Center, Madison, WI, USA

 

Limited research has assessed nitrogen (N) partitioning in relation to dietary crude protein (CP) level and feeding pattern. To test a hypothesized interaction, we examined 8 mid- to late-lactation Holsteins (M = 142, SD = 23 DIM) in a Latin Rectangle with 2x2 factorial treatments CP level (LP, 13.9%; HP, 15.4%) and feeding pattern (O = oscillating, S = static). O alternated 2 diets (O-LP 12.2-15.5%, O-HP 13.9-16.9% CP) every 48 hr so mean diet composition equaled that of corresponding S treatments (S-LP, S-HP). Diets exchanged soy hulls and ground corn with solvent soybean meal to maintain constant ratios of NDF:starch (1.18), rumen-degradable protein:CP (0.61), and forage:concentrate (60:40). Each 28-d period on d-25-28, we weighed and sampled total collections (3x/d) of feces and urine and collected samples of milk (2x/d) and orts (1x/d). We analyzed feed and feces period composites and individual urine samples. We fit linear mixed models with fixed CP level, feeding pattern, and period effects, and a random intercept for cow; computing model-implied means and standard errors (SEM). Neither CP level, feeding pattern, nor the interaction affected production of milk (38.9±1.9 kg/d) or fat-protein-corrected milk (37.1±1.4 kg/d). Neither CP level, feeding pattern nor the interaction affected dry matter intake (25.0±0.8 kg/d) or apparent total tract digestibility of neutral detergent fiber (aNDFom; 56.6±1.3%) or organic matter (72.9±0.7%). Relative to LP, HP increased N intake (546 vs. 627 g/d, SEM = 23) and urine N (153 vs. 207 g/d, SEM = 6), and tended to increase fecal N (183 vs. 201 g/d, SEM = 8). Neither CP level, feeding pattern, nor the interaction affected milk N (177±7 g/d), N digestibility (69.6±0.6%), or apparent N balance (38±11 g/d). Compared to LP, HP reduced N use efficiency (32.4 vs. 28.9%; SEM = 1.1) and increased N intake allocated to urine (28.4 vs. 33.5%; SE = 0.8) both of which were unaffected by feeding pattern or the interaction. Results showed CP level affected N partitioning regardless of feeding pattern, which had minimal effects.  

 

Keywords:  total collection, protein oscillation, dairy cow


References

1.     Rauch, R., Martín-Tereso, J., Daniel, J. B., & Dijkstra, J. (2021). Dietary protein oscillation: Effects on feed intake, lactation performance, and milk nitrogen efficiency in lactating dairy cows. Journal of Dairy Science104(10), 10714–10726. https://doi.org/10.3168/JDS.2021-20219

2.     Tebbe, A. W., & Weiss, W. P. (2020). Effects of oscillating dietary crude protein concentrations on production, nutrient digestion, plasma metabolites, and body composition in lactating dairy cows. Journal of Dairy Science103(11), 10219–10232. https://doi.org/10.3168/JDS.2020-18613

3.     Kohler, J. (2014). The influence of oscillating dietary crude protein concentrations on milk production and nitrogen utilization in lactating dairy cowshttps://harvest.usask.ca/handle/10388/7292

4.     Barros, T., Quaassdorff, M. A., Aguerre, M. J., Colmenero, J. J. O., Bertics, S. J., Crump, P. M., & Wattiaux, M. A. (2017). Effects of dietary crude protein concentration on late-lactation dairy cow performance and indicators of nitrogen utilization. Journal of Dairy Science100(7), 5434–5448. https://doi.org/10.3168/jds.2016-11917

5.     Huhtanen, P., & Hristov, A. N. (2009). A meta-analysis of the effects of dietary protein concentration and degradability on milk protein yield and milk n efficiency in dairy cows. Journal of Dairy Science92(7), 3222–3232. https://doi.org/10.3168/jds.2008-1352

6.     Powell, J. M., & Rotz, C. A. (2015). Measures of nitrogen use efficiency and nitrogen loss from dairy production systems. Journal of Environmental Quality44(2), 336–344. https://doi.org/10.2134/JEQ2014.07.0299

7.     Menezes, A. C. B., v. Filho, S. C., Pucetti, P., C. Pacheco, M. v, Godoi, L. A., Zanetti, D., Alhadas, H. M., Paulino, M. F., & Caton, J. S. (2019). Oscillating and static dietary crude protein supply: II. Energy and protein requirements of young Nellore bulls. Translational Animal Science3(4), 1216–1226. https://doi.org/10.1093/tas/txz139

8.     Ludden, P. A., Wechter, T. L., & Hess, B. W. (2002). Effects of oscillating dietary protein on nutrient digestibility, nitrogen metabolism, and gastrointestinal organ mass in sheep1,2. Journal of Animal Science80(11), 3021–3026. https://doi.org/10.2527/2002.80113021x

 



KeywordsADSA, 2022, abstract, nutrient, digestibility, nitrogen, nitrogen balance, total collection, protein oscillation, dairy cow   Doc ID118626
OwnerMaryGrace E.GroupDairy Nutrient
Created2022-05-20 09:11:27Updated2022-05-20 09:15:21
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