Department of Agriculture, Nutrition, and Food Systems, University of New Hampshire, Durham 03824.
Ajinomoto Co. Inc., Kawasaki-shi, Japan 210-8681.
J Dairy Sci. 2019 May;102(5):4138-4154. doi: 10.3168/jds.2018-15780. Epub 2019 Mar 7.
The dairy industry can benefit from low crude protein (CP) diets due to reduced N excretion, but shortages of Met, Lys, and His may limit milk protein synthesis. We studied the effect of incremental amounts of rumen-protected (RP)-His on plasma and muscle AA profile, nutrient utilization, and yields of milk and milk true protein in dairy cows. Eight multiparous Holstein cows (130 ± 30 d in milk) were randomly assigned to treatment sequences in a replicated 4 × 4 Latin square design with 28-d experimental periods. Treatments included a basal diet composed (dry matter basis) of 50% corn silage, 15% haylage, and 35% concentrate supplemented with 0, 82, 164, and 246 g/d of RP-His and 11 g/d of RP-Met. Milk, plasma, and muscle samples were collected weekly or every other week during all 4 periods, whereas spot urine and fecal grab samples were taken only in wk 4 of each period. Data were analyzed individually by week using linear, quadratic, and cubic orthogonal polynomials and repeated measures. Plasma His increased linearly with RP-His during wk 1 (30.3 to 57.2 µM) to wk 4 (33.2 to 63.1 µM). Plasma carnosine increased linearly with supplemental RP-His except in wk 2. No treatment effect was observed for plasma 3-methylhistidine except a quadratic effect in wk 3. Inclusion of RP-His showed linear effects on muscle His in wk 2 (20.1 to 32.5 µM) and 4 (20.3 to 35.5 µM). Whereas muscle anserine and carnosine concentrations were not affected by treatments in wk 4, anserine responded quadratically and carnosine showed a trend for a quadratic response to RP-His in wk 2. During wk 4, treatments did not affect urinary excretion of total purine derivatives, as well as dry matter intake and milk concentrations of fat and true protein. In contrast, milk yield tended to increase linearly (31.2 to 32.7 kg/d) and milk true protein yield responded linearly (0.93 to 0.98 kg/d) and tended to increase quadratically to RP-His supplementation in wk 4. Also, milk urea-N (11.7 to 12.9 mg/dL) and urinary excretion of urea-N (23.7 to 27.0% of N intake) increased linearly with feeding RP-His in wk 4. Overall, RP-His was effective to enhance plasma and muscle concentrations of His and milk protein synthesis. Elevated milk urea-N and urinary excretion of urea-N suggest that plasma His may have exceeded the requirement with excess N converted to urea in the liver. Future research is needed to determine the bioavailability of RP-His supplements to improve the accuracy of diet formulation for AA.
乳制品行业可以从低粗蛋白(CP)饮食中受益,因为氮排泄减少,但蛋氨酸、赖氨酸和组氨酸的短缺可能会限制乳蛋白合成。我们研究了添加不同量包膜(RP)-组氨酸对奶牛血浆和肌肉氨基酸谱、养分利用以及牛奶和乳真蛋白产量的影响。
8 头经产荷斯坦奶牛(泌乳 130±30 天)随机分配到重复 4×4 拉丁方设计的处理序列中,每个实验期为 28 天。处理包括以 50%玉米青贮、15%干草青贮和 35%精料为基础的基础日粮,补充 0、82、164 和 246 g/d RP-His 和 11 g/d RP-蛋氨酸。所有 4 个时期每周或每隔一周采集牛奶、血浆和肌肉样本,而仅在每个时期的第 4 周采集随机尿和粪便样本。数据通过线性、二次和三次正交多项式和重复测量单独在每周进行分析。
在第 1 周到第 4 周(30.3 至 57.2 μM),血浆组氨酸随 RP-His 的添加呈线性增加。血浆肉碱随补充 RP-His 呈线性增加,除了在第 2 周。除了在第 3 周出现二次效应外,血浆 3-甲基组氨酸未受处理影响。在第 2 周(20.1 至 32.5 μM)和第 4 周(20.3 至 35.5 μM),添加 RP-His 对肌肉组氨酸有线性影响。虽然肌肉鹅肌肽和肉碱浓度不受处理影响,但在第 2 周,鹅肌肽呈二次响应,肉碱呈二次趋势对 RP-His 有响应。在第 4 周,处理对尿总嘌呤衍生物排泄、干物质摄入以及牛奶脂肪和真蛋白浓度没有影响。相比之下,牛奶产量呈线性趋势增加(31.2 至 32.7 kg/d),牛奶真蛋白产量呈线性趋势增加(0.93 至 0.98 kg/d),并在第 4 周呈二次趋势增加对 RP-His 的添加。此外,牛奶尿素氮(11.7 至 12.9 mg/dL)和尿中尿素氮排泄(氮摄入量的 23.7%至 27.0%)随第 4 周添加 RP-His 而线性增加。
总之,RP-His 有效增强了血浆和肌肉中组氨酸的浓度和乳蛋白的合成。升高的牛奶尿素氮和尿中尿素氮排泄表明,血浆组氨酸的需求可能已经超过了肝脏中多余氮转化为尿素的需求。需要进一步的研究来确定 RP-His 补充剂的生物利用度,以提高氨基酸日粮配方的准确性。
