Mathews A T, Rico J E, Sprenkle N T, Lock A L, McFadden J W
Division of Animal and Nutritional Sciences, West Virginia University, Morgantown 26506.
Department of Animal Science, Michigan State University, East Lansing 48824.
J Dairy Sci. 2016 Nov;99(11):8802-8816. doi: 10.3168/jds.2016-11295. Epub 2016 Sep 13.
Feeding saturated fatty acids may enhance milk yield in part by decreasing insulin sensitivity and shifting glucose utilization toward the mammary gland. Our objective was to evaluate the effects of palmitic acid (C16:0) on milk production and insulin sensitivity in cows. Twenty multiparous mid-lactation Holstein cows were enrolled in a study consisting of a 5-d covariate, 49-d treatment, and 14-d posttreatment period. All cows received a common sorghum silage-based diet and were randomly assigned to a diet containing no supplemental fat (control; n=10; 138±45d in milk) or C16:0 at 4% of ration DM (PALM; 98% C16:0; n=10; 136±44d in milk). Blood and milk were collected at routine intervals. Intravenous glucose tolerance tests (300mg/kg of body weight) were performed at d -1, 24, and 49 relative to start of treatment. Data were analyzed as repeated measures using a mixed model with fixed effects of treatment and time, and milk yield served as a covariate. The PALM treatment increased milk yield by wk 7. Furthermore, PALM increased milk fat yield and energy-corrected milk at wk 3 and 7. Changes in milk production occurred in parallel with enhanced energy intake. Increased milk fat yield during PALM treatment was due to increased C16:0 and C16:1 incorporation; PALM had no effect on concentration of milk components, BW, or body condition score. Two weeks posttreatment, energy-corrected milk and milk fat yield remained elevated in PALM-fed cows whereas yields of milk were similar between treatments. Increased milk fat yield after PALM treatment was due to increased de novo lipogenesis and uptake of preformed fatty acids. The basal concentration of nonesterified fatty acids (NEFA) in plasma increased by d 4, 6, and 8 of PALM treatment, a response not observed thereafter. Although PALM supplementation did not modify insulin, glucose, or triacylglycerol levels in plasma, total cholesterol in plasma was elevated by wk 3. Estimated insulin sensitivity was lower during the first week of PALM treatment; however, glucose disposal following glucose tolerance tests was not modified. In contrast, C16:0 feeding reduced glucose-stimulated NEFA disappearance by wk 7. Results demonstrate that increasing dietary energy from C16:0 for 7wk improves milk yield and milk composition without modifying systemic glucose tolerance. Reduced glucose-stimulated NEFA disappearance with C16:0 feeding and elevated circulating NEFA may reflect changes in adipose tissue insulin sensitivity.
饲喂饱和脂肪酸可能部分通过降低胰岛素敏感性并将葡萄糖利用转向乳腺来提高产奶量。我们的目标是评估棕榈酸(C16:0)对奶牛产奶量和胰岛素敏感性的影响。二十头经产中期泌乳的荷斯坦奶牛参与了一项研究,该研究包括一个5天的协变量期、49天的治疗期和14天的治疗后期。所有奶牛都接受基于高粱青贮的普通日粮,并被随机分配到不添加脂肪的日粮组(对照组;n = 10;产奶天数138±45天)或日粮干物质中含4% C16:0的组(棕榈酸组;98% C16:0;n = 10;产奶天数136±44天)。定期采集血液和牛奶样本。在相对于治疗开始的第 -1、24和49天进行静脉葡萄糖耐量试验(300mg/kg体重)。数据采用重复测量分析,使用具有治疗和时间固定效应的混合模型,并将产奶量作为协变量。棕榈酸处理在第7周时提高了产奶量。此外,棕榈酸组在第3周和第7周时提高了乳脂产量和能量校正乳产量。产奶量的变化与能量摄入量的增加同时发生。棕榈酸处理期间乳脂产量的增加是由于C16:0和C16:1掺入量增加;棕榈酸对乳成分浓度、体重或体况评分没有影响。治疗后两周,棕榈酸组奶牛的能量校正乳和乳脂产量仍然较高,而不同处理间的产奶量相似。棕榈酸处理后乳脂产量的增加是由于从头脂肪生成增加和预先形成的脂肪酸摄取增加。棕榈酸处理第4、6和8天时血浆中非酯化脂肪酸(NEFA)的基础浓度升高,此后未观察到这种反应。虽然添加棕榈酸并未改变血浆中的胰岛素、葡萄糖或三酰甘油水平,但血浆总胆固醇在第3周时升高。在棕榈酸处理的第一周估计的胰岛素敏感性较低;然而,葡萄糖耐量试验后的葡萄糖处置未发生改变。相反,到第7周时,饲喂C16:0降低了葡萄糖刺激的NEFA消失。结果表明,7周内从C16:0增加日粮能量可提高产奶量和乳成分,而不改变全身葡萄糖耐量。饲喂C16:0导致葡萄糖刺激的NEFA消失减少以及循环NEFA升高,这可能反映了脂肪组织胰岛素敏感性的变化。
