Agri-Food and Land Use, School of Biological Sciences, Queen's University Belfast, Belfast BT9 5AY, United Kingdom.
J Dairy Sci. 2012 Mar;95(3):1527-44. doi: 10.3168/jds.2011-4410.
Although interest in crossbreeding within dairy systems has increased, the role of Jersey crossbred cows within high concentrate input systems has received little attention. This experiment was designed to examine the performance of Holstein-Friesian (HF) and Jersey × Holstein-Friesian (J × HF) cows within a high concentrate input total confinement system (CON) and a medium concentrate input grazing system (GRZ). Eighty spring-calving dairy cows were used in a 2 (cow genotype) × 2 (milk production system) factorial design experiment. The experiment commenced when cows calved and encompassed a full lactation. With GRZ, cows were offered diets containing grass silage and concentrates [70:30 dry matter (DM) ratio] until turnout, grazed grass plus 1.0 kg of concentrate/day during a 199-d grazing period, and grass silage and concentrates (75:25 DM ratio) following rehousing and until drying-off. With CON, cows were confined throughout the lactation and offered diets containing grass silage and concentrates (DM ratio; 40:60, 50:50, 40:40, and 75:25 during d 1 to 100, 101 to 200, 201 to 250, and 251 until drying-off, respectively). Full-lactation concentrate DM intakes were 791 and 2,905 kg/cow for systems GRZ and CON, respectively. Although HF cows had a higher lactation milk yield than J × HF cows, the latter produced milk with a higher fat and protein content, so that solids-corrected milk yield (SCM) was unaffected by genotype. Somatic cell score was higher with the J × HF cows. Throughout lactation, HF cows were on average 37 kg heavier than J × HF cows, whereas the J × HF cows had a higher body condition score. Within each system, food intake did not differ between genotypes, whereas full-lactation yields of milk, fat plus protein, and SCM were higher with CON than with GRZ. A significant genotype × environment interaction was observed for milk yield, and a trend was found for an interaction with SCM. Crossbred cows on CON gained more body condition than HF cows, and overall pregnancy rate was unaffected by either genotype or management system. In summary, milk and SCM yields were higher with CON than with GRZ, whereas genotype had no effect on SCM. However, HF cows exhibited a greater milk yield response and a trend toward a greater SCM yield response with increasing concentrate levels compared with the crossbred cows.
尽管人们对奶牛体系内的杂交越来越感兴趣,但泽西杂交奶牛在高浓缩物投入体系中的作用却很少受到关注。本实验旨在研究荷斯坦-弗里生(HF)和泽西×荷斯坦-弗里生(J×HF)奶牛在高浓缩物投入全封闭系统(CON)和中浓缩物投入放牧系统(GRZ)中的表现。80 头春季产奶牛采用 2(奶牛基因型)×2(牛奶生产系统)因子设计实验。实验从奶牛产犊开始,涵盖整个泌乳期。在 GRZ 中,奶牛在放牧前提供含有青贮草和浓缩物的饲料[干物质(DM)比例为 70:30],在 199 天的放牧期内放牧,每天放牧 1.0 公斤浓缩物,然后在重新圈养和干奶期间,提供青贮草和浓缩物(DM 比例为 75:25)。在 CON 中,奶牛在整个泌乳期内被限制,并提供含有青贮草和浓缩物的饲料(DM 比例分别为 1 至 100 天为 40:60、101 至 200 天为 50:50、201 至 250 天为 40:40、251 天至干奶期为 75:25)。GRZ 和 CON 系统的奶牛全泌乳期浓缩物 DM 摄入量分别为 791 和 2905 千克/头。尽管 HF 奶牛的泌乳量高于 J×HF 奶牛,但后者生产的牛奶脂肪和蛋白质含量较高,因此固体校正奶产量(SCM)不受基因型影响。体细胞评分 J×HF 奶牛较高。整个泌乳期,HF 奶牛比 J×HF 奶牛平均重 37 公斤,而 J×HF 奶牛的体况评分较高。在每个系统中,基因型之间的食物摄入量没有差异,而 CON 系统的牛奶、脂肪加蛋白质和 SCM 的全泌乳期产量均高于 GRZ。观察到产奶量存在显著的基因型×环境互作,SCM 也存在趋势。与 HF 奶牛相比,CON 上的杂交奶牛获得了更高的体况,妊娠率不受基因型或管理系统的影响。总之,CON 系统的牛奶和 SCM 产量高于 GRZ 系统,而基因型对 SCM 没有影响。然而,与杂交奶牛相比,HF 奶牛对浓缩物水平的增加表现出更大的产奶量响应和更大的 SCM 产量响应趋势。
