Department of Agricultural Sciences, PO Box 28, FI-00014, University of Helsinki, Finland.
J Dairy Sci. 2012 Mar;95(3):1376-94. doi: 10.3168/jds.2011-4390.
Dietary unsaturated fatty acids are extensively hydrogenated in the rumen, resulting in the formation of numerous intermediates that may exert physiological effects and alter the fat composition of ruminant-derived foods. A batch culture method was used to characterize the hydrogenation of linoleic acid (LeA) by strained rumen fluid in vitro. Incubations (n = 5) were performed in 100-mL flasks maintained at 39 °C containing 400mg of grass hay, 50 mL of buffered rumen fluid, and incremental amounts of LeA (0, 1.0, 2.5, 5.0, or 10.0mg) for 0, 1.5, 3.0, 4.5, 6.0, and 9.0 h. The fatty acid composition of flask contents was determined using complimentary silver-ion thin-layer chromatography, gas chromatography mass-spectrometry, and silver-ion high-performance liquid chromatography. Linoleic acid was extensively (98.1, 97.6, 98.0, and 89.8% for additions of 1.0, 2.5, 5.0, and 10.0mg of LeA, respectively) hydrogenated over time. Complete reduction of LeA to 18:0 was inhibited in direct relation to the amount of added substrate, the extent of which was greatest for the highest amount of LeA addition. Recoveries of 1.0, 2.5, 5.0, and 10.0mg of added LeA as 18:0 averaged 73.6, 65.0, 57.3, and 10.7%, respectively. Incubation of incremental amounts of LeA resulted in a time-dependent accumulation of geometric isomers of 9,11 and 10,12 conjugated linoleic acid, several nonconjugated 18:2 isomers, and a wide range of cis 18:1 and trans 18:1 intermediates. Several unusual intermediates including cis-6,cis-12 18:2; cis-7,cis-12 18:2; and cis-8,cis-12 18:2, were found to accumulate in direct relation to the amount of added LeA, providing the first indications that hydrogenation of LeA by ruminal bacteria may also involve mechanisms other than hydrogen abstraction or isomerization of the cis-12 double bond. Fitting of single-pool, first-order kinetic models to experimental data indicated that the rate of LeA disappearance decreased with increases in substrate availability. Reduction of 18:1 and 18:2 intermediates occurred at much lower rates compared with conjugated linoleic acid and nonconjugated 18:2 isomer formation. In conclusion, the extent of LeA biohydrogenation in vitro was shown to be time- and dose-dependent with evidence that LeA is hydrogenated by ruminal bacteria via several distinct metabolic pathways. The accumulation of several unusual 18:2 isomers indicates that biohydrogenation of LeA also proceeds via mechanisms other than isomerization of the cis-12 double bond.
日粮不饱和脂肪酸在瘤胃中大量被氢化,形成许多可能具有生理效应的中间产物,并改变反刍动物源性食物的脂肪组成。采用批培养方法,在 39°C 的 100 毫升烧瓶中用缓冲瘤胃液和递增剂量的亚油酸(0、1.0、2.5、5.0 或 10.0mg)孵育 400mg 干草,0、1.5、3.0、4.5、6.0 和 9.0 h,来研究瘤胃液对亚油酸(LeA)的氢化作用。使用互补的银离子薄层层析、气相色谱-质谱联用和银离子高效液相色谱法来确定烧瓶内容物的脂肪酸组成。亚油酸在时间上被大量(添加 1.0、2.5、5.0 和 10.0mg 的 LeA 时分别为 98.1、97.6、98.0 和 89.8%)氢化。LeA 完全还原为 18:0 受到添加底物数量的直接抑制,添加的底物越多,抑制程度越大。添加的 1.0、2.5、5.0 和 10.0mg LeA 分别作为 18:0 的回收率平均为 73.6、65.0、57.3 和 10.7%。递增量 LeA 的孵育导致几何异构体 9,11 和 10,12 共轭亚油酸、几种非共轭 18:2 异构体以及广泛的顺式 18:1 和反式 18:1 中间产物的时间依赖性积累。发现几种异常中间产物,包括 cis-6,cis-12 18:2;cis-7,cis-12 18:2;和 cis-8,cis-12 18:2,与添加的 LeA 数量直接相关,这首次表明瘤胃细菌对 LeA 的氢化作用可能还涉及除顺式 12 双键的氢提取或异构化之外的机制。用单池一级动力学模型拟合实验数据表明,LeA 消失的速率随底物可用性的增加而降低。18:1 和 18:2 中间产物的减少速度远低于共轭亚油酸和非共轭 18:2 异构体的形成速度。总之,体外 LeA 的生物氢化程度表现为时间和剂量依赖性,并且证据表明 LeA 是通过几种不同的代谢途径被瘤胃细菌氢化的。几种异常 18:2 异构体的积累表明,LeA 的生物氢化也通过除顺式 12 双键异构化之外的机制进行。
