Milk Production Solutions, Green Technology, Natural Resources Institute Finland (Luke), Jokioinen, FI-31600, Finland.
Milk Production Solutions, Green Technology, Natural Resources Institute Finland (Luke), Jokioinen, FI-31600, Finland.
J Dairy Sci. 2018 Apr;101(4):3021-3035. doi: 10.3168/jds.2017-13776. Epub 2018 Feb 7.
Fish oil (FO) alters ruminal biohydrogenation causing trans fatty acid (FA) intermediates to accumulate, but the effects of 18-carbon polyunsaturated FA supply on ruminal long-chain FA metabolism and microbial communities in cattle fed FO are not well established. Four cows fitted with rumen cannula were used in a 4 × 4 Latin square with 21-d experimental periods to evaluate the effects of FO alone or in combination with plant oils high in 18:2n-6 or 18:3n-3 on rumen microbial ecology and flow of FA at the omasum. Treatments comprised a basal grass silage-based diet containing no additional oil (control) or supplements of FO (200 g/d) or FO (200 g/d) plus 500 g/d of sunflower oil (SFO) or linseed oil (LFO). Flow of FA was determined using the omasal sampling technique. The relative abundance of key biohydrogenating bacteria was assessed by quantitative PCR on 16S rRNA genes in omasal digesta. Fish oil-supplemented treatments increased the amounts of trans-18:1, trans-18:2, and 20- to 22-carbon polyunsaturated FA escaping the rumen. Relative to the control, oil supplements had no effect on the amount of 18:0 leaving the rumen, but LFO decreased the flow of 18:0 at the omasum compared with SFO. Both SFO and LFO increased trans-18:1 relative to FO, whereas LFO resulted in the highest trans-18:2 and 20- to 22-carbon FA flow. Supplements of FO plus plant oils shifted biohydrogenation toward trans-10 18:1 formation. Compared with FO alone, the ruminal metabolism of 22:6n-3 in the rumen of lactating cows is more extensive on diets containing higher amounts of 18-carbon polyunsaturated FA. However, the biohydrogenation of 22:5n-3 was less extensive in LFO than SFO, but showed no difference between FO and diets containing plant oils. Ruminal outflow of 20:5n-3 was not altered when plant oils were added to FO. Alterations in the amount of intermediates at the omasum or ruminal biohydrogenation pathways were not accompanied by major changes in analyzed bacterial populations. In conclusion, dietary supplements of FO alone or in combination with plant oils increase the amount of biohydrogenation intermediates containing 1 or more trans double bonds escaping the rumen, which may have implications for host metabolism and the nutritional quality of ruminant foods.
鱼油(FO)改变瘤胃生物氢化作用,导致反式脂肪酸(FA)中间体积累,但在给牛饲喂 FO 时,18 碳多不饱和 FA 供应对瘤胃长链 FA 代谢和微生物群落的影响尚未得到很好的证实。使用 4 头带有瘤胃套管的奶牛进行了 4×4 拉丁方试验,试验期为 21 天,以评估 FO 单独或与富含 18:2n-6 或 18:3n-3 的植物油脂组合对瘤胃微生物生态和 FA 在网胃中的流量的影响。处理包括不含额外油脂的基础草青贮日粮(对照)或 FO(200 g/d)或 FO(200 g/d)加 500 g/d 葵花籽油(SFO)或亚麻籽油(LFO)的补充。使用网胃采样技术确定 FA 的流量。通过 16S rRNA 基因的定量 PCR 评估网胃消化物中关键生物氢化细菌的相对丰度。添加 FO 的处理增加了反式 18:1、反式 18:2 和 20-22 碳多不饱和 FA 逃离瘤胃的量。与对照组相比,油脂补充剂对离开瘤胃的 18:0 量没有影响,但与 SFO 相比,LFO 减少了 18:0 在网胃中的流量。SFO 和 LFO 均增加了反式 18:1 的相对含量,而 LFO 导致反式 18:2 和 20-22 碳 FA 的流量最高。FO 加植物油脂的补充物使生物氢化向反式 10 18:1 形成转移。与单独添加 FO 相比,在含有较高 18 碳多不饱和 FA 的日粮中,泌乳奶牛瘤胃中 22:6n-3 的瘤胃代谢更为广泛。然而,LFO 中 22:5n-3 的生物氢化程度低于 SFO,但 FO 和含植物油脂的日粮之间没有差异。添加植物油脂时,20:5n-3 在瘤胃中的流出量没有改变。在网胃或瘤胃生物氢化途径中中间产物的数量发生变化时,分析的细菌种群没有发生重大变化。总之,单独添加 FO 或与植物油脂组合添加 FO 会增加含有 1 个或多个反式双键的生物氢化中间体的数量,这些中间体逃离瘤胃,这可能对宿主代谢和反刍动物食品的营养价值产生影响。
