Department of Dairy Science, Virginia Tech, Blacksburg 24061; State Key Laboratory of Animal Nutrition, College of Animal Science and Technology, China Agricultural University, Beijing, P. R. China, 100193.
Department of Dairy Science, Virginia Tech, Blacksburg 24061.
J Dairy Sci. 2022 Nov;105(11):8879-8897. doi: 10.3168/jds.2022-22084. Epub 2022 Sep 7.
To investigate the effects of acetate, propionate, and pH on thermodynamics of volatile fatty acids (VFA) in the rumen, a dual-flow continuous culture study was conducted to quantify production of major VFA, interconversions among the VFA, and H and CH emissions in a 4 × 4 Latin square design. The 4 treatments were (1) control: pH buffered to an average of 6.75; (2) control plus 20 mmol/d of infused acetate (InfAc); (3) control plus 7 mmol/d of infused propionate (InfPr); and (4) a 0.5-unit decline in pH elicited by adjustment of the buffer (LowpH). All fermentors were fed 40 g of a pelleted diet containing whole alfalfa pellets and concentrate mix pellets (50:50) once daily. After 7 d of treatment, sequential, continuous infusions of [2-C] sodium acetate (3.5 mmol/d), [U-C] sodium propionate (2.9 mmol/d), and [1-C] sodium butyrate (0.22 mmol/d) were carried out from 12 h before feeding for 36 h. Filtered liquid effluent (4 mL) was sampled at 0, 2, 4, 6, 8, 12, 16, and 22 h after feeding, and assessed for VFA concentrations, with another filtered sample (20 mL) used to quantify aqueous concentrations of CH and H. Headspace CH and H gases were monitored continuously. Ruminal microbes were isolated from the mixed effluent samples, and the microbial community structure was analyzed using the 16S rRNA amplicon sequencing technique. The digestibility of neutral detergent fiber, acid detergent fiber, and starch and microbial C sequestrated from VFA were not affected by treatments. The LowpH treatment increased net propionate production and decreased H and CH headspace emissions, primarily due to shifts in metabolic pathways of VFA formation, likely due to the observed changes in bacterial community structure. Significant interconversions occurred between acetate and butyrate, whereas interconversions of other VFA with propionate were relatively small. The InfAc and InfPr treatments increased net acetate and propionate production, respectively; however, interconversions among VFA were not affected by pH, acetate, or propionate treatments, suggesting that thermodynamics might not be a primary influencer of metabolic pathways used for VFA formation.
为了研究乙酸盐、丙酸盐和 pH 值对瘤胃挥发性脂肪酸 (VFA) 热力学的影响,采用双流动连续培养研究,以定量测定主要 VFA 的产生、VFA 之间的相互转化以及 H 和 CH 排放,采用 4×4 拉丁方设计。4 种处理方法为:(1)对照组:pH 值缓冲至平均 6.75;(2)对照组+每天 20mmol/d 输注乙酸盐(InfAc);(3)对照组+每天 7mmol/d 输注丙酸盐(InfPr);(4)通过调整缓冲液使 pH 值降低 0.5 个单位(LowpH)。所有发酵罐每天一次饲喂 40g 颗粒饲料,含有全苜蓿颗粒和浓缩物混合物颗粒(50:50)。处理 7d 后,从饲喂前 12h 开始连续 36h 进行[2-C]乙酸钠(3.5mmol/d)、[U-C]丙酸钠(2.9mmol/d)和[1-C]丁酸钠(0.22mmol/d)的连续输注。在饲喂后 0、2、4、6、8、12、16 和 22h 采集 4ml 过滤的液体流出物,并测定 VFA 浓度,用另一个过滤样品(20ml)测定 CH 和 H 的水相浓度。连续监测顶空 CH 和 H 气体。从混合流出物样品中分离瘤胃微生物,并使用 16S rRNA 扩增子测序技术分析微生物群落结构。中性洗涤剂纤维、酸性洗涤剂纤维和淀粉的消化率以及 VFA 微生物固定的 C 不受处理影响。LowpH 处理增加了净丙酸产量,减少了 H 和 CH 顶空排放,主要是由于 VFA 形成代谢途径的变化,可能是由于观察到的细菌群落结构变化。乙酸盐和丁酸盐之间发生了显著的相互转化,而其他 VFA 与丙酸盐的相互转化相对较小。InfAc 和 InfPr 处理分别增加了净乙酸盐和丙酸盐的产生;然而,pH 值、乙酸盐或丙酸盐处理对 VFA 之间的相互转化没有影响,这表明热力学可能不是 VFA 形成代谢途径的主要影响因素。
