College of Veterinary Medicine, Northwest A&F University, Yangling 712100, China; Juela Township Government of Cuona County, Cuona 856700, China.
College of Veterinary Medicine, Northwest A&F University, Yangling 712100, China.
J Dairy Sci. 2018 Sep;101(9):8513-8523. doi: 10.3168/jds.2018-14448. Epub 2018 Jun 28.
Ketosis causes serious economic losses for the modern dairy industry because it is a highly prevalent metabolic disease among cows in high-producing herds during the transition period. Due to some striking similarities between diabetes in humans and ketosis in dairy cows, there is potential for the use of methylglyoxal (MGO)-commonly used in human diabetics-as a biomarker in dairy cattle. However, currently no data are available about the presence of MGO in the serum of dairy cattle or about the characteristics of its production or its potential contribution in the pathogenesis of ketosis. To determine the potential origin and pathway of formation of MGO, cows in different metabolic conditions [i.e., non-subclinically ketotic dairy cows in early lactation (n = 7), subclinically ketotic dairy cows in early lactation (n = 8), overconditioned dry cows (BCS >4.25, n = 6), and nonlactating heifers (n = 6)] were selected. Serum MGO concentrations were determined and correlated with indicators of the glucose and lipid metabolism and with haptoglobin (Hp) as an inflammatory marker. The serum MGO concentrations in subclinically ketotic cows (712.60 ± 278.77 nmol/L) were significantly greater than in nonlactating heifers (113.35 ± 38.90 nmol/L), overconditioned dry cows (259.71 ± 117.97 nmol/L), and non-subclinically ketotic cows (347.83 ± 63.56 nmol/L). In serum of lactating cows, concentrations of glucose and fructosamine were lower than in heifers and were negatively correlated with MGO concentrations. Even so, concentrations of metabolic and inflammatory markers such as dihydroxyacetone phosphate, nonesterified fatty acids, β-hydroxybutyrate, acetone, and Hp were remarkably higher in subclinically ketotic cows compared with nonlactating heifers; these metabolites were also positively correlated with MGO. In human diabetics elevated MGO concentrations are stated to originate from both hyperglycemia and the enhanced lipid metabolism, whereas higher MGO concentrations in subclinically ketotic cows were not associated with hyperglycemia. Therefore, our data suggest MGO in dairy cows to be a metabolite produced from the metabolization of acetone within the lipid metabolization pathway and from the metabolization of dihydroxyacetone phosphate. Furthermore, the highly positive correlation between MGO and Hp suggests that this reactive compound might be involved in the proinflammatory state of subclinical ketosis in dairy cows. However, more research is needed to determine the potential use of MGO as a biomarker for metabolic failure in dairy cows.
酮症会给现代奶牛养殖业造成严重的经济损失,因为它是高产奶牛在过渡期的一种高发代谢疾病。由于人类糖尿病和奶牛酮症之间存在一些显著的相似之处,因此使用甲基乙二醛(MGO)作为奶牛的生物标志物具有一定的潜力。然而,目前尚无关于奶牛血清中 MGO 的存在、其产生的特征或在酮症发病机制中的潜在贡献的数据。为了确定 MGO 的潜在起源和形成途径,选择了处于不同代谢状态的奶牛[即处于早期泌乳的非亚临床酮症奶牛(n=7)、处于早期泌乳的亚临床酮症奶牛(n=8)、过度饲养的干奶牛(BCS>4.25,n=6)和非泌乳小母牛(n=6)]。测定了血清 MGO 浓度,并与葡萄糖和脂质代谢的指标以及触珠蛋白(Hp)作为炎症标志物进行了相关性分析。亚临床酮症奶牛的血清 MGO 浓度(712.60±278.77 nmol/L)显著高于非泌乳小母牛(113.35±38.90 nmol/L)、过度饲养的干奶牛(259.71±117.97 nmol/L)和非亚临床酮症奶牛(347.83±63.56 nmol/L)。在泌乳奶牛的血清中,葡萄糖和果糖胺的浓度低于小母牛,并且与 MGO 浓度呈负相关。即便如此,亚临床酮症奶牛的二羟丙酮磷酸、非酯化脂肪酸、β-羟丁酸、丙酮和 Hp 等代谢和炎症标志物的浓度仍然明显高于非泌乳小母牛;这些代谢物也与 MGO 呈正相关。在人类糖尿病患者中,升高的 MGO 浓度据称既源于高血糖,也源于增强的脂质代谢,而亚临床酮症奶牛中升高的 MGO 浓度与高血糖无关。因此,我们的数据表明,奶牛中的 MGO 是一种来自脂质代谢途径中丙酮代谢和二羟丙酮磷酸代谢的代谢产物。此外,MGO 与 Hp 之间的高度正相关表明,这种反应性化合物可能参与了奶牛亚临床酮症的促炎状态。然而,需要进一步的研究来确定 MGO 作为奶牛代谢衰竭的生物标志物的潜在用途。
