Weinisch Patrick, Fiamoncini Jarlei, Schranner Daniela, Raffler Johannes, Skurk Thomas, Rist Manuela J, Römisch-Margl Werner, Prehn Cornelia, Adamski Jerzy, Hauner Hans, Daniel Hannelore, Suhre Karsten, Kastenmüller Gabi
Institute of Computational Biology, Helmholtz Zentrum München, Neuherberg, Germany.
Food Research Center - FoRC, Department of Food Science and Experimental Nutrition, School of Pharmaceutical Sciences, University of São Paulo, São Paulo, Brazil.
Front Nutr. 2022 Sep 22;9:933526. doi: 10.3389/fnut.2022.933526. eCollection 2022.
Food intake triggers extensive changes in the blood metabolome. The kinetics of these changes depend on meal composition and on intrinsic, health-related characteristics of each individual, making the assessment of changes in the postprandial metabolome an opportunity to assess someone's metabolic status. To enable the usage of dietary challenges as diagnostic tools, profound knowledge about changes that occur in the postprandial period in healthy individuals is needed. In this study, we characterize the time-resolved changes in plasma levels of 634 metabolites in response to an oral glucose tolerance test (OGTT), an oral lipid tolerance test (OLTT), and a mixed meal (SLD) in healthy young males ( = 15). Metabolite levels for samples taken at different time points (20 per individual) during the challenges were available from targeted (132 metabolites) and non-targeted (502 metabolites) metabolomics. Almost half of the profiled metabolites ( = 308) showed a significant change in at least one challenge, thereof 111 metabolites responded exclusively to one particular challenge. Examples include azelate, which is linked to ω-oxidation and increased only in OLTT, and a fibrinogen cleavage peptide that has been linked to a higher risk of cardiovascular events in diabetes patients and increased only in OGTT, making its postprandial dynamics a potential target for risk management. A pool of 89 metabolites changed their plasma levels during all three challenges and represents the core postprandial response to food intake regardless of macronutrient composition. We used fuzzy c-means clustering to group these metabolites into eight clusters based on commonalities of their dynamic response patterns, with each cluster following one of four primary response patterns: (i) "decrease-increase" (valley-like) with fatty acids and acylcarnitines indicating the suppression of lipolysis, (ii) "increase-decrease" (mountain-like) including a cluster of conjugated bile acids and the glucose/insulin cluster, (iii) "steady decrease" with metabolites reflecting a carryover from meals prior to the study, and (iv) "mixed" decreasing after the glucose challenge and increasing otherwise. Despite the small number of subjects, the diversity of the challenges and the wealth of metabolomic data make this study an important step toward the characterization of postprandial responses and the identification of markers of metabolic processes regulated by food intake.
食物摄入会引发血液代谢组的广泛变化。这些变化的动力学取决于膳食组成以及个体的内在健康相关特征,这使得评估餐后代谢组的变化成为评估某人代谢状态的一个契机。为了将饮食挑战用作诊断工具,需要深入了解健康个体餐后发生的变化。在本研究中,我们描述了健康年轻男性(n = 15)在口服葡萄糖耐量试验(OGTT)、口服脂质耐量试验(OLTT)和混合餐(SLD)后血浆中634种代谢物水平随时间的变化。在挑战期间不同时间点采集的样本(每人20个)的代谢物水平可通过靶向(132种代谢物)和非靶向(502种代谢物)代谢组学获得。几乎一半的分析代谢物(n = 308)在至少一项挑战中显示出显著变化,其中111种代谢物仅对一种特定挑战有反应。例如,壬二酸与ω-氧化有关,仅在OLTT中升高;一种纤维蛋白原裂解肽与糖尿病患者心血管事件风险较高有关,仅在OGTT中升高,其餐后动态变化成为风险管理的潜在靶点。89种代谢物在所有三项挑战中均改变了血浆水平,代表了无论宏量营养素组成如何,对食物摄入的核心餐后反应。我们使用模糊c均值聚类根据这些代谢物动态反应模式的共性将它们分为八类,每一类遵循四种主要反应模式之一:(i)“先降后升”(谷状),脂肪酸和酰基肉碱表明脂肪分解受到抑制;(ii)“先升后降”(山状),包括一组结合胆汁酸和葡萄糖/胰岛素组;(iii)“持续下降”,代谢物反映了研究前餐食的残留;(iv)“混合”,在葡萄糖挑战后下降,其他情况下上升。尽管受试者数量较少,但挑战的多样性和丰富的代谢组学数据使本研究朝着表征餐后反应和识别受食物摄入调节的代谢过程标志物迈出了重要一步。
