Division of Signal Transduction, Beth Israel Deaconess Medical Center, Boston, MA, USA.
Mass Spectrometry Core, Beth Israel Deaconess Medical Center, Boston, MA, USA.
Nat Protoc. 2019 Feb;14(2):313-330. doi: 10.1038/s41596-018-0102-x.
Targeted tandem mass spectrometry (LC-MS/MS) has been extremely useful for profiling small molecules extracted from biological sources, such as cells, bodily fluids and tissues. Here, we present a protocol for analysing incorporation of the non-radioactive stable isotopes carbon-13 (C) and nitrogen-15 (N) into polar metabolites in central carbon metabolism and related pathways. Our platform utilizes selected reaction monitoring (SRM) with polarity switching and amide hydrophilic interaction liquid chromatography (HILIC) to capture transitions for carbon and nitrogen incorporation into selected metabolites using a hybrid triple quadrupole (QQQ) mass spectrometer. This protocol represents an extension of a previously published protocol for targeted metabolomics of unlabeled species and has been used extensively in tracing the metabolism of nutrients such as C-labeled glucose, C-glutamine and N-glutamine in a variety of biological settings (e.g., cell culture experiments and in vivo mouse labelling via i.p. injection). SRM signals are integrated to produce an array of peak areas for each labelling form that serve as the output for further analysis. The processed data are then used to obtain the degree and distribution of labelling of the targeted molecules (termed fluxomics). Each method can be customized on the basis of known unlabeled Q1/Q3 SRM transitions and adjusted to account for the corresponding C or N incorporation. The entire procedure takes ~6-7 h for a single sample from experimental labelling and metabolite extraction to peak integration.
靶向串联质谱(LC-MS/MS)在分析从生物来源(如细胞、体液和组织)提取的小分子方面非常有用。在这里,我们提出了一种分析中心碳代谢和相关途径中极性代谢物掺入非放射性稳定同位素碳-13(C)和氮-15(N)的方案。我们的平台利用选择反应监测(SRM)与极性切换和酰胺亲水性相互作用液相色谱(HILIC),使用混合三重四极杆(QQQ)质谱仪捕获选定代谢物中碳和氮掺入的跃迁。该方案扩展了以前发布的用于未标记物种靶向代谢组学的方案,并已广泛用于追踪各种生物环境中营养素(如 C 标记葡萄糖、C-谷氨酰胺和 N-谷氨酰胺)的代谢(例如,细胞培养实验和通过腹腔注射在体内标记小鼠)。SRM 信号被积分以产生每个标记形式的一系列峰面积,作为进一步分析的输出。然后,使用处理后的数据获得靶向分子的标记程度和分布(称为通量组学)。每种方法都可以根据已知的未标记 Q1/Q3 SRM 跃迁进行定制,并进行调整以考虑相应的 C 或 N 掺入。对于单个样品,从实验标记和代谢物提取到峰积分,整个过程大约需要 6-7 小时。