The power of trapped ion mobility for isotope tracer experiments

Background: Isotope tracing experiments in cellular metabolomics are challenged by the multiple isomers and in-source fragments, which need to be considered to obtain unbiased isotopologue ratio measurements. Thus, both, selectivity and sensitivity are key requirements for customized workflows. Trapped ion mobility spectrometry (TIMS) introduces an additional separation dimension to mass spectrometry, separating otherwise co-eluting isomers by measuring the ion mobility of a molecule. This study shows for the first time, the potential of this MS platform for accurate isotopologue assessment as showcased in isotope tracer experiments using mammalian cells. Results: The validation exercise focused on spectral accuracy, precision, and metabolite detection capabilities and comprised independent measurements on an orbitrap-based platform. Hydrophilic interaction chromatography, in combination with TIMS-TOF-MS delivered excellent results, with a minimum trueness bias and excellent precision (CV%) between 0.3 % and 6.4 %. The ion mobility separation allowed for differentiation of the otherwise co-eluting isomers fructose-6-phosphate (F6P) and glucose-1-phosphate (G1P). Overall, isotopologue distributions were in good agreement upon crossvalidation with the orbitrap platform. Finally, a proof-of-concept tracer study addressed the activity of the glycolysis and the pentose phosphate pathway (PPP) in resting and endotoxin activated macrophages. We confirmed an activation of glycolysis and PPP in LPS activated macrophages, but found a potentially reduced relative contribution of glucose-6-phosphate (G6P) to increased F6P pools. Our findings imply that TIMS is a powerful technology for the reliable measurements of isotope distribution analysis in metabolic tracing experiments. Significance: By implementation of ion mobility, it is now possible to generate distinct isotopologue patterns for G1P and F6P in isotope tracer experiments. F6P plays a crucial role in glycolysis and PPP, highlighting the importance of precise analytical measurements. This is particularly true for metabolic studies in immunology and cancer research.