RESUMO
RATIONALE: Glycine is the smallest amino acid used in protein synthesis, but it is also a very important precursor for the biosynthesis of other nitrogen-containing metabolites, such as purine nucleosides and nucleotides for synthesis of RNA, DNA etc. Abnormalities in glycine metabolism therefore cause diseases such as cancer. A quick and unambiguous method to trace the metabolites arising from glycine is required for targeting defect points within metabolic networks. METHODS: This paper describes a method for using (15)N-glycine to culture A549 cancer cells for use with high-resolution mass spectrometry (HRMS) and tandem mass spectrometry (HRMS(2)) that can detect the (M+1)/M pair peaks appearing in the cell metabolites. The 1 Da difference in the pair peaks can be used to point out and identify the nitrogen metabolites of glycine. RESULTS: Thirteen nitrogen-containing metabolites derived from glycine were confirmed. Among them were metabolites containing purine, such as adenine, adenosine, AMP, ADP, ATP, S-adenosylmethionine and γ-glutathione; these were the most sensitive to the (15)N-glycine-enrichment technique. Therefore, they are promising biomarkers for monitoring the glycine metabolism network. CONCLUSIONS: The method developed here could be applied to investigations of metabolism of other amino acids, and for drug discovery studies targeting the enzymes related to amino acid metabolism.