Metabolic Tools for Identification of New Mutations of Enzymes Engaged in Purine Synthesis Leading to Neurological Impairment.

The cellular pool of purines is maintained by de novo purine synthesis (DNPS), recycling and degradation. Mutations in genes encoding DNPS enzymes cause their substrates to accumulate, which has detrimental effects on cellular division and organism development, potentially leading to neurological impairments. Unspecified neurological symptoms observed in many patients could not be elucidated even by modern techniques. It is presumable that some of these problems are induced by dysfunctions in DNPS enzymes. Therefore, we determined the concentrations of dephosphorylated DNPS intermediates by LC-MS/MS as markers of yet unpublished mutations in PFAS and PAICS genes connected with dysfunctions of carboxylase/phosphoribosylaminoimidazolesuccinocarboxamide synthase (PAICS) or phosphoribosylformylglycinamidine synthase (PFAS). We determined the criteria for normal values of metabolites and investigated 1,447 samples of urine and 365 dried blood spots of patients suffering from various forms of neurological impairment. We detected slightly elevated aminoimidazole riboside (AIr) concentrations in three urine samples and a highly elevated 5-formamidoimidazole-4-carboxamide riboside (FGAr) concentration in one urine sample. The accumulation of AIr or FGAr in body fluids can indicate PAICS or PFAS deficiency, respectively, which would be new disorders of DNPS caused by mutations in the appropriate genes. Measurement of DNPS intermediates in patients with neurological symptoms can uncover the cause of serious cellular and functional impairments that are otherwise inaccessible to detection. Further genetic and molecular analysis of these patients should establish the causal mutations for prenatal diagnosis, genetic consultation, and reinforce the DNPS pathway as a therapeutic target.

Detection and quantitation of iron in ferritin, transferrin and labile iron pool (LIP) in cardiomyocytes using 55Fe and storage phosphorimaging.

Dysregulated iron metabolism has a detrimental effect on cardiac function. The importance of iron homeostasis in cardiac health and disease warrants detailed studies of cardiomyocyte iron uptake, utilization and recycling at the molecular level. In this study, we have performed metabolic labeling of primary cultures of neonatal rat cardiomyocytes with radioactive iron coupled with separation of labeled iron-containing molecules by native electrophoresis followed by detection and quantification of incorporated radioiron by storage phosphorimaging. For the radiolabeling we used a safe and convenient beta emitter 55Fe which enabled sensitive and simultaneous detection and quantitation of iron in cardiomyocyte ferritin, transferrin and the labile iron pool (LIP). The LIP is believed to represent potentially dangerous redox-active iron bound to uncharacterized molecules. Using size-exclusion chromatography spin micro columns, we demonstrate that iron in the LIP is bound to high molecular weight molecule(s) (≥5000 Da) in the neonatal cardiomyocytes.