1 H and 31 P magnetic resonance spectroscopy reveals potential pathogenic and biomarker metabolite alterations in Lafora disease.
Kimberly L ChanAparna PanatpurSouad MessahelHamza DahshiTalon JohnsonAnke HenningJimin RenBerge A MinassianPublished in: Brain communications (2024)
Lafora disease is a fatal teenage-onset progressive myoclonus epilepsy and neurodegenerative disease associated with polyglucosan bodies. Polyglucosans are long-branched and as a result precipitation- and aggregation-prone glycogen. In mouse models, downregulation of glycogen synthase, the enzyme that elongates glycogen branches, prevents polyglucosan formation and rescues Lafora disease. Mouse work, however, has not yet revealed the mechanisms of polyglucosan generation, and few in vivo human studies have been performed. Here, non-invasive in vivo magnetic resonance spectroscopy ( 1 H and 31 P) was applied to test scan feasibility and assess neurotransmitter balance and energy metabolism in Lafora disease towards a better understanding of pathogenesis. Macromolecule-suppressed gamma-aminobutyric acid (GABA)-edited 1 H magnetic resonance spectroscopy and 31 P magnetic resonance spectroscopy at 3 and 7 tesla, respectively, were performed in 4 Lafora disease patients and a total of 21 healthy controls (12 for the 1 H magnetic resonance spectroscopy and 9 for the 31 PMRS). Spectra were processed using in-house software and fit to extract metabolite concentrations. From the 1 H spectra, we found 33% lower GABA concentrations ( P = 0.013), 34% higher glutamate + glutamine concentrations ( P = 0.011) and 24% lower N -acetylaspartate concentrations ( P = 0.0043) in Lafora disease patients compared with controls. From the 31 P spectra, we found 34% higher phosphoethanolamine concentrations ( P = 0.016), 23% lower nicotinamide adenine dinucleotide concentrations ( P = 0.003), 50% higher uridine diphosphate glucose concentrations ( P = 0.004) and 225% higher glucose 6-phosphate concentrations in Lafora disease patients versus controls ( P = 0.004). Uridine diphosphate glucose is the substrate of glycogen synthase, and glucose 6-phosphate is its extremely potent allosteric activator. The observed elevated uridine diphosphate glucose and glucose 6-phosphate levels are expected to hyperactivate glycogen synthase and may underlie the generation of polyglucosans in Lafora disease. The increased glutamate + glutamine and reduced GABA indicate altered neurotransmission and energy metabolism, which may contribute to the disease's intractable epilepsy. These results suggest a possible basis of polyglucosan formation and potential contributions to the epilepsy of Lafora disease. If confirmed in larger human and animal model studies, measurements of the dysregulated metabolites by magnetic resonance spectroscopy could be developed into non-invasive biomarkers for clinical trials.
Keyphrases
- end stage renal disease
- newly diagnosed
- chronic kidney disease
- type diabetes
- oxidative stress
- endothelial cells
- randomized controlled trial
- signaling pathway
- mouse model
- multiple sclerosis
- blood pressure
- adipose tissue
- immune response
- risk assessment
- peritoneal dialysis
- ms ms
- magnetic resonance
- climate change
- single cell
- density functional theory