The reactive pyruvate metabolite dimethylglyoxal mediates neurological consequences of diabetes.
Sina RheinRiccardo CostalungaJulica InderheesTammo GürtzgenTeresa Christina FaupelZaib ShaheryarAdriana Arrulo PereiraAlaa OthmanKimberly BegemannSonja BinderInes StöltingValentina DortaPeter P NawrothThomas FlemingKonrad OexleVincent PrevotRuben NogueirasSvenja MeyhöferSebastian M MeyhöferMarkus SchwaningerPublished in: Nature communications (2024)
Complications of diabetes are often attributed to glucose and reactive dicarbonyl metabolites derived from glycolysis or gluconeogenesis, such as methylglyoxal. However, in the CNS, neurons and endothelial cells use lactate as energy source in addition to glucose, which does not lead to the formation of methylglyoxal and has previously been considered a safer route of energy consumption than glycolysis. Nevertheless, neurons and endothelial cells are hotspots for the cellular pathology underlying neurological complications in diabetes, suggesting a cause that is distinct from other diabetes complications and independent of methylglyoxal. Here, we show that in clinical and experimental diabetes plasma concentrations of dimethylglyoxal are increased. In a mouse model of diabetes, ilvb acetolactate-synthase-like (ILVBL, HACL2) is the enzyme involved in formation of increased amounts of dimethylglyoxal from lactate-derived pyruvate. Dimethylglyoxal reacts with lysine residues, forms Nε-3-hydroxy-2-butanonelysine (HBL) as an adduct, induces oxidative stress more strongly than other dicarbonyls, causes blood-brain barrier disruption, and can mimic mild cognitive impairment in experimental diabetes. These data suggest dimethylglyoxal formation as a pathway leading to neurological complications in diabetes that is distinct from other complications. Importantly, dimethylglyoxal formation can be reduced using genetic, pharmacological and dietary interventions, offering new strategies for preventing CNS dysfunction in diabetes.
Keyphrases
- type diabetes
- cardiovascular disease
- glycemic control
- blood brain barrier
- endothelial cells
- oxidative stress
- mild cognitive impairment
- mouse model
- risk factors
- spinal cord
- gene expression
- metabolic syndrome
- insulin resistance
- spinal cord injury
- genome wide
- machine learning
- weight loss
- adipose tissue
- subarachnoid hemorrhage
- signaling pathway
- big data
- cerebral ischemia
- brain injury
- vascular endothelial growth factor
- ischemia reperfusion injury