We identified the biosynthesis of glycerol-3-phosphate as a key regulator in mechanisms implicated in learning and memory. Notably, defects in enzymes linked with the glycerol phosphate shuttle have been implicated in neurological disorders and intellectual disability < sub class= " a-plus-plus " > . < /sub > These results could improve our underst..."> We identified the biosynthesis of glycerol-3-phosphate as a key regulator in mechanisms implicated in learning and memory. Notably, defects in enzymes linked with the glycerol phosphate shuttle have been implicated in neurological disorders and intellectual disability < sub class= " a-plus-plus " > . < /sub > These results could improve our underst..." /> We identified the biosynthesis of glycerol-3-phosphate as a key regulator in mechanisms implicated in learning and memory. Notably, defects in enzymes linked with the glycerol phosphate shuttle have been implicated in neurological disorders and intellectual disability < sub class= " a-plus-plus " > . < /sub > These results could improve our underst..." />

Biosynthesis of glycerol phosphate is associated with long-term potentiation in hippocampal neurons

Conclusions < /h3 > < p class= " a-plus-plus " > We identified the biosynthesis of glycerol-3-phosphate as a key regulator in mechanisms implicated in learning and memory. Notably, defects in enzymes linked with the glycerol phosphate shuttle have been implicated in neurological disorders and intellectual disability < sub class= " a-plus-plus " > . < /sub > These results could improve our understanding of the general mechanisms of learning and memory and facilitate the development of novel therapies for metabolic disorders linked with intellectual disability. < /p > < /span >
Source: Metabolomics - Category: Biology Source Type: research