Developmental shift to mitochondrial respiration for energetic support of sustained transmission during maturation at the calyx of Held
Brendan Lujan, Mahendra Singh, Abhyudai Singh, Robert Renden
Abstract
We dissect the role of presynaptic glycolysis versus mitochondrial respiration in supporting high-frequency neurotransmission, by acutely blocking these ATP-generating pathways at a synapse tuned for high-frequency transmission. We find that massive energy expenditure is required to generate failure when only one pathway is inhibited. Action potential propagation is lost before impaired synaptic vesicle recycling. Synaptic transmission is exclusively dependent on oxidative phosphorylation in mature synapses, indicating presynaptic glycolysis may be dispensable for ATP maintenance.
Topics & Concepts
NeurotransmissionSynapseRespirationGlycolysisOxidative phosphorylationSynaptic vesicleMitochondrionBiologyNeuroscienceBioenergeticsCell biologyTransmission (telecommunications)MetabolismVesicleBiochemistryAnatomyComputer scienceMembraneTelecommunicationsReceptorNeuroscience and Neuropharmacology ResearchPhotoreceptor and optogenetics researchRetinal Development and Disorders