6533b828fe1ef96bd1288314

RESEARCH PRODUCT

Transient Confinement of CaV2.1 Ca2+-Channel Splice Variants Shapes Synaptic Short-Term Plasticity

Pierre ParuttoJennifer HeckJennifer HeckMartin HeineMartin HeineMartin HeineJessica MitlöhnerAnna FejtovaAnna FejtovaAnna FejtovaMaria Andres-alonsoAnna CiuraszkiewiczAnna CiuraszkiewiczRomy FreundArthur BikbaevArthur BikbaevDavid HolcmanDavid Holcman

subject

0301 basic medicineVoltage-dependent calcium channelbiologyChemistryGeneral NeuroscienceCalcium channelAlternative splicingNeurotransmissionSynaptic vesiclePresynapseCav2.1Synapse03 medical and health sciences030104 developmental biology0302 clinical medicineBiophysicsbiology.protein030217 neurology & neurosurgery

description

Summary The precision and reliability of synaptic information transfer depend on the molecular organization of voltage-gated calcium channels (VGCCs) within the presynaptic membrane. Alternative splicing of exon 47 affects the C-terminal structure of VGCCs and their affinity to intracellular partners and synaptic vesicles (SVs). We show that hippocampal synapses expressing VGCCs either with exon 47 (CaV2.1+47) or without (CaV2.1Δ47) differ in release probability and short-term plasticity. Tracking single channels revealed transient visits (∼100 ms) of presynaptic VGCCs in nanodomains (∼80 nm) that were controlled by neuronal network activity. Surprisingly, despite harboring prominent binding sites to scaffold proteins, CaV2.1+47 persistently displayed higher mobility within nanodomains. Synaptic accumulation of CaV2.1 was accomplished by optogenetic clustering, but only CaV2.1+47 increased transmitter release and enhanced synaptic short-term depression. We propose that exon 47-related alternative splicing of CaV2.1 channels controls synapse-specific release properties at the level of channel mobility-dependent coupling between VGCCs and SVs.

yearjournalcountryeditionlanguage
2019-07-01Neuron
https://doi.org/10.1016/j.neuron.2019.04.030