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Interactive nanocluster compaction of the ELKS scaffold and Cacophony Ca 2+ channels drives sustained active zone potentiation.

Tina GhelaniMarc EscherUlrich ThomasKlara EschJanine LützkendorfHarald DepnerMarta MaglionePierre ParuttoScott J GratzTanja Matkovic-RachidStefanie RyglewskiAlexander M WalterDavid HolcmanKate M Oâ Connor-GilesMartin HeineStephan J Sigrist
Published in: Science advances (2023)
At presynaptic active zones (AZs), conserved scaffold protein architectures control synaptic vesicle (SV) release by defining the nanoscale distribution and density of voltage-gated Ca 2+ channels (VGCCs). While AZs can potentiate SV release in the minutes range, we lack an understanding of how AZ scaffold components and VGCCs engage into potentiation. We here establish dynamic, intravital single-molecule imaging of endogenously tagged proteins at Drosophila AZs undergoing presynaptic homeostatic potentiation. During potentiation, the numbers of α1 VGCC subunit Cacophony (Cac) increased per AZ, while their mobility decreased and nanoscale distribution compacted. These dynamic Cac changes depended on the interaction between Cac channel's intracellular carboxyl terminus and the membrane-close amino-terminal region of the ELKS-family protein Bruchpilot, whose distribution compacted drastically. The Cac-ELKS/Bruchpilot interaction was also needed for sustained AZ potentiation. Our single-molecule analysis illustrates how the AZ scaffold couples to VGCC nanoscale distribution and dynamics to establish a state of sustained potentiation.
Keyphrases
  • single molecule
  • atomic force microscopy
  • tissue engineering
  • living cells
  • high speed
  • transcription factor
  • protein kinase
  • mass spectrometry
  • reactive oxygen species
  • prefrontal cortex