All-optical voltage interrogation for probing synaptic plasticity in vivo

Carolan, Jacques; Land, Michelle A.; Lu, Xiaoyu; Beau, Maxime; Kostadinov, Dimitar; St-Pierre, François; Clark, Beverley A.; Häusser, Michael

All-optical voltage interrogation for probing synaptic plasticity in vivo

Jacques Carolan (), Michelle A. Land, Xiaoyu Lu, Maxime Beau, Dimitar Kostadinov, François St-Pierre, Beverley A. Clark and Michael Häusser ()
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Jacques Carolan: University College London
Michelle A. Land: Baylor College of Medicine
Xiaoyu Lu: Baylor College of Medicine
Maxime Beau: University College London
Dimitar Kostadinov: University College London
François St-Pierre: Baylor College of Medicine
Beverley A. Clark: University College London
Michael Häusser: University College London

Nature Communications, 2025, vol. 16, issue 1, 1-12

Abstract: Abstract Measuring synaptic efficacy and defining the rules for induction of synaptic plasticity at identified connections in the mammalian brain is essential for understanding how synapses contribute to learning and memory. This requires new approaches to selectively evoke presynaptic activity and measure postsynaptic responses with high spatiotemporal resolution and high sensitivity over long periods in vivo. Here we develop an all-optical approach to probe synaptic plasticity at identified cerebellar synapses in awake, behaving mice. We developed and applied JEDI-2Psub, a genetically encoded voltage indicator with increased sensitivity around resting membrane potentials, to record subthreshold and suprathreshold activity in Purkinje cell (PC) dendrites while selectively activating their granule cell (GrC) inputs using optogenetics and their climbing fiber (CF) inputs using sensory stimulation. We measured synaptic potentials and complex spike signals across the dendrites of multiple neighboring PCs, enabling us to examine correlations in voltage signals within and between neurons. We show how pairing GrC activity with sensory-evoked CF inputs can trigger long-term plasticity of inhibitory responses in PCs. These results provide a blueprint for defining the rules for plasticity induction at identified synapses in awake animals during behavior.

Date: 2025
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DOI: 10.1038/s41467-025-63867-4

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