Inhibition gates supralinear Ca2+ signaling in Purkinje cell dendrites during practiced movements.

Michael A Gaffield,Hirokazu Hirai,Jason M Christie,Matthew J M Rowan,Samantha B Amat

doi:10.7554/elife.36246

Michael A Gaffield, Hirokazu Hirai + Show 3 more

Open Access

https://doi.org/10.7554/elife.36246

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Abstract

Motor learning involves neural circuit modifications in the cerebellar cortex, likely through re-weighting of parallel fiber inputs onto Purkinje cells (PCs). Climbing fibers instruct these synaptic modifications when they excite PCs in conjunction with parallel fiber activity, a pairing that enhances climbing fiber-evoked Ca2+ signaling in PC dendrites. In vivo, climbing fibers spike continuously, including during movements when parallel fibers are simultaneously conveying sensorimotor information to PCs. Whether parallel fiber activity enhances climbing fiber Ca2+ signaling during motor behaviors is unknown. In mice, we found that inhibitory molecular layer interneurons (MLIs), activated by parallel fibers during practiced movements, suppressed parallel fiber enhancement of climbing fiber Ca2+ signaling in PCs. Similar results were obtained in acute slices for brief parallel fiber stimuli. Interestingly, more prolonged parallel fiber excitation revealed latent supralinear Ca2+ signaling. Therefore, the balance of parallel fiber and MLI input onto PCs regulates concomitant climbing fiber Ca2+ signaling.

Highlights

Neural circuits that support motor learning must respond to, and adjust for, stimuli relevant for encoding adaptation
We found that inhibitory molecular layer interneurons (MLIs), activated by parallel fibers during practiced movements, suppressed parallel fiber enhancement of climbing fiber Ca2+ signaling in Purkinje cells (PCs)
Our results show that climbing fiber Ca2+ signals in PCs are regulated by the counterbalance of MLI-mediated inhibition with parallel fiber-evoked excitatory postsynaptic potentials (EPSPs)

Summary

Introduction

Neural circuits that support motor learning must respond to, and adjust for, stimuli relevant for encoding adaptation. With equal importance, these circuits must prevent network alterations during stimuli unrelated or unnecessary for behavioral modification. Climbing fibers instruct synaptic alterations by evoking dendritic Ca2+ spikes in PCs (Kano et al, 1992; Hansel and Linden, 2000; Coesmans et al, 2004) in response to adaptive stimuli (Simpson and Alley, 1974; Gilbert and Thach, 1977; Medina and Lisberger, 2008). The integrative features of PC dendrites offer solutions as to how PCs accomplish this task (Najafi and Medina, 2013)

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