Mechanisms and functional roles of glutamatergic synapse diversity in a cerebellar circuit

Valeria Zampini; Jian K Liu; Marco A Diana; Paloma P Maldonado; Nicolas Brunel; Stéphane Dieudonné

doi:10.7554/eLife.15872

Mechanisms and functional roles of glutamatergic synapse diversity in a cerebellar circuit

Valeria Zampini, Jian K Liu, Marco A Diana, Paloma P Maldonado, Nicolas Brunel, Stéphane Dieudonné

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Synaptic currents display a large degree of heterogeneity of their temporal characteristics, but the functional role of such heterogeneities remains unknown. We investigated in rat cerebellar slices synaptic currents in Unipolar Brush Cells (UBCs), which generate intrinsic mossy fibers relaying vestibular inputs to the cerebellar cortex. We show that UBCs respond to sinusoidal modulations of their sensory input with heterogeneous amplitudes and phase shifts. Experiments and modeling indicate that this variability results both from the kinetics of synaptic glutamate transients and from the diversity of postsynaptic receptors. While phase inversion is produced by an mGluR2-activated outward conductance in OFF-UBCs, the phase delay of ON UBCs is caused by a late rebound current resulting from AMPAR recovery from desensitization. Granular layer network modeling indicates that phase dispersion of UBC responses generates diverse phase coding in the granule cell population, allowing climbing-fiber-driven Purkinje cell learning at arbitrary phases of the vestibular input.

Originele taal-2	Engels
Tijdschrift	eLife
Volume	5
DOI's	https://doi.org/10.7554/eLife.15872
Status	Gepubliceerd - 2016

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abstract = "Synaptic currents display a large degree of heterogeneity of their temporal characteristics, but the functional role of such heterogeneities remains unknown. We investigated in rat cerebellar slices synaptic currents in Unipolar Brush Cells (UBCs), which generate intrinsic mossy fibers relaying vestibular inputs to the cerebellar cortex. We show that UBCs respond to sinusoidal modulations of their sensory input with heterogeneous amplitudes and phase shifts. Experiments and modeling indicate that this variability results both from the kinetics of synaptic glutamate transients and from the diversity of postsynaptic receptors. While phase inversion is produced by an mGluR2-activated outward conductance in OFF-UBCs, the phase delay of ON UBCs is caused by a late rebound current resulting from AMPAR recovery from desensitization. Granular layer network modeling indicates that phase dispersion of UBC responses generates diverse phase coding in the granule cell population, allowing climbing-fiber-driven Purkinje cell learning at arbitrary phases of the vestibular input.",

author = "Valeria Zampini and Liu, {Jian K} and Diana, {Marco A} and Maldonado, {Paloma P} and Nicolas Brunel and St{\'e}phane Dieudonn{\'e}",

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AU - Zampini, Valeria

AU - Liu, Jian K

AU - Diana, Marco A

AU - Maldonado, Paloma P

AU - Brunel, Nicolas

AU - Dieudonné, Stéphane

PY - 2016

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AB - Synaptic currents display a large degree of heterogeneity of their temporal characteristics, but the functional role of such heterogeneities remains unknown. We investigated in rat cerebellar slices synaptic currents in Unipolar Brush Cells (UBCs), which generate intrinsic mossy fibers relaying vestibular inputs to the cerebellar cortex. We show that UBCs respond to sinusoidal modulations of their sensory input with heterogeneous amplitudes and phase shifts. Experiments and modeling indicate that this variability results both from the kinetics of synaptic glutamate transients and from the diversity of postsynaptic receptors. While phase inversion is produced by an mGluR2-activated outward conductance in OFF-UBCs, the phase delay of ON UBCs is caused by a late rebound current resulting from AMPAR recovery from desensitization. Granular layer network modeling indicates that phase dispersion of UBC responses generates diverse phase coding in the granule cell population, allowing climbing-fiber-driven Purkinje cell learning at arbitrary phases of the vestibular input.

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Mechanisms and functional roles of glutamatergic synapse diversity in a cerebellar circuit

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