Parameter tuning differentiates granule cell subtypes enriching the repertoire of retransmission properties at the cerebellum input stage

Masoli, Stefano; Marialuisa, Tognolina; Laforenza, Umberto; Moccia, Francesco; D’Angelo, Egidio

doi:10.1101/638247

Cited by 4 publications

(5 citation statements)

References 74 publications

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“…with TRPM4 channels, which are primarily described in PCs (Kim et al, 2009(Kim et al, , 2013Menigoz et al, 2016). Remarkably, our model, derived from previous models (D 'Angelo et al, 2001;Nieus et al, 2006;Diwakar et al, 2009) and upgraded to account for sophisticated mechanisms of spike generation, predicted that TRPM4 currents, first recorded in GrCs, coupled to calmodulin through intracellular Ca 2+ changes, could effectively generate firing acceleration observed experimentally (Masoli et al, 2020b). Remarkably, mossy fiber-GrC synapse simulations showed that fine-tuning of adaptation/acceleration and short-term plasticity generated effective mossy fiber-GrC transmission channels, which could enrich the processing of incoming spike trains and enhance spatiotemporal coding at the cerebellar input stage (Gabbiani et al, 1994), according to the theoretical prediction of the adaptive filter model (Marr, 1969;Dean and Porrill, 2011;Rössert et al, 2015;D'Angelo et al, 2016).…”

Section: The Granular Layersupporting

confidence: 55%

“…In contrast to the canonical view describing GrCs as a homogenous population of neurons generating regular firing, our recently published work combining data from simulations and experimental findings on GrC electro responsive properties has identified different subtypes: adapting, non-adapting and accelerating GrCs (Masoli et al, 2020b). Adaptation occurs via Ca 2+ influx through high-threshold Ca 2+ conductance and subsequent increase in Ca 2+ -activated K + currents, causing an after-hyperpolarization potential after a burst of spikes (D'Angelo et al, 1998) whereas acceleration is correlated 2016)].…”

Section: The Granular Layermentioning

confidence: 84%

“…Interestingly, the realistic computational model of the granular layer network dynamics developed by Solinas et al (2010) established different roles for the main components of inhibition. Lateral inhibition is crucial for determining center-surface effects [GrCs in the core are more activated than those in the surrounding area (Mapelli and D'Angelo, 2007;D'Angelo and Casali, 2012;Prestori et al, 2019)], feed-forward inhibition to control the temporal window during which GrCs integrate excitatory inputs (D'Angelo and De Zeeuw, 2009;D'Angelo and Casali, 2012;Gandolfi et al, 2014;Eshra et al, 2019;Masoli et al, 2020b), and feedback inhibition to favor coherent oscillations in the theta frequency band (D'Angelo and Casali, 2012;Mapelli et al, 2014).…”

Section: The Granular Layermentioning

confidence: 99%

“…Moreover, the properties of specific AMPA receptor subtypes (gating kinetics and desensitization) determine the precision of spike emission, whereas the properties of NMDA receptor subunits (regulating gating kinetics, desensitization, and voltage-dependent Mg block) determine the intensity and duration of bursts. Another dimension is introduced by cell-to-cell variability, with differentiated excitable and neurotransmission properties even within the same class of neurons, [e.g., GrCs (Chabrol et al, 2015;Gilmer and Person, 2017;Masoli et al, 2020b;Straub et al, 2020), MLIs (Rizza et al, 2021), and candelabrum cells (Osorno et al, 2022), although not included in this work yet]. Finally, the strategic location of NMDA receptors at certain synapses (mossy fiber-GrC, mossy fiber-GoC, parallel fiber-PC, parallel fiber-MLI), as well as Ca permeation in certain types of AMPA receptors and voltage-gated calcium channels, causes various forms of plasticity that can further tune postsynaptic receptor conductance and presynaptic release probability, regulating the filtering properties of the circuit and local computations.…”

Section: A Summary Viewmentioning

confidence: 99%

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Computational models of neurotransmission at cerebellar synapses unveil the impact on network computation

Masoli

Rizza

Tognolina

et al. 2022

Front. Comput. Neurosci.

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The neuroscientific field benefits from the conjoint evolution of experimental and computational techniques, allowing for the reconstruction and simulation of complex models of neurons and synapses. Chemical synapses are characterized by presynaptic vesicle cycling, neurotransmitter diffusion, and postsynaptic receptor activation, which eventually lead to postsynaptic currents and subsequent membrane potential changes. These mechanisms have been accurately modeled for different synapses and receptor types (AMPA, NMDA, and GABA) of the cerebellar cortical network, allowing simulation of their impact on computation. Of special relevance is short-term synaptic plasticity, which generates spatiotemporal filtering in local microcircuits and controls burst transmission and information flow through the network. Here, we present how data-driven computational models recapitulate the properties of neurotransmission at cerebellar synapses. The simulation of microcircuit models is starting to reveal how diverse synaptic mechanisms shape the spatiotemporal profiles of circuit activity and computation.

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Section: The Granular Layersupporting

confidence: 55%

Section: The Granular Layermentioning

confidence: 84%

Section: The Granular Layermentioning

confidence: 99%

Section: A Summary Viewmentioning

confidence: 99%

See 2 more Smart Citations

Computational models of neurotransmission at cerebellar synapses unveil the impact on network computation

Masoli

Rizza

Tognolina

et al. 2022

Front. Comput. Neurosci.

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“…These simulations therefore strongly support the concept that mossy fiber -granule cell plasticity is fundamental to tune the filtering properties of the cerebellar granular layer. The recently discovered granule cell subtypes (adapting, nonadapting and accelerating) may further bias the unit toward high-pass or low-pass filtering depending on the expression of TRPM4 channels 45 .…”

Section: Model Prediction Of Spike Filtering Properties In Granular Lmentioning

confidence: 99%

Cellular-resolution mapping uncovers spatial adaptive filtering at the cerebellum input stage

Casali¹,

Marialuisa²,

D’Angelo

2020

Preprint

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Long-term synaptic plasticity, in the form of either potentiation or depression (LTP or LTD), is thought to provide the substrate for adaptive computations in brain circuits. Although molecular and cellular processes of plasticity have been clarified to a considerable extent at individual synapses, very little is known about the spatiotemporal organization of LTP and LTD in local microcircuits. Here, we have combined multi-spot two-photon laser microscopy and realistic modeling to map the distribution of plasticity in multi-neuronal units of the cerebellar granular layer activated by stimulating an afferent mossy fiber bundle. The units, composed by ~300 active neurons connected to ~50 glomeruli, showed potentiation concentrated in the core and depression in the periphery. This plasticity was effectively accounted for by an NMDA receptor and calcium-dependent induction rule and was regulated by local microcircuit mechanisms in the inhibitory Golgi cell loops. The organization of LTP and LTD created effective spatial filters tuning the time-delay and gain of spike retransmission at the cerebellum input stage and provided a plausible basis for the spatiotemporal recoding of input spike patterns anticipated by the motor learning theory.recording activity from several granular layer neurons simultaneously and was stable enough to monitor long-term changes in synaptic transmission 25 . Therefore, in principle, SLM-2PM should allow to map spatially distributed granular layer activity with single cell resolution before and after the induction of long-term synaptic plasticity with high-frequency mossy fiber stimuli [26][27][28][29] . A further critical step is to extract the single spike patterns of neurons, which cannot be directly measured at the time resolution of calcium imaging but can be inferred using realistic modeling techniques. In recent years, modeling of the granular layer has advanced enough to guarantee a good predictability of local microcircuit dynamics [30][31][32] . Techniques are therefore mature, in principle, to evaluate the cellular determinates of the adaptive filtering properties predicted by theory in computational units of the cerebellum granular layer. RESULTS Multi-neuron responses of the granular layer following mossy fiber stimulationCalcium imaging (with Fura-2 AM) was performed using a spatial light modulator twophoton microscope (SLM-2PM) 25 in order to gain insight into the cellular organization of granular layer responses to MF bundle stimulation in acute cerebellar slices. We recorded up to 200 granule cells simultaneously, many of which (normally <=100) responded with fluorescence changes following delivery of short stimulus bursts (10 pulses @ 50 Hz) ( Fig.1 A-C). Recordings were carried out both on the sagittal and coronal plane, in order to account for potential asymmetries in granular layer responses. The multi-neuron maps (∆F/F 0 of granule cell responses to MF stimulation) covered a surface that was irregularly rounded both in sagittal and coronal slices and showed activity de...

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Cerebellar Golgi cell models predict dendritic processing and mechanisms of synaptic plasticity

Masoli

Ottaviani

D’Angelo

2020

Preprint

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experimental findings and revealed the nature of signal interchange between dendrites and axo-46 somatic compartments. A main prediction of the models is that synaptic activation of apical 47 dendrites can effectively trigger spike generation in the axonal initial segment followed by 48 rapid spike backpropagation into basal dendrites. Here, incoming mossy fiber inputs and 49 backpropagating spikes regulate the voltage-dependent unblock of NMDA channels and the 50 induction of spike timing-dependent plasticity (STDP). STDP, which was predicted by theory, 51 may therefore be controlled by contextual information provided by parallel fibers and 52 integrated in apical dendrites, supporting the view that spike timing is fundamental to control 53 synaptic plasticity at the cerebellar input stage. 54 55

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Parameter tuning differentiates granule cell subtypes enriching the repertoire of retransmission properties at the cerebellum input stage

Cited by 4 publications

References 74 publications

Computational models of neurotransmission at cerebellar synapses unveil the impact on network computation

Computational models of neurotransmission at cerebellar synapses unveil the impact on network computation

Cellular-resolution mapping uncovers spatial adaptive filtering at the cerebellum input stage

Cerebellar Golgi cell models predict dendritic processing and mechanisms of synaptic plasticity

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