Functional clustering of dendritic activity during decision-making

Kerlin, Aaron; Mohar, Boaz; Flickinger, Daniel; MacLennan, Bryan J; Dean, Matthew B; Davis, Courtney; Spruston, Nelson; Svoboda, Karel

doi:10.7554/elife.46966

Cited by 148 publications

(112 citation statements)

References 117 publications

(216 reference statements)

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“…This mechanism is input specific and is efficient only when the coactive synapses are located within ϳ5-10 m distance; it is possible that biochemical compartmentalization contributes to constraining the spatial limits for subthreshold LTP. This small number and spatial scale is remarkably consistent with that of small functional spine clusters observed in several PC types, including CA1 (Sheffield et al, 2017) and cortical PCs (Kleindienst et al, 2011;Takahashi et al, 2012;Iacaruso et al, 2017;Scholl et al, 2017;Kerlin et al, 2019;Lee et al, 2019). Such small clusters are neither necessary (Losonczy and Magee, 2006) nor sufficient to evoke d-spikes even under simulated in vivo conditions (Ujfalussy and Makara, 2020), but this is actually not needed for their local plasticity by the mechanism we describe.…”

Section: Discussionsupporting

confidence: 86%

“…Shorter dendritic segments, with a group of coactive inputs, may also represent integration compartments by producing local NMDARmediated spikes (Polsky et al, 2004). Furthermore, imaging studies revealed spatially restricted Ca 2ϩ signals in vivo, suggesting locally correlated synaptic activity (Kleindienst et al, 2011;Takahashi et al, 2012;Cichon and Gan, 2015;Iacaruso et al, 2017;Scholl et al, 2017;Sheffield et al, 2017;Kerlin et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

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Synaptic Plasticity Depends on the Fine-Scale Input Pattern in Thin Dendrites of CA1 Pyramidal Neurons

et al. 2020

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Coordinated long-term plasticity of nearby excitatory synaptic inputs has been proposed to shape experience-related neuronal information processing. To elucidate the induction rules leading to spatially structured forms of synaptic potentiation in dendrites, we explored plasticity of glutamate uncaging-evoked excitatory input patterns with various spatial distributions in perisomatic dendrites of CA1 pyramidal neurons in slices from adult male rats. We show that (1) the cooperativity rules governing the induction of synaptic LTP depend on dendritic location; (2) LTP of input patterns that are subthreshold or suprathreshold to evoke local dendritic spikes (d-spikes) requires different spatial organization; and (3) input patterns evoking d-spikes can strengthen nearby, nonsynchronous synapses by local heterosynaptic plasticity crosstalk mediated by NMDAR-dependent MEK/ERK signaling. These results suggest that multiple mechanisms can trigger spatially organized synaptic plasticity on various spatial and temporal scales, enriching the ability of neurons to use synaptic clustering for information processing.

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Section: Discussionsupporting

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Synaptic Plasticity Depends on the Fine-Scale Input Pattern in Thin Dendrites of CA1 Pyramidal Neurons

et al. 2020

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“…Here, however several studies support the existence of dendritic plateau potentials in vivo (Lavzin et al, 2012;Xu et al, 2012;Smith et al, 2013;Gambino et al, 2014;Cichon and Gan, 2015;Du et al, Ranganathan et al, 2018). Significantly, two recent studies (Moore et al, 2017;Kerlin et al, 2019) reported in vivo plateau potentials with characteristics directly comparable to the biophysics of the plateau potentials discussed in the present study. Glia-encapsulated-tetrode in vivo recordings showed large-amplitude, sustained plateau depolarizations (lasting several hundred milliseconds) accompanied by sodium spikes (ref.…”

Section: Distortion Of the Neuronal R In And Tau By Simple Depolarizasupporting

confidence: 79%

Local Glutamate-Mediated Dendritic Plateau Potentials Change the State of the Cortical Pyramidal Neuron

Gao

Graham

Zhou

et al. 2019

Preprint

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37Dendritic spikes in thin dendritic branches (basal and oblique dendrites) of pyramidal neurons 38 are traditionally inferred from spikelets measured in the cell body. Here, we used laser-spot 39 voltage-sensitive dye imaging in cortical pyramidal neurons (rat brain slices) to investigate the 40 voltage waveforms of dendritic potentials occurring in response to spatially-restricted 41 glutamatergic inputs. Local dendritic potentials lasted 200-500 ms and propagated to the cell 42 body where they caused sustained 10-20 mV depolarizations. Plateau potentials propagating 43 from dendrite to soma, and action potentials propagating from soma to dendrite, created 44 complex voltage waveforms in the middle of the thin basal dendrite, comprised of local sodium 45 spikelets, local plateau potentials, and back-propagating action potentials, superimposed on 46 each other. Our model replicated these experimental observations and made the following 47 predictions: (i) membrane time constant is shortened during the plateau; and (ii) synaptic 48 responses are more effective drivers of neuronal action potentials during the plateau potential.49 Dendritic plateau potentials occurring in basal and oblique branches put pyramidal neurons into 50 an activated neuronal state ("prepared state"), characterized by depolarized membrane potential 51 and notably faster membrane responses. The prepared state provides a time window of 200-52 500 ms during which cortical neurons are particularly excitable and capable of following afferent 53 inputs. At the network level, this predicts that sets of cells with simultaneous plateaus would 54 provide cellular substrate for the formation of functional neuronal ensembles. 55 56 57 58 59Significance statement: Strong and clustered glutamatergic inputs will have a major 60 influence on activity at both neuronal and network scales. We recorded glutamate-mediated 61 dendritic voltage plateaus using voltage imaging, and created a computer model that recreated 62 experimental measures. Our model predicts the manner in which plateaus are triggered and the 63 impact of inputs to an individual thin dendrite on the membrane response in the cell body. 64 Plateau potentials profoundly change neuronal state --a plateau potential triggered in one basal 65 dendrite depolarizes the soma and shortens membrane time constant, making the cell more 66 susceptible to firing triggered by other afferent inputs. We tested model predictions 67 experimentally. 68 69 70 The individual spiny neuron is subjected to a variety of excitatory input patterns, often resulting 71 from concurrent release across multiple synapses on a single dendrite. Due to combinations of 72 temporal and spatial clustering 1-3 , the amount of glutamate released on a single basilar dendrite 73 can be quite large, potentially spilling over to extrasynaptic NMDA receptors, and temporarily 74 overwhelming the ability of astrocytes to fully compensate. In vitro focal applications of 75 comparable amounts of glutamate, or repetitive synaptic stimulations, wi...

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“…Second, our result that global plasticity can contribute to the weakening of other synapses when the cell is driven by the activation of clustered inputs can promote new theoretical and experimental research investigating the interaction between local and global plasticity rules in shaping neuronal feature selectivity and cluster formation 65 . Third, our insights could motivate novel in vivo experiments both to further quantify the mid-scale organisation and diversity of synaptic inputs targeting the dendritic tree (focusing less on the fine-scale within-branch arrangements 5,6 ), as well as to directly test predictions of our simulations.…”

Section: Discussionmentioning

confidence: 99%

“…In particular, the spatial scale of the synapses showing correlated activity in vivo has been found to be restricted to~5-10 μm and involved a small number,~2-5 dendritic spines 2,[4][5][6] . This is substantially less than the~10-20 inputs required to trigger dendritic Na + or NMDA spikes (characteristic for thin branches) under in vitro conditions 7-10 leaving the potential impact of the clusters elusive.…”

mentioning

confidence: 99%

Impact of functional synapse clusters on neuronal response selectivity

Ujfalussy

Makara

2020

Nat Commun

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Clustering of functionally similar synapses in dendrites is thought to affect neuronal inputoutput transformation by triggering local nonlinearities. However, neither the in vivo impact of synaptic clusters on somatic membrane potential (sVm), nor the rules of cluster formation are elucidated. We develop a computational approach to measure the effect of functional synaptic clusters on sVm response of biophysical model CA1 and L2/3 pyramidal neurons to in vivo-like inputs. We demonstrate that small synaptic clusters appearing with random connectivity do not influence sVm. With structured connectivity,~10-20 synapses/cluster are optimal for clustering-based tuning via state-dependent mechanisms, but larger selectivity is achieved by 2-fold potentiation of the same synapses. We further show that without nonlinear amplification of the effect of random clusters, action potential-based, global plasticity rules cannot generate functional clustering. Our results suggest that clusters likely form via local synaptic interactions, and have to be moderately large to impact sVm responses.

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Functional clustering of dendritic activity during decision-making

Cited by 148 publications

References 117 publications

Synaptic Plasticity Depends on the Fine-Scale Input Pattern in Thin Dendrites of CA1 Pyramidal Neurons

Synaptic Plasticity Depends on the Fine-Scale Input Pattern in Thin Dendrites of CA1 Pyramidal Neurons

Local Glutamate-Mediated Dendritic Plateau Potentials Change the State of the Cortical Pyramidal Neuron

Impact of functional synapse clusters on neuronal response selectivity

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