A unifying framework for synaptic organization on cortical dendrites

Kirchner, Jan H.; Gjorgjieva, Julijana

doi:10.1101/771907

Cited by 8 publications

(7 citation statements)

References 92 publications

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“…This would give rise to soma-biased input populations 9 , 13 and could be achieved by modulating synaptogenesis and synaptic pruning 23 ; increasing the probability of stabilizing inputs co-tuned with the somatic output. While developmental models have made similar predictions 24 , this process has not been observed in vivo . How the strength of individual synapses relates to visual processing remains unclear, but this may be constrained by other operational features distinguishing presynaptic afferents.…”

mentioning

confidence: 91%

Cortical response selectivity derives from strength in numbers of synapses

Scholl

Thomas

Ryan

et al. 2020

Nature

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Single neocortical neurons are driven by populations of excitatory inputs, forming the basis of neuronal selectivity to features of sensory input. Excitatory connections are thought to mature during development through activity-dependent Hebbian plasticity 1 , whereby similarity between presynaptic and postsynaptic activity selectively strengthens some synapses and weakens others 2 . Evidence in support of this process ranges from measurements of synaptic ultrastructure to in vitro and in vivo physiology and imaging studies 3 , 4 , 5 , 6 , 7 , 8 . These corroborating lines of evidence lead to the prediction that a small number of strong synaptic inputs drive neuronal selectivity, while weak synaptic inputs are less correlated with the somatic output and modulate activity overall 6 , 7 . Supporting evidence from cortical circuits, however, has been limited to measurements of neighboring, connected cell pairs, raising the question of whether this prediction holds for a broad range of synapses converging onto cortical neurons. Here we measure the strengths of functionally characterized excitatory inputs contacting single pyramidal neurons in ferret primary visual cortex (V1) by combining in vivo two-photon synaptic imaging and post hoc electron microscopy (EM). Using EM reconstruction of individual synapses as a metric of strength, we find no evidence that strong synapses play a predominant role in the selectivity of cortical neuron responses to visual stimuli. Instead, selectivity appears to arise from the total number of synapses activated by different stimuli. Moreover, spatial clustering of co-active inputs appears reserved for weaker synapses, enhancing the contribution of weak synapses to somatic responses. Our results challenge the role of Hebbian mechanisms in shaping neuronal selectivity in cortical circuits, and suggest that selectivity reflects the co-activation of large populations of presynaptic neurons with similar properties and a mixture of strengths.

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mentioning

confidence: 91%

Cortical response selectivity derives from strength in numbers of synapses

Scholl

Thomas

Ryan

et al. 2020

Nature

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“…Notably, this mechanism did not generate clusters composed of functionally homogenous inputs, as global plasticity stabilises any input irrespective of its location within the dendritic tree that show correlated activity with a functional cluster. The interspersion of inputs with a wide range of functional properties on individual branches is an important characteristic of both experimental data 5,42,54 and computational models 55 and may thus be a signature of the regulation of structural synaptic plasticity on various spatial scales. Importantly, to generate functional clusters by global plasticity alone, dendritic nonlinearities have to be sufficiently strong with a low threshold to amplify the effect of small, randomly occurring clusters and to control the plasticity process, whereas clustering via local plasticity mechanisms does not necessarily require dendritic nonlinearities 21 .…”

Section: Discussionmentioning

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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“…This could be achieved by modulating synaptogenesis and synaptic pruning 23 ; increasing the probability of stabilizing inputs co-tuned with the somatic output. While developmental models of single neurons have made similar predictions 24 , this process has yet to be observed in vivo. Unitary synaptic strength, instead, may simply depend on operational properties of presynaptic afferents.…”

Section: Mainmentioning

confidence: 98%

Cortical neuron response selectivity derives from strength in numbers of synapses

Scholl

Thomas

Ryan

et al. 2019

Preprint

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Single neocortical neurons are driven by populations of excitatory inputs, forming the basis of neural selectivity to features of sensory input. Excitatory connections are thought to mature during development through activity-dependent Hebbian plasticity 1 , whereby similarity between presynaptic and postsynaptic activity selectively strengthens some synapses and weakens others 2 . Evidence in support of this process ranges from measurements of synaptic ultrastructure to slice and in vivo physiology and imaging studies 3,4,5,6,7,8 . These corroborating lines of evidence lead to the prediction that a small number of strong synaptic inputs drive neural selectivity, while weak synaptic inputs are less correlated with the functional properties of somatic output and act to modulate activity overall 6,7 . Supporting evidence from cortical circuits, however, has been limited to measurements of neighboring, connected cell pairs, raising the question of whether this prediction holds for the full profile of synapses converging onto cortical neurons. Here we measure the strengths of functionally characterized excitatory inputs contacting single pyramidal neurons in ferret primary visual cortex (V1) by combining in vivo two-photon synaptic imaging and post hoc electron microscopy (EM). Using EM reconstruction of individual synapses as a metric of strength, we find no evidence that strong synapses play a predominant role in the selectivity of cortical neuron responses to visual stimuli. Instead, selectivity appears to arise from the total number of synapses activated by different stimuli. Moreover, spatial clustering of co-active inputs, thought to amplify synaptic drive, appears reserved for weaker synapses, further enhancing the contribution of the large number of weak synapses to somatic response. Our results challenge the role of Hebbian mechanisms in shaping neuronal selectivity in cortical circuits, and suggest that selectivity reflects the co-activation of large populations of presynaptic neurons with similar properties and a mixture of strengths.

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A unifying framework for synaptic organization on cortical dendrites

Cited by 8 publications

References 92 publications

Cortical response selectivity derives from strength in numbers of synapses

Cortical response selectivity derives from strength in numbers of synapses

Impact of functional synapse clusters on neuronal response selectivity

Cortical neuron response selectivity derives from strength in numbers of synapses

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