Synaptic Plasticity in Cortical Inhibitory Neurons: What Mechanisms May Help to Balance Synaptic Weight Changes?

Bannon, Nicholas M.; Chistiakova, Marina; Volgushev, Maxim

doi:10.3389/fncel.2020.00204

Cited by 22 publications

(25 citation statements)

References 147 publications

(482 reference statements)

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“…Several identities of this circuit are consistent with our data. Sparsening could be mediated by a class of local interneurons, whose inputs from local pyramidal cells tuned to taskinformative stimuli are strengthened after learning (29,30). Alternatively, it could be mediated by feedback from more distal cortical regions or neuromodulators, which target local inhibitory circuits to cause retinotopically-aligned suppression.…”

Section: Discussionmentioning

confidence: 99%

Visuomotor association orthogonalizes visual cortical population codes

Carandini

Harris

2021

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The response of a neuronal population to a stimulus can be summarized by a vector in a high-dimensional space. Learning theory suggests that the brain should be most able to produce distinct behavioral responses to two stimuli when the rate vectors they evoke are close to orthogonal. To investigate how learning modifies population codes, we measured the orientation tuning of 4,000-neuron populations in visual cortex before and after training on a visual discrimination task. Learning suppressed responses to the task-informative stimuli, most strongly amongst weakly-tuned neurons. This suppression reflected a simple change at the population level: sparsening of population responses to relevant stimuli, resulting in orthogonalization of their rate vectors. A model of F-I curve modulation, requiring no synaptic plasticity, quantitatively predicted the learning effect.

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Section: Discussionmentioning

confidence: 99%

Visuomotor association orthogonalizes visual cortical population codes

Carandini

Harris

2021

Preprint

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“…Experimental results confirming this prediction offer broader evidence in support of the proposed homeostatic role of heterosynaptic plasticity during on-going associative learning (Oja 1982;MIller and MacKay 1994;von der Malsburg 1973;Miller 1996;Watt et. al., 2010;Zenke and Gerstner 2017;Bannon et. al., 2020).…”

Section: Discussionmentioning

confidence: 99%

Altered Heterosynaptic Plasticity Impairs Visual Discrimination Learning in Adenosine A1 Receptor Knock-Out Mice

et al. 2021

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Theoretical and modeling studies demonstrate that heterosynaptic plasticity -changes at synapses inactive during induction -facilitates fine-grained discriminative learning in Hebbian-type systems, and helps to achieve a robust ability for repetitive learning. A dearth of tools for selective manipulation has hindered experimental analysis of the proposed role of heterosynaptic plasticity in behavior. Here we circumvent this obstacle by testing specific predictions about changes in heterosynaptic plasticity, and associated behavioral consequences, following experimental manipulation of adenosine A1 receptors (A1R). We show that, compared to wild-type controls, A1R-knockout mice have impaired synaptic plasticity in visual cortex neurons, coupled with significant deficits in visual discrimination learning. Deficits in A1R-knockouts were seen specifically during re-learning, becoming progressively more apparent with learning on sequential visual discrimination tasks of increasing complexity. These behavioral results confirm our model predictions, and provide the first experimental evidence for a proposed role of heterosynaptic plasticity in learning.

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“…This new relationship can further help to understand a range of observations. Since this cooperation originates from excitatory neurons' desire to monopolize a certain input pattern, it is not hard to understand why the strongest lateral inhibition will occur among neurons that fire together [84], why the inhibition will dynamically increase with excitation [85,86], and why the distribution of inhibition is found to be precisely matched with that of excitation [87,88,89]. All these facts follow the logic that inhibitory neurons are recruited for the competition among excitatory neurons.…”

Section: Inhibitionmentioning

confidence: 91%

Account for Neuronal Representations from the Perspective of Neurons

Zheng¹

2021

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Mounting evidence in neuroscience suggests the possibility of neuronal representations that individual neurons serve as the substrates of different mental representations in a point-to-point way. Combined with associationism, it can potentially address a range of theoretical problems and provide a straightforward explanation for our cognition. However, this idea is merely a hypothesis with many questions unsolved. In this paper, I will bring up a new framework to defend the idea of neuronal representations. The strategy is from micro-to macro-level. Specifically, in the micro-level, I first propose that our brain' prefers and preserves more active neurons. Yet as total chance of discharge, neurons must take strategies to fire more strongly and frequently. Then I describe how they take synaptic plasticity, inhibition, and synchronization as their strategies and demonstrate how the execution of these strategies during turn them into specialized neurons that selectively but strongly respond to familiar entities. In the macro-level, I further discuss how these specialized neurons underlie various cognitive functions and phenomena. Significantly, this paper, through defending neuronal representation, introduces a novel way to understand the relationship between brain and cognition.

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Synaptic Plasticity in Cortical Inhibitory Neurons: What Mechanisms May Help to Balance Synaptic Weight Changes?

Cited by 22 publications

References 147 publications

Visuomotor association orthogonalizes visual cortical population codes

Visuomotor association orthogonalizes visual cortical population codes

Altered Heterosynaptic Plasticity Impairs Visual Discrimination Learning in Adenosine A1 Receptor Knock-Out Mice

Account for Neuronal Representations from the Perspective of Neurons

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