The contribution of synaptic location to inhibitory gain control in pyramidal cells

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Abstract

The activity of pyramidal cells is controlled by two opposing forces: synaptic inhibition and synaptic excitation. Interestingly, these synaptic inputs are not distributed evenly across the dendritic trees of cortical pyramidal cells. Excitatory synapses are densely packed along only the more peripheral dendrites, but are absent from the proximal stems and the soma. In contrast, inhibitory synapses are located throughout the dendritic tree, the soma, and the axon initial segment. Thus both excitatory and inhibitory inputs exist on the peripheral dendritic tree, while the proximal segments only receive inhibition. The functional consequences of this uneven organization remain unclear. We used both optogenetics and dynamic patch clamp techniques to simulate excitatory synaptic conductances in pyramidal cells, and then assessed how their firing output is modulated by gamma-amino-butyric acid type A (GABA _A) receptor activation at different regions of the somatodendritic axis. We report here that activation of GABA _A receptor on the same dendritic compartment as excitatory inputs causes a rightwards shift in the function relating firing rate to excitatory conductance (the input–output function). In contrast, GABA _A receptor activation proximal to the soma causes both a rightwards shift and also a reduction in the maximal firing rate. The experimental data are well reproduced in a simple, four compartmental model of a neuron with inhibition either on the same compartment, or proximal, to the excitatory drive.

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Most cited references 22

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Activation of Specific Interneurons Improves V1 Feature Selectivity and Visual Perception

Seung-Hee Lee, Alex Kwan, Siyu Zhang … (2012)

Inhibitory interneurons are essential components of the neural circuits underlying various brain functions. In the neocortex, a large diversity of GABAergic interneurons have been identified based on their morphology, molecular markers, biophysical properties, and innervation pattern 1,2,3 . However, how the activity of each subtype of interneurons contributes to sensory processing remains unclear. Here we show that optogenetic activation of parvalbumin-positive (PV+) interneurons in mouse V1 sharpens neuronal feature selectivity and improves perceptual discrimination. Using multichannel recording with silicon probes 4,5 and channelrhodopsin 2 (ChR2)-mediated optical activation 6 , we found that elevated spiking of PV+ interneurons markedly sharpened orientation tuning and enhanced direction selectivity of nearby neurons. These effects were caused by the activation of inhibitory neurons rather than decreased spiking of excitatory neurons, since archaerhodopsin-3 (Arch)-mediated optical silencing 7 of calcium/calmodulin-dependent protein kinase IIα-positive (CaMKIIα+) excitatory neurons caused no significant change in V1 stimulus selectivity. Moreover, the improved selectivity specifically required PV+ neuron activation, since activating somatostatin (SOM+) or vasointestinal peptide (VIP+) interneurons had no significant effect. Notably, PV+ neuron activation in awake mice caused a significant improvement in their orientation discrimination, mirroring the sharpened V1 orientation tuning. Together, these results provide the first demonstration that visual coding and perception can be improved by elevated spiking of a specific subtype of cortical inhibitory interneurons.

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Parvalbumin-Expressing Interneurons Linearly Transform Cortical Responses to Visual Stimuli

Bassam V. Atallah, William Bruns, Matteo Carandini … (2012)

The response of cortical neurons to a sensory stimulus is shaped by the network in which they are embedded. Here we establish a role of parvalbumin (PV)-expressing cells, a large class of inhibitory neurons that target the soma and perisomatic compartments of pyramidal cells, in controlling cortical responses. By bidirectionally manipulating PV cell activity in visual cortex we show that these neurons strongly modulate layer 2/3 pyramidal cell spiking responses to visual stimuli while only modestly affecting their tuning properties. PV cells' impact on pyramidal cells is captured by a linear transformation, both additive and multiplicative, with a threshold. These results indicate that PV cells are ideally suited to modulate cortical gain and establish a causal relationship between a select neuron type and specific computations performed by the cortex during sensory processing. Copyright © 2012 Elsevier Inc. All rights reserved.

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NMDA spikes in basal dendrites of cortical pyramidal neurons.

J. Schiller, G Major, H Koester … (2000)

Basal dendrites are a major target for synaptic inputs innervating cortical pyramidal neurons. At present little is known about signal processing in these fine dendrites. Here we show that coactivation of clustered neighbouring basal inputs initiated local dendritic spikes, which resulted in a 5.9 +/- 1.5 mV (peak) and 64.4 +/- 19.8 ms (half-width) cable-filtered voltage change at the soma that amplified the somatic voltage response by 226 +/- 46%. These spikes were accompanied by large calcium transients restricted to the activated dendritic segment. In contrast to conventional sodium or calcium spikes, these spikes were mediated mostly by NMDA (N-methyl-D-aspartate) receptor channels, which contributed at least 80% of the total charge. The ionic mechanism of these NMDA spikes may allow 'dynamic spike-initiation zones', set by the spatial distribution of glutamate pre-bound to NMDA receptors, which in turn would depend on recent and ongoing activity in the cortical network. In addition, NMDA spikes may serve as a powerful mechanism for modification of the cortical network by inducing long-term strengthening of co-activated neighbouring inputs.

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Author and article information

Journal

Journal ID (nlm-ta): Physiol Rep

Journal ID (iso-abbrev): Physiol Rep

Journal ID (publisher-id): phy2

Title: Physiological Reports

Publisher: Blackwell Publishing Ltd

ISSN (Print): 2051-817X

ISSN (Electronic): 2051-817X

Publication date (Print): October 2013

Publication date (Electronic): 23 September 2013

Volume: 1

Issue: 5

Electronic Location Identifier: e00067

Affiliations

[1 ]Howard Hughes Medical Institute, University of California San Diego La Jolla, 92093-0634, California

[2 ]Department of Physiology and Biophysics, University of Colorado Denver, Colorado

[3 ]Cardiology Department, Papworth Hospital Papworth Everard, CB23 3RE, Cambridge, U.K

[4 ]Institute of Neuroscience, Newcastle University Newcastle upon Tyne, NE2 4HH, U.K

Author notes

Andrew Trevelyan, Institute of Neuroscience, Newcastle University, Newcastle upon Tyne, NE2 4HH U.K. Tel: +44-191-222-5732 Fax: 44-191-222-6992 E-mail: andrew.trevelyan@ 123456ncl.ac.uk

Funding Information The work was supported by funding from the Howard Hughes Medical Institute (Scanziani laboratory), and Epilepsy Research U.K. and the MRC (A. J. T.).

Article

DOI: 10.1002/phy2.67

PMC ID: 3841021

PubMed ID: 24303159

SO-VID: 9b01d97f-1995-429c-84b2-022c3a25c2ed

License:

Re-use of this article is permitted in accordance with the Creative Commons Deed, Attribution 2.5, which does not permit commercial exploitation.

History

Date received : 19 July 2013

Date accepted : 28 July 2013

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