Superficial Layers Suppress the Deep Layers to Fine-tune Cortical Coding

Pluta, Scott R.; Telian, Greg I.; Naka, Alexander; Adesnik, Hillel

doi:10.1523/jneurosci.1459-18.2018

Cited by 39 publications

(40 citation statements)

References 75 publications

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“…Updating our prior model to reflect this hypothesis did not significantly change the robustly observed stereotypical beta event waveform shape (10,12), and was crucial to our conclusions regarding beta event-mediated tactile suppression. Our findings are also in agreement with several studies that have suggested slow inhibition in the supragranular layers -including through GABAB mechanisms -is a key regulator of conscious perception (31,32) and is specifically involved in inhibiting somatosensory perception (33). For example, Larkum and colleagues have shown that dendrite-mediated suppression of rodent somatosensory perception is regulated by GABAB receptor activation in the mid-apical dendrite of L5 pyramidal cells, driven by a transcallosal inhibitory projection (28,34).…”

Section: Consistency Of the Current Findings With Prior Studies Of Sisupporting

confidence: 93%

A supragranular nexus for the effects of neocortical beta events on human tactile perception

Law

Pugliese

Shin

et al. 2019

Preprint

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Transient neocortical events with high spectral power in the 15-29Hz beta band are among the most reliable predictors of sensory perception: High prestimulus beta event rates in primary somatosensory lead to sensory suppression, most effective at 100-300ms prestimulus latency. However, the synaptic and neuronal mechanisms inducing beta's perceptual effects have not been completely localized. We combined human MEG with neural modeling designed to account for these macroscale signals to interpret the cellular and circuit mechanisms that underlie the influence of beta on tactile detection. Extending prior studies, we modeled the hypothesis that higher-order thalamic bursts, sufficient for beta event generation in cortex, recruit supragranular GABAB inhibition acting on a 300ms time scale to suppress sensory information. Consistency between model and MEG data supported this hypothesis and led to a further prediction, validated in our data, that stimuli are perceived when beta events occur simultaneously with tactile stimulation. The post-event suppressive mechanism explains an array of studies that associate beta with decreased processing, while the during-event mechanism may demand a reinterpretation of the role of beta events in the context of coincident timing. Significance statementSomatosensory beta events -transient 15-29Hz oscillations in electromagnetic recordings -are thought to be generated when "top-down" bursts of spikes presumably originating in higher-order thalamus arrive in upper layers of somatosensory cortex. Physiological evidence had shown that the immediate action of these top-down projections should be excitatory; however, after a beta event, sensory perception is noticeably inhibited for approximately 300ms. The source of this post-event sensory suppression, in particular, had been unresolved. Using a detailed computational model of somatosensory cortex, we find evidence for the hypothesis that these bursts couple indirectly to GABAB inhibition in upper layers of cortex, and that beta events first briefly disinhibit sensory relay before a longer period of inhibition. * Here, we use "event" rather than "burst" so as not to confuse events with their mechanistic generators, which we believe to be bursts in upstream sources. Our interpretation of events is as "sequences of bursts", viz. "bursts of bursts" where the length of the sequence can be as low as one.

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Section: Consistency Of the Current Findings With Prior Studies Of Sisupporting

confidence: 93%

A supragranular nexus for the effects of neocortical beta events on human tactile perception

Law

Pugliese

Shin

et al. 2019

Preprint

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“…At a general level, our data are also compatible with this hypothesis. However, the most prominent synergy observed to date showed L2/3 suppresses deep layer activity (Adesnik & Scanziani 2010, Pluta et al 2019, predicting opposite results of deep versus superficial manipulations. We find on the contrary that mice tend to classify textures as rough when either deep or superficial layers are inhibited.…”

Section: Both Deep and Superficial Layers Are Essential For Texture Dmentioning

confidence: 97%

“…L2/3 has a strongly suppressive effect on deep layer activity (Adesnik & Scanziani 2010, Pluta et al 2019. Conceivably, strong connections like these could produce local forms of diaschisis, whereby silencing one set of layers does not reveal its task involvement but rather that it disrupts another key set of layers.…”

Section: Deep and Superficial Layers Are Critical For Texture Discrimmentioning

confidence: 99%

Deep and superficial layers of the primary somatosensory cortex are critical for whisker-based texture discrimination in mice

Park

Hong

Rodgers

et al. 2020

Preprint

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SummaryThe neocortex, comprised of multiple distinct layers, processes sensory input from the periphery, makes decisions, and executes actions. Despite extensive investigation of cortical anatomy and physiology, the contributions of different cortical layers to sensory guided behaviors remain unknown. Here, we developed a two-alternative forced choice (2AFC) paradigm in which head-fixed mice use a single whisker to either discriminate textures of parametrically varied roughness or detect the same textured surfaces. Lesioning the barrel cortex revealed that 2AFC texture discrimination, but not detection, was cortex-dependent. Paralyzing the whisker pad had little effect on performance, demonstrating that passive can rival active perception and cortical dependence is not movement-related. Transgenic Cre lines were used to target inhibitory opsins to excitatory cortical neurons of specific layers for selective perturbations. Both deep and superficial layers were critical for texture discrimination. We conclude that even basic cortical computations require coordinated transformation of sensory information across layers.Abstract Figure

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“…The dynamic modulation of PN firing, induced by plasticity of feed-forward inhibition had a powerful effect on the columnar integration of activity across cortical layers. Indeed, activation of layer 2/3 PNs was shown to increase the firing of PNs in layer 5 of the same column (Adesnik and Scanziani, 2010; but see Pluta et al, 2019). LTP of feed-forward inhibition strongly diminished (in fact, on average, it abolished) the layer 2/3-dependent activation of layer 5 PNs, thereby affecting the flow of neuronal communication across cortical layers.…”

Section: Discussionmentioning

confidence: 96%

“…In principle, feed-forward inhibition can result from long-range recruitment of different interneuron subclasses (Pluta et al, 2019). Yet, potentiation of FFI likely involves perisomatic inhibition originating almost exclusively from PV basket cells.…”

Section: Discussionmentioning

confidence: 99%

Modulation of coordinated activity across cortical layers by plasticity of inhibitory synapses onto layer 5 pyramidal neurons

Lourenço¹,

Stasi²,

Deleuze³

et al. 2019

Preprint

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In the neocortex, synaptic inhibition shapes all forms of spontaneous and sensory-evoked activity. Importantly, inhibitory transmission is highly plastic, but the functional role of inhibitory synaptic plasticity is unknown. In the mouse barrel cortex, activation of layer 2/3 PNs elicited strong feed-forward perisomatic inhibition (FFI) onto layer 5 PNs. We found that FFI involving PV cells was strongly potentiated by postsynaptic PN burst firing. FFI plasticity modified PN excitation-to-inhibition (E/I) ratio, strongly modulated PN gain and altered information transfer across cortical layers. Moreover, our LTPi-inducing protocol modified the firing of layer 5 PNs and altered the temporal association of PN spikes to γ-oscillations both in vitro and in vivo. All these effects were captured by unbalancing the E/I ratio in a feed-forward inhibition circuit model. Altogether, our results indicate that activity-dependent modulation of perisomatic inhibitory strength effectively influences the participation of single principal cortical neurons to cognitive-relevant network activity. Impact Statement: Long-term potentiation of feed-forward perisomatic inhibition effectively alters the computational properties of single layer 5 pyramidal neurons and their association to network activity.

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Superficial Layers Suppress the Deep Layers to Fine-tune Cortical Coding

Cited by 39 publications

References 75 publications

A supragranular nexus for the effects of neocortical beta events on human tactile perception

A supragranular nexus for the effects of neocortical beta events on human tactile perception

Deep and superficial layers of the primary somatosensory cortex are critical for whisker-based texture discrimination in mice

Modulation of coordinated activity across cortical layers by plasticity of inhibitory synapses onto layer 5 pyramidal neurons

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