Cortical gamma band synchronization through somatostatin interneurons

Veit, Julia; Hakim, Richard; Jadi, Monika P.; Sejnowski, Terrence J.; Adesnik, Hillel

doi:10.1038/nn.4562

Cited by 320 publications

(433 citation statements)

References 65 publications

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“…Control trials were interleaved with trials in which the cortex was illuminated with an optic fiber coupled to a red LED. Under identical experimental conditions, extracellular recording from SOM cells revealed a 67±8% decrease in SOM firing for the largest stimulus size (Veit et al, 2017). Consistent with the reduced surround suppression observed during their inactivation (~30% decrease for ~57% suppression of SOM firing) (Adesnik et al, 2012), optogenetic suppression of SOM cells substantially increased both visually evoked E and I (E: p < 0.0005, I: p < 0.005, two-way-ANOVA, n = 8, Figure 8B,C), but did not eliminate the size-dependent decrement in the E/I ratio (p > 0.05, two-way-ANOVA, Fig.…”

Section: Resultsmentioning

confidence: 96%

“…Superficially, the increase in I seems paradoxical, as the direct inhibition from SOM cells should be reduced. However, this paradoxical effect is precisely a core prediction of the ISN regime (Litwin-Kumar et al, 2016; Rubin et al, 2015; Tsodyks et al, 1997); when SOM cells are suppressed, PV cells firing rates substantially increase (Veit et al, 2017). In the ISN model, the increased activity of PV cells is a result of increased drive from L2/3 excitatory neurons (which are net disinhibited).…”

Section: Discussionmentioning

confidence: 99%

“…The increased activity of PV neurons drives net increases in inhibitory currents in excitatory neurons. A second explanation for the increase in I that does not invoke ISN dynamics is that SOM cells directly inhibit PV neurons (Pfeffer et al, 2013), and thus suppressing SOM cells should result in increased somatic inhibition in pyramidal cells since PV neurons are themselves disinhibited (Veit et al, 2017). The data presented here are similar to what has been recently found for sound frequency tuning in the awake auditory cortex (Kato et al, 2017), implying these might be general mechanisms for feature coding across sensory cortex.…”

Section: Discussionmentioning

confidence: 99%

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Synaptic Mechanisms of Feature Coding in the Visual Cortex of Awake Mice

Adesnik

2017

Neuron

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102

135

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Summary The synaptic mechanisms of feature coding in the visual cortex are poorly understood, particularly in awake animals. The ratio between excitation (E) and inhibition (I) might be constant across stimulus space, controlling only the gain and timing of neuronal responses, or it might change, directly contributing to feature coding. Whole-cell recordings in L2/3 of awake mice revealed that the E/I ratio systematically declines with increasing stimulus contrast or size. Suppressing somatostatin neurons enhanced the E and I underlying size tuning, explaining SOM neurons’ role in surround suppression. These data imply that contrast and size tuning result from a combination of a changing E/I ratio and the tuning of total synaptic input. Furthermore, they provide experimental support in awake animals for the ‘Stabilized Supralinear Network’, a model that explains diverse cortical phenomena, and suggest that a decreasing E/I ratio with increasing cortical drive could contribute to many different cortical computations.

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Section: Resultsmentioning

confidence: 96%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Synaptic Mechanisms of Feature Coding in the Visual Cortex of Awake Mice

Adesnik

2017

Neuron

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102

135

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“…; Veit et al . ), we hypothesized that GAERS could present a layer‐specific increase of interneurons density, especially of PV+ or SOM+ cells. Recent studies indicated modifications of GABAergic interneurons densities in models of genetic epilepsy that further support our hypothesis (Wimmer et al .…”

Section: Resultsmentioning

confidence: 99%

“…; Buzsáki & Wang, ; Veit et al . ), an increased number of these interneurons could explain the augmented gamma power in GAERS that not only favours SWDs, but also may alter sensory coding. A recent study showed no difference in terms of GABA+ interneurons in the S1Bf of GAERS (Bombardi et al .…”

Section: Discussionmentioning

confidence: 99%

Sensory coding is impaired in rat absence epilepsy

Studer

Laghouati

Jarre

et al. 2019

The Journal of Physiology

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Key points Absence epilepsy is characterized by the occurrence of spike‐and‐wave discharges concomitant with an alteration of consciousness and is associated with cognitive comorbidities. In a genetic model of absence epilepsy in the rat, the genetic absence epilepsy rat from Strasbourg (GAERS), spike‐and‐wave discharges are shown to be initiated in the barrel field primary somatosensory cortex that codes whisker‐related information, therefore playing an essential role in the interactions of rodents with their environment. Sensory‐information processing is impaired in the epileptic barrel field primary somatosensory cortex of GAERS, with a delayed sensory‐evoked potential and a duplicated neuronal response to whisker stimulation in in vivo extracellular recordings. Yet, GAERS present no defaults of performance in a texture discrimination task, suggesting the existence of a compensatory mechanism within the epileptic neuronal network. The results of the present study indicate that physiological primary functions are processed differently in an epileptic cortical network. Abstract Several neurodevelopmental pathologies are associated with disorganized cortical circuits that may alter primary functions such as sensory processes. In the present study, we investigated whether the function of a cortical area is altered in the seizure onset zone of absence epilepsy, a prototypical form of childhood genetic epilepsy associated with cognitive impairments. We first combined in vivo multichannel electrophysiological recordings and histology to precisely localize the seizure onset zone in the genetic absence epilepsy rat from Strasbourg (GAERS). We then investigated the functionality of this epileptic zone using extracellular silicon probe recordings of sensory‐evoked local field potentials and multi‐unit activity, as well as a behavioural test of texture discrimination. We show that seizures in this model are initiated in the barrel field part of the primary somatosensory cortex and are associated with high‐frequency oscillations. In this cortex, we found an increased density of parvalbumin‐expressing interneurons in layer 5 in GAERS compared to non‐epileptic Wistar rats. Its functional investigation revealed that sensory abilities of GAERS are not affected in a texture‐discrimination task, whereas the intracortical processing of sensory‐evoked information is delayed and duplicated. Altogether, these results suggest that absence seizures are associated with an increase of parvalbumin‐inhibitory neurons, which may promote the functional relationship between epileptic oscillations and high‐frequency activities. Our findings suggest that cortical circuits operate differently in the epileptic onset zone and may adapt to maintain their ability to process highly specialized information.

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Association of Magnetoencephalographically Measured High-Frequency Oscillations in Visual Cortex With Circuit Dysfunctions in Local and Large-scale Networks During Emerging Psychosis

et al. 2020

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IMPORTANCE Psychotic disorders are characterized by impairments in neural oscillations, but the nature of the deficit, the trajectory across illness stages, and functional relevance remain unclear. OBJECTIVES To examine whether changes in spectral power, phase locking, and functional connectivity in visual cortex are present during emerging psychosis and whether these abnormalities are associated with clinical outcomes. DESIGN, SETTING, AND PARTICIPANTS In this cross-sectional study, participants meeting clinical high-risk criteria for psychosis, participants with first-episode psychosis, participants with affective disorders and substance abuse, and a group of control participants were recruited. Participants underwent measurements with magnetoencephalography and magnetic resonance imaging. Data analysis was carried out between 2018 and 2019. MAIN OUTCOMES AND MEASURES Magnetoencephalographical activity was examined in the 1to 90-Hz frequency range in combination with source reconstruction during a visual grating task. Event-related fields, power modulation, intertrial phase consistency, and connectivity measures in visual and frontal cortices were associated with neuropsychological scores, psychosocial functioning, and clinical symptoms as well as persistence of subthreshold psychotic symptoms at 12 months. RESULTS The study participants included those meeting clinical high-risk criteria for psychosis (n = 119; mean [SD] age, 22 [4.4] years; 32 men), 26 patients with first-episode psychosis (mean [SD] age, 24 [4.2] years; 16 men), 38 participants with affective disorders and substance abuse (mean [SD] age, 23 [4.7] years; 11 men), and 49 control participants (mean age [SD], 23 [3.6] years; 16 men). Clinical high-risk participants and patients with first-episode psychosis were characterized by reduced phase consistency of β/γ-band oscillations in visual cortex (d = 0.63/d = 0.93). Moreover, the first-episode psychosis group was also characterized by reduced occipital γ-band power (d = 1.14) and altered visual cortex connectivity (d = 0.74-0.84). Impaired fronto-occipital connectivity was present in both clinical high-risk participants (d = 0.54) and patients with first-episode psychosis (d = 0.84). Importantly, reductions in intertrial phase coherence predicted persistence of subthreshold psychosis in clinical high-risk participants (receiver operating characteristic area under curve = 0.728; 95% CI, 0.612-0.841; P = .001). CONCLUSIONS AND RELEVANCE High-frequency oscillations are impaired in the visual cortex during emerging psychosis and may be linked to behavioral and clinical impairments. Impaired phase consistency of γ-band oscillations was also associated with the persistence of subthreshold psychosis, suggesting that magnetoencephalographical measured neural oscillations could constitute a biomarker for clinical staging of emerging psychosis.

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Cortical gamma band synchronization through somatostatin interneurons

Cited by 320 publications

References 65 publications

Synaptic Mechanisms of Feature Coding in the Visual Cortex of Awake Mice

Synaptic Mechanisms of Feature Coding in the Visual Cortex of Awake Mice

Sensory coding is impaired in rat absence epilepsy

Association of Magnetoencephalographically Measured High-Frequency Oscillations in Visual Cortex With Circuit Dysfunctions in Local and Large-scale Networks During Emerging Psychosis

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