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Ketamine disinhibits dendrites and enhances calcium signals in prefrontal dendritic spines

Farhan Ali, Danielle M. Gerhard, Katherine Sweasy, Santosh Pothula, C. Pittenger, R. Duman, A. Kwan

Nature Communications June 3, 2019 DOI: 10.1038/s41467-019-13809-8 via Semantic Scholar

Summary

A subanesthetic dose of ketamine suppresses somatostatin-expressing (SST) interneurons in the medial prefrontal cortex of awake mice, leading to deficient dendritic inhibition. This causes greater synaptically evoked calcium transients in the apical dendritic spines of pyramidal neurons. By manipulating NMDAR signaling via GluN2B knockdown, the authors show that this dendritic inhibitory mechanism affects frontal cortex-dependent behaviors and cortico-cortical connectivity. The results demonstrate dendritic disinhibition and elevated calcium levels in dendritic spines as key local-circuit alterations driven by subanesthetic ketamine.

Study at a glance

Characteristics Experimental study Peer reviewed
Population Awake mice
Keywords Chemistry Medicine Biology
Citations 201
Key finding Ketamine suppresses SST interneurons in the medial prefrontal cortex, causing dendritic disinhibition and elevated calcium signals in apical dendritic spines of pyramidal neurons.

Abstract

A subanesthetic dose of ketamine causes acute psychotomimetic symptoms and sustained antidepressant effects. In prefrontal cortex, the prevailing disinhibition hypothesis posits that N-methyl-d-aspartate receptor (NMDAR) antagonists such as ketamine act preferentially on GABAergic neurons. However, cortical interneurons are heterogeneous. In particular, somatostatin-expressing (SST) interneurons selectively inhibit dendrites and regulate synaptic inputs, yet their response to systemic NMDAR antagonism is unknown. Here, we report that ketamine acutely suppresses the activity of SST interneurons in the medial prefrontal cortex of the awake mouse. The deficient dendritic inhibition leads to greater synaptically evoked calcium transients in the apical dendritic spines of pyramidal neurons. By manipulating NMDAR signaling via GluN2B knockdown, we show that ketamine’s actions on the dendritic inhibitory mechanism has ramifications for frontal cortex-dependent behaviors and cortico-cortical connectivity. Collectively, these results demonstrate dendritic disinhibition and elevated calcium levels in dendritic spines as important local-circuit alterations driven by the administration of subanesthetic ketamine. The authors show that a subanesthetic dose of ketamine markedly elevate calcium signals in apical dendritic spines in the mouse prefrontal cortex. This effect is driven by a local-circuit mechanism that involves the suppression of somatostatin interneurons leading to dendritic disinhibition.

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