Somatostatin neuron contributions to cortical slow wave dysfunction in adult mice exposed to developmental ethanol

IntroductionTransitions between sleep and waking and sleep-dependent cortical oscillations are heavily dependent on GABAergic neurons. Importantly, GABAergic neurons are especially sensitive to developmental ethanol exposure, suggesting a potential unique vulnerability of sleep circuits to early ethanol. In fact, developmental ethanol exposure can produce long-lasting impairments in sleep, including increased sleep fragmentation and decreased delta wave amplitude. Here, we assessed the efficacy of optogenetic manipulations of somatostatin (SST) GABAergic neurons in the neocortex of adult mice exposed to saline or ethanol on P7, to modulate cortical slow-wave physiology. MethodsSST-cre x Ai32 mice, which selectively express channel rhodopsin in SST neurons, were exposed to ethanol or saline on P7. This line expressed similar developmental ethanol induced loss of SST cortical neurons and sleep impairments as C57BL/6By mice. As adults, optical fibers were implanted targeting the prefrontal cortex (PFC) and telemetry electrodes were implanted in the neocortex to monitor slow-wave activity and sleep-wake states. ResultsOptical stimulation of PFC SST neurons evoked slow-wave potentials and long-latency single-unit excitation in saline treated mice but not in ethanol mice. Closed-loop optogenetic stimulation of PFC SST neuron activation on spontaneous slow-waves enhanced cortical delta oscillations, and this manipulation was more effective in saline mice than P7 ethanol mice. DiscussionTogether, these results suggest that SST cortical neurons may contribute to slow-wave impairment after developmental ethanol.

Automated summary

This study aimed to investigate the effects of optogenetic manipulation on the neocortex of adult mice after early ethanol exposure. The results showed that in mice exposed to ethanol, optical stimulation of prefrontal cortex SST neurons failed to evoke slow-wave potentials and long-latency single-unit excitation, while this effect was observed in saline-treated mice. These findings suggest that SST neurons may contribute to slow-wave sleep impairment after developmental ethanol exposure.