Oscillatory population-level activity of dorsal raphe serotonergic neurons sculpts sleep structure

Dorsal raphe (DR) 5-HT neurons are involved in regulating sleep-wake transitions. Previous studies demonstrated that single-unit activity of DR 5-HT neurons is high during wakefulness, decreases during non–rapid eye movement (NREM) sleep, and ceases during rapid eye movement (REM) sleep. However, characteristics of the population-level activity of DR 5-HT neurons, which can influence the entire brain, are largely unknown. Here we measured population activities of 5-HT neurons in male and female mouse DR across the sleep-wake cycle by a ratiometric fiber photometry system. We found a slow oscillatory activity of compound intracellular Ca2+ signals during NREM sleep. The trough of concave 5-HT activity increased along with sleep progression, but the 5-HT activity level always returned to that seen in wake periods. When the trough reached the minimum level and remained there, REM sleep initiated. We also found a unique coupling of the oscillatory 5-HT activity and EEG power fluctuation, suggesting that EEG fluctuation is a proxy for 5-HT activity. Optogenetic activation of 5-HT neurons during NREM sleep triggered a high EMG power and induced wakefulness. Optogenetic inhibition induced REM sleep or sustained NREM with an EEG power increase and EEG fluctuation. These manipulations demonstrated a causal role of DR 5-HT neurons in sculpting sleep-wake structure. We also observed EEG fluctuations in human males during NREM sleep, implicating the existence of 5- HT oscillatory activity in humans. We propose that NREM sleep is not a monotonous state, but that it is dynamically regulated by the oscillatory population activity of DR 5- HT neurons. Significant statement Previous studies have demonstrated single-cell 5-HT neuronal activity across sleep- wake conditions; however, population-level activities of these neurons are largely unknown. We monitored dorsal raphe (DR) 5-HT population activity using a fiber photometry system in mice and demonstrated that activity was highest during wakefulness, and lowest during rapid eye movement (REM) sleep. Surprisingly, during non-REM (NREM) sleep, the 5-HT population activity decreased with an oscillatory pattern, coinciding with EEG fluctuations. We examined the causal role of these 5-HT neuron activities by optogenetics and found that DR 5-HT neurons sculpted sleep-wake conditions by influencing EEG and EMG patterns. We found similar EEG fluctuations in a human sleep EEG study, suggesting the presence of oscillatory 5-HT neuron activity during NREM across species. ### Competing Interest Statement The authors have declared no competing interest.