Understanding the neural mechanisms underlying sleep state transitions is a fundamental goal of neurobiology and important for the development of new treatments for insomnia and other sleep disorders. Yet, brain circuits controlling this process remain poorly understood. Here we identify a population of sleep-active glutamatergic neurons in the ventrolateral medulla (VLM) that project to the preoptic area (POA), a prominent sleep-promoting region, in mice. Microendoscopic calcium imaging demonstrate that these VLM glutamatergic neurons display increased activity during the transitions from wakefulness to Non-Rapid Eye Movement (NREM) sleep. Chemogenetic silencing of POA-projecting VLM neurons suppresses NREM sleep, whereas chemogenetic activation of these neurons promotes NREM sleep. Moreover, we show that optogenetic activation of VLM glutamatergic neurons or their projections in the POA initiates NREM sleep in awake mice. Together, our findings uncover an excitatory brainstem-hypothalamic circuit that controls the wake-sleep transitions.
The importance of sleep in memory consolidation is well-established, with the hippocampal CA1 and CA3 subregions playing a crucial role in this process. The current working hypothesis postulates that episodic memory traces captured during waking hours are replayed in the hippocampal CA1-CA3 areas and transferred to the cortex for long-term storage during sleep. While the entorhinal cortex provides sensory and spatial information primarily to the hippocampus via the dentate gyrus (DG), the DG has traditionally been regarded as a "silent partner" in memory consolidation. The transfer of captured memory traces from the DG to downstream hippocampal areas remains largely unknown. To investigate this, we used optical imaging tools to record neural activity in the DG during different sleep stages. Strikingly, we found that many of the DG cells are even more active during sleep than wakefulness and the populational activity in the DG slowly oscillates during non-REM (NREM) sleep. The cycles of this oscillatory activity coincided with microarousals and were tightly locked to brief serotonin (5-HT) bursts during NREM sleep. Pharmacological blockade of 5-HT1a receptors abolished the calcium oscillations in the DG. Furthermore, the genetic knockdown of 5-HT1a receptors in the DG lead to memory impairment in spatial and contextual memory tasks. Together, our findings suggest that serotonin-driven infraslow calcium oscillations in the DG during NREM sleep are necessary for memory consolidation.
Sleep is a ubiquitous behavior in animal species. Yet, brain circuits controlling sleep remain poorly understood. Previous studies have identified several brain structures that promote sleep, but whether these structures are involved in sleep initiation or sleep maintenance remains largely unknown. Here we identified a population of glutamatergic neurons in the medulla that project to the preoptic area (POA), a prominent sleep-promoting region. Chemogenetic silencing of POA-projecting medulla neurons disrupts the transitions from wakefulness to Non-Rapid Eye Movement (NREM) sleep, whereas chemogenetic activation of these neurons promotes NREM sleep. Moreover, we show that optogenetic activation of medulla glutamatergic neurons or their projections in the POA reliably initiates long-lasting NREM sleep in awake mice. Together, our findings uncover a novel excitatory brainstem-hypothalamic circuit that controls the wake-sleep transitions.
Absence seizures, a type of non-convulsive epilepsy manifested by spike-wave discharges (SWD) in the electroencephalogram (EEG), display synchronous reciprocal excitation between the neocortex and thalamus. Recent studies have revealed that inhibitory neurons in the reticular thalamic (RT) nucleus and excitatory thalamocortical (TC) neurons are two key subcortical players in generating SWD. However, the signals that drive SWD-related thalamic activity remain elusive. Here, we show that SWD predominately occurs during wakefulness in several mouse models of absence epilepsy. In more focused studies of Gnb1 mutant mice, we found that sensory input regulates SWD. Using in vivo recording, we demonstrate that TC cells are activated prior to the onset of SWD and then inhibited during SWD. On the contrary, RT cells are slightly inhibited prior to SWD, but are strongly activated during SWD. Furthermore, chemogenetic activation of TC cells leads to the enhancement of SWD in Gnb1 mice. Together, our results indicate that sensory input in the periphery can regulate SWD by activating the thalamocortical pathway.
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