The acute sleep-inducing effects of light require histamine neurotransmission in mice

Sleep regulation depends on the complex interplay between homeostatic and circadian processes synchronized by the light/dark cycle. Sleep is also directly regulated by light via the retinal inputs to the preoptic area (POA). Although the light-responsive POA neurons project to several wake-promoting structures, including histaminergic neurons in the tuberomammillary nucleus (TMn), there is no functional evidence for their involvement in light-induced sleep. To bridge this gap, we used histidine decarboxylase (HDC, the histamine-synthetizing enzyme) knockout mice (HDC−/−, n=7) and hM4Di-HDC-cre mice (HDC+/+, n=8) subjected to an ultradian light/dark protocol (LD 1h:1h over 24h), and another group of hM4Di-HDC-cre mice (n=8) exposed to a 1-h light pulse. We found that light pulses during the biological night enhanced slow wave sleep and increased cortical EEG power in the delta range (0.5-3Hz), and that these effects were significantly attenuated both in HDC−/− (83 vs 23 min/6h, p=0.005) under LD 1h:1h condition and in hM4Di-HDC-cre mice after acute chemogenetic silencing of histamine neurons by the DREADD ligand deschloroclozapine (15 vs 6 min/h, p=0.0016) under a 1-h light pulse. In addition, the sleep-inducing effect of light was circadian dependent, with the strongest effect at the beginning and end of the night but no effect at all during the biological day in HDC+/+mice. Our study provides functional evidence that the acute sleep-inducing effects of light on sleep require histamine neurotransmission in mice.