Light detected in the retina modulates several physiological processes including circadian photo-entrainment and pupillary light reflex. Intrinsically photosensitive retinal ganglion cells (ipRGCs) convey rod-cone and melanopsin-driven light input to the brain. Using EEGs and electromyograms, we show that acute light induces sleep in mice during their nocturnal active phase whereas acute dark awakens mice during their diurnal sleep phase. We used retinal mutant mouse lines that lack (i) the ipRGCs, (ii) the photo-transduction pathways of rods and cones, or (iii) the melanopsin protein and showed that the influence of light and dark on sleep requires both rod-cone and melanopsin signaling through ipRGCs and is independent of image formation. We further show that, although acute light pulses overcome circadian and homeostatic drives for sleep, upon repeated light exposures using a 3.5 h/3.5 h light/dark cycle, the circadian and homeostatic drives override the light input. Thus, in addition to their known role in aligning circadian physiology with day and night, ipRGCs also relay light and dark information from both rod-cone and melanopsin-based pathways to modulate sleep and wakefulness.
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机译:视网膜中检测到的光可调节多种生理过程,包括昼夜节律性光夹带和瞳孔光反射。本质上,光敏性视网膜神经节细胞(ipRGC)将视锥细胞和黑色素驱动的光输入到大脑。使用脑电图和肌电图,我们表明急性光诱导小鼠夜间活动阶段的睡眠,而急性黑暗则在昼夜睡眠阶段唤醒小鼠。我们使用了缺乏(i)ipRGC,(ii)视杆和视锥的光转导途径或(iii)黑色素蛋白的视网膜突变小鼠系,并表明光暗对睡眠的影响都需要视锥细胞。和黑视蛋白通过ipRGC发出信号,并且与图像形成无关。我们进一步表明,尽管急性光脉冲克服了昼夜节律和稳态驱动器的睡眠,但是在使用3.5 h / 3.5 h亮/暗循环重复曝光后,昼夜节律和稳态驱动器会覆盖光输入。因此,除了其在昼夜昼夜节律生理中的作用外,ipRGC还从基于视锥细胞和基于黑色素的途径中传递明暗信息,以调节睡眠和清醒状态。
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