The mammalian retina contains an endogenous circadian pacemaker that broadly regulates retinal physiology and function, yet the cellular origin and organization of the mammalian retinal circadian clock remains unclear. Circadian clock neurons generate daily rhythms via cell-autonomous autoregulatory clock gene networks, and, thus, to localize circadian clock neurons within the mammalian retina, we have studied the cell type-specific expression of six core circadian clock genes in individual, identified mouse retinal neurons, as well as characterized the clock gene expression rhythms in photoreceptor degenerate rd mouse retinas. Individual photoreceptors, horizontal, bipolar, dopaminergic (DA) amacrines, catecholaminergic (CA) amacrines, and ganglion neurons were identified either by morphology or by a tyrosine hydroxylase (TH) promoter-driven red fluorescent protein (RFP) fluorescent reporter. Cells were collected, and their transcriptomes were subjected to multiplex single-cell RT-PCR for the core clock genes Period (Per) 1 and 2, Cryptochrome (Cry) 1 and 2, Clock, and Bmal1. Individual horizontal, bipolar, DA, CA, and ganglion neurons, but not photoreceptors, were found to coordinately express all six core clock genes, with the lowest proportion of putative clock cells in photoreceptors (0%) and the highest proportion in DA neurons (30%). In addition, clock gene rhythms were found to persist for >25 days in isolated, cultured rd mouse retinas in which photoreceptors had degenerated. Our results indicate that multiple types of retinal neurons are potential circadian clock neurons that express key elements of the circadian autoregulatory gene network and that the inner nuclear and ganglion cell layers of the mammalian retina contain functionally autonomous circadian clocks.circadian clock ͉ clock gene ͉ mouse retina ͉ photoreceptor ͉ real-time PCR T he mammalian retinal circadian clock exerts extensive control over retinal physiology and function, regulating a wide variety of retinal circadian rhythms, including rod disk shedding (1-3), melatonin release (4-6), dopamine synthesis (7, 8), electroretinogram (ERG) b-wave amplitude (9), extracellular pH (10), visual sensitivity (11, 12), and intraocular pressure (13,14). The retinal circadian clock and its dopamine-and melatonin-signaling molecules also influence pathological processes in the eye, including the susceptibility of photoreceptors to degeneration from light damage (15, 16), photoreceptor survival in animal models of retinal degeneration (17), and the degree of refractive errors in primate models of myopia (18). Despite its widespread influence, the cellular origin and organization of the circadian clock in the mammalian retina remain unclear.Neural circadian clocks generate endogenous circadian rhythms through cell-autonomous autoregulatory transcriptiontranslation feedback loops comprised of a defined set of ''clock genes'' in subsets of circadian pacemaker neurons. Gene targeting has demonstrated that, in mammals, the genes Period (Per) 1 and 2 and Cr...
Melanopsin-expressing intrinsically photosensitive retinal ganglion cells (ipRGCs
The canonical flow of visual signals proceeds from outer to inner retina (photoreceptors→bipolar cells→ganglion cells). However, melanopsin-expressing ganglion cells are photosensitive and functional sustained light signaling to retinal dopaminergic interneurons persists in the absence of rods and cones. Here we show that the sustained-type light response of retinal dopamine neurons requires melanopsin and that the response is mediated by AMPA-type glutamate receptors, defining a retrograde retinal visual signaling pathway that fully reverses the usual flow of light signals in retinal circuits.
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