Retinal pathways influence temporal niche

SE Doyle, T Yoshikawa, H Hillson… - Proceedings of the …, 2008 - National Acad Sciences
SE Doyle, T Yoshikawa, H Hillson, M Menaker
Proceedings of the National Academy of Sciences, 2008National Acad Sciences
In mammals, light input from the retina entrains central circadian oscillators located in the
suprachiasmatic nuclei (SCN). The phase of circadian activity rhythms with respect to the
external light: dark cycle is reversed in diurnal and nocturnal species, although the phase of
SCN rhythms relative to the light cycle remains unchanged. Neural mechanisms
downstream from the SCN are therefore believed to determine diurnality or nocturnality.
Here, we report a switch from nocturnal to diurnal entrainment of circadian activity rhythms in …
In mammals, light input from the retina entrains central circadian oscillators located in the suprachiasmatic nuclei (SCN). The phase of circadian activity rhythms with respect to the external light:dark cycle is reversed in diurnal and nocturnal species, although the phase of SCN rhythms relative to the light cycle remains unchanged. Neural mechanisms downstream from the SCN are therefore believed to determine diurnality or nocturnality. Here, we report a switch from nocturnal to diurnal entrainment of circadian activity rhythms in double-knockout mice lacking the inner-retinal photopigment melanopsin (OPN4) and RPE65, a key protein used in retinal chromophore recycling. These mice retained only a small amount of rod function. The change in entrainment phase of Rpe65−/−;Opn4−/− mice was accompanied by a reversal of the rhythm of clock gene expression in the SCN and a reversal in acute masking effects of both light and darkness on activity, suggesting that the nocturnal to diurnal switch is due to a change in the neural response to light upstream from the SCN. A switch from nocturnal to diurnal activity rhythms was also found in wild-type mice transferred from standard intensity light:dark cycles to light:dark cycles in which the intensity of the light phase was reduced to scotopic levels. These results reveal a novel mechanism by which changes in retinal input can mediate acute temporal-niche switching.
National Acad Sciences