Nonvisual Light Responses in the Rpe65 Knockout Mouse: Rod Loss Restores Sensitivity to the Melanopsin System

Intrinsically photosensitive retinal ganglion cells (ipRGCs) expressing the photopigment melanopsin (OPN4), together with rods and cones, provide light information driving nonvisual light responses. We examined nonvisual photoreception in mice lacking RPE65, a protein that is required for regeneration of visual chromophore in rods and cones. Although Rpe65 knockouts retain a small degree of rod function, we show here that circadian phase shifting responses in$Rpe65^{-/-}$mice are attenuated far beyond what has been reported for rodless/coneless mice. Furthermore, the number of melanopsin-immunoreactive perikarya and the extent of dendritic arborizations were decreased in Rpe65 knockout mice compared with controls. To assess the nature of the photoreceptive defect in Rpe65 null mice, we eliminated either rods or melanopsin from$Rpe65^{-/-}$retinas by generating (i)$Rpe65^{-/-}$mice carrying a transgene (rdta) that results in selective elimination of rods and (ii) double knockout$Rpe65^{-/-}$;$Opn4^{-/-}$mice. Surprisingly, rod loss in Rpe65 knockout mice resulted in restoration of circadian photosensitivity. Normal photoentrainment was lost in$Rpe65^{-/-}$;$Opn4^{-/-}$mice, and, instead, a diurnal phenotype was observed. Our findings demonstrate that RPE65 is not required for ipRGC function but reveal the existence of a mechanism whereby rods may influence the function of ipRGCs.