Rod and cone photoreceptors detect light and relay this information through a multisynaptic pathway to the brain via retinal ganglion cells (RGCs) 1 . These retinal outputs support not only pattern vision, but also non-image forming (NIF) functions, which include circadian photoentrainment and pupillary light reflex (PLR). In mammals, NIF functions are mediated by rods, cones and the melanopsincontaining intrinsically photosensitive retinal ganglion cells (ipRGCs) 2, 3 . Rod/cone photoreceptors and ipRGCs are complementary in signalling light intensity for NIF functions 4-12 . The ipRGCs, in addition to being directly photosensitive, also receive synaptic input from rod/cone networks 13, 14 . To determine how the ipRGCs relay rod/cone light information for both image and non-image forming functions, we genetically ablated ipRGCs in mice. Here we show that animals lacking ipRGCs retain pattern vision, but have deficits in both PLR and circadian photoentrainment that are more extensive than those observed in melanopsin knockouts 8,10,11 . The defects in PLR and photoentrainment resemble those observed in animals that lack phototransduction in all three †To whom correspondence should be addressed.
SUMMARY Disorders of vascular structure and function play a central role in a wide variety of CNS diseases. Mutations in the Frizzled4 (Fz4) receptor, Lrp5 co-receptor, or Norrin ligand cause retinal hypovascularization, but the role of Norrin/Fz4/Lrp signaling in vascular development has not been defined. Using mouse genetic and cell culture models, we show that loss of Fz4 signaling in endothelial cells causes defective vascular growth, which leads to chronic but reversible silencing of retinal neurons. Loss of Fz4 in all endothelial cells disrupts the blood brain barrier in the cerebellum, while excessive Fz4 signaling disrupts embryonic angiogenesis. Sox17, a transcription factor that is up-regulated by Norrin/Fz4/Lrp signaling, plays a central role in inducing the angiogenic program controlled by Norrin/Fz4/Lrp. These experiments establish a cellular basis for retinal hypovascularization diseases due to insufficient Frizzled signaling, and they suggest a broader role for Frizzled signaling in vascular growth, remodeling, maintenance, and disease.
SUMMARY Transcriptional regulatory networks that control the morphologic and functional diversity of mammalian neurons are still largely undefined. Here we dissect the roles of the highly homologous POU-domain transcription factors Brn3a and Brn3b in retinal ganglion cell (RGC) development and function using conditional Brn3a and Brn3b alleles that permit the visualization of individual wild type or mutant cells. We show that Brn3a- and Brn3b-expressing RGCs exhibit overlapping but distinct dendritic stratifications and central projections. Deletion of Brn3a alters dendritic stratification and the ratio of monostratified: bistratified RGCs, with little or no change in central projections. In contrast, deletion of Brn3b leads to RGC transdifferentiation and loss, axon defects in the eye and brain, and defects in central projections that differentially compromise a variety of visually-driven behaviors. These findings reveal distinct roles for Brn3a and Brn3b in programming RGC diversity, and they illustrate the broad utility of germ-line methods for genetically manipulating and visualizing individual identified mammalian neurons.
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