Conversely, fewer neurons were labeled in the contralateral retin

Conversely, fewer neurons were labeled in the contralateral retina of mutants compared with wild-types ( Figure 5E). Loss of VEGF164 therefore increases the number of ipsilaterally projecting RGC axons at the expense of contralaterally projecting RGCs. Because VEGF164 signals through NRP1 in blood vessels and because NRP1 organizes blood vessels in the brain (Soker et al., 1998 and Gerhardt JQ1 in vitro et al., 2004), we asked if defective blood vessel pattering was responsible for impaired axon crossing at the optic chiasm in

Vegfa120/120 and Nrp1 null mutants by counting all retrogradely labeled RGCs in sections through the entire ipsilateral and contralateral eyes of embryos lacking NRP1 specifically PFI-2 molecular weight in blood vessels (Tie2Cre Nrp1fl/−; Gu et al., 2003). In contrast to the Vegfa120/120 mutants, the vessel-specific Nrp1 mutants contained a normal proportion of ipsilaterally

projecting RGCs (3.6% ± 1.0%, n = 5; Figure 5C). Moreover, the cell bodies of ipsilaterally projecting RGCs were distributed normally within the retina, with the vast majority being derived from the temporal retina (77.0% ± 4.8%, n = 5; Figure 5D). Because endothelial-specific Nrp1 null mutants display microphthalmia and vascular brain abnormalities similar to those of full Nrp1 null and Vegfa120/120 mutants ( Gu et al., 2003 and Fantin et al., 2010), reduced eye size or defective blood vessel Thymidine kinase patterning cannot explain the decreased midline crossing of RGC axons in the absence of VEGF164/NRP1 signaling. We conclude that VEGF164/NRP1 signaling promotes contralateral axon crossing at the chiasmatic midline independently of blood vessels. The expression pattern of VEGF-A in the diencephalon raised the possibility that it promotes the growth of NRP1-expressing RGC axons at the chiasmatic midline. To test this hypothesis, we explanted the peripheral

region of all four quadrants of E14.5 retinas (Figure 6A) and assayed the response of RGC axons to recombinant VEGF-A on collagen or laminin (Figures 6B, 6C, S4A, and S4B). On both substrates, VEGF164 significantly increased outgrowth in a dose-dependent manner from the retinal regions that give rise to contralaterally projecting RGCs (dorsotemporal, ventronasal, dorsonasal; Figures 6B, 6C, S4A, and S4B). In contrast, outgrowth from the ventrotemporal retina, the origin of ipsilaterally projecting RGCs, was not altered significantly (Figures 6C and S4B). Addition of VEGF120 did not promote axon outgrowth from any retinal region (Figures 6B, 6C, S4A, and S4B). Consistent with the failure to respond to VEGF164, Nrp1 was not expressed at detectable levels in the Zic2-positive ventrotemporal crescent that gives rise to ipsilateral RGCs; in contrast, Nrp1 was expressed in RGCs outside the Zic2 domain ( Figure 6D).

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