Gordon L, Mansh M, Kinsman H, Morris AR.

K01 NS052551 NINDS NIH HHS

	Figure 1. Xshh expression in the developing brain. A–C: Lateral views of Xshh mRNA expression (blue) in stage 32, 34, and 38 embryonic brains, respectively. D:Xshh is found at the level of the midbrain in a transverse section of a stage 38 Xenopus embryo. Dotted red line denotes the presumptive location of the optic tract. E: A ventral view of HRP-labeled retinal axons (brown), along with Xshh expression (blue) in a stage 38 brain, at the optic chiasm. F: A lateral view of the same co-labeled brain, along the optic tract, with the white arrow at RGC axons, midway across the diencephalon. Unless otherwise noted, in all appropriate figures, dorsal is to the top. fp, floor plate; no, notochord; nt, neural tube; oc, optic chiasm; ot, optic tectum. Scale bar in D = 100 μm, and in F = 40 μm.
	Figure 2. XPtc1 and XSmo co-receptor expression in RGCs. Ptc1 and Smo expression is observed in the RGC layer and the retinal pigment epithelium (RPE) of sectioned retinas from stage 39 embryos (A, B, respectively) as compared to a negative control (C). D, E: Individual cultured RGCs are identified by neurofilament associated antigen (NAA) immunoreactivity. These retinal cells are also shown to express both Ptc1 (G) and Smo (H). F, I: No appreciable staining is detected in negative controls. rgcl: retinal ganglion cell layer; rpe, retinal pigment epithelium. Scale bar in D = 10 μm.
	Figure 3. Abnormal RGC axon extension after Shh disruption. Changes in the width of retinal projections at the ventral optic tract in an untreated embryo (A) and a cyclopamine-treated sample (B) are shown. C: Cyclopamine treatment also causes defasiculation of retinal axons. D: The transverse section of a control sample reveals normal RGC axonal projections (arrows) just below the lateral surface neuroepidermis. E: After cyclopamine treatment, RGC axons project inwards (arrows). F: A lateral view of a control sample shows normal RGC axon extension along the entire optic tract. G: After cyclopamine treatment, there is spreading of retinal axons at the tectum. A closer view of the tectum in an untreated control (H) versus a cyclopamine-treated embryo (I) shows abnormal targeting (arrows). The tectal boundary is outlined by the dotted white lines in H and I. Scale bar in H = 10 μm.

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