Yoon BC , Zivraj KH , Strochlic L , Holt CE .

085314 Wellcome Trust , Wellcome Trust , WT085314 Wellcome Trust

Xla Wt + Difopein (fig.5.a)

	Figure 1 Localization of 14-3-3ς mRNA in retinal axons and growth cones. (A) RT-PCR of mRNAs purified from heads and eyes of various stages. RT only control was performed to rule out genomic contaminations. (B) Representative images of FISH with either anti-sense or sense probes (scale bar = 5 μm) (R1). (C) Quantification of FISH mean intensity per unit area (n = no. of growth cones; **** = p<0.0001; Mann–Whitney). (D) In situ hybridization of stage 40 embryo sections (ONH = optic nerve head, LS = lens, RGC = retinal ganglion cells, IPL = inner plexiform layer, OPL = outer plexiform layer, OT = optic tectum; scale bars = 25 μm for left panel and 100 μm for the middle panel).
	Figure 2 14-3-3/14-3-3ς proteins are expressed in retinal growth cones. (A) Western blot of head or eye lysates using 14-3-3 or 14-3-3ς antibodies. The 14-3-3ς antibody recognizes both the unphosphorylated and the phosphorylated form of 14-3-3ς at a predicted molecular weight of * 29 kD (R1), which is more apparently visualized at low exposures (inset). (B) Immunofluorescence staining of retinal growth cones using 14-3-3 or 14-3-3ς antibodies. The area marked by square shows localization of 14-3-3ς within filopodia. A magnified view of the squared area is shown in the inset (scale bar = 5 μm).
	Figure 3 The level of 14-3-3ς in growth cones decreases with age. (A) Representative 14-3-3ς IF staining in growth cones cultured for 8, 24, and 48 h (scale bars = 5 μm). (B) Quantitation of mean 14-3-3ς IF intensity/unit area in growth cones cultured 8, 24, 48 h (n = no. of growth cones; three replicates; ** = p<0.01; one-way ANOVA with Bonferroni post-test).
	Figure 4 Inhibition of 14-3-3/14-3-3ς shortens retinal axon projection in vivo. (A) Schematics of R18 and R18K constructs tagged with YFP. (B) Schematics of eye electroporation. FITC-tagged morpholinos are electroporated into the eye at stage 26. (C) Dissected brains from stage 40 embryos that have been electroporated with either R18-YFP or R18K-YFP. The arrowhead indicates markedly shorter axons found in R18-YFP transfected brains (dashed line = anterior tectal border; scale bar = 50 μm; CH = optic chiasm; TEL = telencephalon; OT = optic tectum). (D) The length of the pathway was measured in two ways: (1) following the curvature of the pathway (a) and (2) measuring the shortest distance from the optic chiasm to the longest axon (LA; b) divided by the shortest distance from the chiasm to the posterior tectum (PT; c). (E) Measurement of the pathway length (equivalent to \a" in Fig. 4D). (F) Measurement of CH to LA length/CH to PT length (equivalent to \b/c" in Fig 4.4). (G) Measurement of CH to PT length to rule out significant differences in brain size. (Note: in E, F, and G, n = number of brains analyzed; three replicates; **p<0.01; ***p<0.001; unpaired t-test).
	Figure 5 Shortened retinal projection due to retarded axon elongation rate. (A) Brains of stage 43 embryos that have been eye-electroporated with R18-YFP or R18K-YFP (R1). Axons reach the tectum even in those that were electroporated with R18-YFP. The rightmost panel represents the magnified view of the R18 pathway with an axon taking an unusually tortuous path (arrowhead; dashed line = anterior tectal border; scale bar = 50 μm). (B) Measurement of the pathway length. (C) Distance from CH-LA/CH-PT. (D) Distance from CH-PT (For B, C, D, n = no. of brains analyzed; unpaired t-test). (E) Whole eye culture of eyes that have been electroporated with R18-YFP or R18K-YFP (scale bar = 50 μm). (F) The elongation rate of axons transfected with R18-YFP or R18K-YFP (n = no. of growth cones; *p<0.05; Mann–Whitney).
	Figure 6 Colocalization of 14-3-3ς with pXAC and XAC. (A) Growth cone staining with Alexa 488-conjugated pXAC antibody and Alexa 594-conjugated 14-3-3ς antibody. The squared area shows colocalization in a filopodium. The inset shows more magnified view of the squared area (scale bar = 5 μm; image intensity adjusted). (B) Growth cone staining with Alexa 488-conjugated XAC antibody and Alexa 594-conjugated 14-3-3ς antibody. (C) Growth cone staining with Alexa 488 and Alexa 594 fluorophores without antibody conjugation. (D) Measurement of Pearson coefficient for determination of colocalization (n = no. of growth cones;***p<0.001; statistical analysis by Kruskal–Wallis test with Dunn post-test). (R1)
	Figure 7 14-3-3/14-3-3ς knockdown decreases phospho-XAC in retinal growth cones. (A, B) QIF analysis of pXAC (A) and XAC (B) in growth cones transfected with either R18K- or R18-YFP (n = no. of growth cones; four replicates; *p<0.05; Mann–Whitney). (C) Western blot of eye lysates showing 14-3-3ς knockdown with the antisense morpholino. a-Tubulin was used as a loading control. (D) QIF analysis of 14-3-3ς in growth cones injected with either control or 14-3-3ς morpholino (*** p<0.001; n = no. of growth cones; three replicates; unpaired t-test). (E, F) QIF analysis of pXAC (E) and XAC (F) in growth cones injected with control or 14-3-3ς morpholino (n = no of growth cones; *** p<0.001; three replicates; unpaired t-test).
	Figure 8 14-3-3/14-3-3ς inhibition sensitizes growth cones to Slit1-induced collapse. (A) R18K transfected growth cones stimulated with either control or Slit2 CM at sub-threshold concentration (scale bar = 5 μm). (B) R18-YFP transfected growth cones stimulated with either control or Slit2 CM at sub-threshold concentration. (C) Collapse rate of R18K- or difopein-transfected growth cones stimulated with either control or Slit2 CM at sub-threshold concentration (n = number of growth cones; three replicates; * = p<0.05; one-way ANOVA with Bonferroni post-test).

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