, 2008). Based on its expression in dI1 commissural neurons and in the floorplate (Figures 1A and 1B), GPC1 was a good candidate as a regulator of Shh activity. Of the six GPCs expressed in chick, only GPC1 was found in mature commissural neurons ( Figure S1 available online). To evaluate the role of GPC1 in the guidance of commissural axons, we performed unilateral knockdowns by in ovo electroporation of plasmids expressing artificial microRNAs (miRNAs) (Figures 1C and S2) (Wilson and Stoeckli, 2011). Knockdowns were performed at Hamburger and Hamilton stages 17–18 (HH17–HH18; Hamburger and Hamilton, 1951), just before the onset of commissural axon growth. Because a mixture of small interfering
RNA (siRNAs) can produce more penetrant phenotypes (Parsons et al., 2009), we first coelectroporated a mixture of three plasmids encoding effective miRNAs against GPC1 (mi4GPC1, mi6GPC1, and mi7GPC1; Table S1; Figure S2) Bcl-2 phosphorylation or, as controls, the same amount of plasmids expressing miRNA against Luciferase (mi1Luc or mi2Luc; Table S1). DiI tracing of dorsal commissural axons in the spinal cord revealed that GPC1 knockdown caused
pathfinding errors of commissural axons at the midline ( Figures 1D–1G). Lapatinib nmr Some axons failed to enter the floorplate and stopped at the floorplate entry site in the absence of GPC1, while those that did enter often stalled within the floorplate. The axons that managed to cross to the contralateral side often failed to turn into the longitudinal axis and occasionally even turned posteriorly instead of anteriorly. Most importantly, in contrast to correctly navigating axons, the growth cones of axons that failed to turn correctly were not biased toward the rostral direction at the floorplate exit site. The phenotype observed in embryos deficient in GPC1 was highly Resveratrol reminiscent of the postcrossing commissural axon phenotype seen in the absence of Shh ( Bourikas et al., 2005). Only 17.9% of DiI injection sites were normal in embryos lacking GPC1, compared to 64.9% in control embryos electroporated with mi2Luc. The abnormal phenotypes were qualitatively
similar when we electroporated a single plasmid encoding mi7GPC1, the most effective of eight miRNAs that were tested ( Figures 1H and S2B). To test the specificity of gene silencing elicited by our miRNAs, we confirmed that the expression of nontargeted GPC family members was unchanged (Figures S2C–S2E), and we performed rescue experiments using a modified, full-length GPC1 construct that was resistant to knockdown by mi7GPC1 (GPC1ΔmiR; Figures 1I and S3). When GPC1ΔmiR was coelectroporated with mi7GPC1 ( Figure 1J), the resulting axon guidance phenotypes were indistinguishable from controls, demonstrating that expression of GPC1ΔmiR could completely rescue the effects of knocking down endogenous GPC1 with mi7GPC1 ( Figures 1K–1M).