To examine the abnormalities in the brain of the transgenic embryos, we analyzed cryosections at E9.5. The neural tube was thinner in KCC2-FL (78% of wild-type; P = 0.0003, n = 6) and in most KCC2-ΔNTD embryos (80% of wild-type; P = 0.240, not significant, n = 4) compared to wild-type littermates (n = 4 and n = 3, respectively). However, neurulation was completed in all embryos except for one KCC2-ΔNTD embryo, which displayed an open neural tube posteriorly (supporting Fig. S2). Immunostaining for the early neuronal
marker TuJ1 revealed the morphology of differentiating neuronal cells (Fig. 4A–D). selleck In both wild-type and transgenic embryos, TuJ1-positive cells in the neural tube had radial processes and were found mostly in proximity to the pial surface. However, the neuronal cells in wild-type embryos displayed more protrusions in the tangential direction see more than did the cells in KCC2-FL and KCC2-ΔNTD embryos. In addition, there was a reduced number of TuJ1-positive cells in the neural tube of KCC2-FL (77% of wild-type; P = 0.005, n = 4) and KCC2-ΔNTD (66% of
wild-type; P = 0.016, n = 4) embryos, but no significant difference in KCC2-C568A embryos (92% of wild-type; P = 0.465, n = 3) compared to wild-type littermates (n = 3 per group; Fig. 4M). As a reduced differentiation could be due to a decrease in proliferation, we stained for the mitotic marker phosphohistone-3. However, the number of cells positive for phosphohistone-3 did not differ between the neural tubes of transgenic embryos and wild-type littermates (supporting Chorioepithelioma Fig. S3). To further analyze whether the reduced differentiation could be due to increased apoptosis, we examined the expression of caspase-3. We found a small number of apoptotic cells scattered in the neural tube of both the wild-type and transgenic embryos (supporting Fig. S3). There was no detectable increase in apoptosis in the transgenic embryos. These findings indicate that overexpression of KCC2-FL and KCC2-ΔNTD reduced the number of TuJ1-positive cells without affecting proliferation or
apoptosis. Next, we examined a possible effect on neuronal migration. Doublecortin labeling showed migrating neurons in the neural tube and neural crest. The pattern resembled that of TuJ1 with positive cells distributed mainly in the marginal zone (Fig. 4E–H). Similar to TuJ1, doublecortin-expressing cells were significantly reduced in the neural tube of KCC2-FL (42% of wild-type; P = 0.025, n = 3) and KCC2-ΔNTD (31% of wild-type; P = 0.048, n = 3) embryos compared to wild-type (n = 3 per group) and KCC2-C568A (n = 3) embryos. Moreover, we stained for polysialylated neural cell adhesion molecule (PSA-NCAM). PSA-NCAM-positive cells displayed radial projections similar to TuJ1- and doublecortin-expressing cells and were found both in the ventricular and marginal zones of the neural tube, with a higher abundance in the posterior part (Fig. 4I–L).