The foregoing data suggest that these genes play a key role in th

The foregoing data suggest that these genes play a key role in the specification and differentiation of glial populations; therefore, we next sought to understand how

they function to promote gliogenesis. To this end we performed shRNAi knockdown Enzalutamide of Mmd2 with an RCAS-shRNAi system. The effective knockdown of Mmd2 at E6 was verified by in situ hybridization and resulted in decreased expression of ASP markers GLAST, FGFR3, and FABP7 and of OLP marker Olig2 ( Figures 6A–6F). Further analysis revealed a ∼60% decrease in the number of Pax6-expressing progenitors, without a significant increase in cell death as measured by caspase 3 staining or concomitant increase in neurogenesis ( Figure S8). To control for the specificity of the Mmd2 knockdown phenotype, we generated a mutant version of the Mmd2-shRNAi containing five nucleotide substitutions, which had no effect on ASP, OLP, or Pax6 marker expression and demonstrated similarly low levels of caspase 3 staining ( Figures 6H–6M and S8). Next, to confirm that these phenotypes are due to a loss of Mmd2, we performed a rescue

experiment, where we coelectroporated a mouse cDNA to Mmd2 with the Mmd2 shRNAi. Gemcitabine As indicated in Figures 6O–6T, Mmd2 is able to rescue the loss of ASP and OLP markers. Collectively, these data indicate that knockdown of Mmd2 results in the loss of glial precursor populations

in the embryonic spinal cord. That knockdown of Mmd2 resulted in a loss of precursor populations without increased cell whatever death suggests that it influences cell proliferation. To determine whether loss of Mmd2 effects proliferation, we electroporated the Mmd2-shRNAi (or mutant control) and performed BrdU labeling on chick embryos at E6. We found that knockdown of Mmd2 results in a 70% decrease in BrdU incorporation at E6, suggesting that these phenotypes are the result of decreased proliferation ( Figures 6G, 6N, and 6U). Mmd2 (or PAQR10) contains a putative mitochondrial targeting sequence (MTS) and has previously been shown to localize to the mitochondria ( Góñez et al., 2008). To confirm these findings, we overexpressed Myc-tagged Mmd2 in U87 astrocytoma cells and found that it localizes to mitochondria ( Figures 6V–6X). Because loss of Mmd2 does not appear to influence cell death ( Figure S8), we reasoned that it plays a role in energy metabolism. To determine whether Mmd2 influences mitochondrial oxidative energy metabolism, we performed enzymologic assays of respiratory chain complexes II–IV and citrate synthase on E6 chick spinal cord electroporated with Mmd2-shRNAi, mutant control, and a GFP-only control.

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