How might the distinct functions of Olig2 be dynamically modulate

How might the distinct functions of Olig2 be dynamically modulated

to suit biological context? Using mass spectroscopy, phosphorylation state-specific antibodies, and site-directed mutagenesis, we show here that the separate functions of Olig2 in progenitor self-renewal and oligodendrocyte development are controlled in part by developmentally regulated phosphorylation of a conserved triple serine motif within the amino-terminal domain. The promitotic functions of this triple serine motif are reflected in human glioma neurosphere cultures and in a murine model of primary glioma (the most common manifestation of the disease in humans) (Kleihues and Cavenee, 2007). Using immunoaffinity chromatography, selleck chemicals we purified microgram quantities of endogenous Olig2 protein from both normal murine neurosphere cultures and from gliomas generated by orthotopic transplant of primary human tumor neurospheres (see Figure S1 available online). High-confidence phosphorylation sites within Olig2 were mapped by mass spectroscopy (Figures 1, S1D, and S2). As indicated in Figure S1, a number of potential phosphorylation sites within Olig2 can be detected by computer algorithm. However, mass spectroscopy reveals that very few of these potential sites are actually utilized in endogenous Olig2 isolated from these murine and human

progenitor cell types (see Discussion). Notably, no phosphorylated residues were detected within a serine/threonine-rich “box” www.selleckchem.com/products/abt-199.html that is a distinctive feature of all mammalian Olig2 homologs (Lu et al., 2000, Takebayashi et al., 2000 and Zhou et al., 2000). Instead, high-confidence Carnitine dehydrogenase phosphorylation sites within endogenous Olig2 were confined to S10, S13, S14, and T43 within the amino-terminal domain (Figures 1A, S1, and S2). Olig2 null progenitor cells can be cultured

as neurospheres in vitro. However, the population doubling time of Olig2-null progenitors is significantly extended relative to their wild-type counterparts (∼43 versus ∼35 hr, respectively) ( Ligon et al., 2007). The four S/T residues comprising the high-confidence phosphorylation sites were mutated singly or in combinatorial fashion to glycine or valine so as to create phospho null Olig2 mutant proteins ( Figure 1B). These phospho null variants were transduced into Olig2-null neural progenitor cells, and secondary neurosphere assays were conducted to examine their roles in proliferation. As indicated (Figures 1C and 1D), the phosphorylation state of Olig2 is irrelevant to the total number of neurospheres that are produced in secondary neurosphere assays. However, the viable cell count within these neurospheres (and, hence, the size of the secondary neurospheres) is greatly reduced by phospho null substitutions at S10, S13, and S14 (triple phospho null [TPN]).

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