ABSTRACT The zinc finger protein 24 (ZFP24) is required for oligodendrocyte maturation and CNS myelination. ZFP24 binds to a consensus DNA sequence in proximity to genes important for oligodendrocyte differentiation, and this binding enhances target gene expression. ZFP24 contains four C2H2 zinc-finger domains that are interspersed by three conserved linkers. ZFP24 DNA binding is controlled by phosphorylation of the conserved linkers: phosphorylated ZFP24, which does not bind DNA, is the predominant form in oligodendrocyte progenitor cells (OPCs). As these cells mature into oligodendrocytes, the non-phosphorylated, DNA-binding form accumulates. Our findings indicate that changes to ZFP24 phosphorylation control its binding to regulatory regions of genes important for oligodendrocyte maturation, controls their expression, and thereby regulates oligodendrocyte differentiation and CNS myelination. Therefore, it is critical to identify the kinase(s) and phosphatase(s) responsible for controlling the functional status of ZFP24. In the first aim we propose two distinct unbiased screening approaches toward the identification of the ZFP24 kinase(s). We will also examine the effect of inhibition of the identified kinase(s) on ZFP24 phosphorylation, ZFP24 activity, oligodendrocyte maturation and myelin related gene expression. The second aim focuses on identifying the phosphatase(s) that de-phosphorylates ZFP24 to generate the functional transcriptional factor. We will use a candidate phosphatase screen, as well as an unbiased screen to identify these ZFP24 phosphatases. We will also examine the effect of inhibition of the identified phosphatase(s) on ZFP24 activity, ZFP24 phosphorylation, oligodendrocyte maturation and myelin related gene expression. In the third aim we will characterize phosphorylation intermediate isoforms of ZFP24. We have identified ZFP24 isoforms in which one, two or all three potential phosphorylation sites in the conserved ZFP24 linker domains are phosphorylated in cultured oligodendrocyte lineage cells. Currently it is unclear whether these are non-functional, transitional ZFP24 isoforms, or if these forms are important intermediates with unique functions in oligodendrocyte development. Therefore, in the third aim we will study the half-life of the intermediate forms and determine if the distinct isoforms have unique functions in oligodendrocyte development. Aim four is devoted to the elucidation of the potential role that ZFP24 plays in the CNS of adult animals, including myelin maintenance and remyelination. We also propose to generate a new mouse model that will allow for the inducible expression of the active, non- phosphorylated, form of ZFP24 in OPCs. This model will be used to test the potential ability of the active form of ZFP24 to enhance remyelination. Overall, the studies described here will provide a more detailed understanding of the role that ZFP24 phosphorylation plays in oligodendrocyte maturation, CNS myelination...