Molecular and genetic studies imply Akt-mediated signaling promotes protein kinase CbetaII alternative splicing via phosphorylation of serine/arginine-rich splicing factor SRp40.

Insulin regulates alternative splicing of PKCbetaII mRNA by phosphorylation of SRp40 via a phosphatidylinositol 3-kinase pathway (Patel, N. A., Chalfant, C. E., Watson, J. E., Wyatt, J. R., Dean, N. M., Eichler, D. C., and Cooper, D. C. (2001) J. Biol. Chem. 276, 22648-22654). Transient transfection of constitutively active Akt2 kinase promotes PKCbetaII exon inclusion. Serine/arginine-rich (SR) RNA-binding proteins regulating the selection of alternatively spliced exons are potential substrates of Akt kinase because many of them contain RXRXX(S/T) motifs. Here we show that Akt2 kinase phosphorylated SRp40 in vivo and in vitro. Mutation of Ser86 on SRp40 blocked in vitro phosphorylation. In control Akt2(+/+) fibroblasts, insulin treatment increased the phosphorylation of endogenous SR proteins, but their phosphorylation state remained unaltered by insulin in fibroblasts from Akt2(-/-) mice. Levels of PKCbetaII protein were up-regulated by insulin in Akt2(+/+) cells; however, only very low levels of PKCbetaII were detected in Akt2(-/-) cells and did not change following insulin treatment. Endogenous PKCbetaI and -betaII mRNA levels in Akt2(+/+) and Akt2(-/-) gastrocnemius muscle tissues were compared using quantitative real time PCR. The results indicated a 54% decrease in the expression of PKCbetaII levels in Akt(-/-), whereas PKCbetaI levels remained unchanged in both samples. Further, transfection of Akt2(-/-) cells with a PKCbetaII splicing minigene revealed defective betaII exon inclusion. Co-transfection of the mutated SRp40 attenuated betaII exon inclusion. This study provides in vitro and in vivo evidence showing Akt2 kinase directly phosphorylated SRp40, thereby connecting the insulin, PI 3-kinase/Akt pathway with phosphorylation of a site on a nuclear splicing protein promoting exon inclusion. This model is upheld in Akt2-deficient mice with insulin resistance leading to diabetes mellitus.

The protein kinase C beta II exon confers mRNA instability in the presence of high glucose concentrations.

Previous studies showed that short term exposure of cells to high glucose destabilized protein kinase C (PKC) betaII mRNA, whereas PKCbetaI mRNA levels remained unaltered. Because PKCbeta mRNAs share common sequences other than the PKCbetaII exon encoding a different carboxyl terminus, we examined PKCbetaII mRNA for a cis-acting region that could confer glucose-induced destabilization. A beta-globin/growth hormone reporter con struct containing the PKCbetaII exon was transfected into human aorta and rat vascular smooth muscle cells (A10) to follow glucose-induced destabilization. Glucose (25 mm) exposure destabilized PKCbetaII chimeric mRNA but not control mRNA. Deletion analysis and electrophoretic mobility shift assays followed by UV cross-linking experiments demonstrated that a region introduced by inclusion of the betaII exon was required to confer destabilization. Although a cis-acting element mapped to 38 nucleotides within the betaII exon was necessary to bestow destabilization, it was not sufficient by itself to confer complete mRNA destabilization. Yet, in intact cells antisense oligonucleotides complementary to this region blocked glucose-induced destabilization. These results suggest that this region must function in context with other sequence elements created by exon inclusion involved in affecting mRNA stability. In summary, inclusion of an exon that encodes PKCbetaII mRNA introduces a cis-acting region that confers destabilization to the mRNA in response to glucose.

Phosphoinositide 3-kinase mediates protein kinase C beta II mRNA destabilization in rat A10 smooth muscle cell cultures exposed to high glucose.

High-glucose exposure down-regulates protein kinaseC beta II posttranscriptionally in rat and human vascular smooth muscle cells and contributes to increased cell proliferation. High-glucose-induced mRNA destabilization is specific for PKC beta II mRNA, while PKC beta I and other PKC mRNA are not affected. This study focused on whether glucose metabolism was required. The effect was blocked by cytochalasin B, suggesting a requirement for glucose uptake. Glucosamine did not mimic the effect, indicating that metabolism via hexosamine pathway was not involved. The effect was hexokinase-independent since 3-O-methylglucose, in a dose-dependent manner, mimicked high-glucose effects. Cycloheximide did not block the effect excluding dependency on new protein synthesis. Wortmannin and LY294002, phosphoinositide 3-kinase (PI3-kinase) inhibitors, blocked glucose effects in the presence of 5,6-dichloro-1-beta-d-ribofuranosylbenzimidazole. Glucose and 3-O-methylglucose activated PI3-kinase, and LY294002 blocked glucose effects on Akt phosphorylation. In these cells, high-glucose concentrations activated a metabolically linked signaling pathway independent of glucose metabolism to regulate mRNA processing.