Cdk5 promotes synaptogenesis by regulating the subcellular distribution of the MAGUK family member CASK.

Synaptogenesis is a highly regulated process that underlies formation of neural circuitry. Considerable work has demonstrated the capability of some adhesion molecules, such as SynCAM and Neurexins/Neuroligins, to induce synapse formation in vitro. Furthermore, Cdk5 gain of function results in an increased number of synapses in vivo. To gain a better understanding of how Cdk5 might promote synaptogenesis, we investigated potential crosstalk between Cdk5 and the cascade of events mediated by synapse-inducing proteins. One protein recruited to developing terminals by SynCAM and Neurexins/Neuroligins is the MAGUK family member CASK. We found that Cdk5 phosphorylates and regulates CASK distribution to membranes. In the absence of Cdk5-dependent phosphorylation, CASK is not recruited to developing synapses and thus fails to interact with essential presynaptic components. Functional consequences include alterations in calcium influx. Mechanistically, Cdk5 regulates the interaction between CASK and liprin-alpha. These results provide a molecular explanation of how Cdk5 can promote synaptogenesis.

Partial rescue of the p35-/- brain phenotype by low expression of a neuronal-specific enolase p25 transgene.

Cyclin-dependent kinase 5 (Cdk5) is activated on binding of activator proteins p35 and p39. A N-terminally truncated p35, termed p25, is generated through cleavage by the Ca(2+)-dependent protease calpain after induction of ischemia in rat brain. p25 has been shown to accumulate in brains of patients with Alzheimer's disease and may contribute to A-beta peptide-mediated toxicity. Studies from transfected neurons as well as p35 and p25 transgenic mice have indicated that Cdk5, when activated by p25, gains some toxic function compared with p35/Cdk5. It remains unclear, however, whether p25/Cdk5 signaling additionally channels into pathways usually used by p35/Cdk5 and whether p25 is associated with a loss of p35 function. To clarify these issues, we have generated p25-transgenic mice in a p35-null background. We find that low levels of p25 during development induce a partial rescue of the p35-/- phenotype in several brain regions analyzed, including a rescue of cell positioning of a subset of neurons in the neocortex. In accordance with the partial rescue of brain anatomy, phosphorylation of the Cdk5 substrate mouse disabled 1 is partially restored during development. Besides this, p25/Cdk5 fails to phosphorylate other substrates that are normally phosphorylated by p35/Cdk5. Our results show that p25 can substitute for p35/Cdk5 under certain circumstances during development. In addition, they suggest that p25 may have lost some functions of p35.

Mitogen-activated protein kinases regulate LSF occupancy at the human immunodeficiency virus type 1 promoter.

Human immunodeficiency virus type 1 (HIV-1) establishes a persistent, nonproductive state within a small population of memory CD4(+) cells. The transcription factor LSF binds to sequences within the HIV-1 long terminal repeat (LTR) initiation region and recruits a second factor, YY1, to the LTR. These factors then cooperatively recruit histone deacetylase 1 to the LTR, resulting in inhibition of transcription. This appears to be one mechanism contributing to HIV persistence within resting CD4(+) T cells. We sought to further detail LSF binding to the HIV-1 LTR and factors that regulate LSF occupancy. We find that LSF binds the LTR as a tetramer and that binding is regulated by phosphorylation mediated by mitogen-activated protein kinases (MAPKs). In vitro, phosphorylation of LSF by Erk decreases binding to the LTR, while binding is increased by p38 phosphorylation. LSF occupancy at LTR chromatin is increased by the p38 agonist anisomycin and decreased by specific p38 inhibition. p38 inhibition also results in increased acetylation of histone H4 at the LTR nucleosome adjacent to the LSF binding site. p38 inhibition also blocked the ability of YY1 to inhibit activation of the integrated HIV promoter. Finally, HIV was recovered from the resting CD4(+) T cells of aviremic, HIV-infected donors upon treatment of these cells with specific inhibitor of p38. These data suggest that the MAPK pathway regulates LSF binding to the LTR and thereby one aspect of the regulation of HIV expression. This mechanism could be exploited as a novel therapeutic target to disrupt latent HIV infection.

Mammalian transcription factor LSF is a target of ERK signaling.

LSF is a mammalian transcription factor that is rapidly and quantitatively phosphorylated upon growth induction of resting, peripheral human T cells, as assayed by a reduction in its electrophoretic mobility. The DNA-binding activity of LSF in primary T cells is greatly increased after this phosphorylation event (Volker et al. [1997]: Genes Dev 11:1435-1446). We demonstrate here that LSF is also rapidly and quantitatively phosphorylated upon growth induction in NIH 3T3 cells, although its DNA-binding activity is not significantly altered. Three lines of experimentation established that ERK is responsible for phosphorylating LSF upon growth induction in both cell types. First, phosphorylation of LSF by ERK is sufficient to cause the reduced electrophoretic mobility of LSF. Second, the amount of ERK activity correlates with the extent of LSF phosphorylation in both primary human T cells and NIH 3T3 cells. Finally, specific inhibitors of the Ras/Raf/MEK/ERK pathway inhibit LSF modification in vivo. This phosphorylation by ERK is not sufficient for activation of LSF DNA-binding activity, as evidenced both in vitro and in mouse fibroblasts. Nonetheless, activation of ERK is a prerequisite for the substantial increase in LSF DNA-binding activity upon activation of resting T cells, indicating that ERK phosphorylation is necessary but not sufficient for activation of LSF in this cell type.