The Fission Yeast Mitotic Regulator win1+ Encodes an MAP Kinase Kinase Kinase That Phosphorylates and Activates Wis1 MAP Kinase Kinase in Response to High Osmolarity

The Schizosaccharomyces pombe win1-1 mutant has a defect in the G2-M transition of the cell cycle. Although the defect is suppressed by wis1+ and wis4+, which are components of a stress-activated MAP kinase pathway that links stress response and cell cycle control, the molecular identity of Win1 has not been known. We show here that win1+ encodes a polypeptide of 1436 residues with an apparent molecular size of 180 kDa and demonstrate that Win1 is a MAP kinase kinase kinase that phosphorylates and activates Wis1. Despite extensive similarities between Win1 and Wis4, the two MAP kinase kinase kinases have distinct functions. Wis4 is able to compensate for loss of Win1 only under unstressed conditions to maintain basal Wis1 activity, but it fails to suppress the osmosignaling defect conferred by win1 mutations. The win1-1 mutation is a spontaneous duplication of 16 nucleotides, which leads to a frameshift and production of a truncated protein lacking the kinase domain. We discuss the cell cycle phenotype of the win1-1 cdc25-22 wee1-50 mutant and its suppression by wis genes.

A nerve growth factor peptide retards seizure development and inhibits neuronal sprouting in a rat model of epilepsy.

Kindling, an animal model of epilepsy wherein seizures are induced by subcortical electrical stimulation, results in the upregulation of neurotrophin mRNA and protein in the adult rat forebrain and causes mossy fiber sprouting in the hippocampus. Intraventricular infusion of a synthetic peptide mimic of a nerve growth factor domain that interferes with the binding of neurotrophins to their receptors resulted in significant retardation of kindling and inhibition of mossy fiber sprouting. These findings suggest a critical role for neurotrophins in both kindling and kindling-induced synaptic reorganization.

Tissue specificity of a glucocorticoid-dependent enhancer in transgenic mice.

The glucocorticoid-responsive units (GRUs) of the rat tyrosine aminotransferase were associated with the regulatory sequences of a cellular gene expressed ubiquitously--that coding for the largest subunit of RNA polymerase II. In transient expression assays, glucocorticoid responsiveness of the hybrid regulatory regions depends on the spatial relationship and number of regulatory elements. Two parameters affect the ratio of induction by glucocorticoids: the basal level of the hybrid promoter that is affected by the RNA polymerase II regulatory sequences and the glucocorticoid-induced level that depends on the distance between the GRUs and the TATA box. A fully active glucocorticoid-responsive hybrid gene was used to generate transgenic mice. Results show that a composite regulatory pattern is obtained: ubiquitous basal expression characteristic of the RNA polymerase II gene and liver-specific glucocorticoid activation characteristic of the tyrosine aminotransferase GRUs. This result demonstrates that the activity of the tyrosine aminotransferase GRUs is cell-type-specific not only in cultured cells but also in the whole animal.