The cdc25+ tyrosine phosphatase is a key mitotic inducer of the fission yeast Schizosaccharomyces pombe, controlling the timing of the initiation of mitosis. Mammals contain at least three cdc25+ homologues called cdc25A, cdc25B and cdc25C. In this study we investigate the biological function of cdc25A. Although very potent in rescuing the S.pombe cdc25 mutant, cdc25A is less structurally related to the S.pombe enzyme. Northern and Western blotting detection reveals that unlike cdc25B, cdc25C and cdc2, cdc25A is predominantly expressed in late G1. Moreover, immunodepletion of cdc25A in rat cells by microinjection of a specific antibody effectively blocks their cell cycle progression from G1 into the S phase, as determined by laser scanning single cell cytometry. These results indicate that cdc25A is not a mitotic regulator but a novel phosphatase that plays a crucial role in the start of the cell cycle. In view of its strong ability to activate cdc2 kinase and its specific expression in late G1, cdc2‐related kinases functioning early in the cell cycle may be targets for this phosphatase.
We describe a highly efficient alkali cation method and library transducing vectors for cloning mammalian cDNAs by trans-complementation of fission yeast Schizosaccharomyces pombe mutants. cDNA libraries constructed with the pcD or pcD2 vector are transduced into yeast by cotransfection with a linearized vector, which allows an enhanced homologous recombination between the yeast vector and the library plasmid leading to the efficient formation of concatemers containing pcD molecules. The transformation frequencies obtained by the method are 10(6) colonies per 10(8) cells transfected with 2 micrograms of library and 1 microgram of vector, 50-60% of which contain pcD molecules. The high-efficiency alkali cation method circumvents many of the shortcomings of the spheroplast method generally used for Schiz. pombe transfection. The vectors are maximized for the efficiency of library transduction and minimized for the rearrangements of pcD molecules during propagation in yeast. This system allows rapid screening of multi-million cDNA clone libraries for rare cDNAs in a routine scale of experiments. Using this system, various mammalian cDNAs that are extremely difficult, time-consuming, or unclonable to clone by other methods have been cloned.
Exposure to ultraviolet light arrests the function of mammalian fibroblasts in the G1 phase of the cell cycle, as well as the S and G2 phases. Although p21, an inhibitor of cyclin-dependent kinase (Cdk) that is induced by DNA damage may partly account for the arrest in G1 (ref. 1), the mechanism is little understood. Here we show that tyrosine phosphorylation of Cdk4 is required for this arrest. In rat fibroblast, Cdk4 is tyrosine-phosphorylated during G1 progression, and its dephosphorylation is required for S phase. When cells are ultraviolet-irradiated, their arrest in G1 is accompanied by an increase in phosphorylation level. Conversely, cells expressing unphosphorylatable Cdk4F17 fail to arrest in G1, and suffer significantly elevated chromosomal aberrations and cell death.
The wee1+ gene is a mitotic inhibitor controlling the G2 to M transition of the fission yeast Schizosaccharomyces pombe and encodes a protein kinase with both serine- and tyrosine-phosphorylating activities. We have cloned a human gene (WEE1Hu) similar to wee1+ by transcomplementation of a yeast mutant. WEE1Hu encodes a protein homologous to the S. pombe wee1+ and mik1+ (a functionally redundant sibling of wee1+) kinases and effectively rescues a wee1 mutation. We report here that overexpression of WEE1Hu in fission yeast generates very elongated cells as a result of inhibition of the G2-M transition in the cell cycle. In addition, we detected a 3-kilobase-long WEE1Hu messenger RNA in all the human cell lines we examined. We conclude that a wee1(+)-like gene exists and is expressed in human cells.
In the fission yeast Schizosaccharomyces pombe the nrd1؉ gene encoding an RNA binding protein negatively regulates the onset of differentiation. Its biological role is to block differentiation by repressing a subset of the Ste11-regulated genes essential for conjugation and meiosis until the cells reach a critical level of nutrient starvation. By using the phenotypic suppression of the S. pombe temperature-sensitive pat1 mutant that commits lethal haploid meiosis at the restrictive temperature, we have cloned ROD1, a functional homologue of nrd1 ؉ , from rat and human cDNA libraries. Like nrd1 ؉ , ROD1 encodes a protein with four repeats of typical RNA binding domains, though its amino acid homology to Nrd1 is limited. When expressed in the fission yeast, ROD1 behaves in a way that is functionally similar to nrd1 ؉ , being able to repress Ste11-regulated genes and to inhibit conjugation upon overexpression. ROD1 is predominantly expressed in hematopoietic cells or organs of adult and embryonic rat. Like nrd1 ؉ for fission yeast differentiation, overexpressed ROD1 effectively blocks both 12-O-tetradecanoyl phorbol-13-acetate-induced megakaryocytic and sodium butyrate-induced erythroid differentiation of the K562 human leukemia cells without affecting their proliferative ability. These results suggest a role for ROD1 in differentiation control in mammalian cells. We discuss the possibility that a differentiation control system found in the fission yeast might well be conserved in more complex organisms, including mammals.
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