Composition and conservation of the telomeric complex.

The telomere is composed of telomeric DNA and telomere-associated proteins. Recently, many telomere-associated proteins have been identified, and various telomere functions have been uncovered. In budding yeast, scRap1 binds directly to telomeric DNA, and other telomere regulators (Sir proteins and Rif proteins) are recruited to the telomeres by interacting with scRap1. Cdc13 binds to the most distal end of the chromosome and recruits telomerase to the telomeres. In fission yeast and humans, TTAGGG repeat binding factor (TRF) family proteins bind directly to telomeric DNA, and Rap1 proteins and other telomere regulators are recruited to the telomeres by interacting with the TRF family proteins. Both organisms have Pot1 proteins at the most distal end of the telomere instead of a budding-yeast Cdc13-like protein. Therefore, fission yeast and humans have in part common telomeric compositions that differ from that of budding yeast, a result that suggests budding yeast has lost some telomere components during the course of evolution.

spRap1 and spRif1, recruited to telomeres by Taz1, are essential for telomere function in fission yeast.

Telomeres are essential for genome integrity. scRap1 (S. cerevisiae Rap1) directly binds to telomeric DNA and regulates telomere length and telomere position effect (TPE) by recruiting two different groups of proteins to its RCT (Rap1 C-terminal) domain. The first group, Rif1 and Rif2, regulates telomere length. The second group, Sir3 and Sir4, is involved in heterochromatin formation. On the other hand, human TRF1 and TRF2, as well as their fission yeast homolog, Taz1, directly bind to telomeric DNA and negatively regulate telomere length. Taz1 also plays important roles in TPE and meiosis. Human Rap1, the ortholog of scRap1, negatively regulates telomere length and appears to be recruited to telomeres by interacting with TRF2. Here, we describe two novel fission yeast proteins, spRap1 (S. pombe Rap1) and spRif1 (S. pombe Rif1), which are orthologous to scRap1 and scRif1, respectively. spRap1 and spRif1 are independently recruited to telomeres by interacting with Taz1. The rap1 mutant is severely defective in telomere length control, TPE, and telomere clustering toward the spindle pole body (SPB) at the premeiotic horsetail stage, indicating that spRap1 has critical roles in these telomere functions. The rif1 mutant also shows some defects in telomere length control and meiosis. Our results indicate that Taz1 provides binding sites for telomere regulators, spRap1 and spRif1, which perform the essential telomere functions. This study establishes the similarity of telomere organization in fission yeast and humans.

Nuclear exclusion of Cdc25 is not required for the DNA damage checkpoint in fission yeast.

Maintenance of genome integrity requires a checkpoint that restrains mitosis in response to DNA damage [1]. This checkpoint is enforced by Chk1, a protein kinase that targets Cdc25 [2--7]. Phosphorylated Cdc25 associates with 14-3-3 proteins, which appear to occlude a nuclear localization signal (NLS) and thereby inhibit Cdc25 nuclear import [6, 8--14]. Proficient checkpoint arrest is thought to require Cdc25 nuclear exclusion, although definitive evidence for this model is lacking. We have tested this hypothesis in fission yeast. We show that elimination of an NLS in Cdc25 causes Cdc25 nuclear exclusion and a mitotic delay, as predicted by the model. Attachment of an exogenous NLS forces nuclear inclusion of Cdc25 in damaged cells. However, forced nuclear localization of Cdc25 fails to override the damage checkpoint. Thus, nuclear exclusion of Cdc25 is unnecessary for checkpoint enforcement. We propose that direct inhibition of Cdc25 phosphatase activity by Chk1, as demonstrated in vitro with fission yeast and human Chk1 [15, 16], is sufficient for proficient checkpoint regulation of Cdc25 and may be the primary mechanism of checkpoint enforcement in fission yeast.

Slm9, a novel nuclear protein involved in mitotic control in fission yeast.

In the fission yeast Schizosaccharomyces pombe, as in other eukaryotic cells, Cdc2/cyclin B complex is the key regulator of mitosis. Perhaps the most important regulation of Cdc2 is the inhibitory phosphorylation of tyrosine-15 that is catalyzed by Wee1 and Mik1. Cdc25 and Pyp3 phosphatases dephosphorylate tyrosine-15 and activate Cdc2. To isolate novel activators of Cdc2 kinase, we screened synthetic lethal mutants in a cdc25-22 background at the permissive temperature (25 degrees ). One of the genes, slm9, encodes a novel protein of 807 amino acids. Slm9 is most similar to Hir2, the histone gene regulator in budding yeast. Slm9 protein level is constant and Slm9 is localized to the nucleus throughout the cell cycle. The slm9 disruptant is delayed at the G(2)-M transition as indicated by cell elongation and analysis of DNA content. Inactivation of Wee1 fully suppressed the cell elongation phenotype caused by the slm9 mutation. The slm9 mutant is defective in recovery from G(1) arrest after nitrogen starvation. The slm9 mutant is also UV sensitive, showing a defect in recovery from the cell cycle arrest after UV irradiation.

The protein kinase Cdr2, related to Nim1/Cdr1 mitotic inducer, regulates the onset of mitosis in fission yeast.

Cdc2-Cyclin B, the protein kinase that catalyzes the onset of mitosis, is subject to multiple forms of regulation. In the fission yeast Schizosaccharomyces pombe and most other species, a key mode of Cdc2-Cyclin B regulation is the inhibitory phosphorylation of Cdc2 on tyrosine-15. This phosphorylation is catalyzed by the protein kinases Wee1 and Mik1 and removed by the phosphatase Cdc25. These proteins are also regulated, a notable example being the inhibition of Wee1 by the protein kinase Nim1/Cdr1. The temperature-sensitive mutation cdc25-22 is synthetic lethal with nim1/cdr1 mutations, suggesting that a synthetic lethal genetic screen could be used to identify novel mitotic regulators. Here we describe that such a screen has identified cdr2(+), a gene that has an important role in the mitotic control. Cdr2 is a 775 amino acid protein kinase that is closely related to Nim1 and mitotic control proteins in budding yeast. Deletion of cdr2 causes a G2-M delay that is more severe than that caused by nim1/cdr1 mutations. Genetic studies are consistent with a model in which Cdr2 negatively regulates Wee1. This model is supported by experiments showing that Cdr2 associates with the N-terminal regulatory domain of Wee1 in cell lysates and phosphorylates Wee1 in vitro. Thus, Cdr2 is a novel mitotic control protein that appears to regulate Wee1.

Schizosaccharomyces pombe gad7+ encodes a phosphoprotein with a bZIP domain, which is required for proper G1 arrest and gene expression under nitrogen starvation.

BACKGROUND: Fission yeast cells arrest at G1 phase when starved of nitrogen. The molecular mechanism that ensures this arrest is poorly understood. We took a genetic approach to this problem. RESULTS: The fission yeast gad7-1 mutant failed to arrest at G1 when starved of nitrogen, and was poor in mating and sporulation. The gad7 gene was cloned by complementation. The deduced gad7 gene product was a bZIP protein of 566 amino acids, which could bind to the CRE (cAMP response element) sequence in vitro. Disruption of gad7 resulted in the same phenotypes as gad7-1. Expression of ste11, which encodes a key transcription factor for sexual development, was not inducible in the disruptant. Gad7 was co-immunoprecipitated with another bZIP protein Pcr1, suggesting that the two proteins form a heterodimer in vivo. Gad7 was phosphorylated, and the state of its phosphorylation appeared to be modified in pka1delta or wis1delta cells. CONCLUSIONS: Gad7, a CRE-binding protein that cooperates with Pcr1, is required for proper G1 arrest and gene expression under nitrogen starvation. Gad7 is a phosphoprotein, whose activity may be regulated by protein kinases including the cAMP-dependent protein kinase (Pka1) and Wis1 osmosensory MAP kinase kinase.

Schizosaccharomyces pombe zfs1+ encoding a zinc-finger protein functions in the mating pheromone recognition pathway.

We isolated the Schizosaccharomyces pombe zfs1 gene as a multicopy suppressor of the sterility caused by overexpression of a double-stranded RNase. The deduced zfs1 gene product of 404 amino acids showed similarity to a mouse growth factor-inducible nuclear protein Nup475. Its C-terminal region carried two putative zinc-fingers, both of which should be intact for the protein to be functional as the suppressor. This protein appeared to localize in nuclei. Disruption of zfs1 was not lethal but conferred deficiency in mating and sporulation. Activation of transcription in response to the mating pheromone signaling was greatly reduced in the zfs1-disrupted cells. The mating deficiency of the zfs1-disruptant was suppressed partially by overexpression of either gpa1, ras1, byr1, or byr2, which are involved in the transmission of the pheromone signal. Disruption of zfs1 reduced both hypersensitivity of the ras1Val17 mutant to the mating pheromone and uncontrolled mating response caused by mutational activation of Gpa1, the G protein alpha subunit coupled to the mating pheromone receptors. However, overexpression of zfs1 could not bypass complete loss of function of either gpa1, ras1, byr1, or byr2. These observations indicate that the function of zfs1 is involved in the mating pheromone signaling pathway, and are consistent with its function being required to fully activate a factor in this pathway, either directly or indirectly.

New technique using intraductal ultrasonography for the diagnosis of diseases of the pancreatobiliary system.

Intraductal ultrasonography (IDUS), a new technique for visualizing arterial structures, operates at an ultrasound frequency of 30 MHz to produce high resolution, cross-sectional images in real time. The purpose of this study was to provide a basis for interpreting IDUS images in vitro. We also attempted to determine the clinical usefulness of the IDUS system in diagnosing pancreatobiliary diseases in vivo. IDUS echograms of both the bile duct (BD) and main pancreatic duct (MPD) from autopsy specimens of 15 patients demonstrated three distinct layers with a fine reticular pattern in the pancreas in vitro. In clinical cases, the MPD and BD of four patients could be scanned by inserting the IDUS catheter via the major papilla without requiring endoscopic sphincterotomy. We hope that IDUS will become routine in scanning the BD and MPD to achieve early and accurate diagnoses of pancreatobiliary diseases.

Monitoring the pressure of the sphincter of Oddi by percutaneous transhepatic choledochoscopy: new method for evaluating motor function.

The pressure of the sphincter of Oddi was measured in 40 patients using a thin microtransducer introduced via percutaneous transhepatic choledochoscopy. Choledochograms of the Vaterian bile duct were classified into four types: N (normal), I, II and III. Judging from the length of the Vaterian bile duct and the degree of fibrosis observed in the biopsy specimens, duodenal papillitis was found to be more severe in Type III than in Type II. Nevertheless the systolic pressure was significantly lower in Type III. We considered that when duodenal papillitis is considerably advanced, the force of contraction of the sphincter is reduced. In addition, based on choledochoscopic observations, as duodenal papillitis increased in severity, the incidence of an irregular shape at the end of the common bile duct during diastole increased. The indications for endoscopic sphincterotomy were determined based on the pressure of the sphincter of Oddi in patients with normal duodenal papilla. In the 26 patients in whom the procedure was not indicated, no gallstones developed. In the 3 patients in whom the procedure was indicated and performed, gallstones have not developed. However, 3 of the 6 patients in whom the procedure was indicated but not performed developed gallstones. This method is useful in evaluating the motor function of the sphincter of Oddi under relatively physiological conditions.