Live analysis of lagging chromosomes during anaphase and their effect on spindle elongation rate in fission yeast.

The fission yeast Schizosaccharomyces pombe is widely used as a model system for studies of the cell cycle and chromosome biology. To enhance these studies we have fused GFP to the chromodomain protein Swi6p, thus allowing nuclear and chromosome behaviour to be followed in living cells using time-lapse fluorescence microscopy. Like endogenous Swi6p, GFP-Swi6p localises to the nucleus and is concentrated at the heterochromatic centromeres and telomeres. The nucleus is highly dynamic during interphase: the clustered centromeres, in particular, are highly mobile. By expressing GFP-(&agr;)2-tubulin and GFP-Swi6p in the same cells we observe that the clustered centromeres move in concert with the cytoplasmic microtubules, which is likely to reflect their association with the spindle pole body. Drug treatment indicates that this movement is dependent on intact cytoplasmic microtubules. We have also used GFP-Swi6p to investigate the properties of lagging chromosomes observed in mutants with defects in chromosome segregation. Lagging chromosomes display a variety of behaviours on anaphase spindles, most surprisingly, chromosomes appear to initiate microtubule interactions and move to the poles late in anaphase B. Interestingly, in cells displaying lagging chromosomes, the rate of spindle elongation is slowed by a factor of two. This suggests that cells are able to sense the presence of a lagging chromosome and slow anaphase B in order to allow it extra time to reach the pole. However, this mechanism is not dependent on the spindle checkpoint proteins Bub1p or Dma1p, raising the possibility that a novel checkpoint mechanism operates to retard spindle elongation if lagging chromosomes are detected. An alternative model is also discussed in which single defective kinetochores on lagging chromatids are able to interact simultaneously with microtubules emanating from both poles and affect spindle dynamics by counteracting the spindle elongation force.

The structure and unusual pH dependence of plastocyanin from the fern Dryopteris crassirhizoma. The protonation of an active site histidine is hindered by pi-pi interactions.

Spectroscopic properties, amino acid sequence, electron transfer kinetics, and crystal structures of the oxidized (at 1.7 A resolution) and reduced form (at 1.8 A resolution) of a novel plastocyanin from the fern Dryopteris crassirhizoma are presented. Kinetic studies show that the reduced form of Dryopteris plastocyanin remains redox-active at low pH, under conditions where the oxidation of the reduced form of other plastocyanins is inhibited by the protonation of a solvent-exposed active site residue, His87 (equivalent to His90 in Dryopteris plastocyanin). The x-ray crystal structure analysis of Dryopteris plastocyanin reveals pi-pi stacking between Phe12 and His90, suggesting that the active site is uniquely protected against inactivation. Like higher plant plastocyanins, Dryopteris plastocyanin has an acidic patch, but this patch is located closer to the solvent-exposed active site His residue, and the total number of acidic residues is smaller. In the reactions of Dryopteris plastocyanin with inorganic redox reagents, the acidic patch (the "remote" site) and the hydrophobic patch surrounding His90 (the "adjacent" site) are equally efficient for electron transfer. These results indicate the significance of the lack of protonation at the active site of Dryopteris plastocyanin, the equivalence of the two electron transfer sites in this protein, and a possibility of obtaining a novel insight into the photosynthetic electron transfer system of the first vascular plant fern, including its molecular evolutionary aspects. This is the first report on the characterization of plastocyanin and the first three-dimensional protein structure from fern plant.

Fit discrimination of implant-supported fixed partial dentures fabricated from implant level impressions made at stage I surgery.

STATEMENT OF PROBLEM: The implant level impression can shorten the overall time frame of implant treatment. PURPOSE OF STUDY: The purpose of this study was to analyze the accuracy of fixed partial dentures constructed from impressions taken at implant installation surgery in partially edentulous dogs. The study compared the fit of welded titanium fixed partial dentures with that of cast gold alloy fixed partial dentures. MATERIAL AND METHODS: Three implants were placed on each side of the mandible in six adult greyhound dogs during stage I surgery. Impressions were taken of the implant positional relationships and two types of fixed partial dentures were fabricated for each side of the mandible. Stage II surgery was performed after 3 months. RESULTS: Both types of fixed partial dentures compared favorably with the fit of implant-supported fixed partial dentures in the edentulous jaw or traditional cast fixed partial denture frameworks. CONCLUSIONS: Impressions taken at implant installation surgery provide a valid transfer of information for the laboratory fabrication of the final restoration when the implants are placed to fulfill the requirements of primary stability.

Conserved histidine residues of RCC1 are essential for nucleotide exchange on Ran.

Charged amino acid residues of human RCC1 were converted to alanine and mutants which were unable to complement tsBN2 cells (a temperature-sensitive rcc1- mutant of the hamster BHK21 cell line) were selected. These RCC1 mutants were analyzed for the ability to inhibit premature chromatin condensation by microinjection into tsBN2 cells, and their steady-state kinetic parameters for guanine nucleotide exchange reaction were measured. Examined RCC1 mutants were unstable in tsBN2 cells at the restrictive temperature, yet they significantly inhibited premature chromatin condensation. Mutants located on the N-terminus of the RCC1 repeat showed an increased K(m), while their kcat values were comparable to that of wild-type RCC1. In contrast, mutants containing the conserved histidine residues in the C-terminus of the RCC1 repeat showed a value of K(m) similar to that of wild-type RCC1, while the kcat values of these mutants were reduced, depending upon the RCC1 repeats on which the mutation was located. These steady-state kinetic parameters of mutants indicate that the N-terminus and the C-terminus of RCC1 repeats play different roles in guanine nucleotide exchange on Ran. The comparison of kcat among the histidine mutants suggests that those histidine residues which are conserved in the RCC1 repeats and also through evolution comprise the catalytic site for the guanine nucleotide exchange reaction.

Cell cycle-dependent specific positioning and clustering of centromeres and telomeres in fission yeast.

Fluorescence in situ hybridization (FISH) shows that fission yeast centromeres and telomeres make up specific spatial arrangements in the nucleus. Their positioning and clustering are cell cycle regulated. In G2, centromeres cluster adjacent to the spindle pole body (SPB), while in mitosis, their association with each other and with the SPB is disrupted. Similarly, telomeres cluster at the nuclear periphery in G2 and their associations are disrupted in mitosis. Mitotic centromeres interact with the spindle. They remain undivided until the spindle reaches a critical length, then separate and move towards the poles. This demonstrated, for the first time, that anaphase A occurs in fission yeast. The mode of anaphase A and B is similar to that of higher eukaryotes. In nda3 and cut7 mutants defective in tubulin of a kinesin-related motor, cells are blocked in early stages of mitosis due to the absence of the spindle, and centromeres dissociate but remain close to the SPB, whereas in a metaphase-arrested nuc2 mutant, they reside at the middle of the spindle. FISH is therefore a powerful tool for analyzing mitotic chromosome movement and disjunction using various mutants. Surprisingly, in top2 defective in DNA topoisomerase II, while most chromatid DNAs remain undivided, sister centromeres are separated. Significance of this finding is discussed. In contrast, most chromatid DNAs are separated but telomeric DNAs are not in cut1 mutant. In cut1, the dependence of SPB duplication on the completion of mitosis is abolished. In crm1 mutant cells defective in higher-order chromosome organization, the interphase arrangements of centromeres and telomeres are disrupted.

DNA-binding domain of RCC1 protein is not essential for coupling mitosis with DNA replication.

The RCC1 protein that is required for coupling mitosis with the S phase has a DNA-binding domain in the N-terminal region outside the repeat. We found that RCC1 protein without any DNA-binding activity complemented the tsBN2 mutation with the same efficiency as that of intact RCC1 protein. In ts+ transformants of tsBN2 cells transfected with the RCC1 cDNA lacking the DNA-binding domain, an endogenous RCC1 disappeared at 39.5 degrees C, and the deleted RCC1 protein encoded by the transfected cDNA was found in the cytoplasm, but a significant amount of it was also found in the nuclei. This deleted RCC1 protein was eluted from the nuclei with the same concentration of NaCl and DNase I as was used for the intact RCC1 protein in BHK21 cells. Furthermore, the deleted RCC1 protein co-migrated with the nucleosome fraction on sucrose density gradient analysis. These results indicate that the RCC1 protein binds chromatin with the aid of other unknown protein(s). Thus, the DNA-binding domain of RCC1 protein is not essential for coupling between the S and M phases, but was shown instead to function as a nuclear translocation signal.

Mitotic checkpoints.

Entry into mitosis is triggered by activation of maturation promoting factor and a complex of p34cdc2 kinase and cyclin B. Activation induces nuclear lamina breakdown, chromosome condensation and mitotic spindle assembly. Exit from mitosis is initiated by the degradation of cyclin B and the subsequent inactivation of maturation-promoting factor. A more thorough understanding of the checkpoints for initiation of and exit from mitosis has evolved during the past few years.

Visualization of centromeric and nucleolar DNA in fission yeast by fluorescence in situ hybridization.

The nucleolar and centromeric DNAs of the fission yeast Schizosaccharomyces pombe were visualized in the nucleus by fluorescence in situ hybridization using repetitive ribosomal and centromeric DNAs as the probes. The rDNAs were seen in the nuclear domain previously assigned as nucleolar, that is, the region into which the rod-like chromatin protrudes from the hemispherical chromosomal domain. Using mitotically-arrested cells containing condensed chromosomes, it was demonstrated that the rDNAs were present on the smallest chromosome III, consistent with genetic data. Using a centromeric repetitive element as the hybridization probe, the centromere of chromosome III, cen3, which contains the largest number of the repetitive elements, was visualized. The centromere in interphase cells is located near the periphery of the nucleus as a single dot. Early in mitosis, however, it divides into two and is situated in the middle of the short mitotic spindle. After spindle extension in anaphase, the centromeric DNA is present at both ends of the spindle, that is, near the spindle pole bodies. The movement of cen3 during mitosis (anaphase A and B) is discussed in relation to spindle dynamics and chromosome separation.

The fission yeast gamma-tubulin is essential for mitosis and is localized at microtubule organizing centers.

gamma-Tubulin exists in fission yeast as the product of an essential gene, encoding a 446 amino acid protein that is 77.3% identical to Aspergillus nidulans gamma-tubulin. The gene disruption caused cell lethality, displaying condensed, undivided chromosomes with aberrant spindle structures. Anti-gamma-tubulin staining showed that gamma-tubulin is located, throughout the wild-type cell cycle, at the spindle pole bodies (SPBs), indicating that gamma-tubulin associates with interphase SPB in the absence of microtubules. In addition, anti-gamma-tubulin immunofluorescence staining revealed cytoplasmic, cell-equatorial putative MTOCs (microtubule organizing centers), which appear only during mitotic telophase and cytokinesis, and are located at the centers for the new cytoplasmic microtubule arrays of the two daughter cells. In the multiple-SPB mutant cut1-cdc11, anti-gamma-tubulin antibodies revealed many dots on the periphery of the nucleus. These results confirm that gamma-tubulin is an important member of the tubulin superfamily, suggest that it may be a universal component of MTOCs, and are consistent with a role for gamma-tubulin in controlling microtubule formation in vivo.

The fission yeast cut1+ gene regulates spindle pole body duplication and has homology to the budding yeast ESP1 gene.

Mutations in the fission yeast cut1+, cut2+, and cut10+ genes uncouple normally coordinated mitotic events and deregulate, rather than arrest, mitosis. DNA synthesis continues, making polyploid nuclei with several spindles. Multiple, aberrant spindle pole bodies (SPBs) are produced in cut1 mutant cells. The cut1+ and cut2+ genes are cloned by transformation. High gene dosage of cut1+ also complements cut2 and cut10 mutants. The cut2+ gene, however, complements only cut2. The 210 kd cut1+ gene product contains putative ATP binding and helical coil regions followed by a COOH-terminal domain homologous to the S. cerevisiae gene ESP1. Mutations in the ESP1 gene also result in many SPBs. The cut1+ product is shown by anti-cut1 antibody to be a rare component of the insoluble nuclear fraction. It may play a key role in coupling chromosome disjunction with other cell cycle events and is potentially a component, regulator, or motor for the SPB and/or kinetochores.

Cloning and sequencing of Schizosaccharomyces pombe DNA topoisomerase I gene, and effect of gene disruption.

We cloned the structural gene topl+ for Schizosaccharomyces pombe DNA topoisomerase I (topo I) by hybridization. An eight-fold increase of topo I relaxing activity was obtained in S. pombe cells transformed with multicopy plasmid with topl+ insert. Nucleotide sequence determination showed a hypothetical coding frame interrupted by two short introns, encoding a 812 residue polypeptide (M.W. 94,000), 43 residues longer than and 47% homologous to Saccharomyces cerevisiae topo I. We show that the topl (null) strain made by gene disruption is viable, although its generation time is 20% longer than that of wild type. The topl locus is mapped in the long arm of chromosome II, using the Leu+ marker integrated with the cloned topl+ sequence. We constructed a double mutant topl (null) top2 (ts) and found its defective phenotype similar to that of previously obtained topl (heat sensitive) top2 (ts). The other double mutant topl (null) top2 (cs), however, was lethal. Our results suggest that topl+ gene of S. pombe is dispensable only if topo II activity is abundant.

A possible regulatory role of Ca++-calmodulin system in cellular cholesterol ester hydrolysis in the steroidogenic response to ACTH in bovine adrenocortical cells.

In order to corroborate the regulatory role of Ca++-calmodulin system in the steroidogenic response to adrenocorticotropic hormone (ACTH), the effects of calmodulin inhibitors (chlorpromazine, trifluoperazine, and W-7) on cortisol production and cellular cholesterol ester hydrolysis induced by ACTH in bovine adrenocortical cells were examined. Three calmodulin inhibitors diminished not only the cholesterol ester hydrolysis and cortisol production induced by ACTH in the presence of Ca++, but also inhibited the Ca++-induced hydrolysis and cortisol production in the absence of ACTH. Neither cortisol production in crude mitochondrial fraction nor the ACTH-induced Ca++-influx was affected by chlorpromazine. These results indicate that Ca++f-calmodulin system plays a significant regulatory role in the supply of free cholesterol to the adrenal mitochondria in the steroidogenic response to ACTH.