DNA degradation at unprotected telomeres in yeast is regulated by the CDK1 (Cdc28/Clb) cell-cycle kinase

In the absence of functional telomeric cap protection, the ends of eukaryotic chromosomes are subject to DNA damage responses that lead to cell-cycle arrest and, eventually, genomic instability. However, the controlling activities responsible for the initiation of genome instability on unprotected telomeres remained unclear. Here we show that in budding yeast, unprotected telomeres undergo a tightly cell-cycle-regulated DNA degradation. Ablation of the function of essential capping proteins Cdc13p or Stn1p only caused telomere degradation in G2/M, but not in G1 of the cell cycle. Accordingly, G1-arrested cells with unprotected telomeres remained viable, while G2/M-arrested cells failed to recover. The data also show that completion of S phase and the activity of the S-Cdk1 kinase were required for telomere degradation. These results strongly suggest that after a loss of the telomere capping function, telomere-led genome instability is caused by tightly regulated cellular DNA repair attempts.     

A novel repetitive DNA sequence in the genus Oryza

Summary Repetitive DNA sequences in the genus Oryza (rice) represent a large fraction of the nuclear DNA. The isolation and characterization of major repetitive DNA sequences will lead to a better understanding of rice genome organization and evolution. Here we report the characterization of a novel repetitive sequence, CC-1, from the CC genome. This repetitive sequence is present as long tandem arrays with a repeat unit 194 bp in length in the CC-diploid genome but 172 bp in length in the BBCC and CCDD tetraploid genomes. This repetitive sequence is also present, though at lower copy numbers, in the AA and BB genomes, but is absent in the EE and FF genomes. Hybridization experiments revealed considerable differences both in copy numbers and in restriction fragment patterns of CC-1 both between and within rice species. The results support the hypothesis that the CC genome is more closely related to the AA genome than to the BB genome, and most distantly related to the EE and FF genomes.     

A chromosome 5-specific repetitive DNA sequence in rice (Oryza sativa L)

Repetitive DNA sequences in the rice genome comprise more than half of the nuclear DNA. The isolation and characterization of these repetitive DNA sequences should lead to a better understanding of rice chromosome structure and genome organization. We report here the characterization and chromosome localization of a chromosome 5-specific repetitive DNA sequence. This repetitive DNA sequence was estimated to have at least 900 copies. DNA sequence analysis of three genomic clones which contain the repeat unit indicated that the DNA sequences have two sub-repeat units of 37 bp and 19 bp, connected by 30-to 90-bp short sequences with high similarity. RFLP mapping and physical mapping by fluorescence in situ hybridization (FISH) indicated that almost all copies of the repetitive DNA sequence are located in the centromeric heterochromatic region of the long arm of chromosome 5. The strategy for cloning such repetitive DNA sequences and their uses in rice genome research are discussed.     

Nucleotide sequence of the CLS4 (CDC24) gene of Saccharomyces cerevisiae

The nucleotide sequence of the CLS4 gene controlling Ca2+ regulatory process of bud emergence, which was cloned previously [Ohya et al., J. Bacteriol. 165 (1986) 28-33], was determined. The CLS4 (CDC24) locus encodes a protein consisting of 736 amino acid (aa) residues with an Mr of 83,970. By primer extension mapping, the mRNA start point was located 139 bp upstream from the translation start codon. The predicted CLS4 protein was hydrophilic with two serine + threonine-rich domains in the middle and C-terminal regions. It has two putative Ca2+-binding regions, one being partly homologous to the Ca2+-binding domain of the S-100a protein and the other that of alpha-lactalbumin.     

Preparation of product-specific antisera by gene fusion: antibodies specific for the product of the yeast cell-division-cycle gene CDC28

Antisera with specificity for the product of a yeast cell-division-cycle (CDC) gene were prepared by immunizing rabbits to a novel hybrid polypeptide. A segment of the yeast gene CDC28 was fused to the Escherichia coli lacZ gene, which encodes beta-galactosidase, by insertion of yeast sequences into the plasmid pBGF1. pBGF1 contains the lac promoter-operator and most of the lacZ gene. An EcoRI site, 16 codons upstream from the carboxyterminus of the beta-galactosidase coding region, served as a convenient splicing site for the heterologous sequences. To insure that an open reading frame be maintained between the two gene segments for some portion of the fusions, the CDC28-encoding segments were first subjected to limited digestion with nuclease BAL31 to produce random junction points. A hybrid polypeptide encoded by such a continuous open reading frame was purified from E. coli by preparative SDS-polyacrylamide gel electrophoresis and used to immunize rabbits. The resulting antisera were shown to have specificity for CDC28 gene product synthesized by cell-free translation of yeast mRNA.     

A new repetitive DNA sequence family in the olive (Olea europaea L.)

Two families of repeated DNA sequences were cloned from Olea europaea ssp sativa cv. "Picual". The first repetitive DNA is organized in a tandem repeat of monomers of 178 bp. Sequencing of several clones showed that it is relatively A-T rich (54.49%) and possesses short direct and inverted subrepeats as well as some palindromic sequences. Comparison between the monomers revealed heterogeneity of the sequence primary structure. This repetitive DNA is present in several cultivars of olive cultivates. Comparison of sequences with other repetitive DNAs described in Olea europaea has been carried out. No significant similarity was found. All the obtained results suggest that this repetitive DNA described here is a new family of repetitive DNA. The second repetitive DNA is organized in a tandem repeat of monomers of 78 bp. This second family of repetitive DNA showed significant similarity with other repetitive DNAs previously described in Olea europaea. Their existence in new cultivars of olive is shown.     

A pathway in the yeast cell division cycle linking protein kinase C (Pkc1) to activation of Cdc28 at START.

In an effort to study further the mechanism of Cdc28 function and cell cycle commitment, we describe here a genetic approach to identify components of pathways downstream of the Cdc28 kinase at START by screening for mutations that decrease the effectiveness of signaling by Cdc28. The first locus to be characterized in detail using this approach was PKC1 which encodes a homolog of the Ca(2+)-dependent isozymes of the mammalian protein kinase C (PKC) superfamily (Levin et al., 1990). By several genetic criteria, we show a functional interaction between CDC28 and PKC1 with PKC1 apparently functioning with respect to bud emergence downstream of START. Consistent with this, activity of the MAP kinase homolog Mpk1 (a putative Pkc1 effector) is stimulated by activation of Cdc28. Furthermore, we demonstrate a cell cycle-dependent hydrolysis of phosphatidylcholine to diacylglycerol (a PKC activator) and choline phosphate at START. Diacylglycerol production is stimulated by Cdc28 in cycling cells and is closely associated with Cdc28 activation at START. These results imply that the activation of Pkc1, which is known to be necessary during bud morphogenesis, is mediated via the CDC28-dependent stimulation of PC-PLC activity in a novel cell cycle-regulated signaling pathway.     

A unique repetitive DNA sequence in the Myxococcus xanthus genome.

We found a novel type of repetitive DNA sequence in the Myxococcus xanthus genome. The first repetitive sequence is located in the spacer region between the ops and tps genes. We cloned five other repetitive sequences using the first repetitive sequence as a probe and determined their nucleotide sequences. Comparison of these sequences revealed that the repetitive sequences consist of a 87-bp core sequence and that some clones share additional homology on their flanking regions.