A hyper-recombination mutation in S. cerevisiae identifies a novel eukaryotic topoisomerase

A hyper-recombination mutation was isolated that causes an increase in recombination between short repeated delta sequences surrounding the SUP4-omicron gene in S. cerevisiae. The wild-type copy of this gene was cloned by complementation of one of its pleiotropic phenotypes, slow growth. DNA sequence of the clone revealed a 656 amino acid open reading frame capable of encoding a protein homologous to the bacterial type I topoisomerase. No homology was detected with previously identified eukaryotic topoisomerases. Construction of double mutants with either of the two known yeast topoisomerase genes revealed synergistic effects on growth suggesting overlapping functions. Expression of bacterial topoisomerase I in yeast can fully complement the slow growth defect of a null mutation. We have named this locus TOP3 and suggest that it defines a novel eukaryotic topoisomerase gene.     

Cloning and sequence determination of the gene encoding the largest subunit of the fission yeast Schizosaccharomyces pombe RNA polymerase I

The gene encoding the largest subunit of RNA polymerase I (SPRPA190) was cloned from the fission yeast Schizosaccharomyces pombe by cross-hybridization with a probe containing part of the corresponding Saccharomyces cerevisiae gene RPA190. The SPRPA190 gene is present in a single copy per haploid genome and is essential for cell growth. The polypeptide encoded by this gene, as deduced from the nucleotide sequence of the uninterrupted coding frame, consists of 1689 amino acids and its calculated Mr is 189,300. The amino acid identity between the subunits of the two yeast species is 50%. Amino acid sequence conservation covers the regions previously suggested to be functionally important for the S. cerevisiae enzyme. In addition, two markedly hydrophilic regions recognized in the S. cerevisiae polypeptide can also be recognized in the S. pombe polypeptide in approximately the same positions, even though the amino acid sequences in these regions are diverged from each other. In the 5'-flanking region of the gene, several nucleotide sequence elements are detected which are also found in the two S. pombe ribosomal protein genes so far sequenced.     

Analysis of the alpha-amylase gene of Schwanniomyces occidentalis and the secretion of its gene product in transformants of different yeast genera

We have cloned and characterized the alpha-amylase gene (AMY1) of the yeast Schwanniomyces occidentalis. A cosmid gene library of S. occidentalis DNA was screened in Saccharomyces cerevisiae for alpha-amylase secretion. The positive clone contained a DNA fragment harbouring an open reading frame of 1536 nucleotides coding for a 512-amino-acid polypeptide with a calculated Mr of 56,500. The deduced amino acid sequence reveals significant similarity to the sequence of the Saccharomycopsis fibuligera and Aspergillus oryzae alpha-amylases. The AMY l gene was found to be expressed from its original promoter in S. cerevisiae, Kluyveromyces lactis and Schizo-saccharomyces pombe leading to an active secreted gene product and thus enabling the different yeast transformants to grow on starch as a sole carbon source.     

Evolutionary conservation of excision repair in Schizosaccharomyces pombe: evidence for a family of sequences related to the Saccharomyces cerevisiae RAD2 gene.

Cells mutated at the rad13 locus in the fission yeast, Schizosaccharomyces pombe are deficient in excision-repair of UV damage. We have cloned the S.pombe rad13 gene by its ability to complement the UV sensitivity of a rad13 mutant. The gene is not essential for cell proliferation. Sequence analysis of the cloned gene revealed an open reading-frame of 1113 amino acids with structural homology to the RAD2 gene of the distantly related Saccharomyces cerevisiae. The sequence similarity is confined to three domains, two close to the N-terminus of the encoded protein, the third being close to the C-terminus. The central region of about 500 amino acids shows little similarity between the two organisms. The first and third domains are also found in a related yet distinct pair of homologous S.pombe/S.cerevisiae DNA repair genes (rad2/YKL510), which have only a very short region between these two conserved domains. Using the polymerase chain reaction with degenerate primers, we have isolated fragments from a gene homologous to rad13/RAD2 from Aspergillus nidulans. These findings define new functional domains involved in excision-repair, as well as identifying a conserved family of genes related to RAD2.     

Topoisomerase III is essential for accurate nuclear division in Schizosaccharomyces pombe.

Topoisomerases catalyse changes in the topological state of DNA and are required for many aspects of DNA metabolism. While the functions of topoisomerases I and II in eukaryotes are well established, the role of topoisomerase III remains poorly defined. We have identified a gene in the fission yeast Schizosaccharomyces pombe, designated top3 (+), which shows significant sequence similarity to genes encoding topoisomerase III enzymes in other eukaryotic species. In common with murine TOP3 alpha, but in contrast to Saccharomyces cerevisiae TOP3, the S.pombe top3 (+)gene is essential for long-term cell viability. Fission yeast haploid spores containing a disrupted top3 (+)gene germinate successfully, but then undergo only a limited number of cell divisions. Analysis of these top3 mutants revealed evidence of aberrant mitotic chromosome segregation, including the 'cut' phenotype, where septation is completed prior to nuclear division. Consistent with the existence of an intimate association (originally identified in S.cerevisiae ) between topoisomerase III and DNA helicases of the RecQ family, deletion of the rqh1 (+)gene encoding the only known RecQ helicase in S.pombe suppresses lethality in top3 mutants. This conservation of genetic interaction between two widely diverged yeasts suggests that the RecQ family helicases encoded by the Bloom's and Werner's syndrome genes are likely to act in concert with topoisomerase III isozymes in human cells. Our data are consistent with a model in which the association of a RecQ helicase and topoisomerase III is important for facilitating decatenation of late stage replicons to permit faithful chromosome segregation during anaphase.     

Structural insights on the small subunit of DNA topoisomerase I from the unicellular parasite Leishmania donovani

Leishmania donovani, the causative organism of visceral leishmaniasis, contains a unique heterodimeric DNA topoisomerase IB (LdTop1). The catalytically active enzyme consists of a large subunit (LdTop1L), which contains the non-conserved N-terminal end and a phylogenetically conserved core domain, and of a small subunit (LdTop1S) which harbours the C-terminal region with a characteristic tyrosine residue in the active site. Heterologous co-expression of LdTop1L and LdTop1S in a topoisomerase I deficient yeast strain, reconstitutes a fully functional enzyme which can be used for structural studies. The role played by the non-conserved N-terminal extension of LdTop1S in both relaxation activity and CPT sensitivity of LdTop1 has been examined co-expressing the full-length LdTop1L with several deletions of LdTop1S lacking growing sequences of the N-terminal end. The sequential deletion study shows that the first 174 amino acids of LdTop1S are dispensable in terms of relaxation activity and DNA cleavage. It is also described that the trapping of the covalent complex between LdTop1 and DNA by CPT requires a pentapeptide between amino acid residues 175 and 179 of LdTop1S. Our results suggest the crucial role played by the N-terminal extension of the small subunit of DNA topoisomerase I.     

Organization, primary structure, and evolution of histone H2A and H2B genes of the fission yeast Schizosaccharomyces pombe.

The histone H2A and H2B genes of the fission yeast Schizosaccharomyces pombe were cloned and sequenced. Southern blot and sequence analyses showed that, unlike other eucaryotes, Saccharomyces cerevisiae included, S. pombe has unequal numbers of these genes, containing two histone H2A genes (H2A-alpha and -beta) and only one H2B gene (H2B-alpha) per haploid genome. H2A- and H2B-alpha are adjacent to each other and are divergently transcribed. H2A-beta has no other histone gene in close proximity. Preceding both H2A-alpha and -beta is a highly conserved 19-base-pair sequence (5'-CATCAC/AAACCCTAACCCTG-3'). The H2A DNA sequences encode two histone H2A subtypes differing in amino acid sequence (three residues) and size (H2A-alpha, 131 residues; H2A-beta, 130 residues). H2B-alpha codes for a 125-amino-acid protein. Sequence evolution is extensive between S. pombe and S. cerevisiae and displays unique patterns of divergence. Certain N-terminal sequences normally divergent between eucaryotes are conserved between the two yeasts. In contrast, the normally conserved hydrophobic core of H2A is as divergent between the yeasts as between S. pombe and calf.     

Resolution of Holliday junction substrates by human topoisomerase I

Prompted by the close relationship between tyrosine recombinases and type IB topoisomerases we have investigated the ability of human topoisomerase I to resolve the typical intermediate of recombinase catalysis, the Holliday junction. We demonstrate that human topoisomerase I catalyzes unidirectional resolution of a synthetic Holliday junction substrate containing two preferred cleavage sites surrounded by DNA sequences supporting branch migration. Deleting part of the N-terminal domain (amino acid residues 1-202) did not affect topoisomerase I resolution activity, whereas a topoisomerase I variant lacking both the N-terminal domain and amino acid residues 660-688 of the linker domain was unable to resolve the Holliday junction substrate. The inability of the double deleted variant to mediate resolution correlated with the inability of this enzyme to introduce concomitant cleavage at the two preferred cleavage sites in a single Holliday junction substrate, which is a prerequisite for resolution. As determined by the gel electrophoretic mobility of native enzyme or enzyme crosslinked by disulfide bridging, the double deleted mutant existed almost entirely in a dimeric form. The impairment of this enzyme in performing double cleavages on the Holliday junction substrate may be explained by only one cleavage competent active site being formed at a time within the dimer. The assembly of only one active site within dimers is a well-known characteristic of the tyrosine recombinases. Hence, the obtained results may suggest a recombinase-like active site assembly of the double deleted topoisomerase I variant. Taken together the presented results consolidate the relationship between type IB topoisomerases and tyrosine recombinases.     

Identification of the gene encoding DNA topoisomerase I from Candida albicans

Abstract A gene encoding a type I topoisomerase (TOP1) was isolated from Candida albicans , sequenced, and expressed in Saccharomyces cerevisiae . The TOP1 gene was identified from a C. albicans genomic library by hybridization with the product of a polymerase chain reaction with degenerate primer sets encoding regions conserved in other TOP1 genes. A clone containing an open reading frame of 2463 bp and predicted to encode a protein of 778 amino acids with sequence similarity to eukaryotic type I topoisomerases was identified. The C. albicans TOP1 gene restored camptothecin sensitivity and increased the topoisomerase activity in S. cerevisiae , indicating that the DNA fragment encodes a functional C. albicans topoisomerase I.     

Vacuolar protein sorting in fission yeast: cloning, biosynthesis, transport, and processing of carboxypeptidase Y from Schizosaccharomyces pombe.

PCR was used to isolate a carboxypeptidase Y (CPY) homolog gene from the fission yeast Schizosaccharomyces pombe. The cloned S. pombe cpy1+ gene has a single open reading frame, which encodes 950 amino acids with one potential N-glycosylation site. It appears to be synthesized as an inactive pre-pro protein that likely undergoes processing following translocation into appropriate intracellular organelles. The C-terminal mature region is highly conserved in other serine carboxypeptidases. In contrast, the N-terminal pro region containing the vacuolar sorting signal in CPY from Saccharomyces cerevisiae shows fewer identical residues. The pro region contains two unusual repeating sequences; repeating sequence I consists of seven contiguous repeating segments of 13 amino acids each, and repeating sequence II consists of seven contiguous repeating segments of 9 amino acids each. Pulse-chase radiolabeling analysis revealed that Cpy1p was initially synthesized in a 110-kDa pro-precursor form and via the 51-kDa single-polypeptide-chain intermediate form which has had its pro segment removed is finally converted to a heterodimer, the mature form, which is detected as a 32-kDa protein on sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions. Like S. cerevisiae CPY, S. pombe Cpy1p does not require the N-linked oligosaccharide moiety for vacuolar delivery. To investigate the vacuolar sorting signal of S. pombe Cpy1p, we have constructed cpy1+-SUC2 gene fusions that direct the synthesis of hybrid proteins consisting of N-terminal segments of various lengths of S. pombe Cpy1p fused to the secreted enzyme S. cerevisiae invertase. The N-terminal 478 amino acids of Cpy1 are sufficient to direct delivery of a Cpy1-Inv hybrid protein to the vacuole. These results showed that the pro peptide of Cpy1 contains the putative vacuolar sorting signal.     

The topoisomerase I gene from Ustilago maydis: sequence, disruption and mutant phenotype.

The Ustilago maydis genomic TOP1 gene encoding DNA topoisomerase I was cloned by amplifying a gene fragment using the polymerase chain reaction, and using this fragment to search a genomic DNA library by hybridization. The predicted peptide sequence exhibited 30-40% identity to other eukaryotic TOP1 genes, yet differed in several features. First, an unusually long acidic region was identified near the amino terminus (28/29 residues are acidic), which resembles other nucleolar peptide motifs. Second, an atypical carboxy-terminal 'tail', absent in other TOP1 genes, followed the active site tyrosine residue. A top1 gene disruption mutant was constructed by replacing the genomic TOP1 gene, with a top1::HygR null allele. This mutant lost the abundant topoisomerase I activity evident in wild-type U.maydis, and displayed a subtle coloration phenotype evident during cell senescence.     

Histone gene organization of fission yeast: a common upstream sequence.

Histone genes of the fission yeast Schizosaccharomyces pombe were cloned from Charon 4A and cosmid gene libraries by hybridization, and their nucleotide sequences were determined. The genome of S. pombe has a single, isolated H2A, a pair of H2A-H2B and three pairs of H3-H4 (one H2B, two H2A and three each of H3 and H4). This non-assorted histone gene organization is distinct from that of the budding yeast which has two pairs of H2A-H2B and H3-H4. The predicted amino acid sequences of S. pombe histone H2As, H3s and H4s were identical except for three residue changes in H2As. Compared with those os S. cerevisiae and human, variable residues were clustered near the NH2- and COOH-terminal regions of H2A and H2B. Sequence homologies to the two organisms were roughly the same in H2A (79-83%), H3 (92-93%) and H4 (91%), but differed in H2B (82% to S. cerevisiae and 68% to human). The coding sequences in pairs of S. pombe histone genes were divergently directed. A 17-bp long highly homologous sequence (AACCCT box) that had internal 6-bp direct repeats was present in the intergene spacer sequences or in the 5' upstream region of all the cloned histone genes. A possible regulatory role of the common upstream sequence for histone gene expression is discussed.     

Characterization of Exc,a novel protein required for the excision of Bacteroides conjugative transposon

Conjugative transposons are integrated elements that excise from the chromosome, then transfer by conjugation to a recipient in which they integrate once again. Recently, a gene, designated exc, was shown to be essential for excision of the Bacteroides conjugative transposon (CTnDOT) from the chromosome. The deduced amino acid sequence of Exc had low amino acid sequence similarity to DNA topoisomerase III, an enzyme that relaxes DNA supercoils. This similarity raised the question of whether Exc protein was a topoisomerase and, if so, whether topoisomerase activity might contribute to the excision process. Here, we demonstrate that Exc does have topoisomerase activity in vitro. Exc relaxed supercoiled DNA, had a conserved tyrosine as its active site and required magnesium ions for its relaxation activity. However, although mutation of the catalytic tyrosine of Exc to phenylalanine abolished the ability of the enzyme to relax DNA supercoils in vitro, the mutation did not abolish the ability of the protein to mediate excision in vivo. This surprising result suggests that CTnDOT excision does not rely on the topoisomerase activity of Exc in vivo.     

Cloning and sequencing of arg3 and arg11 genes of Schizosaccharomyces pombe on a 10-kb DNA fragment. Heterologous expression and mitochondrial targeting of their translation products.

The Schizosaccharomyces pombe arginine anabolic genes encoding ornithine carbamoyltransferase (arg3) and acetylglutamate kinase/acetylglutamyl-phosphate reductase (arg11) were cloned by functional complementation of S. pombe arg3 and arg11 mutant strains from S. pombe DNA genomic libraries. Restriction analysis and sequencing of the two clones showed that both genes are located on a common DNA fragment. The arg3 gene encodes a 327-amino-acid polypeptide presenting a strong identity to Saccharomyces cerevisiae and human ornithine carbamoyltransferases. The arg11 gene encodes a 884-amino-acid polypeptide. The acetylglutamate kinase and acetylglutamate-phosphate reductase domains have been defined by their identity with the S. cerevisiae ARG5,6 protein. The cloned arg11 gene from S. pombe does not complement an arg5,6 mutation in S. cerevisiae, nor does the ARG5,6 gene complement the S. pombe arg11- mutation. In contrast, both ornithine-carbamoyltransferase-encoding genes function in S. pombe. However, the S. pombe arg3 gene complements only weakly an arg3 S. cerevisiae strain, which is in agreement with the low level of expression of the S. pombe gene in S. cerevisiae. The subcellular localization of both ornithine carbamoyltransferases in the two yeasts indicates that, in contrast to the S. pombe enzyme, more than 95% of the S. cerevisiae enzyme remains in the S. pombe cytoplasm. The low expression of S. pombe ornithine carbamoyltransferases in S. cerevisiae did not allow its localization. The promoters of S. pombe arg3 and arg11 genes do not present striking similarities among themselves nor with the promoters of the equivalent genes of S. cerevisiae.     

The gamma subfamily of DNA polymerases: cloning of a developmentally regulated cDNA encoding Xenopus laevis mitochondrial DNA polymerase gamma.

We used the known sequence of the Saccharomyces cerevisiae DNA polymerase gamma to clone the genes or cDNAs encoding this enzyme in two other yeasts, Pychia pastoris and Schizosaccharomyces pombe, and one higher eukaryote, Xenopus laevis. To confirm the identity of the final X.laevis clone, two antisera raised against peptide sequences were shown to react with DNA polymerase gamma purified from X.laevis oocyte mitochondria. A developmentally regulated 4.6 kb mRNA is recognized on Northern blots of oocyte RNA using the X.laevis cDNA. Comparison of the four DNA polymerase gamma gene sequences revealed several highly conserved sequence blocks, comprising an N-terminal 3'-->5'exonuclease domain and a C-terminal polymerase active center interspersed with gamma-specific gene sequences. The consensus sequences for the DNA polymerase gamma exonuclease and polymerase domains show extensive sequence similarity to DNA polymerase I from Escherichia coli. Sequence conservation is greatest for residues located near the active centers of the exo and pol domains of the E.coli DNA polymerase I structure. The domain separating the exonuclease and polymerase active sites is larger in DNA polymerase gamma than in other members of family A (DNA polymerase I-like) polymerases. The S.cerevisiae DNA polymerase gamma is atypical in that it includes a 240 residue C-terminal extension that is not found in the other members of the DNA polymerase gamma family, or in other family A DNA polymerases.