Radiosensitive and mitotic recombination phenotypes of the Saccharomyces cerevisiae dun1 mutant defective in DNA damage-inducible gene expression.

The biological significance of DNA damage-induced gene expression in conferring resistance to DNA-damaging agents is unclear. We investigated the role of DUN1-mediated, DNA damage-inducible gene expression in conferring radiation resistance in Saccharomyces cerevisiae. The DUN1 gene was assigned to the RAD3 epistasis group by quantitating the radiation sensitivities of dun1, rad52, rad1, rad9, rad18 single and double mutants, and of the dun1 rad9 rad52 triple mutant. The dun1 and rad52 single mutants were similar in terms of UV sensitivities; however, the dun1 rad52 double mutant exhibited a synergistic decrease in UV resistance. Both spontaneous intrachromosomal and heteroallelic gene conversion events between two ade2 alleles were enhanced in dun1 mutants, compared to DUN1 strains, and elevated recombination was dependent on RAD52 but not RAD1 gene function. Spontaneous sister chromatid exchange (SCE), as monitored between truncated his3 fragments, was not enhanced in dun1 mutants, but UV-induced SCE and heteroallelic recombination were enhanced. Ionizing radiation and methyl methanesulfonate (MMS)-induced DNA damage did not exhibit greater recombinogenicity in the dun1 mutant compared to the DUN1 strain. We suggest that one function of DUN1-mediated DNA damage-induced gene expression is to channel the repair of UV damage into a nonrecombinogenic repair pathway.     

Cotransport of the heterodimeric small subunit of the Saccharomyces cerevisiae ribonucleotide reductase between the nucleus and the cytoplasm

Ribonucleotide reductase (RNR) catalyzes the rate-limiting step in de novo deoxyribonucleotide biosynthesis and is essential in DNA replication and repair. Cells have evolved complex mechanisms to modulate RNR activity during normal cell cycle progression and in response to genotoxic stress. A recently characterized mode of RNR regulation is DNA damage-induced RNR subunit redistribution. The RNR holoenzyme consists of a large subunit, R1, and a small subunit, R2. The Saccharomyces cerevisiae R2 is an Rnr2:Rnr4 heterodimer. Rnr2 generates a diferric-tyrosyl radical cofactor required for catalysis; Rnr4 facilitates cofactor assembly and stabilizes the resulting holo-heterodimer. Upon DNA damage, Rnr2 and Rnr4 undergo checkpoint-dependent, nucleus-to-cytoplasm redistribution, resulting in colocalization of R1 and R2. Here we present evidence that Rnr2 and Rnr4 are transported between the nucleus and the cytoplasm as one protein complex. Tagging either Rnr2 or Rnr4 with a nuclear export sequence causes cytoplasmic localization of both proteins. Moreover, mutations at the Rnr2:Rnr4 heterodimer interface can affect the localization of both proteins without disrupting the heterodimeric complex. Finally, the relocalization of Rnr4 appears to involve both active export and blockage of nuclear import. Our findings provide new insights into the mechanism of DNA damage-induced RNR subunit redistribution.     

The active form of the Saccharomyces cerevisiae ribonucleotide reductase small subunit is a heterodimer in vitro and in vivo

The class I ribonucleotide reductases (RNRs) are composed of two homodimeric subunits: R1 and R2. R2 houses a diferric-tyrosyl radical (Y*) cofactor. Saccharomyces cerevisiae has two R2s: Y2 (beta2) and Y4 (beta'2). Y4 is an unusual R2 because three residues required for iron binding have been mutated. While the heterodimer (betabeta') is thought to be the active form, several rnr4delta strains are viable. To resolve this paradox, N-terminally epitope-tagged beta and beta' were expressed in E. coli or integrated into the yeast genome. In vitro exchange studies reveal that when apo-(His6)-beta2 ((His)beta2) is mixed with beta'2, apo-(His)betabeta' forms quantitatively within 2 min. In contrast, holo-betabeta' fails to exchange with apo-(His)beta2 to form holo-(His)betabeta and beta'2. Isolation of genomically encoded tagged beta or beta' from yeast extracts gave a 1:1 complex of beta and beta', suggesting that betabeta' is the active form. The catalytic activity, protein concentrations, and Y* content of the rnr4delta and wild type (wt) strains were compared to clarify the role of beta' in vivo. The Y* content of rnr4delta is 15-fold less than that of wt, consistent with the observed low activity of rnr4delta extracts (<0.01 nmol min(-1) mg(-1)) versus wt (0.06 +/- 0.01 nmol min(-1) mg(-1)). (FLAG)beta2 isolated from the rnr4delta strain has a specific activity of 2 nmol min(-1) mg(-1), similar to that of reconstituted apo-(His)beta2 (10 nmol min(-1) mg(-1)), but significantly less than holo-(His)betabeta' (approximately 2000 nmol min(-1) mg(-1)). These studies together demonstrate that beta' plays a crucial role in cluster assembly in vitro and in vivo and that the active form of the yeast R2 is betabeta'.     

The bacteriophage T4 gene for the small subunit of ribonucleotide reductase contains an intron.

The bacteriophage T4 gene nrdB codes for the small subunit of the enzyme ribonucleotide reductase. The T4 nrdB gene was localized between 136.1 kb and 137.8 kb in the T4 genetic map according to the deduced structural homology of the protein to the amino acid sequence of its bacterial counterpart, the B2 subunit of Escherichia coli. This positions the C-terminal end of the T4 nrdB gene approximately 2 kb closer to the T4 gene 63 than earlier anticipated from genetic recombinational analyses. The most surprising feature of the T4 nrdB gene is the presence of an approximately 625 bp intron which divides the structural gene into two parts. This is the second example of a prokaryotic structural gene with an intron. The first prokaryotic intron was reported in the nearby td gene, coding for the bacteriophage T4-specific thymidylate synthase enzyme. The nucleotide sequence at the exon-intron junctions of the T4 nrdB gene is similar to that of the junctions of the T4 td gene: the anticipated exon-intron boundary at the donor site ends with a TAA stop codon and there is an ATG start codon at the putative downstream intron-exon boundary of the acceptor site. In the course of this work the denA gene of T4 (endonuclease II) was also located.     

Structure and function of the Saccharomyces cerevisiae CDC2 gene encoding the large subunit of DNA polymerase III.

Saccharomyces cerevisiae cdc2 mutants arrest in the S-phase of the cell cycle when grown at the non-permissive temperature, implicating this gene product as essential for DNA synthesis. The CDC2 gene has been cloned from a yeast genomic library in vector YEp13 by complementation of a cdc2 mutation. An open reading frame coding for a 1093 amino acid long protein with a calculated mol. wt of 124,518 was determined from the sequence. This putative protein shows significant homology with a class of eukaryotic DNA polymerases exemplified by human DNA polymerase alpha and herpes simplex virus DNA polymerase. Fractionation of extracts from cdc2 strains showed that these mutants lacked both the polymerase and proofreading 3'-5' exonuclease activity of DNA polymerase III, the yeast analog of mammalian DNA polymerase delta. These studies indicate that DNA polymerase III is an essential component of the DNA replication machinery.     

mRNA capping enzyme. Isolation and characterization of the gene encoding mRNA guanylytransferase subunit from Saccharomyces cerevisiae.

The highly purified yeast mRNA capping enzyme is composed of two separate chains of 52 (alpha) and 80 kDa (beta), responsible for the activities of mRNA guanylyltransferase and RNA 5'-triphosphatase, respectively (Itoh, N., Yamada, H., Kaziro, Y., and Mizumoto, K. (1987) J. Biol. Chem. 262, 1989-1995). The gene encoding the mRNA guanylyltransferase subunit (alpha subunit), CEG1, has been isolated by immunological screening of a yeast genomic expression library in lambda gt11 with polyclonal antibodies directed against purified yeast capping enzyme. The identity of CEG1 was confirmed by epitope selection and by expressing the gene in Escherichia coli to give a catalytically active mRNA guanylyltransferase. The gene is present in one copy per haploid genome, and encodes a polypeptide of 459 amino acid residues. From its primary structure as well as its mRNA size, it was concluded that the alpha and the beta subunits of yeast mRNA capping enzyme are encoded by two separate genes, not as a fused protein. CEG1 is located on the chromosome VII by a pulse-field gel electrophoresis. Gene disruption experiment indicated that CEG1 is essential for the growth of yeast. We have also found another open reading frame (ORF2) which lies in close proximity to CEG1 in our clones and encodes a 450 amino acid-polypeptide of yet unknown function.     

cDNA sequence of the small subunit of the hamster ribonucleotide reductase.

Ribonucleotide reductase activity is markedly elevated in cell lines selected for resistance to hydroxyurea, a cytotoxic drug known specifically to inhibit ribonucleotide reductase. From a cDNA library constructed from a highly hydroxyurea-resistant hamster lung cell line, 600H in which the activity is elevated more than 80-fold, we have isolated a full length cDNA for the small subunit of the reductase. The cDNA is 3.48 kb long with an open reading frame of 1158 nucleotides and a long 3' flanking region of 2169 nucleotides from the termination codon. The derived polypeptide sequence is closely similar to the small subunit of the mouse, differing from it in 20 amino acid positions. Most of these replacements occur in the N-terminal segment of the protein. The hamster subunit does not contain 4 amino acid residues found in the mouse small subunit near the C-terminal end. RNA blots probed with the cDNA show two poly(A)+ RNA species which are elevated in hydroxyurea-resistant cells.     

Molecular cloning of chromosome I DNA from Saccharomyces cerevisiae: isolation of the ADE1 gene.

The ADE1 gene of Saccharomyces cerevisiae was isolated by complementation in S. cerevisiae from a yeast genomic DNA library carried on plasmid YEp13. Electron microscopy of R-loop-containing DNA indicated the location of the ADE1 gene on the plasmid insert. Gene disruption and gene replacement were used to demonstrate that the ade1-complementing sequence was the actual ADE1 gene that maps on chromosome I. ade1 strains which normally form red colonies form white ones when transformed with the cloned ADE1 gene. This property should be very useful, since it enables detection of plasmids carrying this gene under nonselective conditions.     

Identification, isolation, and overexpression of the gene encoding the psi subunit of DNA polymerase III holoenzyme.

The gene encoding the psi subunit of DNA polymerase III holoenzyme, holD, was identified and isolated by an approach in which peptide sequence data were used to obtain a DNA hybridization probe. The gene, which maps to 99.3 centisomes, was sequenced and found to be identical to a previously uncharacterized open reading frame that overlaps the 5' end of rimI by 29 bases, contains 411 bp, and is predicted to encode a protein of 15,174 Da. When expressed in a plasmid that also expressed holC, holD directed expression of the psi subunit to about 3% of total soluble protein.     

Mutation of the gene encoding protein kinase C 1 stimulates mitotic recombination in Saccharomyces cerevisiae.

We have isolated a recessive allele of the yeast protein kinase C gene (PKC1) which promotes an elevated rate of mitotic recombination and confers a temperature-sensitive growth defect. The rate of recombination was increased between genes in direct repeat and at a series of heteroalleles and was dependent upon the RAD52 gene product. The mutant pkc1 allele was sequenced and found to encode a single amino acid change within the catalytic domain. Osmotic stabilizing agents rescued the temperature-sensitive growth defect but not the hyperrecombination phenotype, indicating that the two traits are separable. This separability suggests that the PKC1 gene product (Pkc1p) regulates DNA metabolism by an alternate pathway to that used in the regulation of cell lysis. The regulation of recombination is a previously unidentified role for Pkc1p.     

Reduced forms of the iron-containing small subunit of ribonucleotide reductase from Escherichia coli

The B2 subunit of ribonucleotide reductase from Escherichia coli contains a stable tyrosyl free radical and an antiferromagnetically coupled dimeric iron center with high-spin ferric ions. The tyrosyl radical is an oxidized form of tyrosine-122. This study shows that the B2 protein has a fully reduced state, denoted reduced B2, characterized by a normal nonradical tyrosine-122 residue and a dimeric ferrous iron center. Reduced B2 can be formed either from active B2 by a three-electron reduction in the presence of suitable mediators or from apoB2 by addition of two equimolar amounts of ferrous ions in the absence of oxygen. The oxidized tyrosyl radical and the ferric iron center can be generated from reduced B2 by the admission of air. The tyrosyl radical can be selectively reduced by one-electron reduction in the presence of a suitable mediator, yielding metB2, a form that seems identical with the form resulting from treatment of active B2 with hydroxyurea. 1H NMR was used to characterize the paramagnetically shifted resonances associated with the reduced iron center. Prominent resonances were observed around 45 ppm (nonexchangeable with solvent) and 57 ppm (exchangeable with solvent) at 37 degrees C. From the temperature dependence of the chemical shifts of these resonances it was concluded that the ferrous ions in reduced B2 are only weakly, if at all, antiferromagnetically coupled. By comparison with data on the similar iron center of deoxyhemerythrin it is suggested that the 57 ppm resonance should be assigned to protons in histidine ligands of the iron center.