RAD4 gene of Saccharomyces cerevisiae: molecular cloning and partial characterization of a gene that is inactivated in Escherichia coli

The NER protein Rad33 shows functional homology to human Centrin2 and is involved in modification of Rad4

In the yeast Saccharomyces cerevisiae the Rad4-Rad23 complex is implicated in the initial damage recognition of the Nucleotide Excision Repair (NER) pathway. NER removes a variety of lesions via two subpathways: Transcription Coupled Repair (TCR) and Global Genome Repair (GGR). We previously showed that the new NER protein Rad33 is involved in both NER subpathways TCR and GGR. In the present study we show UV induced modification of Rad4 that is strongly increased in cells deleted for RAD33. Modification of Rad4 in rad33 cells does not require the incision reaction but is dependent on the TCR factor Rad26. The predicted structure of Rad33 shows resemblance to the Centrin homologue Cdc31. In human cells, Centrin2 binds to XPC and is involved in NER. We demonstrate that Rad4 binds Rad33 directly and via the same conserved amino acids required for the interaction of XPC with Centrin2. Disruption of the Rad4-Rad33 interaction is sufficient to enhance the modification of Rad4 and results in a repair defect similar to that of a rad33 mutant. The current study suggests that the role of Rad33 in the Rad4-Rad23 complex might have parallels with the role of Centrin2 in the XPC-HHR23B complex.

Preferential binding of yeast Rad4.Rad23 complex to damaged DNA

The yeast Rad4 and Rad23 proteins form a complex that is involved in nucleotide excision repair (NER). Their function in this process is not known yet, but genetic data suggest that they act in an early step in NER. We have purified an epitope-tagged Rad4.Rad23 (tRad4. Rad23) complex from yeast cells, using a clone overproducing Rad4 with a hemagglutinin-tag at its C terminus. tRad4.Rad23 complex purified by both conventional and immuno-affinity chromatography complements the in vitro repair defect of rad4 and rad23 mutant extracts, demonstrating that these proteins are functional in NER. Using electrophoretic mobility shift assays, we show preferential binding of the tRad4.Rad23 complex to damaged DNA in vitro. UV-irradiated, as well as N-acetoxy-2-(acetylamino)fluorene-treated DNA, is efficiently bound by the protein complex. These data suggest that Rad4.Rad23 interacts with DNA damage during NER and may play a role in recognition of the damage.

A fragment of the yeast DNA repair protein Rad4 confers toxicity to E. coli and is required for its interaction with Rad7 protein

The RAD4 gene of Saccharomyces cerevisiae is required for the incision of damaged DNA during nucleotide excision repair. Plasmids carrying the wild-type RAD4 gene cannot be propagated in Escherichia coli. In this study, a rad4 mutant that can be grown in E. coli was isolated. This rad4 allele is deleted of a large positively charged segment of the RAD4 coding region which is toxic to E. coli when expressed alone. The deletion mutant retains its ability to interact with Rad23 protein but not with Rad7 protein and is defective in nucleotide excision repair. The smallest Rad4 fragment that is toxic to E. coli consists of 336 amino acids with a calculated pI=9.99.

The nucleotide sequence of Saccharomyces cerevisiae chromosome V

Here we report the sequence of 569,202 base pairs of Saccharomyces cerevisiae chromosome V. Analysis of the sequence revealed a centromere, two telomeres and 271 open reading frames (ORFs) plus 13 tRNAs and four small nuclear RNAs. There are two Tyl transposable elements, each of which contains an ORF (included in the count of 271). Of the ORFs, 78 (29%) are new, 81 (30%) have potential homologues in the public databases, and 112 (41%) are previously characterized yeast genes.

The HMG-domain protein Ixr1 blocks excision repair of cisplatin-DNA adducts in yeast

Ixr1 is a yeast HMG-domain protein which binds the major DNA adducts of the antitumor drug cisplatin. Previous work demonstrated that Saccharomyces cerevisiae cells lacking the IXR1 gene were two-fold less sensitive to cisplatin treatment than wild-type cells, and the present investigation reveals a six-fold difference in yeast having a different background. The possibility that the lower cytotoxicity of cisplatin in the ixr1 strain is the result of enhanced repair was investigated in rad1, rad2, rad4, rad6, rad9, rad10, rad14 and rad52 backgrounds. In three of the excision repair mutants, rad2, rad4 and rad14, the differential sensitivity caused by removing the Ixr1 protein was nearly abolished. This result demonstrates that the greater cisplatin resistance in the ixr1 strain is most likely a consequence of excision repair, supporting the theory that Ixr1 and other HMG-domain proteins can block repair of the major cisplatin-DNA adducts in vivo. The differential sensitivity of wild-type cells and those lacking Ixr1 persisted in the rad1 and rad10 strains, however, indicating that these two proteins act at a stage in the excision repair pathway where damage recognition is less critical. A model is proposed to account for these results, which is strongly supported recently identified functional roles for the rad excision repair gene products. A rad52 mutant was more sensitive to cisplatin than the RAD52 parental strain, which reveals that Rad52, a double-strand break repair protein, repairs cisplatin-DNA adducts, probably interstrand cross-links. A rad52 ixr1 strain was less sensitive to cisplatin than the rad52 IXR1 strain, consistent with Ixr1 not blocking repair of cisplatin adducts removed by Rad52 rad6 strains behaved similarly, except they were both substantially more sensitive to cisplatin. Interruption of the RAD9 gene, which is involved in DNA-damage-induced cell cycle arrest, had no affect on cisplatin cytotoxicity.

Physical maps of the six smallest chromosomes of Saccharomyces cerevisiae at a resolution of 2.6 kilobase pairs

Physical maps of the six smallest chromosomes of Saccharomyces cerevisiae are presented. In order of increasing size, they are chromosomes I, VI, III, IX, V and VIII, comprising 2.49 megabase pairs of DNA. The maps are based on the analysis of an overlapping set of lambda and cosmid clones. Overlaps between adjacent clones were recognized by shared restriction fragments produced by the combined action of EcoRI and HindIII. The average spacing between mapped cleavage sites is 2.6 kb. Five of the six chromosomes were mapped from end to end without discontinuities; a single internal gap remains in the map of chromosome IX. The reported maps span an estimated 97% of the DNA on the six chromosomes; nearly all the missing segments are telomeric. The maps are fully cross-correlated with the previously published SfiI/NotI map of the yeast genome by A. J. Link and M. V. Olson. They have also been cross-correlated with the yeast genetic map at 51 loci.

Identification of nuclear genes which participate to mitochondrial translation in Saccharomyces cerevisiae

The mitochondrial protein synthesis presents specific features and uses specific components different from their cytoplasmic counterparts. Since most genes which code for these components are localized in the chromosomes and only a small number are encoded by the mitochondrial DNA, it is important to identify and characterize the nuclear genes involved in this process. In order to do this, we have used a genetic screening which implies the selection and study of nuclear suppressors of mitochondrial mutations (or the reverse situation) which affect the mitochondrial protein synthesis. Three mutations have been used for this purpose. Two of them (ts 1398, cs 909) impair the mitochondrial ribosome; they were used to characterize new interacting components as well as two genes, MBR1 and MBR2, which control the assembly or the regulation of other genes involved in mitochondrial protein synthesis. The third mutation (ts 932), blocks the 3'-end maturation of the mitochondrial aspartyl tRNA. A nuclear suppressor has been obtained which presents all the characteristics of a mutation in the gene encoding the enzyme responsible for this process.

A yeast origin of replication is activated late in S phase

The mechanism that causes large regions of eukaryotic chromosomes to remain unreplicated until late in S phase is not understood. We have found that 67 kb of telomere-adjacent DNA at the right end of chromosome V in S. cerevisiae is replicated late in S phase. An ARS element in this region, ARS501, was shown by two-dimensional gel analysis to be an active origin of replication. Kinetic analyses indicate that the rate of replication fork movement within this late region is similar to that in early replicating regions. Therefore, the delayed replication of the region is a consequence of late origin activation. The results also support the idea that the pattern of interspersed early and late replication along the chromosomes of higher eukaryotes is a consequence of the temporal regulation of origin activation.

Applications of high efficiency lithium acetate transformation of intact yeast cells using single-stranded nucleic acids as carrier

The highly efficient yeast lithium acetate transformation protocol of Schiestl and Gietz (1989) was tested for its applicability to some of the most important needs of current yeast molecular biology. The method allows efficient cloning of genes by direct transformation of gene libraries into yeast. When a random gene pool ligation reaction was transformed into yeast, the LEU2, HIS3, URA3, TRP1 and ARG4 genes were found among the primary transformants at a frequency of approximately 0.1%. The RAD4 gene, which is toxic to Escherichia coli, was also identified among the primary transformants of a ligation library at a frequency of 0.18%. Non-selective transformation using this transformation protocol was shown to increase the frequency of gene disruption three-fold. Co-transformation showed that 30-40% of the transformation-competent cells take up more than one DNA molecule which can be used to enrich for integration and deletion events 30- to 60-fold. Co-transformation was used in the construction of simultaneous double gene disruptions as well as disrupting both copies of one gene in a diploid which occurred at 2-5% the frequency of the single event.

Characterization of RAD4 gene required for ultraviolet-induced excision repair of Saccharomyces cerevisiae propagated in Escherichia coli without inactivation

The previously isolated RAD4 gene designated as pPC1 from the genomic library of Saccharomyces cerevisiae (Yoon et al., 1985, Korean J. Genetics 7, 97-104) appeared to propagate in Escherichia coli and yet retained its complementing activity to rad4 mutants without inactivation. The subcloned RAD4 gene was found to be localized within a 2.5 kb DNA fragment flanking Bg1II and BamHI sites in the insert DNA, and was shown to have the same restriction map as a yeast chromosomal DNA, as determined by Southern hybridization. Tetrad analysis and pulse-field chromosome mapping have revealed that the cloned RAD4 gene can be mapped and integrated into the yeast chromosome V, the actual site of this gene. DNA-tRNA hybridization has shown that the isolated RAD4 gene did not contain a suppressor tRNA gene. These results have indicated that the pPC1 is a functional RAD4 gene playing a unique role involved in the nucleotide excision repair of yeast without any genetic change during amplification in E. coli.

Cloning of the DNA repair gene, uvsF, by transformation of Aspergillus nidulans

As a first step in the cloning of the DNA repair gene uvsF of Aspergillus nidulans, uvsF pyrG double mutant strains were transformed with a genomic library which carried the complementing Neurospora pyr-4 gene in the vector. Rare pyr+ uvs+ cotransformants were obtained on media lacking pyrimidines, overlayed with MMS (methyl-methane sulfonate) to which uvsF is hypersensitive. Among MMS-resistant transformants, Southerns revealed two types which showed single bands of different sizes when BglII-digested genomic DNA was probed with the vector. Both types produced uvsF- recombinants without vector sequences in homozygous crosses, but only those with the larger band also produced haploid uvs+ progeny. Using BglII-digested genomic DNA to transform Escherichia coli, plasmids of the corresponding two sizes could be rescued. Their inserts had a short internal region in common, giving evidence of rearrangement(s). In secondary transformation of uvsF mutants, only the plasmids with the larger insert showed complementation and these were used to screen Aspergillus libraries. Three types of genomic and two overlapping cDNA clones were identified. The cDNAs hybridized not only to each other, but also to the common region of the rescued plasmids. Therefore, cDNA subclones were used to map the putative uvsF sequences to a short segment in one genomic clone. In Northerns, the complementing large plasmid hybridized to three mRNAs, while the cDNA subclone identified one of these as the probable uvsF message.

Nucleotide sequence of the wild-type RAD4 gene of Saccharomyces cerevisiae and characterization of mutant rad4 alleles

Shuttle plasmids carrying the wild-type RAD4 gene of Saccharomyces cerevisiae cannot be propagated in Escherichia coli (R. Fleer, W. Siede, and E. C. Friedberg, J. Bacteriol. 169:4884-4892, 1987). In order to determine the nucleotide sequence of the cloned gene, we used a plasmid carrying a mutant allele that allows plasmid propagation in E. coli. The wild-type sequence in the region of this mutation was determined from a second plasmid carrying a different mutant rad4 allele. We established the locations and characteristics of a number of spontaneously generated plasmid-borne RAD4 mutations that alleviate the toxicity of the wild-type gene in E. coli and of several mutagen-induced chromosomal mutations that inactivate the excision repair function of RAD4. These mutations are situated in very close proximity to each other, and all are expected to result in the expression of truncated polypeptides missing the carboxy-terminal one-third of the Rad4 polypeptide. This region of the gene may be important both for the toxic effect of the Rad4 protein in E. coli and for its role in DNA repair in S. cerevisiae.

Cloning and nucleotide sequence analysis of the Saccharomyces cerevisiae RAD4 gene required for excision repair of UV-damaged DNA

The RAD4 gene of Saccharomyces cerevisiae is required for the incision step of excision repair. We have cloned the RAD4 gene and determined its nucleotide sequence. RAD4 encodes a somewhat basic protein of 754 amino acids (aa) with an Mr of 87,173. RAD4 contains several groups of 4-7 consecutive basic aa residues that could be involved in DNA binding and it also contains an alpha-helix-turn-alpha-helix motif for DNA binding. Like several other DNA repair proteins of S. cerevisiae, the C terminus of RAD4 protein is highly acidic.

The molecular genetics of the incision step in the DNA excision repair process

This review describes the evolution of research into the genetic basis of how different organisms use the process of excision repair to recognize and remove lesions from their cellular DNA. One particular aspect of excision repair, DNA incision, and how it is controlled at the genetic level in bacteriophage, bacteria, S. cerevisae, D. melanogaster, rodent cells and humans is examined. In phage T4, DNA is incised by a DNA glycosylase-AP endonuclease that is coded for by the denV gene. In E. coli, the products of three genes, uvrA, uvrB and uvrC, are required to form the UVRABC excinuclease that cleaves DNA and releases a fragment 12-13 nucleotides long containing the site of damage. In S. cerevisiae, genes complementing five mutants of the RAD3 epistasis group, rad1, rad2, rad3, rad4 and rad10 have been cloned and analyzed. Rodent cells sensitive to a variety of mutagenic agents and deficient in excision repair are being used in molecular studies to identify and clone human repair genes (e.g. ERCC1) capable of complementing mammalian repair defects. Most studies of the human system, however, have been done with cells isolated from patients suffering from the repair defective, cancer-prone disorder, xeroderma pigmentosum, and these cells are now beginning to be characterized at the molecular level. Studies such as these that provide a greater understanding of the genetic basis of DNA repair should also offer new insights into other cellular processes, including genetic recombination, differentiation, mutagenesis, carcinogenesis and aging.

Overexpression of the RAD2 gene of S. cerevisiae: identification and preliminary characterization of Rad2 protein

The cloned RAD2 gene of S. cerevisiae was tailored into regulatable expression vectors for overexpression of Rad2 protein in E. coli and in yeast. In E. coli both Rad2/beta-galactosidase fusion protein and native Rad2 protein are insoluble, but are extractable with 1% Sarkosyl. In yeast some of the overexpressed native Rad2 protein is also insoluble; however, soluble protein is readily detected by immunoblotting with Rad2-specific antibodies. All forms of the protein detected in transformed or untransformed yeast cells and the insoluble species in E. coli migrate in denaturing polyacrylamide gels with an apparent molecular weight considerably larger than the size predicted from the sequence of the RAD2 coding region. This property is not the result of post-translational glycosylation detectable by binding of concanavalin A, or of phosphorylation of the protein. Overexpression of the RAD2 gene is toxic to yeast. Transformed yeast cells grow much more slowly than untransformed controls and when yeast transformants are serially propagated cultures show considerably colony heterogeneity and concomitant selection for rapidly growing variants which express less Rad2 protein. Antisera raised against Rad2/beta-galactosidase fusion protein expressed in E. coli do not cross-react with Rad1, Rad3 or Rad10 protein in crude extracts of yeast, nor with purified E. coli UvrA, UvrB or UvrC proteins.