Induction of yeast DNA ligase genes in exponential and stationary phase cultures in response to DNA damaging agents

Mitochondrial DNA ligase function in Saccharomyces cerevisiae

The Saccharomyces cerevisiae CDC9 gene encodes a DNA ligase protein that is targeted to both the nucleus and the mitochondria. While nuclear Cdc9p is known to play an essential role in nuclear DNA replication and repair, its role in mitochondrial DNA dynamics has not been defined. It is also unclear whether additional DNA ligase proteins are present in yeast mitochondria. To address these issues, mitochondrial DNA ligase function in S.cerevisiae was analyzed. Biochemical analysis of mitochondrial protein extracts supported the conclusion that Cdc9p was the sole DNA ligase protein present in this organelle. Inactivation of mitochondrial Cdc9p function led to a rapid decline in cellular mitochondrial DNA content in both dividing and stationary yeast cultures. In contrast, there was no apparent defect in mitochondrial DNA dynamics in a yeast strain deficient in Dnl4p (Deltadnl4). The Escherichia coli ECO:RI endonuclease was targeted to yeast mitochondria. Transient expression of this recombinant ECO:RI endonuclease led to the formation of mitochondrial DNA double-strand breaks. While wild-type and Deltadnl4 yeast were able to rapidly recover from this mitochondrial DNA damage, clones deficient in mitochondrial Cdc9p were not. These results support the conclusion that yeast rely upon a single DNA ligase, Cdc9p, to carry out mitochondrial DNA replication and recovery from both spontaneous and induced mitochondrial DNA damage.

The yeast CDC9 gene encodes both a nuclear and a mitochondrial form of DNA ligase I

BACKGROUND

The yeast CDC9 gene encodes a DNA ligase I activity required during nuclear DNA replication to ligate the Okazaki fragments formed when the lagging DNA strand is synthesised. The only other DNA ligase predicted from the yeast genome sequence, DNL4/LIG4, is specifically involved in a non-homologous DNA end-joining reaction. What then is the source of the DNA ligase activity required for replication of the yeast mitochondrial genome?

RESULTS

We report that CDC9 encodes two distinct polypeptides expressed from consecutive in-frame AUG codons. Translational initiation at these two sites gives rise to polypeptides differing by a 23 residue amino-terminal extension, which corresponds to a functional mitochondrial pre-sequence sufficient to direct import into yeast mitochondria. Initiation at the first AUG codon results in a 755 amino-acid polypeptide that is imported into mitochondria, whereupon the pre-sequence is proteolytically removed to yield the mature mitochondrial form of Cdc9p. Initiation at the second AUG codon produces a 732 amino-acid polypeptide, which is localised to the nucleus. Cells expressing only the nuclear isoform were found to be specifically defective in the maintenance of the mitochondrial genome.

CONCLUSIONS

CDC9 encodes two distinct forms of DNA ligase I. The first is targeted to the mitochondrion and is required for propagation and maintenance of mitochondrial DNA, the second localises to the nucleus and is sufficient for the essential cell-division function associated with this gene.

Structural and functional architecture of the yeast cell-cycle transcription factor swi6

The structural and functional organisation of Swi6, a transcriptional regulator of the budding yeast cell cycle has been analysed by a combination of biochemical, biophysical and genetic methods. Limited proteolysis indicates the presence of a approximately 15 kDa N-terminal domain which is dispensable for Swi6 activity in vivo and which is separated from the rest of the molecule by an extended linker of at least 43 residues. Within the central region, a 141 residue segment that is capable of transcriptional activation encompasses a structural domain of approximately 85 residues. In turn, this is tightly associated with an adjacent 28 kDa domain containing at least four ankyrin-repeat (ANK) motifs. A second protease sensitive region connects the ANK domain to the remaining 30 kDa C-terminal portion of Swi6 which contains a second transcriptional activator and sequences required for heteromerisation with Swi4 or Mbp1. Transactivation by the activating regions of Swi6 is antagonised when either are combined with the central ankyrin repeat motifs. Hydrodynamic measurements indicate that an N-terminal 62 kDa fragment comprising the first three domains is monomeric in solution and exhibits an unusually high frictional coefficient consistent with the extended, multi-domain structure suggested by proteolytic analysis.

Thylacine 1 is expressed segmentally within the paraxial mesoderm of the Xenopus embryo and interacts with the Notch pathway

The presomitic mesoderm of vertebrates undergoes a process of segmentation in which cell-cell interactions mediated by the Notch family of receptors and their associated ligands are involved. The vertebrate homologues of Drosophila Δ are expressed in a dynamic, segmental pattern within the presomitic mesoderm, and alterations in the function of these genes leads to a perturbed pattern of somite segmentation. In this study we have characterised Thylacine 1 which encodes a basic helix-loop-helix class transcription activator. Expression of Thylacine is restricted to the presomitic mesoderm, localising to the anterior half of several somitomeres in register with domains of X-Delta-2 expression. Ectopic expression of Thylacine in embryos causes segmentation defects similar to those seen in embryos in which Notch signalling is altered, and these embryos also show severe disruption in the expression patterns of the marker genes X-Delta-2 and X-ESR5 within the presomitic mesoderm. Finally, the expression of Thylacine is altered in embryos when Notch signalling is perturbed. These observations suggest strongly that Thylacine 1 has a role in the segmentation pathway of the Xenopus embryo, by interacting with the Notch signalling pathway.

Molecular cloning and functional analysis of the Arabidopsis thaliana DNA ligase I homologue

A cDNA encoding the DNA ligase I homologue has been isolated from Arabidopsis thaliana using a degenerate PCR approach. The ORF of this cDNA encodes an amino acid sequence of 790 residues, representing a protein with a theoretical molecular mass of 87.8 kDa and an isoelectric point (pi) of 8.20. Alignment of the A. thaliana DNA ligase protein sequence with the sequence of DNA ligases from human (Homo sapiens), murine (Mus musculus), clawed toad (Xenopus laevis) and the yeasts Schizosaccharomyces pombe and Saccharomyces cerevisiae showed good sequence homology (42-45% identity, 61-66% similarity), particularly around the active site. Sequence data indicate that the Arabidopsis DNA ligase is the homologue of the animal DNA ligase I species. Functional analysis of the cDNA clone demonstrated its ability to complement the conditional lethal phenotype of an S. cerevisiae cdc9 mutant defective in DNA ligase activity, confirming that the cloned sequence encodes an active DNA ligase. The level of the DNA ligase transcript was not increased in A. thaliana seedlings in response to DNA damage induced by a period of enhanced UV-B irradiation. However, the cellular level of the DNA ligase mRNA transcript does correlate with the replicative state of plant cells.

DNA polymerase delta isolated from Schizosaccharomyces pombe contains five subunits

DNA polymerase delta (pol delta) plays an essential role in DNA replication, repair, and recombination. We have purified pol delta from Schizosaccharomyces pombe more than 10(3)-fold and demonstrated that the polymerase activity of purified S. pombe pol delta is completely dependent on proliferating cell nuclear antigen and replication factor C. SDS/PAGE analysis of the purified fraction indicated that the pol delta complex consists of five subunits that migrate with apparent molecular masses of 125, 55, 54, 42, and 22 kDa. Western blot analysis indicated that the 125, 55, and 54 kDa proteins are the large catalytic subunit (Pol3), Cdc1, and Cdc27, respectively. The identity of the other two subunits, p42 and p22, was determined following proteolytic digestion and sequence analysis of the resulting peptides. The peptide sequences derived from the p22 subunit indicated that this subunit is identical to Cdm1, previously identified as a multicopy suppressor of the temperature-sensitive cdc1-P13 mutant, whereas peptide sequences derived from the p42 subunit were identical to a previously uncharacterized ORF located on S. pombe chromosome 1.

Mitochondrial association of a plus end-directed microtubule motor expressed during mitosis in Drosophila

The kinesin superfamily is a large group of proteins (kinesin-like proteins [KLPs]) that share sequence similarity with the microtubule (MT) motor kinesin. Several members of this superfamily have been implicated in various stages of mitosis and meiosis. Here we report our studies on KLP67A of Drosophila. DNA sequence analysis of KLP67A predicts an MT motor protein with an amino-terminal motor domain. To prove this directly, KLP67A expressed in Escherichia coli was shown in an in vitro motility assay to move MTs in the plus direction. We also report expression analyses at both the mRNA and protein level, which implicate KLP67A in the localization of mitochondria in undifferentiated cell types. In situ hybridization studies of the KLP67A mRNA during embryogenesis and larval central nervous system development indicate a proliferation-specific expression pattern. Furthermore, when affinity-purified anti-KLP67A antisera are used to stain blastoderm embryos, mitochondria in the region of the spindle asters are labeled. These data suggest that KLP67A is a mitotic motor of Drosophila that may have the unique role of positioning mitochondria near the spindle.

Role of the casein kinase I isoform, Hrr25, and the cell cycle-regulatory transcription factor, SBF, in the transcriptional response to DNA damage in Saccharomyces cerevisiae

In the budding yeast, Saccharomyces cerevisiae, DNA damage or ribonucleotide depletion causes the transcriptional induction of an array of genes with known or putative roles in DNA repair. The ATM-like kinase, Mec1, and the serine/threonine protein kinases, Rad53 and Dun1, are required for this transcriptional response. In this paper, we provide evidence suggesting that another kinase, Hrr25, is also involved in the transcriptional response to DNA damage through its interaction with the transcription factor, Swi6. The Swi6 protein interacts with Swi4 to form the SBF complex and with Mbp1 to form the MBF complex. SBF and MBF are required for the G1-specific expression of G1 cyclins and genes required for S-phase. We show that Swi6 associates with and is phosphorylated by Hrr25 in vitro. We find that swi4, swi6, and hrr25 mutants, but not mbp1 mutants, are sensitive to hydroxyurea and the DNA-damaging agent methyl methane-sulfonate and are defective in the transcriptional induction of a subset of DNA damage-inducible genes. Both the sensitivity of swi6 mutants to methyl methanesulfonate and hydroxyurea and the transcriptional defect of hrr25 mutants are rescued by overexpression of SWI4, implicating the SBF complex in the Hrr25/Swi6-dependent response to DNA damage.

Mammalian DNA damage-inducible genes associated with growth arrest and apoptosis

Mammalian cells are exposed to a wide variety of genotoxic stresses from both endogenous and exogenous sources. Cells typically exhibit cell cycle delays, or checkpoints, in response to acute genotoxic stress. Other types of cellular responses to DNA damage include apoptosis and probably increases in DNA repair levels. These response pathways are altered in cancer cells, by genetic alterations such as overexpression or mutation of oncogenes, or loss of tumor suppressor gene functions. As cancer chemotherapy relies primarily on the selective killing of cancer cells by DNA-damaging agents, genetic alterations affecting cellular stress response pathways may affect the outcome of cancer treatment.

Induction in the gene RNR3 in Saccharomyces cerevisiae upon exposure to different agents related to carcinogenesis

The induction of the gene RNR3 was investigated in yeast Saccharomyces cerevisiae using RNR31 lacZ fusion. Gene induction was monitored by measuring beta-galactosidase activity. Various drugs that cause DNA damage effectively induced RNR3 expression; alkylating agents (cisplatin, mitomycin C and N-methyl-N'-nitro-N-nitrosoguanidine), a radical producer (bleomycin), and an intercalator (actinomycin D) induced RNR3. When yeast expressing rat CYP1A1 was exposed to 2-aminofluorene, a concentration-dependent induction of RNR3 was observed. Aflatoxin B1 also induced the expression of RNR3 in the same yeast strain concomitant with inhibition of cell growth. In control yeast, no induction of RNR3 was observed upon exposure to 2-aminofluorene or aflatoxin B1. Exposure to 2-acetylaminofluorene or benzo[a]pyrene did not lead to induction of RNR3 in yeast expressing CYP1A1. These results indicate that DNA damage by chemicals related to carcinogenesis induces RNR3, and that activation of these procarcinogens was required for DNA damage-dependent induction of RNR3.

Regulation of the Saccharomyces cerevisiae Srs2 helicase during the mitotic cell cycle, meiosis and after irradiation

The expression of the SRS2 gene, which encodes a DNA helicase involved in DNA repair in Saccharomyces cerevisiae, was studied using an SRS2-lacZ fusion integrated at the chromosomal SRS2 locus. It is shown here that this gene is expressed at a low level and is tightly regulated. It is cell-cycle regulated, with induction probably being coordinated with that of the DNA-synthesis genes, which are transcribed at the G1-S boundary. It is also induced by DNA-damaging agents, but only during the G2 phase of the cell cycle; this distinguishes it from a number of other repair genes, which are inducible throughout the cycle. During meiosis, the expression of SRS2 rises at a time nearly coincident with commitment to recombination. Since srs2 null mutants are radiation sensitive essentially when treated in G1, the mitotic regulation pattern described here leads us to postulate that either secondary regulatory events limit Srs2 activity of G1 cells or Srs2 functions in a repair mechanism associated with replication.

The DNA repair genes RAD54 and UNG1 are cell cycle regulated in budding yeast but MCB promoter elements have no essential role in the DNA damage response

The DNA repair genes RAD54 and UNG1 have MCB elements in their promoters and are shown to be cell cycle regulated. Their transcripts are coordinately expressed with RNR1, ribonucleotide reductase, a MCB-regulated gene known to be expressed in late G1. However, no evidence was obtained for a direct role of MCB elements in DNA repair. Of the proteins that bind and activate MCB elements, only mutations in SWI6 have a defect in DNA repair, showing significant sensitivity to methyl methane sulphonate. Furthermore, analysis of the CDC9 promoter indicates that MCB elements are not required for the induction of the gene by ultraviolet light irradiation. These promoter elements may not respond directly to DNA damage but may have a role in enhancing the induction response.

Further characterization of HeLa DNA polymerase epsilon

DNA polymerase epsilon (pol epsilon) from HeLa cells was purified to near homogeneity, utilizing Mono S fast protein liquid chromatography for complete separation from pol alpha. The purified pol epsilon preparation showed two polypeptides of > 200 and 55 kDa and a small amount of active 122-kDa proteolysis product on denaturing polyacrylamide gels. Pol epsilon (as well as pols alpha and delta) is optimally active in 100-150 mM potassium glutamate and 15 mM MgCl2. Replication factors RF-A and RF-C, proliferating cell nuclear antigen, and Escherichia coli single-stranded DNA binding protein showed no significant effect on this preparation's pol epsilon activity, processivity, or substrate specificity. The size of the pol epsilon transcript for the catalytic subunit (> 200 kDa) was investigated in both normal human fibroblasts and HeLa cells. A 7.7-kilobase transcript was detected which was 5-16-fold more prevalent in proliferating than in quiescent HeLa cells. No significant difference in the level of pol epsilon transcript in HeLa cells or fibroblasts was seen after ultraviolet irradiation. Mouse polyclonal antiserum was produced to a 144-amino acid fragment of pol epsilon fused to staphylococcal protein A. This non-neutralizing polyclonal antiserum specifically recognized the catalytic subunit of pol epsilon by immunoblotting, but not that of pol alpha, beta, or delta. In addition, mouse polyclonal antiserum raised against column-purified pol epsilon was able to recognize and to neutralize pol epsilon, and a mouse monoclonal antibody was raised which was able to recognize specifically the catalytic subunit of pol epsilon.

Late induction of human DNA ligase I after UV-C irradiation

We have studied the regulation of DNA ligase I gene expression in UV-C irradiated human primary fibroblasts. An increase of approximately 6-fold both in DNA ligase I messenger and activity levels was observed 24 h after UV treatment, when nucleotide excision repair (NER) is no longer operating. DNA ligase I induction is serum-independent and is controlled mainly by the steady-state level of its mRNA. The activation is a function of the UV dose and occurs at lower doses in cells showing UV hypersensitivity. No increase in replicative DNA polymerase alpha activity was found, indicating that UV induction of DNA ligase I occurs through a pathway that differs from the one causing activation of the replication machinery. These data suggest that DNA ligase I induction could be linked to the repair of DNA damage not removed by NER.

A spacer protein in the Saccharomyces cerevisiae spindle poly body whose transcript is cell cycle-regulated

Monoclonal antibodies against the 110-kD component of the yeast spindle pole body (SPB) were used to clone the corresponding gene SPC110. SPC110 is identical to NUF1 (Mirzayan, C., C. S. Copeland, and M. Synder. 1992. J. Cell Biol. 116:1319-1332). SPC110/NUF1 has an MluI cell cycle box consensus sequence in its putative promoter region, and we found that the transcript was cell cycle regulated in a similar way to other MluI-regulated transcripts. Spc110p/Nuflp has a long central region with a predicted coiled-coil structure. We expressed this region in Escherichia coli and showed by rotary shadowing that rods of the predicted length were present. The 110-kD component is localized in the SPB to the gap between the central plaque and the sealed ends of the nuclear microtubules near the inner plaque (Rout, M., and J. V. Kilmartin. 1990. J. Cell Biol. 111:1913-1927). We found that rodlike structures bridge this gap. When truncations of SPC110 with deletions in the coiled-coil region of the protein replaced the wild-type gene, the gap between the central plaque and the ends of the microtubules decreased in proportion to the size of the deletion. This suggests that Spc110p connects these two parts of the SPB together and that the coiled-coil domain acts as a spacer element.

De novo synthesis of budding yeast DNA polymerase alpha and POL1 transcription at the G1/S boundary are not required for entrance into S phase

The POL1 gene, encoding DNA polymerase alpha (pol alpha) in Saccharomyces cerevisiae, is transiently transcribed during the cell cycle at the G1/S phase boundary. Here we show that yeast pol alpha is present at every stage of the cell cycle, and its level only slightly increases following the peak of POL1 transcription. POL1 mRNA synthesis driven by a GAL1 promoter can be completely abolished without affecting the growth rate of logarithmically growing yeast cultures for several cell divisions, although the amount of the pol alpha polypeptide drops below the physiological level. Moreover, alpha-factor-arrested cells can enter S phase and divide synchronously even if POL1 transcription is abolished. These results indicate that the level of yeast pol alpha is not rate limiting and de novo synthesis of the enzyme is not required for entrance into S phase.

Budding yeast mutants showing constitutive basal levels of expression of DNA synthesis genes

Two mutants have been isolated in Saccharomyces cerevisiae in which transcripts from at least CDC8, CDC9, CDC21 (TMP1) and POL1 genes are expressed constitutively in cells blocked at START by use of either alpha-pheromone or the cdc28 mutation. The transcripts from these genes also persist in mutant stationary phase cells; however, cell cycle regulation of these four DNA synthesis genes occurs normally in late G1. The mutation therefore does not appear to lie in the MCB-DSC1 (MBF) system that controls the periodic regulation of the genes, but must affect some control mechanism regulating basal levels of expression.

DNA damage and cell cycle regulation of ribonucleotide reductase

Ribonucleotide reductase (RNR) catalyzes the rate limiting step in the production of deoxyribonucleotides needed for DNA synthesis. In addition to the well documented allosteric regulation, the synthesis of the enzyme is also tightly regulated at the level of transcription. mRNAs for both subunits are cell cycle regulated and inducible by DNA damage in all organisms examined, including E. coli, S. cerevisiae and H. sapiens. This DNA damage regulation is thought to provide a metabolic state that facilitates DNA replicational repair processes. S. cerevisiae also encodes a second large subunit gene, RNR3, that is expressed only in the presence of DNA damage. Genetic analysis of the DNA damage response in S. cerevisiae has shown that RNR expression is under both positive and negative control. Among mutants constitutive for RNR expression are the general transcriptional repression genes, SSN6 and TUP1. Mutations in POL1 and POL3 also activate RNR expression, indicating that the DNA damage sensory network may respond directly to blocks in DNA synthesis. A protein kinase, Dun1, has been identified that controls inducibility of RNR1, RNR2 and RNR3 in response to DNA damage and replication blocks. This result suggests that the RNR genes in S. cerevisiae form a regulon that is coordinately regulated by protein phosphorylation in response to DNA damage.

DNA ligase I gene expression during differentiation and cell proliferation

We have studied the regulation of mammalian DNA ligase I gene by using a cDNA probe in Northern blot experiments with RNA extracted from several cell types in different growth conditions. DNA ligase I mRNA is detected in all analysed cell systems, regardless of their proliferation state, including mature rat neurons. A significant increase in DNA ligase I mRNA level is observed when cells are induced to proliferate, in agreement with the raise of DNA joining activity found in the same cell systems. The increase parallels the start of DNA synthesis, but the messenger remains at high level beyond the end of the S phase and is detected also in the presence of aphidicolin. A decrease in DNA ligase I mRNA is observed in HL-60 and NIH-3T3 cells after differentiation. The high stability of DNA ligase I mRNA in both resting and proliferating human fibroblasts suggests a cell proliferation dependent rate of transcription. On the other hand the presence of a basal level of DNA ligase I in nondividing cells, strongly suggests an involvement of this enzyme in DNA repair. This conclusion is supported by a threefold increase in DNA ligase I observed 24 h after UV irradiation of human confluent primary fibroblasts.

Positive cis-acting regulatory sequences mediate proper control of POL1 transcription in Saccharomyces cerevisiae

The 5'ACGCGT3' MluI motif, which is found in the upstream region of several yeast DNA-synthesis genes which are periodically expressed during the mitotic cell-cycle, is present twice in the 5' non-coding region of the DNA-polymerase alpha gene (POL1). Deletion of the most distal repeat does not affect POL1 transcription, while the adjacent 40 base-pair (bp) downstream sequence is necessary both for the proper level and the fluctuation of POL1 mRNA. This region contains the 5'ACGCGTCGCGT3' sequence, which is sufficient to control periodic transcription of a CYC1-lacZ reporter gene with the same kinetics observed for POL1. The adjacent 29 bp AT-rich region does not show any activity by itself, but it acts synergistically in conjunction with at least one MluI hexamer to stimulate CYC1-lacZ expression. By further deletion analysis, DNA sequences necessary to initiate POL1 transcription at the proper sites have also been identified.

Coordination of expression of DNA synthesis genes in budding yeast by a cell-cycle regulated trans factor

All of the DNA synthesis genes of budding yeast examined so far are periodically expressed and hence under cell-cycle control (Table 1). Expression occurs near the G1/S phase boundary and the genes seem to be coordinately regulated (reviewed in ref. 4). The upstream promoter sequences of these genes have only a hexamer element, ACGCGT (an MluI restriction site), in common. Here we show that this hexamer is able to impart periodic expression to a heterologous gene and, significantly, this expression occurs coincidentally with that of CDC9, one of the DNA synthesis genes (Table 1). We have also identified a protein that binds specifically to these sequences in a similar periodic manner. These ACGCGT sequences and the transcription factor that binds to them therefore seem to be the elements controlling both the periodic expression and coordinate regulation of the DNA synthesis genes.

The yeast DNA ligase gene CDC9 is controlled by six orientation specific upstream activating sequences that respond to cellular proliferation but which alone cannot mediate cell cycle regulation

By fusing the CDC9 structural gene to the PGK upstream sequences and the CDC9 upstream to lacZ, we showed that the cell cycle expression of CDC9 is largely due to transcriptional regulation. To investigate the role of six ATGATT upstream repeats in CDC9 regulation, synthetic copies of the sequence were attached to a heterologous gene. The repeats stimulated transcription strongly and additively, but, unlike conventional yeast UAS elements, only when present in one orientation. Transcription driven by the repeats declines in cells held at START of the cell cycle or in stationary phase, as occurs with CDC9. However, the repeats by themselves cannot impart cell cycle regulation to a heterologous gene. CDC9 may therefore be controlled by an activating system operating through the repeats that is sensitive to cellular proliferation and a separate mechanism that governs the periodic expression in the cell cycle.

Expression of the yeast PHR1 gene is induced by DNA-damaging agents

The PHR1 gene of Saccharomyces cerevisiae encodes a photolyase which repairs specifically and exclusively pyrimidine dimers, the most frequent lesions induced in DNA by far-UV radiation. We have asked whether expression of PHR1 is modulated in response to UV-induced DNA damage and to DNA-damaging agents that induce lesions structurally dissimilar to pyrimidine dimers. Using a PHR1-lacZ fusion gene in which expression of beta-galactosidase is regulated by PHR1 5' regulatory elements, we found that exposure of cells to 254-nm light, 4-nitroquinoline-N-oxide, methyl methanesulfonate, and N-methyl-N'-nitro-N-nitrosoguanidine induced synthesis of increased amounts of fusion protein. In contrast to these DNA-damaging agents, neither heat shock nor exposure to photoreactivating light elicited a response. Induction by far-UV radiation was evident both when the fusion gene was carried on a multicopy plasmid and when it replaced the endogenous chromosomal copy of PHR1, and it was accompanied by an increase in the steady-state concentration of PHR1-lacZ mRNA. Northern (RNA) blot analysis of PHR1 mRNA encoded by the chromosomal locus was consistent with either enhanced transcription of PHR1 after DNA damage or stabilization of the transcripts. Neither the intact PHR1 or RAD2 gene was required for induction. Comparison of the region of PHR1 implicated in regulation of its expression with other damage-inducible genes from yeast cells revealed a common conserved sequence that is present in the PHR1, RAD2, and RNR2 genes and is required for damage inducibility of the latter two genes. These sequences may constitute elements of a damage-responsive regulon in S. cerevisiae.

Expression of the yeast PHR1 gene is induced by DNA-damaging agents

The PHR1 gene of Saccharomyces cerevisiae encodes a photolyase which repairs specifically and exclusively pyrimidine dimers, the most frequent lesions induced in DNA by far-UV radiation. We have asked whether expression of PHR1 is modulated in response to UV-induced DNA damage and to DNA-damaging agents that induce lesions structurally dissimilar to pyrimidine dimers. Using a PHR1-lacZ fusion gene in which expression of beta-galactosidase is regulated by PHR1 5' regulatory elements, we found that exposure of cells to 254-nm light, 4-nitroquinoline-N-oxide, methyl methanesulfonate, and N-methyl-N'-nitro-N-nitrosoguanidine induced synthesis of increased amounts of fusion protein. In contrast to these DNA-damaging agents, neither heat shock nor exposure to photoreactivating light elicited a response. Induction by far-UV radiation was evident both when the fusion gene was carried on a multicopy plasmid and when it replaced the endogenous chromosomal copy of PHR1, and it was accompanied by an increase in the steady-state concentration of PHR1-lacZ mRNA. Northern (RNA) blot analysis of PHR1 mRNA encoded by the chromosomal locus was consistent with either enhanced transcription of PHR1 after DNA damage or stabilization of the transcripts. Neither the intact PHR1 or RAD2 gene was required for induction. Comparison of the region of PHR1 implicated in regulation of its expression with other damage-inducible genes from yeast cells revealed a common conserved sequence that is present in the PHR1, RAD2, and RNR2 genes and is required for damage inducibility of the latter two genes. These sequences may constitute elements of a damage-responsive regulon in S. cerevisiae.

Regulation of the RAD2 gene of Saccharomyces cerevisiae

Regulation of the DNA damage-inducible RAD2 gene was investigated in yeast cells transformed with centromeric plasmids containing RAD2-lacZ fusion constructs. Deletion analysis defined several regions in the 350bp region upstream of the translational start codon which are required for induction of beta-galactosidase activity. No deletions resulted in constitutively enhanced expression. We therefore conclude that induction of RAD2 by DNA-damaging agents is positively regulated. Two domains required for induction have a similar sequence and are located approximately 70 and approximately 140bp upstream of the major transcriptional start site. Four other sequence domains required for induction contain uninterrupted poly(dA) poly(dT) stretches 9-13bp long. Deletion of some of these AT-rich domains also affects constitutive expression of RAD2. Expression of RAD2 is not cell-cycle-regulated in mitotic cells. However, meiosis is accompanied by increased steady-state levels of RAD2 mRNA in the absence of DNA damage. This enhanced transcription is not dependent on the presence of upstream sequences required for regulation of induction by DNA damage. Increased steady-state levels of RAD2 mRNA are induced by cycloheximide in asynchronously dividing populations of cells, but not in non-replicating cells arrested in G1 phase of the cell cycle. Following exposure to u.v. irradiation induction is also dramatically reduced in non-replicating cells.

Induction of beta-polymerase mRNA by DNA-damaging agents in Chinese hamster ovary cells

Only a few of the genes involved in DNA repair in mammalian cells have been isolated, and induction of a DNA repair gene in response to DNA damage has not yet been established. DNA polymerase beta (beta-polymerase) appears to have a synthetic role in DNA repair after certain types of DNA damage. Here we show that the level of beta-polymerase mRNA is increased in CHO cells after treatment with several DNA-damaging agents.

Induction of beta-polymerase mRNA by DNA-damaging agents in Chinese hamster ovary cells

Only a few of the genes involved in DNA repair in mammalian cells have been isolated, and induction of a DNA repair gene in response to DNA damage has not yet been established. DNA polymerase beta (beta-polymerase) appears to have a synthetic role in DNA repair after certain types of DNA damage. Here we show that the level of beta-polymerase mRNA is increased in CHO cells after treatment with several DNA-damaging agents.

The yeast DNA polymerase I transcript is regulated in both the mitotic cell cycle and in meiosis and is also induced after DNA damage

Using mitotic cultures synchronised by a feed-starve protocol or by elutriation, we have shown that the yeast DNA polymerase I gene is periodically expressed with its transcript increasing at least 100-fold in late G1 with a peak around the G1/S phase boundary. This is precisely the same interval of the cell cycle in which three other yeast DNA synthesis genes, CDC8, CDC9 and CDC21, have been found to be periodically expressed (White et al 1987. Expl. Cell. Res., in press). The polymerase I transcript is also regulated in meiosis, showing an overall fluctuation in level of some 20-fold, with a peak at about mid-S phase. In addition, following irradiation with 50J/m2 ultraviolet light, there was a 20-fold increase in the transcript, starting after 30 minutes and reaching a peak two hours later. These results indicate that DNA polymerase I is subject to a complex control and imply that it has a role in both DNA synthesis and DNA repair.