The dependence of HNO2 mutagenesis in phage T4 on ligase and the lack of dependence of 2AP mutagenesis on repair functions

Summary A temperature sensitive ligase allele of phage T4 reduced or eliminated HNO₂ induced reversion of am mutants. Since at the temperatures used, the ligase mutant is defective in the repair of some types of lethal lesions (i.e., UV, MMS and EMS induced lesions) these results indicate that HNO₂ mutagenesis may occur through a ligase dependent repair pathway. In contrast, 2AP induced mutation was not inhibited by mutants defective in the gene 30 ligase or in genes 32, 39, 41, 44, 45, 46, 47, 49, 52, 56, 58–61 and v. This indicates that 2AP mutagenesis probably does not depend on a repair pathway in phage T4.     

Replication of Damaged DNA and the Molecular Mechanism of Ultraviolet Light Mutagenesis

Abstract

On UV irradiation of Escherichia coli cells, DNA replication is transiently arrested to allow removal of DNA damage by DNA repair mechanisms. This is followed by a resumption of DNA replication, a major recovery function whose mechanism is poorly understood. During the post-UV irradiation period the SOS stress response is induced, giving rise to a multiplicity of phenomena, including UV mutagenesis. The prevailing model is that UV mutagenesis occurs by the filling in of single-stranded DNA gaps present opposite UV lesions in the irradiated chromosome. These gaps can be formed by the activity of DNA replication or repair on the damaged DNA. The gap filling involves polymerization through UV lesions (also termed bypass synthesis or error-prone repair) by DNA polymerase III. The primary source of mutations is the incorporation of incorrect nucleotides opposite lesions. UV mutagenesis is a genetically regulated process, and it requires the SOS-inducible proteins RecA, UmuD, and UmuC. It may represent a minor repair pathway or a genetic program to accelerate evolution of cells under environmental stress conditions.     

UV hyper‐resistance in Prochlorococcus MED4 results from a single base pair deletion just upstream of an operon encoding nudix hydrolase and photolyase

Exposure to solar radiation can cause mortality in natural communities of pico‐phytoplankton, both at the surface and to a depth of at least 30 m. DNA damage is a significant cause of death, mainly due to cyclobutane pyrimidine dimer formation, which can be lethal if not repaired. While developing a UV mutagenesis protocol for the marine cyanobacterium Prochlorococcus, we isolated a UV‐hyper‐resistant variant of high light‐adapted strain MED4. The hyper‐resistant strain was constitutively upregulated for expression of the mutT‐phrB operon, encoding nudix hydrolase and photolyase, both of which are involved in repair of DNA damage that can be caused by UV light. Photolyase (PhrB) breaks pyrimidine dimers typically caused by UV exposure, using energy from visible light in the process known as photoreactivation. Nudix hydrolase (MutT) hydrolyses 8‐oxo‐dGTP, an aberrant form of GTP that results from oxidizing conditions, including UV radiation, thus impeding mispairing and mutagenesis by preventing incorporation of the aberrant form into DNA. These processes are error‐free, in contrast to error‐prone SOS dark repair systems that are widespread in bacteria. The UV‐hyper‐resistant strain contained only a single mutation: a 1 bp deletion in the intergenic region directly upstream of the mutT‐phrB operon. Two subsequent enrichments for MED4 UV‐hyper‐resistant strains from MED4 wild‐type cultures gave rise to strains containing this same 1 bp deletion, affirming its connection to the hyper‐resistant phenotype. These results have implications for Prochlorococcus DNA repair mechanisms, genome stability and possibly lysogeny.     

Repair Responses to DNA Damage: Enzymatic Pathways in E coli and Human Cells

Bacteria and eukaryotic cells employ a variety of enzymatic pathways to remove damage from DNA or to lessen its impact upon cellular functions. Most of these processes were discovered in Escherichia coli and have been most extensively analyzed in this organism because suitable mutants have been isolated and characterized. Analogous pathways have been inferred to exist in mammalian cells from the presence of enzyme activities similar to those known to be involved in repair in bacteria, from the analysis of events in cells treated with DNA damaging agents, and from the analysis of the few naturally occurring mutant cell types. Excision repair of pyrimidine dimers produced by UV in E coli is initiated by an incision event catalyzed by a complex composed of uvrA, uvrB, and uvrC gene products. Multiple exonuclease and polymerase activities are available for the subsequent excision and resynthesis steps. In addition to the constitutive pathway, which produces short patches of 20–30 nucleotides, an inducible excision repair process exists that produces much longer patches. This long patch pathway is controlled by the recA-lexA regulatory circuit and also requires the recF gene. It is apparently not responsible for UV-induced mutagenesis. However, the ability to perform inducible long patch repair correlates with enhanced bacterial survival and with a major component of the Weigle reactivation of bacteriophage with double-strand DNA genomes. Mammalian cells possess an excision repair pathway similar to the constitutive pathway in E coli. Although not as well understood, the incision event is at least as complex, and repair resynthesis produces patches of about the same size as the constitutive short patches. In mammalian cells, no patches comparable in size to those produced by the inducible pathway of E coli are observed. Repair in mammalian cells may be more complicated than in bacteria because of the structure of chromatin, which can affect both the distribution of DNA damage and its accessibility to repair enzymes. A coordinated alteration and reassembly of chromatin at sites of repair may be required. We have observed that the sensitivity of digestion by staphylococcal nuclease (SN) of newly synthesized repair patches resulting from excision of furocoumarin adducts changes with time in the same way as that of patches resulting from excision of pyrimidine dimers. Since furocoumarin adducts are formed only in the SN-sensitive linker DNA between nucleosome cores, this suggests that after repair resynthesis is completed, the nucleosome cores in the region of the repair event do not return exactly to their original positions. We have also studied excision repair of UV and chemical damage in the highly repeated 172 base pair α DNA sequence in African green monkey cells. In UV irradiated cells, the rate and extent of repair resynthesis in this sequence is similar to that in bulk DNA. However, in cells containing furocoumarin adducts, repair resynthesis in α DNA is only about 30% of that in bulk DNA. Since the frequency of adducts does not seem to be reduced in α DNA, it appears that certain adducts in this unique DNA may be less accessible to repair. Endonuclease V of bacteriophage T4 incises DNA at pyrimidine dimers by cleaving first the glycosylic bond between deoxyribose and the 5′ pyrimidine of the dimer and then the phosphodiester bond between the two pyrimidines. We have cloned the gene (denV) that codes for this enzyme and have demonstrated its expression in uvrA recA and uvrB recA cells of E coli. Because T4 endonuclease V can alleviate the excision repair deficiency of xeroderma pigmentosum when added to permeabilized cells or to isolated nuclei after UV irradiation, the cloned denV gene may ultimately be of value for analyzing DNA repair pathways in cultured human cells.     

UV-induced mutability in repair-deficientrad6-1 strains ofSaccharomyces cerevisiae is caused by a suppressor gene

TheRAD6 gene is a multifunctional gene required for DNA repair, induced mutagenesis and sporulation. The survival and revertibility of two loci in fourrad6-1 mutant strains of different origin after UV irradiation were followed. As expected, all therad6-1 strains tested were more sensitive to UV radiation in comparison withRAD6 strains. The reversion frequency per survivor intrpl-289 andarg4–17 alleles was significantly higher in all fourrad6-1 mutant strains than in wild-type strains after equal doses of UV radiation. On the basis of genetic analysis we suggest that the phenomenon of increased frequency of induced mutagenesis is caused by a suppressor gene.     

<Emphasis Type="Italic">IXR1</Emphasis> and <Emphasis Type="Italic">HMO1</Emphasis> genes jointly control the level of spontaneous mutagenesis in yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

The yeast genes IXR1 and HMO1 encode proteins belonging to the family of chromatin nonhistone proteins, which are able to recognize and bind to irregular DNA structures. The full deletion of gene IXR1 leads to an increase in cell resistance to the lethal action of UV light, γ-rays, and MMS, increases spontaneous mutagenesis and significantlly decreases the level of UV-induced mutations. It was earlier demonstrated in our works that the hmo1 mutation renders cells sensitive to the lethal action of cisplatin and virtually does not affect the sensitivity to UV light. Characteristically, the rates of spontaneous and UV-induced mutagenesis in the mutant are increased. Epistatic analysis of the double mutation hmo1 ixr1 demonstrated that the interaction of these genes in relation to the lethal effect of cisplatin and UV light, as well as UV-induced mutagenesis, is additive. This suggests that the products of genes HMO1 and IXR1 participate in different repair pathways. The ixr1 mutation significantly increases the rate of spontaneous mutagenesis mediated by replication errors, whereas mutation hmo1 increases the rate of repair mutagenesis. In wild-type cells, the level of spontaneous mutagenesis was nearly one order of magnitude lower than that obtained in cells of the double mutant. Consequently, the combined activity of the Hmo1 and the Ixr1 proteins provides efficient correction of both repair and replication errors.     

Mutagenic and error-free DNA repair in Streptomyces

Summary Two mutants of Streptomyces fradiae defective in DNA repair have been characterized for their responses to the mutagenic and lethal effects of several chemical mutagens and ultraviolet (UV) light. S. fradiae JS2 (mcr-2) was more sensitive than wild type to agents which produce bulky lesions resulting in large distortions of the double helix [i.e. UV-light, 4-nitroquinoline-1-oxide (NQO), and mitomycin C (MC)] but not to agents which produce small lesions [i.e. hydroxylamine (HA), methyl methanesulfonate (MMS), ethyl methanesulfonate (EMS) and N-methyl-N-nitro-N-nitrosoguanidine (MNNG)]. JS2 expressed a much higher frequency of mutagenesis induced by UV-light at low doses and thus appeared to be defective in an error-free excision repair pathway for bulky lesions analogous to the uvr ABC pathway of Escherichia coli. S. fradiae JS4 (mcr-4) was defective in repair of damage by most agents which produce small or bulky lesions (i.e., HA, NQO, MMS, MNNG, MC, and UV, but not EMS). JS4 was slightly hypermutable by EMS and MMS but showed reduced mutagenesis by NQO and HA. This unusual phenotype suggests that the mcr-4 ⁺ protein plays some role in error-prone repair in S. fradiae.     

Interstrain crosses enhance excision of Tc1 transposable elements in Caenorhabditis elegans

Summary We have studied spontaneous and UV mutagenesis of the glyU gene in Escherichia coli trpA461 (GAG) strains carrying the pIP11 plasmid, in which the dnaQ gene encoding the 3–5 exonuclease subunit (epsilon) of DNA polymerase III is fused to the tac(trp-lac) promoter. We have used a pair of M13glyU phage in which the gene encoding the glycyl-tRNA is cloned in opposite orientations, consequently the phage present either GGG or CCC anticodon triplets for mutagenesis. The presence of IPTG, the inducer of the tac-dnaQ fusion, results in about 100-fold decrease in frequency of spontaneous Su⁺ (GAG) mutations arising in the CCC phage. The enhanced expression of tac-dnaQ reduces 10-fold the frequency of UV-induced Su⁺ (GAG) mutations in the CCC phage and nearly completely prevents generation by UV of Su⁺ (GAG) mutations in the GGG phage, in which UV-induced pyrimidine photoproducts can be formed only in the vicinity of the target triplet. These results suggest that both locally and regionally targeted mutagenesis is affected by overproduction of the epsilon subunit. By delayed photoreversal mutagenesis we have shown that UV-induced chromosomal mutagenesis of the umuC36 trpA461 strain harboring pIP11 is completely abolished in the presence of IPTG. This result seems to indicate that the misinocorporation step of DNA translesion synthesis is affected by excess of the epsilon subunit. Finally, we have introduced the pIP13 plasmid carrying the dnaQ gene into the recA1207 strain, which is deficient in the recombinase activity of RecA but constitutive in the protease activity. We demonstrate that the transformant shows much higher UV sensitivity than recA1207 carrying the vector plasmid pBR325, indicating that translesion synthesis significantly contributes to DNA repair capacity of cells deficient in recombination.     

Thermal resistance to photoreactivation of ultraviolet light induced mutations in the lacI gene of E. coli ung

Ultraviolet light (UV) induced mutations in the lacI gene of Escherichia coli are thought to be targeted by DNA photoproducts. A number of reports suggest that both cyclobutyl pyrimidine dimers and pyrimidine (6−4) pyrimidone photoproducts may be involved. To investigate the potential contribution of each of these DNA photoproducts to mutagenesis in the lacI gene, we held UV-irradiated cells at a temperature of 44°C for 75 min and then exposed them to photoreactivating light (PR). This protocol is expected to preferentially deaminate specifically those cytosines that are contained in cyclobutyl dimers and subsequently monomerize the dimers to yield uracils in the DNA. In a strain deficient for uracil-DNA glycosylase (Ung⁻), these uracils would not be removed and a G : C → A : T transition would result at the site of the dimer. This protocol resulted in the enhancement of amber nonsense mutations that result from transitions at potential cytosine-containing dimer sites. The enhanced mutation frequencies resulting from this procedure were used to estimate the probability of dimer formation at the individual sites. A comparison of the dimer distribution with the mutation frequencies following UV alone suggests that both cyclobutyl dimers and (6−4) photoproducts contribute to UV-mutagenesis in the lacI gene. In addition, we conclude that the frequency of mutation at any particular site not only reflects the occurrence of DNA damage, but also the action of metabolic processes that are responsible for DNA repair and mutagenesis.     

Isolation and characterization of DNA repair deficient mutants from Penicillium chrysogenum

Summary Mutants sensitive to far ultraviolet light (UV) and 4-nitroquinoline-1-oxide (4NQO) have been isolated from Penicillium chrysogenum NRRL 1951. Two strains HP500 and HP508 are examined in detail. Their cross sensitivity to and altered mutation by UV and 4NQO suggests that damage caused by both agents is repaired through similar pathways in Penicillium chrysogenum. Strain HP500 is refractive to UV and 4NQO mutagenesis and is likely to be defective in an error-prone mechanism of repair. Mutation by N-methyl-N-nitro-N-nitrosoguanidine (MNNG) in HP500 is also reduced, indicating involvement of an error-prone UV repair process in MNNG mutagenesis in Penicillium chrysogenum. Strain HP508 shows an increase of forward mutation rate up to 4.5 times over that of the wild-type, when compared at similar surviving fractions and is also hypermutable by 4NQO. The repair defect present in strain HP508 has been demonstrated by its inability to remove DNA sites sensitive to single strand specific nuclease during post-irradiation incubation of protoplasts.     

Nature of the SOS mutator activity: genetic characterization of untargeted mutagenesis in Escherichia coli

Summary In Escherichia coli, induction of the SOS functions by UV irradiation or by mutation in the recA gene promotes an SOS mutator activity which generates mutations in undamaged DNA. Activation of RecA protein by the recA730 mutation increases the level of spontaneous mutation in the bacterial DNA. The number of recA730-induced mutations is greatly increased in mismatch repair deficient strains in which replication errors are not corrected. This suggests that the majority of recA730-induced mutations (90%) arise through correctable, i.e. non-targeted, replication errors. This recA730 mutator effect is suppressed by a mutation in the umuC gene. We also found that dam recA730 double mutants are unstable, segregating clones that have lost the dam or the recA mutations or that have acquired a new mutation, probably in one of the genes involved in mismatch repair. We suggest that the genetic instability of the dam recA730 mutants is provoked by the high level of replication errors induced by the recA730 mutation, generating killing by coincident mismatch repair on the two unmethylated DNA strands. The recA730 mutation increases spontaneous mutagenesis of phage poorly. UV irradiation of recA730 host bacteria increases phage untargeted mutagenesis to the level observed in UV-irradiated recA ⁺ strains. This UV-induced mutator effect in recA730 mutants is not suppressed by a umuC mutation. Therefore UV and the recA730 mutation seem to induce different SOS mutator activities, both generating untargeted mutations.     

Frameshift and double-amber mutations in the bacteriophage T4 uvsX gene: analysis of mutant UvsX proteins from infected cells

Summary The bacteriophage T4 uvsX gene encodes a 43 kDa, single-stranded DNA-dependent ATPase, double-stranded DNA-binding protein involved in DNA recombination, repair and mutagenesis. Mutants of uvsX have a DNA-arrest phenotype and reduced burst size. Western blot immunoassay of UvsX peptides made by a number of amber mutants revealed amber peptides ranging from 25–32 kDa. Wild-type UvsX protein was also detected in lysates of cells infected with uvsX amber mutants, suggesting that their mutations are suppressed by translational ambiguity. We investigated the effects of mutations near the 5 end of uvsX. A frameshift mutation was engineered at codon 33. Western immunoblots for UvsX protein demonstrated that the frameshift mutant expresses no detectable wild-type UvsX; instead, a 37 kDa reactive peptide was detected. In order to determine if this peptide represents truncated UvsX protein, the mutation was regenerated in the cloned uvsX gene and expressed in transformed Escherichia coli. Endopeptidase digestion of the 37 kDa protein from the cloned gene generated peptide fragments indistinguishable from those obtained from wild-type UvsX. A double-amber mutant of uvsX was also generated by oligonucleotide site-directed mutagenesis. No UvsX protein was detected in lysates of cells infected with the uvsX-am64am67 double mutant. Plaque size and sensitivity to UV inactivation for both the double-amber and the frame-shift mutants were indistinguishable from those of other uvsX mutants. Mutations in uvsY had no demonstrable effect on efficiency of plating or UV sensitivity of uvsX mutants. Thus, null mutants of uvsX are viable.     

Involvement of bacteriophage T4 genes in radiation repair

One interpretation of Ebisuzaki's (1966) observation that the functional survival of certain early phage T4 genes is identical in v⁺ and v -infected cells is that the product of the early gene being studied is essential for the successful completion of excision repair (which is known to be mediated by the v gene). An experiment designed to test this hypothesis is described, with results which fully support the idea. Assuming then that this interpretation is valid, it became possible to determine the involvement in excision repair of a much wider range of early genes by establishing whether or not the v allele affects their functional survival. In addition a comparable series of experiments was performed with phages carrying the u.v.-sensitive y mutation which is known to mediate a quite different type of repair in T4-infected cells.The results indicate that genes 1, 30, 42, 43 and 56 are involved in excision repair, but not genes 32, 41, 43 or 44. All these genes are however involved in y-mediated repair. It appears therefore that this latter repair system (which bears some resemblance to that controlled by the rec genes in bacteria) depends on normal phage DNA synthesis for its completion. However the repair synthesis following the excision of pyrimidine dimers in u.v.-irradiated T4 DNA seems distinct from normal DNA synthesis in that it does not involve certain of the early phage genes, and in particular does not utilize the DNA polymerase coded by gene 43. It is suggested that the polymerase activity associated with this repair synthesis is provided by the bacterial Kornberg polymerase pol I.     

Characterization of gene-specific DNA repair by primary cultures of rat hepatocytes

At present, almost all the information on gene-specific DNA repair in mammals comes from studies with transformed cell lines and proliferating primary cells obtained from rodents and humans. In the present study, we measured the repair of specific DNA regions in primary cultures of nondividing rat hepatocytes (parenchymal cells). DNA damage was induced by irradiating the primary cultures of hepatocytes with ultraviolet (UV) light, and the presence of cyclobutane pyrimidine dimers (CPDs) was measured by using T4 endonuclease V in the following: a 21-kb BamHI fragment containing the albumin gene, a 14-kb BamHI fragment containing the H-ras gene, and the genome overall. The frequency of CPDs in the two BamHI fragments and the genome overall were similar and ranged from 0.5 to 1.3 CPDs per 10 kb for UV doses of 5–30 J/m². However, the removal of CPDs from the DNA fragment containing the albumin gene was significantly higher than from that of the genome overall and the DNA fragment containing the H-ras gene. Within 24 hr, approximately 67% of the CPDs was removed from the DNA fragment containing the albumin gene versus less than 40% for the genome overall and the DNA fragment containing the H-ras gene. The lower repair observed for the 14-kb fragment containing the H-ras gene is probably indicative of repair of the nontranscribed region of this fragment because the H-ras gene makes up only 2.4 kb of the 14-kb fragment. Primary cultures of hepatocytes removed CPDs from the transcribed strand of albumin fragment more efficiently than from the nontranscribed strand; however, no differences were observed in the repair of the two strands of the fragment containing the H-ras gene. These results demonstrate that primary cultures of nondividing rat hepatocytes show differential repair of UV-induced DNA damage that is comparable to what has been reported for transformed, proliferating mammalian cell lines. J. Cell. Physiol. 176:314–322, 1998. © 1998 Wiley-Liss, Inc.     

Recombination and mutagenesis in rad6 mutants of Saccharomyces cerevisiae: Evidence for multiple functions of the RAD6 gene

Summary The rad6-1 and rad6-3 mutants are highly UV sensitive and show an increase in spontaneous and UV induced mitotic heteroallelic recombination in diploids. Both rad6 mutants are proficient in spontaneous and UV induced unequal sister chromatid recombination in the reiterated ribosomal DNA sequence and are deficient in UV induced mutagenesis. In contrast to the above effects where both mutants appear similar, rad6-1 mutants are deficient in sporulation and meiotic recombination whereas rad6-3 mutants are proficient. The differential effects of these mutations indicate that the RAD6 gene is multifunctional. The possible role of the RAD6 gene in error prone excision repair of UV damage during the G1 phase of the cell cycle in addition to its role in postreplication repair is discussed.     

Effect of proofreading and dam-instructed mismatch repair systems on N4-hydroxycytidine-induced mutagenesis

Summary The role of the proofreading (35 exonuclease) function of T4 DNA polymerase and the mismatch repair system ofE. coli on N⁴-hydroxycytidine (oh⁴Cyd)¹ induced mutagenesis was investigated. oh⁴Cyd-induced mutation is strongly suppressed when the proofreading activity increases as a result of the presence oftsCB87-antimutator polymerase or elevated temperature (43° C vs 30° C). Mutagenic activity of oh⁴Cyd, however, is little, if at all, affected by the presence of thetsLB56 mutator allele of T4 DNA polymerase with suppressed proofreading activity. This leads to the conclusion that oh⁴C nucleotides are not frequently removed by proofreading activity of wild-type T4 DNA polymerase. The number of mutations induced by oh⁴Cyd increases 3- to 5-fold due to damage of the genesmutS,mutL,uvrE, but notmutR.Dam ^- cells are more sensitive to, and hypermutable by, oh⁴Cyd in comparison withdam ⁺ cells. This is compatible with the notion that oh⁴C residues are recognised and excised by mismatch repair enzymes. The results indicate thath neither the proofreading function of T4 DNA polymerase, nor the mismatch repair enzymes, are responsible for the high specificity of oh⁴Cyd which causes ATGC transition.     

Localization of the plasmid (pKM101) gene(s) involved in recA+lexA+-dependent mutagenesis

Summary Twenty Tn5 insertion mutants of the drug resistance plasmid pKM101 have been isolated that are unable to enhance mutagenesis with ultraviolet (UV) irradiation or methyl methanesulfonate. By restriction mapping, the Tn5 insertion in each of these pKM101 mutants was shown to be within a 1.9 kb region of the plasmid genome. We have termed this segment of the pKM101 map the muc (mutagenesis: UV and chemical) gene(s). Characterization of these mutants indicated that any Tn5 insertion within the muc gene(s) abolished the ability of pKM101 to: (a) enhance spontaneous, UV and chemical mutagenesis, (b) increase host survival following UV-irradiation, (c) increase the survival of UV-irradiated phage plated on irradiated or unirradiated cells, and (d) suppress the repair and mutagenesis deficiencies of a umuC ^– mutant. Possible models to explain the role of the pKM101 muc gene(s) in mutagenesis and repair are discussed.