Recombinational repair of alkylation lesions in phage T4

Summary Treatment of bacteriophage T4 by ethyl methanesulfonate (EMS)¹ caused more than a doubling in recombination between two rII markers. The functions of genes 47, 46, 32, 30, uvsX and y are known to be required for genetic recombination, and mutants defective in these genes were found to be more sensitive to inactivation by EMS than wild-type phage. This suggests that a recombinational pathway involving the products of these genes may be employed in repairing EMS induced lethal lesions. Genes 45 and denV are apparently not involved in recombination, and mutants defective in these genes were not EMS-sensitive. Gene 47, 46 and y mutants which were defective in the repair of EMS induced lethal lesions had no detectable deficiency in their ability to undergo EMS-induced mutation. This implies that recombinational repair of EMS lesions does not contribute substantially to EMS mutatenesis. The results obtained here with EMS are in general similar to the results reported in the preceding paper with MNNG, suggesting that the lesions caused by both of these monofunctional alkylating agents may be eliminated by similar recombinational repair processes.     

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.     

Bacteriophage T4 DNA polymerase determines the amount and specificity of ultraviolet mutagenesis

Summary Ultraviolet mutagenesis in bacteriophage T4 proceeds via error-prone repair (EPR) and requires the functional integrity of the uvsWXY system which mediates genetic recombination, recombinational repair, and mutability by diverse DNA damaging agents. Current opinion holds that mutagens acting through EPR generate DNA damage which blocks the progress of the replication complex and that EPR consists of the facilitated bypass of such inaccurate, damaged templates. This notion predicts that the T4 DNA polymerase (encoded by gene 43) mediates EPR in UV irradiated phage T4. This prediction is verified by the discovery that gene 43 mutations often enhance or reduce UV mutagenesis (which is scored by the induction of r mutants) and sometimes change its specificity.     

UV-induced mutation in bacteriophage T4.

Two late gene am mutants of bacteriophage T4 that can be induced to revert by UV were crossed to a temperature-sensitive ligase mutant. In the double mutants, UV-induced reversion was eliminated at a semirestrictive temperature. When the single am mutants were irradiated and then allowed a single passage in a permissive host, the UV-induced reversion frequency was increased by 15- to 25-fold. This increased mutagenesis was also abolished by the presence of the ligase allele. When the UV-irradiated single am mutants multiply infected a permissive host, allowing multiplicity reactivation to occur, the induced reversion frequency was reduced similarly to the reduction in lethality. The mutagenesis that remained was again abolished by the presence of the ligase allele. It is concluded that UV induces mutations in phage T4 through the action of a pathway that includes polynucleotide ligase. The increase in mutation frequency after growth in a permissive host implies that mutagenesis can occur at more than one stage of the infection rather than only in an early stage before expression of the mutant genome. The process of multiplicity reactivation appears to be error-free since it overcomes lethal lesions without inducing new mutations.     

Uvm mutants of Escherichia coli K12 deficient in UV mutagenesis

Summary Uvm mutants of Escherichia coli K12 selected for defective UV reversion induction have previously been reported to differ considerably from the UV-reversion-less recA and lexA mutants with regard to survival or mutagenic response to UV, X-rays and alkylating agents. In the present study, the phenotypic characterization of uvm mutants was extended to investigate several cellular processes which also may be related to or involved in UV mutagenesis. Like recA and lexA mutations, the uvm mutations exhibit highly reduced Weigle reactivation and normal host cell reactivation of UV irradiated phage . But unlike recA and lexA, the uvm mutations do not impair genetic recombination, UV induction of prophage or R plasmid-mediated UV resistance and mutagenesis. These phenotypical characteristics and preliminary results of genetic mapping lend further support to the assumption that the uvm site may be a novel locus affecting, apart from the recA and lexA loci, the error-prone repair pathway in E. coli.     

DNA repair and sequence context affect 1O2-induced mutagenesis in bacteria

Electronic excited molecular oxygen (singlet oxygen, ¹O₂) is known to damage DNA, yielding mutations. In this work, the mutagenicity induced by ¹O₂ in a defined sequence of DNA was investigated after replication in Escherichia coli mutants deficient for nucleotide and base excision DNA repair pathways. For this purpose a plasmid containing a ¹O₂-damaged 14 base oligonucleotide was introduced into E.coli by transfection and mutations were screened by hybridization with an oligonucleotide with the original sequence. Mutagenesis was observed in all strains tested, but it was especially high in the BH20 (fpg), AYM57 (fpg mutY) and AYM84 (fpg mutY uvrC) strains. The frequency of mutants in the fpg mutY strain was higher than in the triple mutant fpg mutY uvrC, suggesting that activity of the UvrABC excinuclease can favor the mutagenesis of these lesions. Additionally, most of the mutations were G→T and G→C transversions, but this was dependent on the position of the guanine in the sequence and on repair deficiency in the host bacteria. Thus, the kind of repair and the mutagenesis associated with ¹O₂-induced DNA damage are linked to the context of the damaged sequence.     

Functional Interactions between the DNA Ligase of ESCHERICHIA COLI and Components of the DNA Metabolic Apparatus of T4 Bacteriophage

T4 phage completely defective in both gene 30 (DNA ligase) and the rII gene (function unknown) require at least normal levels of host-derived DNA ligase (E. coli lig gene) for growth. Viable E. coli mutant strains that harbor less than 5% of the wild-type level of bacterial ligase do not support growth of T4 doubly defective in genes 30 and rII (T4 30- rII- mutants). We describe here two classes of secondary phage mutations that permit the growth of T4 30- rII- phage on ligase-defective hosts. One class mapped in T4 gene su30 (Krylov 1972) and improved T4 30- rII- phage growth on all E. coli strains, but to varying degrees that depended on levels of residual host ligase. Another class mapped in T4 gene 32 (helix-destabilizing protein) and improved growth specifically on a host carrying the lig2 mutation, but not on a host carrying another lig- lesion (lig4). Two conclusions are drawn from the work: (1) the role of DNA ligase in essential DNA metabolic processes in T4-infected E. coli is catalytic rather than stoichiometric, and (2) the E. coli DNA ligase is capable of specific functional interactions with components of the T4 DNA replication and/or repair apparatus.     

On the mechanism of bromouracil-induced mutagenesis

Bromouracil (BU)-induced mutagenesis of λC17 am o8 phage, in relation to the recombination systems of phage (red) or bacteria (rec), was studied. The mutations investigated were am → am⁺. For efficient BU-induced mutagenesis, red or recA genes as well as bacterial lex gene functions, known to be involved in UV-induced mutagenesis, were required. This suggests a common mechanism or some common step(s) in UV- and BU-induced mutagenesis. Moreover, a several-fold increase was observed in the number of mutants induced by BU in the excision-repair-deficient strain (uvrA), implying that incorporated BU induces some premutational lesions that are recognized and repaired by excision-repair enzymes. A hypothesis on the possible mechanism of BU-induced mutagenesis is proposed, which assumes a common mechanism for UV- and BU-induced mutagenesis, involving recombination repair processes. Incorporation of a tautomeric or ionized form of BU is considered only as a premutational change in DNA activating the dark-repair mechanisms in cells. The observation that BU enhances the frequency of recombination in λ phages also supports teh idea that recombination processes are involved in BU-induced mutagenesis.     

Ultraviolet mutagenesis in bacteriophage T-4. I. Irradiation of extracellular phage particles

Drake, John W. (University of Illinois, Urbana). Ultraviolet mutagenesis in bacteriophage T4. I. Irradiation of extracellular phage particles. J. Bacteriol. 91:1775-1780. 1966.-Ultraviolet (UV) irradiation of extracellular T4 phage particles induces about 2 x 10(-4)r mutations per lethal hit. The mutants largely escape detection unless the irradiated phages are plated with very soft overlay agar. Multiplicity reactivation is not a prerequisite for mutagenesis. A much higher frequency of base pair substitution-type mutants is induced than is found in the spontaneous background, but sign mutants are also induced. Nearly half of the mutants map into previously identified UV hot spots. The rII mutants induced extracellularly are very similar to those induced intracellularly. The mutants also appear to result from direct radiation effects upon the bacteriophage deoxyribonucleic acid.     

Effect of in vitro cleavage of apurinic/apyrimidinic sites on bleomycin-induced mutagenesis of repackaged lambda phage

Previous studies have revealed bleomycin to be a potent base-substitution mutagen in repackaged phage lambda. In order to assess the role of apurinic/apyrimidinic (AP) sites in bleomycin-induced mutagenesis, bleomycin-damaged lambda DNA was treated with putrescine or endonuclease IV to effect cleavage of bleomycin-induced AP sites. The DNA was then packaged, the phage grown in SOS-induced E. coli, and the frequency of clear-plaque mutants in the progeny was determined. Bleomycin-induced mutagenesis was decreased approx. 2-fold by treating the DNA with putrescine, but was unaffected by endonuclease IV. The results are consistent with the production of bleomycin-induced mutation at certain AP sites having a closely opposed single-strand break, since such sites are cleaved by putrescine but not by endonuclease IV.     

Inducible, error-free DNA repair in tsl recA mutants of E. coli

Summary Host cell reactivation and UV reactivation and mutagenesis of UV-irradiated phage were measured in tsl recA ⁺ and tsl recA host mutants. Host cell reactivation was slightly more efficient in the tsl recA strain compared to the tsl ⁺ recA strain. Phage was UV-reactivated in the tsl recA strain with about one-half the efficiency of that in the wild type strain, but there was no corresponding mutagenesis of phage. UV-reactivation was also slightly lower and mutagenesis several-fold lower than normal in the tsl recA ⁺ strain. To account for these observations, we propose that there is an inducible, error-free pathway of DNA repair in E. coli that competes with error-prone repair for repair of phage lesions.     

DNA base sequence changes induced by bromouracil mutagenesis of lambda phage

The base sequence changes induced by bromouracil mutagenesis in the cI gene of phage lambda have been determined by direct sequence analysis. Phage DNA mutagenized during prophage replication or during phage lytic growth showed predominantly A · T → G · C transitions. The frequency of this mutation was strongly sequence-dependent: 5′ A-C-G-C 3′ > A-C(A.C or T) > A(A.G or T). The difference in mutability of bases in the gene is not the result of specificity in mutL-dependent mismatch repair, since phage grown in mutL host cells showed the same distribution of bromouracil mutations. The observations made in phage mutagenized with bromouracil in the prophage state should be representative of bromouracil mutagenesis in the Escherichia coli chromosome.     

Vergleichende Untersuchungen an HNO2-Inaktivierten und UV-Inaktivierten Bakteriophagen T4

Summary The inactivation of phage T4 by nitrous acid (HNO₂) is essentially an exponential function of time of treatment. HNO₂-inactivated T4 is able to undergo multiplicity reactivation, and genetic markers may be rescued by live phage, however, the extent of both effects is appreciably less than after UV-inactivation. Also, the survival of phenotypic function of the cistronsr II-A andr II-B is lower with HNO₂-treatment than with a UV-irradiation of a corresponding number of hits.The reduced effects are quantitatively accounted for by the assumption of lethal hits blocking early steps of infection. These early-step damages amount to approximately 1/6 of the total hit number; it is still unknown whether they occur in DNA or in protein. Some indication for the occurrence in protein comes from the result that the host-killing efficiency of HNO₂-inactivated phage is reduced at a similar rate as these early-step damages occur. However, at least 5/6 of the lethal hits are due to chemical changes within the DNA, as can be calculated from the results of multiplicity reactivation, marker rescue, and phenotypic survival of therII-cistrons.

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Spectrum of N4-aminocytidine mutagenesis

N4-Aminocytidine, a nucleoside analog, is a potent mutagen towards phages, bacteria, Drosophila and mammalian cells in culture. In vitro, biochemical studies indicate that this reagent acts by being incorporated into DNA. To elucidate the mechanism of N4-aminocytidine mutagenesis, it is essential to identify the nature of DNA sequence alterations taking place during the mutagenesis. We have analyzed the nucleotide sequence changes in the lac promoter-lacZ alpha region of M13mp2 phage induced by treatment of phage-infected Escherichia coli with N4-aminocytidine. The sequence alterations of DNA samples from 89 mutants of the phage were determined. These mutants had single point mutations, except one mutant, in which a double point mutation was detected. Several hot spots were found: however, there are no apparent relations to particular DNA sequences regarding the locations of these spots. All the mutations are transitions; neither transversions nor deletions/insertions were found. A feature in these transitions is that the A/T to G/C and G/C to A/T changes occur at approximately equal rates. The overall picture of the mutagenesis is consistent with a scheme in which misincorporation and misreplication caused by the modified cytosine structure are the key steps in the DNA replication leading to transitions. Similar nucleotide alterations were found for the mutagenesis induced by an alkylated derivative, N'-methyl-N4-aminocytidine. N4-Aminocytidine also induced reversions of these mutants; both A/T to G/C and G/C to A/T transitions again took place.     

Differential effects of caffeine on DNA damage and replication cell cycle checkpoints in the fission yeast Schizosaccharomyces pombe

Caffeine potentiates the lethal effects of ultraviolet and ionising radiation on wild-type Schizosaccharomyces pombe cells. In previous studies this was attributed to the inhibition by caffeine of a novel DNA repair pathway in S. pombe that was absent in the budding yeast Saccharomyces cerevisiae. Studies with radiation-sensitive S. pombe mutants suggested that this caffeine-sensitive pathway could repair ultraviolet radiation damage in the absence of nucleotide excision repair. The alternative pathway was thought to be recombinational and to operate in the G₂ phase of the cell cycle. However, in this study we show that cells held in G₁ of the cell cycle can remove ultraviolet-induced lesions in the absence of nucleotide excision repair. We also show that recombination-defective mutants, and those now known to define the alternative repair pathway, still exhibit the caffeine effect. Our observations suggest that the basis of the caffeine effect is not due to direct inhibition of recombinational repair. The mutants originally thought to be involved in a caffeine-sensitive recombinational repair process are now known to be defective in arresting the cell cycle in S and/or G₂ following DNA damage or incomplete replication. The gene products may also have an additional role in a DNA repair or damage tolerance pathway. The effect of caffeine could, therefore, be due to interference with DNA damage checkpoints, or inhibition of the DNA damage repair/tolerance pathway. Using a combination of flow cytometric analysis, mitotic index analysis and fluorescence microscopy we show that caffeine interferes with intra-S phase and G₂ DNA damage checkpoints, overcoming cell cycle delays associated with damaged DNA. In contrast, caffeine has no effect on the DNA replication S phase checkpoint in reponse to inhibition of DNA synthesis by hydroxyurea. Received: 16 June 1998 / Accepted: 13 July 1998     

Ribonucleotide reductase: A determinant of 5-bromodeoxyuridine mutagenesis in phage T4

Summary Mutagenesis by 5-bromodeoxyuridine (BrdUrd) can result from base-pairing errors either during replication of a BrdUrd-containing template or at the nucleotide incorporation step. Replication errors give rise predominantly to AT-to-GC transitions, while incorporation errors, in which 5-bromo-dUTP competes with dCTP at a template guanine site, should give rise to GC-to-AT transitions. The latter pathway should be sensitive to deoxyribonucleoside triphosphate (dNTP) pool fluctuations. Since dNTP pools are regulated through allosteric control of ribonucleotide reductase, the control of this enzyme should be a determinant of BrdUrd mutagenesis — if mutagenesis results largely from incorporation errors. Since T4 phage-encoded ribonucleotide reductase is insensitive to feedback inhibition, we established conditions under which phage DNA replication is dependent upon ribonucleotide reductase of the host, Escherichia coli. We examined BrdUrd mutagenesis of rII mutants known to revert to wild type either by AT-to-GC or GC-to-AT transition pathways. While both reversion pathways were stimulated under all conditions analyzed, the AT-to-GC pathway was stimulated more when the E. coli reductase was functioning, while the GC-to-AT pathway was more specifically enhanced when the T4 reductase was active. These results confirm that ribonucleotide reductase is a determinant of BrdUrd mutagenesis, but our observations, plus experiments showing that BrdUrd has relatively small effects upon dNTP pool sizes, indicate that the relationship between deoxyribonucleotide metabolism and BrdUrd mutagenesis is more complex than anticipated.     

Restriction in vivo

Summary Degradation products of restricted T4 DNA induced filamentation, mutagenesis, and to a lesser extent, synthesis of recA protein in wild type cells but not in recA, lexA or recBC mutants of Escherichia coli. We conclude that the structural damage to the DNA caused by restriction cleavage and exonuclease V degradation can induce SOS functions. Degradation of restricted nonglucosylated T4 DNA by exonuclease V delayed cell division and induced filament formation and mutagenesis in lexA ⁺ but not in lexA ^- cells. Delay of cell division was also dependent upon recA and recBC funtions. Such degradation of DNA also dramatically increased mutagenesis in tif ^- Sfi^- cells at 42°C. The synthesis of recA protein continued in the restricting host after infection by the nonglucosylated T4 phage, but enhanced synthesis is not induced to the extent seen in SOS induced tif ^- cells grown at 42°. We also found that restriction of nonglucosylated T4 was alleviated in UV irradiated cells. The UV induced alleviation of rgl and r _K restriction depended upon post irradiation protein synthesis and was not observed in recA, lexA or recBC mutants.     

Damage and mutagenesis of E. coli and bacteriophage λ induced by oxathiolane and aziridinyl steroids

λ-Escherichia coli complexes exhibited remarkable sensitivity to the treatment with test steroidal derivatives in the presence of Cu(II). The decline in plaque-forming units after steroid treatment was more pronounced in complexes with some of the irradiation repair-defective mutants of E. coli K-12, i.e., recA, lexA and polA, as compared to uvrA and wild-type strains. The red gene of λ phage and recA gene of E. coli seem to have a complementary effect on the steroid-induced lesions. An enhanced level of mutagenesis was observed when steroid-treated E. coli cells were transformed with steroid-treated pBR322 plasmid DNA. A remarkable degree of c mutation was also observed when steroid I-treated phage particles were allowed to adsorb on steroid-treated wild-type bacteria. Moreover, the oxathione steroid treatment of λcI857-E. coli lysogen resulted in prophage induction in nutrient broth even at 32°C. Thus on the basis of these results, the role of SOS repair system in steroid-induced mutagenesis and repair of DNA lesions in E. coli and bacteriophage λ has been suggested.     

Influence of DNA repair defects (rad1, rad52) on nitrogen mustard mutagenesis in yeast.

Summary Nitrogen mustard (HN2) mutagenesis of a plasmid-borne copy of the Saccharomyces cerevisiae SUP4-o gene was examined in a repair-proficient yeast strain and isogenic derivatives defective for excision (radl) or DNA double-strand break (rad52) repair. The excision repair deficiency sensitized the cells to killing by HN2 and abolished mutation induction. Inactivation of RAD52 had no influence on the lethality of HN2 treatment but diminished the induced mutation frequency by 50% at all doses tested. DNA sequence analysis of HN2-induced SUP4-o mutations suggested that RAD52 contributed to the production of basepair substitutions at G·C sites. The rad52 defect appeared to alter the distribution of G·C A·T transitions in SUP4-o relative to the distribution for the wild-type strain. This difference did not seem to be due to an effect of RAD52 on the relative fractions of HN2-induced transitions at localized (flanked by A·T pairs) or contiguous (flanked by at least one G·C pair) G·C sites but instead to an influence on the strand specificity of HN2 mutagenesis. In the repair-proficient strain, the transitions showed a small bias for sites having the guanine on the transcribed strand and this preference was eliminated by inactivation of RAD52.     

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.