The mutagenic and lethal effects of monofunctional methylating agents in strains of Haemophilus influenzae defective in repair processes

Prophage induction in Haemophilus influenzae and its relationship to mutation by chemical and physical agents

It is known that UV, X-rays, MMC and MMS are not mutagenic for H. influenzae, whereas HZ, EMS and MNNG are potent mutagens for this bacterium. All of these agents, however, are known to be both mutagenic and able to induce prophage in E. coli. We report here that all the agents except HZ induce prophage in H. influenzae, and EMS even induces in the recombination-defective recl mutant, which is non-inducible by UV, MMC, MNNG and MMS. MMS did not cause single-strand breaks or gaps in DNA synthesized after treatment of H. influenzae, but EMS and MNNG produced them. EMS caused more breaks in DNA synthesized before treatment than in that synthesized after treatment. On the other hand we did observe such breaks or gaps induced in E. coli in DNA synthesized posttreatment by EMS as well as by MMS and MNNG, at comparable survival levels.

Genetic effects of N-methyl-N'-nitro-N-nitrosoguanidine and its homologs

Since the discovery of the mutagenic activity of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) in 1960, this compound has become one of the most widely used chemical mutagens. The present paper gives a survey on the chemistry, metabolism, and mode of interaction of MNNG with DNA and proteins, and of the genotoxic effects of this agent on microorganisms, plants, and animals, including human cells cultured in vitro. Data on the carcinogenicity and teratogenicity of MNNG as well as on the genotoxic effects of homologs of MNNG are also presented.

Novobiocin resistance marker in Haemophilus influenzae that is not expressed on a plasmid

The plasmid pNov2, carrying a cloned chromosomal marker conferring resistance to at least 2.5 micrograms of novobiocin per ml, was constructed with a new Haemophilus influenzae cloning vehicle, pDM2. The novobiocin marker of pNov2 was not normally expressed, but in Rec+ cells approximately one in 10(4) cells in a culture of a transformant became novobiocin resistant, a frequency about four orders of magnitude higher than the spontaneous mutation frequency. Variants of such cells that had lost the plasmid were also novobiocin resistant. Since Rec- cultures bearing pNov2 showed novobiocin resistance only at the normal mutation frequency, we concluded that the Rec+ novobiocin-resistant transformants arose because of a rare recombination between plasmid and chromosome in which the chromosome acquired the novobiocin marker from the plasmid. Evidence is presented that novobiocin sensitivity is dominant over this particular novobiocin resistance marker.

UV light-induced survival response in a highly radiation-resistant isolate of the Moraxella-Acinetobacter group

A highly radiation-resistant member of the Moraxella-Acinetobacter group, isolate 4, obtained from meat, was studied to determine the effect of preexposure to UV radiation on subsequent UV light resistance. Cultures that were preexposed to UV light and incubated for a short time in plate count both exhibited increased survival of a UV light challenge dose. This response was inhibited in the presence of chloramphenicol. Frequencies of mutation to streptomycin, trimethoprim, and sulfanilamide resistance remained the same after the induction of this survival response and were not altered by treatment with mutagens, with the exception of mutation to streptomycin resistance after gamma-irradiation or nitrosoguanidine or methyl methane sulfonate treatment. The results indicated that isolate 4 has a UV light-inducible UV light resistance mechanism which is not associated with increased mutagenesis. The characteristics of the radiation resistance response in this organism are similar to those of certain other common food contaminants. Therefore, considered as part of the total microflora of meat, isolate 4 and the other radiation-resistant Moraxella-Acinetobacter isolates should not pose unique problems in a proposed radappertization process.

Mutation induction in Haemophilus influenzae by ICR-191. I. Development of a detection system for frameshift mutations

The investigation of mutagenic mechanisms in Haemophilus influenzae has been confined until now to mutagens that normally produce mainly base pair substitutions. This paper describes the development of a system suitable for detecting frameshift mutations induced by ICR-191. The system involves reversions from thymidine dependence to thymidine independence. Evidence is presented from a comparison of the responses to ICR-191 and to N-methyl-N'-nitro-N-nitrosoguanidine that the system is specific for frameshift mutations. The genetic recombination involved in transformation leads to a marked increase in "spontaneous" reversion of the frameshift mutations but not of the base substitution mutations. Presumably, this is a consequence of mispairing, with consequent change in the number of bases, during the recombination.

A possible mechanism for an interaction between postreplication recombination repair and base misincorporation in mutation induction by N-methyl-N'-nitro-N-nitrosoguanidine in Haemophilus influenzae

Evidence in previous publications has suggested that treatment with monofunctional alkylating agents such as N-methyl-N'-nitro-nitrosoguanidine (MNNG) results in gaps being left in the DNA synthesized shortly after the treatment. This paper presents further evidence that suggests, though it does not conclusively prove, that there are indeed gaps. It shows that these events increase linearly with MNNG concentration, that they are formed mainly in DNA synthesized during the first hour after treatment, and that only a few are formed at later times. An hypothesis that involves the conversion by recombination repair of a single-strand base substitution, resulting from insertion of an incorrect base opposite an alkylated base, to a double-strand base substitution is proposed. It is suggested that most single-strand substitutions are removed by mismatch repair, leaving the double-strand substitutions as the main source of mutations. This hypothesis predicts that the mutation frequency will increase as the square of the exposure to MNNG, and this seems to be the case, at least at lower exposures at which complicating factors such as lengthened expression time are avoided. It also can explain a number of earlier observations on mutation fixation as detected by transformation. An attempt to show that the non-coding lesions causing the gaps were apurinic sites was unsuccessful.

Deoxyribonucleic Acid Repair in Bacillus subtilis : Development of Competent Cells into a Tester for Carcinogens

The development of competent transformed Bacillus subtilis into a tester system for carcinogens is described. Precocious or noninduced activation of SOS functions occur in competent cells. Thus, lower doses or concentrations of SOS inducing agents are needed to cause cell death due to indigenous prophage activation and lysis of bacteria. The two known defective prophages in B. subtilis enhance the sensitivity of competent cells to the carcinogens ultraviolet light, mitomycin C, and methyl methanesulfonate. However, these same cells have no enhanced sensitivity for the non-carcinogenic ethyl methanesulfonate or for nalidixic acid. Therefore, competent B. subtilis appear to be a sensitive tester for carcinogens.

Action spectrum for lethality of near-UV light on Haemophilus influenzae and lack of mutation

Mutation and inactivation of H. influenzae have been measured following irradiation at various near-UV wavelengths. Inactivation takes place most readily at 334 nm (but is unaffected by absence of excision or postreplication repair), and decreases markedly at longer wavelengths. No induced mutations to resistance to novobiocin or streptomycin or to ability to utilize protoporphyrin instead of hemin were detected at any of the wavelengths used. There were also no detectable induced mutations in an excision-defective strain after 334-nm irradiation. These results are in contrast to the in vitro mutation of purified transforming DNA we previously observed.

Mutants of Staphylococcus aureus deficient in recombinational repair. Improved isolation by selecting for mutants exhibiting concurrent sensitivity to ultraviolet radiation and N-methyl-N'-nitro-N-nitrosoguanidine

Recombination-deficient (rec) mutants of Staphylococcus aureus strains 152 and Ps29 were sought by initially screening mutagenized cultures for mutants exhibiting increased sensitivity to both ultraviolet (UV) radiation and N-methyl-N'-nitro-N-nitrosoguanidine (NG). Mutants thus isolated were analyzed for recombinational ability by transduction, and further characterized in terms of sensitivity to UV, NG, ability to repair UV-irradiated bacteriophage, and spontaneous and UV-induced DNA degradation. Mutagenesis of strain 152 yielded three isolates, one of which was rec, the second potentially lex, and the third possessing an undetermined repair deficiency. Mutagenesis of strain Ps29 resulted in the isolation of one mutant, which exhibited a rec genotype. In searching for rec mutants of S. aureus, the value of initially screening mutagenized cultures for mutants exhibiting concurrent sensitivity to UV and NG, as opposed to screening for UV sensitivity alone, is discussed.

The role of pre-replication and post-replication processes in mutation induction in Haemophilus influenzae by N-methyl-N'-nitro-N-nitrosoguanidine

Studies were carried out on the repair and fixation of premutational damage induced in Haemophilus influenzae by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). The studies employed a temperature-sensitive DNA elongation mutant (dna9) and its combinations with mutants defective in pyrimidine dimer excision (uvr1, uvr2) and in recombination (rec1). The dna9 mutant is shown to be leaky, allowing about 1% of the normal rate of DNA synthesis at the restrictive temperature. Repair of premutational lesions was detected by a decline in mutation frequency with increasing delay in DNA replication in dna9 at the restrictive temperature. This repair is unaffected by the pyrimidine dimer excision system. Mutation fixation was detected by the ability of DNA from treated and then lysed cells to transfer mutants to recipient cells by transformation. Some fixation occurred at the restrictive temperature but much less than at the non-restrictive temperature suggesting that an appreciable minority of the mutations resulted from lesions introduced near the replication fork but that the majority of mutations arise from lesions introduced at some distance from the fork, perhaps randomly. The DNA synthesized immediately after MNNG treatment is of lower molecular weight than normal and returns to normal with time. This return is blocked in the rec1 mutant, suggesting that recombination is involved. The possible role of this process in MNNG mutagenesis is discussed.

The relation of repair phenomena to mutation induction in bacteria

The relation of various processes to mutation induction by radiation and chemicals is discussed for for various species of bacteria. A variety of repair processes have been identified at the molecular level that can eliminate many kinds of potentially mutagenic lesions before they can be converted to final mutation. Fixation often but not always occurs at replication. A number of mutagens, including UV light, ionizing radiation, and a number of chemicals, induce an error-prone process, perhaps a modification of the proof-reading system, that allows bacteria to survive after potentially lethal damage at the expense of making errors. Some mutagens, notably monofunctional alkylating agents and base analogues, produce mutations by other processes. Even in these cases, repair processes play an important role. There is some evidence that error-free as well as error-prone repair processes can be induced. A brief discussion is given of the relation of these findings to the practical problems of hazards estimations.

Evidence that UV-inducible error-prone repair is absent in Haemophilus influenzae Rd, with a discussion of the relation to error-prone repair of alkylating-agent damage

Haemophilus influenzae Rd and its derivatives are mutated either not at all or to only a very small extent by ultraviolet (UV) radiation, X-rays, methyl methanesulfonate, and nitrogen mustard, though they are readily mutated by such agents as N-methyl-N'-nitro-N-nitrosoguanidine, ethyl methanesulfonate, and nitrosocarbaryl. In these respects H. influenzae Rd resembles the lexA mutants of Escherichia coli that lack the SOS or reclex UV-inducible error-prone repair system. This similarity is further brought out by the observation that chloramphenicol has little or no effect on post-replication repair after UV irradiation. In E. coli, chloramphenicol has been reported to considerably inhibit post-replication repair in the wild type but not in the lexA mutant. Earlier work has suggested that most or all the mutations induced in H. influenzae by NC result from error-prone repair. Combined treatment with NC and either X-rays or UV shows that the NC error-prone repair system does not produce mutations from the lesions induced by these radiations even while it is producing them from its own lesions. It is concluded that the NC error-prone repair system or systems and the reclex error-prone system are different.

Physiological modification of alkylating-agent induced mutagenesis. I. Effect of growth rate and repair capacity on nitrosomethylurea-induced mutation of Escharichia coli

The effects of repair capacity and growth rate on the induction of mutations by N-methyl-N-nitosourea (MNUA) was investigated using the trpE reversion system of Escherichia coli WP2 and some repair-deficient derivatives isogenic for this gene. In all these strains reducing the growth rate prior to MNUA-treatment caused a reduction in the mutational response, however major differences were observed between strains. In exrA and recA- bacteria stationary phase cells were 100 times less mutable than cells grown at a mean generation time (m.g.t.) of 30 min, whereas reductions of 12 and 25 times were observed in the uvrA- and wild-type strains respectively. In contrast the mutational response of the polA- mutant varied only slightly with growth rate; the increases at high MNUA concentrations being equal to the increase in the trpE gene number. These results show the increasing importance of the error-prone exrA+/recA+-dependent repair system in mutation-induction by MNUA as the growth rate of the culture is reduced and its relative unimportance for mutation induction in nutrient broth-grown cells (m.g.t. 30 min).

Mutation induction by MNNG in a bacteriophage of Haemophilus influenzae

Three temperature-sensitive mutants of the Haemophilus influenzae phage HP1c1 were tested for reversion to wild type (ts leads to ts+). Treatment with N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) produced revertants at levels up to 0.1% of the total progeny phage from treated lysogens. Cells treated with MNNG after infection with whole ts phage produced progeny phage with similar reversion frequencies, but when the uninfected cells or the phage were treated alone no reversion was induced. Fixation of premutational lesions was shown to occur with no evidence for host-cell DNA synthesis, indicating that phage DNA synthesis may be responsible for fixation of mutation in phage DNA. Evidence is given which shows that prophage DNA replicating by the cells' replicating system after treatment and before induction, produces the same number of revertants per survivor as phage DNA which is replicated outside the host genome. Two of the phage mutants (ts1 and ts2) reverted at similar frequencies, while one of the mutants (ts3) exhibited a much lower induced reversion frequency.

Fixation and loss of hydrazine-induced premutational damage in Haemophilus influenzae

Premutational damage induced in Haemophilus influenzae by hydrazine appears to be fixed as final mutation only at replication as judged by the transformation assay. Fixation at replication is independent of the rec1 gene, unlike the case with nitrosocarbaryl. Prior to replication premutational damage induced by hydrazine disappears by an unknown process that is not dependent on the presence of a pyrimidine dimer excision system nor on the rec1 gene. Hydrazine does not produce detectable single-strand breaks or alkali-labile sites in the treated DNA nor gaps in DNA newly synthesized after treatment. In these respects it also differs from nitroso compounds. It is concluded that hydrazine acts to produce and altered base, possibly N(4)-aminocytosine, that produces mutations by mispairing at replication rather than by error-prone repair.

Reversions of two proline-requiring auxotrophs of Haemophilus influenzae by n-methyl-n'-nitro-n-nitrosoguanidine and hydrazine

New mutation detection systems are described for Haemophilus influenzae. They involve two independently isolated proline auxotrophs which appear to be mutants at different sites in a proline locus (proB) that is very closely linked to a locus (thd) for thymidine requirement. One of the mutants, proB1, appears to revert to prototrophy only by mutations at the locus. The other, proB2, reverts both by mutation at the locus and by unlinked suppressors. The latter account for about 90% of the reversions induced by MNNG and by HZ. The close linkage of proB to thd was used to distinguish between true revertants and suppressors by a transformation test. A comparison was made between the mutation induction kinetics of the different classes of revertants and mutations to novobiocin resistance with MNNG and HZ. The very different induction kinetics for these two mutagens previously reported for the novobiocin resistance system were also found for the proline systems. There were some differences between the detection systems, however, in the frequency of induced mutation relative to the spontaneous frequency and, in one case, in the form of the induction curve. It is concluded that the major features of the induction curves reflect the amount of damage done to DNA and so are general for all systems, but that there are some features which are locus-or site-specific.

N-Nitrosocarbaryl-induced mutagenesis in Haemophilus influenzae strains deficient in repair and recombination

Mutagenesis was studied in repair- and recombination-deficient strains of Haemophilus influenzae after treatment with N-nitrosocarbaryl (NC). Three different strains of H. influenzae carrying mutations affecting excision-repair of UV-induced pyrimidine dimers exhibited normal repair of premutational lesions (as detected by decreased mutation yield resulting from post-treatment DNA synthesis delay) and normal nonreplicative mutation fixation. This indicated that neither of these phenomena are caused by the smae repair mechanism that removes UV-induced pyrimidine dimers from the DNA. The recombination-deficient mutant recI is apparently deficient in the replication-dependent mode of NC-induced mutation fixation. This conclusion is based on the following results: (I) NC-induced mutagenesis is lower in the recI strain than in rec+ cells. (2) Repair of premutational lesions (which depends on the existence of replication-dependent mutation fixation for its detection) was not detected in the recI strain. (3) When nonreplicative mutation fixation and final mutation frequency were measured in the same experiment, about I/4 to I/3 of the final mutation yield could be accounted for by nonreplicative mutation fixation in the rec+ strain, whereas all of the mutation could be accounted for in the recI strain by the nonreplicative mutation fixation. (4) When mutation fixation in strain dna9 recI was followed at the permissive (36 degrees) and nonpermissive (41 degrees) temperatures, it became apparent that in the recI strain replication-dependent mutation fixation occurs at early times, but these newly fixed mutations are unstable and disappear at later times, leaving only the mutations fixed by the nonreplicative process. The recI strain exhibits normal repair of NC-induced single-strand breaks or alkali-labile bonds in the DNA labeled before treatment, but is slow in joining discontinuties present in DNA synthesized after treatment. The results are consistent with the idea that in NC-treated H. influenzae cells the replication-dependent mode of mutation fixation occurs by error-prone joining of interruptions present in the DNA synthesized after treatment. The possibility still exists, however, that during DNA replication mispairing occurs opposite certain alkylation-induced lesions and that mutations arising during replication of strain recI later disappear as a result of degradation of newly synthesized DNA, which is excessive in this strain.

Lack of chemically induced mutation in repair-deficient mutants of yeast

Two genes, rad6 and rad9, that confer radiation sensitivity in the yeast Saccharomyces cerevisiae also greatly reduce the frequency of chemically-induced reversions of a tester mutant cyc1-131, which is a chain initiation mutant in the structural gene determining iso-1-cytochrome c. Mutations induced by ethyl methanesulfonate (EMS), diethyl sulfate (DES), methyl methanesulfonate (MMS), dimethyl sulfate (DMS), nitroquinoline oxide (NQO), nitrosoguanidine (NTG), nitrogen mustard (HN2), beta-propiolactone, and tritiated uridine, as well as mutations induced by ultraviolet light (UV) and ionizing radiation were greatly diminished in strains homozygous for either the rad6 or rad9 gene. Nitrous acid and nitrosoimidazolidone (NIL), on the other hand, were highly mutagenic in these repair-deficient mutants, and at low doses, these mutagens acted with about the same efficiency as in the normal RAD strain. At high doses of either nitrous acid or NIL, however, reversion frequencies were significantly reduced in the two rad mutants compared to normal strains. Although both rad mutants are immutable to about the same extent, the rad9 strains tend to be less sensitive to the lethal effect of chemical mutagens than rad6 strains. It is concluded that yeast requires a functional repair system for mutation induction by chemical agents.