Singlet oxygen mutagenicity induced in the lac operon

We have studied the specificity of singlet oxygen (1O2) mutagenesis in single-stranded DNA phage by analysing 1O2-induced mutations in the lac insert of the M13 mp 19 hybrid phage. 107 lac mutants were analysed showing mainly single-base substitutions with a total of 93% and 7% of 40-50 base deletion mutations. Most of the substitutions are G----T and C----A transversions with respectively 27 and 54% of the mutations. The replicative form of the M13 mp 19 DNA (RFDNA) was used as substrate for the 1O2 reactions, there are then two types of progeny phages DNA's. As guanine residues are the targets of the oxidation, it appears that both types of transversions are provided by one type of lesion: the guanine oxidised by 1O2 is read like a thymine by E. coli DNA polymerase-I.     

Pyrimidine dimers are not the principal pre-mutagenic lesions induced in lambda phage DNA by ultraviolet light

Experiments were performed to examine the role of cyclobutyl pyrimidine dimers in the process of mutagenesis by ultraviolet (u.v.) light. Lambda phage DNA was irradiated with u.v. and then incubated with an Escherichia coli photoreactivating enzyme, which monomerizes cyclobutyl pyrimidine dimers upon exposure to visible light. The photoreactivated DNA was packaged into lambda phage particles, which were used to infect E. coli uvr- host cells that had been induced for SOS functions by ultraviolet irradiation. Photoreactivation removed most toxic lesions from irradiated phage, but did not change the frequency of induction of mutations to the clear-plaque phenotype. This implies that cyclobutyl pyrimidine dimers can be lethal, but usually do not serve as sites of mutations in the phage. The DNA sequences of mutants derived from photoreactivated DNA showed that almost two-thirds (16/28) were transitions, the same fraction found for u.v. mutagenesis without photoreactivation. These results show that in this system, the lesion inducing transitions (the major type of u.v.-induced mutation) is not the cyclobutyl pyrimidine dimer; a strong candidate for a mutagenic lesion is the Pyr(6-4)Pyo photoproduct. On the other hand, photoreactivation of SOS-induced host cells before infection with u.v.-irradiated phage reduced mutagenesis substantially. In this case, photoreversal of cyclobutyl dimers serves to reduce expression of the SOS functions that are required in the process of targeted u.v. mutagenesis.     

Ultraviolet reactivation of lambda phage: assay of infectivity of DNA molecules by spheroplast transfection

Prior irradiation of non-lysogenic bacteria by ultraviolet light leads to an increase in the viability of infecting irradiated λ phage (ultraviolet reactivation). Similarly, u.v. irradiation of wild type or uvrD bacteria lysogenic for λcIind^? increased the fraction of closed circular duplex phage DNA molecules formed after infection with u.v.-irradiated λ phage. The closed circular molecules isolated from the irradiated lysogens were shown to be free from u.v. damage by a spheroplast transfection assay. The increase of closed circular molecules is sufficient to explain the ultraviolet reactivation observed by the increase of viability of irradiated phage.In ultraviolet reactivation, damage must be erased on irradiated DNA molecules and the repair is independent of total replication of phage genomes, exchange of sister chromatids or recombination between phage genomes. Protein synthesis is necessary to increase the level of closed circular molecules of irradiated λ phage after irradiation of bacteria.     

Effect of bacteriophage C5 on ultraviolet light survival in Pseudomonas aeruginosa.

Bacteriophage C5 of Pseudomonas aeruginosa is able to reactivate ultraviolet (u.v.)-irradiated phage E79 in coinfection experiments and decrease the u.v.-sensitivity of a host-cell reactivation deficient mutant. These properties suggest that phage C5 has a gene(s) which is involved in the repair of u.v.-damaged DNA. The isolation of two u.v.-sensitive mutants of C5 supports this hypothesis.     

Oxidative damage in DNA. Lack of mutagenicity by thymine glycol lesions

Thymine glycol (5,6-dihydroxy-5,6-dihydrothymine) is a base damage common to oxidative mutagens and the major stable radiolysis product of thymine in DNA. We assessed the mutagenic potential of thymine glycols in single-stranded bacteriophage DNA during transfection of Escherichia coli wild-type and umuC strains. cis-Thymine glycols were induced in DNA by reaction with the chemical oxidant, osmium tetroxide (OsO4); modification of thymines was quantitated by using anti-thymine glycol antibody. Inactivation of transfecting molecules showed that one lethal hit corresponded to 1.5 to 2.1 thymine glycols per phage DNA in normal cells, whereas conditions of W-reactivation (SOS induction) reversed 60 to 80% of inactivating events. Forward mutations in the lacI and lacZ' (alpha) genes of f1 and M13 hybrid phage DNAs were induced in OsO4-treated DNA in a dose-dependent manner, in both wild-type and umuC cells. Sequence analysis of hybrid phage mutants revealed that mutations occurred preferentially at cytosine sites rather than thymine sites, indicating that thymine glycols were not the principal pre-mutagenic lesions in the single-stranded DNA. A mutagenic specificity for C----T transitions was confirmed by OsO4-induced reversion of mutant lac phage. Pathways for mutagenesis at derivatives of oxidized cytosine are discussed.     

Ultraviolet-induced dimerization of non-adjacent pyrimidines. A potential mechanism for the targeted -1 frameshift mutation

The DNA photoproduct responsible for the ultraviolet (u.v.)-induced targeted -1 frameshift mutation is unknown. Based on mutagenesis studies by others, we surmised that this lesion might be found in high abundance in single-stranded DNA. u.v. irradiation of the single-stranded alternating copolymer poly[d(G-T)] yielded a photoproduct that was characterized in detail. It consists of a thymine-thymine cyclobutane dimer of predominantly cis-syn configuration occurring between non-adjacent thymidyl residues on the same strand. Its formation is strongly inhibited in double-stranded DNA. A similar u.v. photoproduct was obtained in higher yield from the polypyrimidine alternating copolymer poly[d(C-T)] under conditions in which it is single-stranded. It is proposed that replication across the unrepaired photoproduct: (formula; see text) is the cause of the targeted u.v.-induced -1 frameshift mutation.     

Mutagenic specificity of ultraviolet light

Genetic and sequencing studies of ultraviolet light (u.v.)-induced mutations in the lacI gene of Escherichia coli show the following: u.v. stimulates many types of mutations. In lacI, base substitutions account for 60 to 65% of the observed mutations, small frameshifts 30 to 35%, and deletions of more than several base-pairs approximately 5%. A comparison of the mutational spectrum of u.v.-induced mutations with those of other SOS-dependent mutagens and with the mutations produced by inducing the SOS system in the absence of mutagenic treatment indicates that most u.v.-induced base substitutions are "targeted", resulting from premutational lesions across from the site of the mutations. Among base substitutions, both transitions and transversions occur, although the most favored mutational sites involve G X C----A X T transitions. G X C----A X T transitions are induced preferentially at sites of adjacent pyrimidines. In one case the conversion of a site from -A-C-A- to -T-C-A- results in a 15-fold increase in u.v.-induced C----T transitions. Frameshifts at certain sites are well-induced by u.v., and the largest hotspot in the I gene involves the loss of an (sequence in text) base pair from a (sequence in text) sequence. Of 25 frameshifts detected by DNA sequencing, 23 mutations at seven different sites result from the elimination of a single base-pair, and two mutations result from the elimination of two base-pairs. No additions were detected. The use of a lacI-Z fusion system, which allows direct selection of frameshifts of either sign, reveals that throughout the entire gene frameshifts that eliminate a single base-pair (-1) predominate by a factor of 20 or more over frameshifts that add a single base-pair (+1). In one case a two-base-pair elimination occurs frequently, resulting in the loss of a -C-T- sequence (on one strand), or a -T-C- sequence, from a -C-T-C-T-C-T-C- sequence. For both frameshifts and base substitutions, some aspect of the larger surrounding sequence beyond the nearest neighbors can influence mutation rates by as much as 50-fold, thus determining which sites are seen as hotspots. The bearing of these and other data on the detailed mechanism of mutagenesis is considered in the Discussion.     

Weigle reactivation of diploid M13 phage

Summary The limited ability of ultraviolet (UV)-irradiated E. coli cells to W-reactivate UV-irradiated, single-stranded DNA phages fd and M13 was investigated. The kinetics of induction for W-reactivation of UV-irradiated fd phage are different from that for other SOS functions. W-reactivation of UV-irradiated M13 phage was studied using phage particles that contain at least two single-stranded DNA genomes. No effect on the extent of W-reactivation of diploid phage was observed, compared to that of normal haploid phage, indicating that the mechanism of W-reactivation of single-stranded DNA phages does not involve recombination between partially replicated genomes.     

Direct and indirect effects of ultraviolet light on the mutagenesis of parvovirus H-1 in human cells.

U.v. radiation is directly mutagenic for the single-stranded DNA parvovirus H-1 propagated in human cells. Mutation induction in the progeny of u.v.-irradiated virus increased linearly with the dose and could be ascribed neither to an increased number of rounds of viral replication nor to the indirect activation of an inducible cellular mutator activity by the u.v.-damaged virus. The level of mutagenesis among the descendants of both unirradiated and u.v.-damaged H-1 was enhanced if the host cells had been exposed to sublethal doses of u.v. light before infection. This indirect enhancement of viral mutagenesis in pre-irradiated cells was maximal at multiplicities lower than 0.2 infectious particles/cell. The frequency of mutations resulting from cell pre-irradiation was only slightly higher for u.v.-irradiated than for intact virus. Thus, the induced cellular mutator appeared to be mostly untargeted in the dose range given to the virus. U.v.-irradiation of the cells also enhanced the mutagenesis of u.v.-irradiated herpes simplex virus, a double-stranded DNA virus ( Lytle and Knott , 1982).     

RecA protein and SOS. Correlation of mutagenesis phenotype with binding of mutant RecA proteins to duplex DNA and LexA cleavage

The RecA protein of Escherichia coli is required for SOS-induced mutagenesis in addition to its recombinational and regulatory roles. We have suggested that RecA might participate directly in targeted mutagenesis by binding preferentially to the site of the DNA damage (e.g. pyrimidine dimer) because of its partially unwound nature; DNA polymerase III will then encounter RecA-coated DNA at the lesion and might replicate across the damaged site more often but with reduced fidelity. In support of this proposal, we have found that the phenotype of wild-type and mutant RecA for mutagenesis correlates with capacity to bind to double-stranded DNA. Wild-type RecA binds more efficiently to ultraviolet (u.v.)-irradiated, duplex DNA than to non-irradiated DNA. The RecA441 (Tif) protein that is constitutive for mutagenesis binds extremely well to double-stranded DNA with no lesions, whereas the RecA430 protein that is defective in mutagenesis binds poorly even to u.v.-irradiated DNA. The RecA phenotype also correlates with capacity to use duplex DNA as a cofactor for cleavage of the LexA repressor protein for SOS-controlled operons. Wild-type RecA provides efficient cleavage of LexA only with u.v.-irradiated duplex DNA; RecA441 cleaves well with non-irradiated DNA; RecA430 gives very poor cleavage even with u.v.-irradiated DNA. We conclude that the interaction of RecA with damaged double-stranded DNA is likely to be a critical component of SOS mutagenesis and to define a pathway for the LexA cleavage reaction as well.     

A simple and efficient method for chemical mutagenesis of DNA.

A simple and efficient procedure for the generation of random GC to AT transition mutations in a specific DNA segment is described. A restriction fragment is inserted in each orientation into an M13 vector, single-stranded virion DNA from each recombinant phage is treated with methoxylamine, and, after reannealing of the mutagenized strands, a double-stranded restriction fragment is obtained. This methoxylamine-derivatized DNA segment is then joined with linearized M13 RF DNA, competent E. coli is transfected, and mutations are directly identified by sequencing of the phage DNA. Using this technique, single and double nucleotide substitutions were generated at a frequency greater than 50% in a 56-base pair segment of the signal codons of the TEM beta-lactamase.     

Relationship between enhanced reactivation and mutagenesis of u.v.-irradiated human cytomegalovirus in normal human cells.

The survival of u.v.-irradiated human cytomegalovirus (HCMV) on u.v.-irradiated human IAFP-1 cells was increased over that on unirradiated cells. Irradiated virus had a higher forward mutation frequency towards temperature sensitivity in irradiated than in unirradiated cells. Enhanced reactivation of u.v.-irradiated HCMV is thus mutagenic in normal human cells. This observation supports the possible induction of an error-prone mode of DNA repair in u.v.-irradiated mammalian cells.     

Stability of coliphage lambda DNA replication initiator, the lambda O protein.

The initiator of coliphage lambda DNA replication, lambda O protein, may be detected among other 35S-labeled phage and bacterial proteins by a method based on immunoprecipitation. This method makes it possible to study lambda O proteolytic degradation in lambda plasmid-harboring or lambda phage-infected cells; it avoids ultraviolet (u.v.)-irradiation of bacteria, used for depression of host protein synthesis, prior to lambda phage infection. We confirm the rapid decay of lambda O protein (half-time of 80 s), but we demonstrate the existence of a stable lambda O fraction. In the standard five minute pulse-chase experiments, 20% of synthesized lambda O is stable. The extension of the [35S]methionine pulse, possible in lambda plasmid-harboring cells, leads to a linear increase of this fraction, as if a part of the synthesized lambda O was constantly made resistant to proteolysis. Less than 5% of lambda O protein synthesized during one minute is transformed into a stable form. We presume that the stable lambda O is identical with lambda O present in the normal replication complex and thus protected from proteases. We cannot find any stable lambda O in Escherichia coli recA+ cells that were irradiated with u.v. light prior to lambda phage infection, but their recA- counterparts behave normally, suggesting that recA function interferes in the assembly of a normal replication complex in u.v.-irradiated bacteria. The stable lambda O found in lambda plasmid-harboring, amino acid-starved relA cells is responsible for the lambda O-dependent lambda plasmid replication that occurs in this system in the absence of lambda O synthesis. The existence of stable lambda O raises doubt concerning its role as the limiting initiator protein in the control of replication. Another significance of lambda O rapid degradation is proposed.     

Differential effects of procaine and phenethyl alcohol on excision repair of DNA in u.v.-irradiated Escherichia coli

Experiments were performed to investigate the involvement of the cell membrane in the excision DNA repair process in Escherichia coli. Two membrane-binding drugs, procaine and phenethyl alcohol (PEA), inhibited liquid-holding recovery (LHR) in u.v.-irradiated E. coli wild-type and recA strains. In uvrB and polA strains where, after u.v.-irradiation, LHR was absent the two drugs had no effect. Both drugs markedly reduced the removal of u.v.-induced thymine dimers in the DNA of wild-type cells (H/r30). Analysis by alkaline sucrose gradients revealed that PEA inhibited the incision step in excision repair. In contrast, procaine had no effect on incision but apparently inhibited the late steps in excision repair. PEA dissociated DNA from the cell membrane, whereas procaine did not. The results suggest that the two drugs PEA and procaine inhibit LHR and the excision repair process operating on u.v.-induced damage in E. coli by at least two different mechanisms each of which may involve the cell membrane.     

Weigle reactivation of diploid M13 phage

Molecular Genetics and Genomics - The limited ability of ultraviolet (UV)-irradiated E. coli cells to W-reactivate UV-irradiated, single-stranded DNA phages fd and M13 was investigated. The...     

Aphidicolin does not inhibit DNA repair synthesis in ultraviolet-irradiated HeLa cells. A radioautographic study.

A radioautographic examination of nuclear DNA synthesis in unirradiated and u.v.-irradiated HeLa cells, in the presence and in the absence of aphidicolin, showed that aphidicolin inhibits nuclear DNA replication and has no detectable effect on DNA repair synthesis. Although the results establish that in u.v.-irradiated HeLa cells most of the DNA repair synthesis is not due to DNA polymerase alpha, they do not preclude a significant role for this enzyme in DNA repair processes.     

Specificity of ionizing radiation-induced mutagenesis in the lac region of single-stranded phage M13 mp10 DNA.

M13 mp10 single-stranded phage DNA was irradiated with 60 Co gamma-rays, and transfected into Escherichia coli. One hundred and sixteen mutant clones having lesions in the lac insert were selected, and mutational sites were examined by DNA sequence analysis. Fourteen out of the 15 nucleotide changes thus detected were base substitutions, and the rest was a base addition. Transitions and transversions were almost equal in number. Mutational events were observed at cytosine residues more frequently than at other residues, and the predominant base change was a C ---- T transition. Possible roles in gamma-ray-induced mutagenesis played by the misincorporation of dAMP owing to radiolytic derivatives of cytosine residues and/or formation of apurinic/apyrimidinic sites are discussed.     

Origin of ultraviolet damage in DNA

A novel ultraviolet (u.v.) footprinting technique has been used to analyze the formation of u.v. photoproducts at 250 bases of a 5 S rRNA gene under conditions where the gene is either double or single-stranded. Because many more types of u.v. damage can be detected by the u.v. footprinting technique than has been previously possible, we have been able to examine in detail why certain bases in DNA are damaged by u.v. light while others are not. Our measurements demonstrate that the ability of u.v. light to damage a given base in DNA is determined by two factors, the sequence of the DNA in the immediate vicinity of the photoproduct, and the flexibility of the DNA at the site of the photoproduct. For pyrimidines, the predominant photoreaction in double-stranded DNA involves covalent dimerization between adjacent pyrimidine residues. Dimerization is much easier in melted DNA because the geometrical changes required for adjacent pyrimidine residues to dimerize are easier in single-stranded DNA. The absorption of a u.v. photon cannot simultaneously induce the geometrical changes required for adjacent pyrimidines or other bases to dimerize with one another. Rather, upon the absorption of a u.v. photon, only those thermally excited bases that are in a geometry capable of easily forming a photodimer during excitation, can photoreact. In contrast to adjacent pyrimidines, non-adjacent pyrimidines (pyrimidines flanked on either side by a purine) do not readily form u.v. photoproducts in double-stranded DNA. Because photoreactions at non-adjacent pyrimidine residues are greatly enhanced in single-stranded DNA, their failure to form in double-helical DNA is attributed to torsional constraints imposed by the double helix which make it difficult for non-adjacent pyrimidines to adopt a geometry necessary for photoreaction. Although purines are believed to be resistant to u.v. damage, our measurements demonstrate that at moderate u.v. dosages purines which are flanked on their 5' side by two or more contiguous pyrimidines readily form u.v. photoproducts in double-stranded DNA. Flanking pyrimidines appear to activate purine photoreactions by transferring triplet excitation energy to the purine. Melting of the DNA helix greatly inhibits the ability of flanking pyrimidines to activate purine photoreactions, presumably by disrupting intimate orbital overlap required for triplet transfer.     

A model for the recA-dependent repair of excision gaps in UV-irradiated Escherichia coli

DNA isolated from lambda phage was treated with bleomycin A2 plus Fe2+. The bleomycin-damaged DNA was added to lambda packaging extracts and the resulting phage were grown in SOS-induced E. coli. Under these conditions, treatment of the DNA with 0.8 microM bleomycin reduced the viability of the repackaged phage to 3% and increased the frequency of clear-plaque mutants in the progeny by a factor of 16. Bleomycin-induced mutations which mapped to the DNA-binding domain of the cI gene were subjected to DNA-sequence analysis. The most frequent events were single-base substitutions at G:C base pairs, nearly all of which occurred at cytosines in the sequence Py-G-C. Cytosines in the third position of the sequence C-G-C-C were particularly susceptible to mutation. At A:T base pairs, mutations were less frequent and were a mixture of single-base substitutions and -1 frameshifts, occurring primarily at G-T and A-T sequences. Thus, the overall specificity of bleomycin-induced mutations matches that of bleomycin-induced DNA lesions (strand breaks and apyrimidinic sites), which are formed at G-C (particularly Py-G-C), G-T and, to a lesser extent, A-T sequences. Furthermore, the frequency of various types of substitutions was consistent with selective incorporation of A and T residues opposite apyrimidinic sites at these sequences. The highly selective nature of bleomycin-induced mutations may explain the lack of mutagenesis by this compound in a number of reversion assays.     

Mechanisms of spontaneous mutagenesis: an analysis of the spectrum of spontaneous mutation in the Escherichia coli lacI gene

We have obtained via DNA sequence analysis a spectrum of 174 spontaneous mutations occurring in the lac I gene of Escherichia coli. The spectrum comprised base substitution, frameshift, deletion, duplication and insertion mutations, of which the relative contributions to spontaneous mutation could be estimated. Two thirds of all lacI mutations occurred in the frameshift hotspot site. An analysis of the local DNA sequence suggested that the intensity of this hotspot may depend on structural features of the DNA that extend beyond those permitted by the repeated tetramer at this site. Deletions comprised the largest non-hotspot class (37%). They could be divided into two subclasses, depending on whether they included the lac operator sequence; the latter was found to be a preferred site for deletion endpoints. Most of the deletions internal to the lacI gene were associated with the presence of directly or invertedly repeated sequences capable of accounting for their endpoints. Base substitutions comprised 34% of the non-hotspot events. Unlike the base substitution spectrum obtained via nonsense mutations, G . C----A . T transitions do not predominate. A new base substitution hotspot was discovered at position +6 in the lac operator; its intensity may reflect specific features of the operator DNA. IS1 insertion mutations contributed 12% of the non-hotspot mutations and occurred dispersed throughout the gene in both orientations. Since the lacI gene is not A + T-rich, the contribution of IS1 insertion to spontaneous mutation in general might be underestimated. Single-base frameshift mutations were found only infrequently. In general, they did not occur in runs of a common base. Instead, their occurrence seemed based on the "perfection" of direct or inverted repeats in the local DNA sequence. Three (tandem) duplication events were recovered. No repeated sequences were found that might have determined their endpoints.