Mechanisms of ultraviolet-induced mutation. Mutational spectra in the Escherichia coli lacI gene for a wild-type and an excision-repair-deficient strain

We have analyzed the DNA sequence changes in a total of 409 ultraviolet light-induced mutations in the lacI gene of Escherichia coli: 227 in a Uvr+ and 182 in a UvrB- strain. Both differences and similarities were observed. In both strains the mutations were predominantly (60 to 75%) base substitutions, followed by smaller contributions of single-base frameshifts, deletions and frameshift hotspot mutations. The base substitutions proved largely similar in the two strains but differences were observed among the single-base frameshifts, the deletions and the hotspot mutations. Among the base substitutions, both transitions (72.5%) and transversions (27.5%) were observed. The largest single group was G.C----A.T (60% of all base substitutions). The sites where G.C----A.T changes occurred were strongly correlated (97.5%) with sequences of adjacent pyrimidines, indicating mutation targeted ultraviolet photoproducts. Comparable amounts of mutation occurred at cytosine/cytosine and (mixed) cytosine/thymine sites. From an analysis of the prevalence of mutation at either the 5' or 3' side of a dipyrimidine, we conclude that both cyclobutane dimers and (6-4) lesions may contribute to mutation. Despite the general similarity of the base-substitution spectra between the wild-type and excision-defective strains, a number of sites were uniquely mutable in the UvrB- strain. Analysis of their surrounding DNA sequences suggested that, in addition to damage directly at the site of mutation, the potential for nearby opposite-strand damage may be important in determining the mutability of a site. The ultraviolet light-induced frameshift mutations were largely single-base losses. Inspection of the DNA sequences at which the frameshifts occurred suggested that they resulted from targeted mutagenesis, probably at cyclobutane pyrimidine dimers. The prevalence of frameshift mutations at homodimers (TT or CC) suggests that their formation involves local misalignment (slippage) and that base-pairing properties are partially retained in cyclobutane dimers. While the frameshift mutations in the Uvr+ strain were distributed over many different sites, more than half in the UvrB- strain were concentrated at a single site. Ultraviolet light-induced deletions as well as frameshift hotspot mutations (+/- TGGC at positions 620 to 632) are considered to be examples of untargeted or semitargeted mutagenesis. Hotspot mutations in the Uvr+ strain showed an increased contribution by (-)TGGC relative to (+)TGGC, indicating that ultraviolet light may specifically promote the loss of the four bases.(ABSTRACT TRUNCATED AT 400 WORDS)     

Sequence specificity of point mutations induced during passage of a UV-irradiated shuttle vector plasmid in monkey cells.

A simian virus 40-based shuttle vector was used to characterize UV-induced mutations generated in mammalian cells. The small size and placement of the mutagenesis marker (the supF suppressor tRNA gene from Escherichia coli) within the vector substantially reduced the frequency of spontaneous mutations normally observed after transfection of mammalian cells with plasmid DNA; hence, UV-induced mutations were easily identified above the spontaneous background. UV-induced mutations characterized by DNA sequencing were found primarily to be base substitutions; about 56% of these were single-base changes, and 17% were tandem double-base changes. About 24% of the UV-induced mutants carried multiple mutations clustered within the 160-base-pair region sequenced. The majority (61%) of base changes were the G . C----A . T transitions; the other transition (A . T----G . C) and all four transversions occurred at about equal frequencies. Hot spots for UV mutagenesis did not correspond to hot spots for UV-induced photoproduct formation (determined by a DNA synthesis arrest assay); in particular, sites of TT dimers were underrepresented among the UV-induced mutations. These observations suggest to us that the DNA polymerase(s) responsible for mutation induction exhibits a localized loss of fidelity in DNA synthesis on UV-damaged templates such that it synthesizes past UV photoproducts, preferentially inserting adenine, and sometimes misincorporates bases at undamaged sites nearby.     

Excision repair influences the site and strand specificity of sunlight mutagenesis in yeast.

A collection of 384 mutations recovered in a tRNA gene (SUP4-o) following exposure of isogenic excision-repair-proficient (RAD1) or deficient (rad1) strains of the yeast Saccharomyces cerevisiae to sunlight was characterized by DNA sequencing. In each case, greater than 90% of the mutations were single base-pair substitutions with events at G.C pairs constituting most of the changes. However, more than half of these substitutions were transversions in the RAD1 strain whereas transitions predominated in the rad1 strain. Tandem double substitutions were recovered in both strains and the individual changes were exclusively G.C----A.T transitions. The majority of single substitutions, and all tandem double changes, were at base-pairs where the pyrimidine(s) was part of a dipyrimidine sequence and the site specificities were consistent with cyclobutane dimers and/or pyrimidine (6-4) pyrimidone photoproducts contributing to sunlight mutagenesis. Yet, the data also pointed to an important role for lesions that form at G.C pairs and give rise to transversions. Analysis of the strand specificity of sunlight mutagenesis indicated that transitions or transversions at G.C pairs occurred preferentially in SUP4-o at sites where a dipyrimidine or a guanine, respectively, was on the transcribed strand. These biases required a functional excision-repair system.     

UV-induced hprt mutations in a UV-sensitive hamster cell line from complementation group 3 are biased towards the transcribed strand.

The molecular nature of 254 nm ultraviolet light (UV)-induced mutations at the hypoxanthine-guanine phosphoribosyltransferase (hprt) locus in UV24 Chinese hamster ovary (CHO) cells, which are defective in nucleotide excision repair, was determined. Sequence analysis of 19 hprt mutants showed that single base substitutions (9 mutants) and tandem base changes (7 mutants) dominated the UV mutation spectrum in this cell line. Sixty-five percent of the base substitutions were GC greater than AT transitions, whereas the rest consisted of transitions and transversions at AT base pairs. Analysis of the distribution of dipyrimidine sites over the two DNA strands, where the photoproducts causing these mutations presumably were formed, showed that 12 out of 14 mutations were located in the transcribed strand of the hprt gene. A similar strand distribution of mutagenic photoproducts as in UV24 has previously been found in two other UV-sensitive Chinese hamster cell lines (V-H1 and UV5), indicating that under defective nucleotide excision repair conditions the induction of mutations is strongly biased towards lesions in the transcribed strand of the hprt gene. A plausible explanation for this phenomenon is that during DNA replication large differences exist in the error rate with which DNA polymerase(s) bypass lesions in the templates for the leading and lagging strand, respectively.     

Abnormal, Error-Prone Bypass of Photoproducts by Xeroderma Pigmentosum Variant Cell Extracts Results in Extreme Strand Bias for the Kinds of Mutations Induced by UV Light

Xeroderma pigmentosum (XP) is a rare genetic disease characterized by a greatly increased susceptibility to sunlight-induced skin cancer. Cells from the majority of patients are defective in nucleotide excision repair. However, cells from one set of patients, XP variants, exhibit normal repair but are abnormally slow in replicating DNA containing UV photoproducts. The frequency of UV radiation-induced mutations in the XP variant cells is significantly higher than that in normal human cells. Furthermore, the kinds of UV-induced mutations differ very significantly from normal. Instead of transitions, mainly C→T, 30% of the base substitutions consist of C→A transversions, all arising from photoproducts located in one strand. Mutations involving cytosine in the other strand are almost all C→T transitions. Forty-five percent of the substitutions involve thymine, and the majority are transversions. To test the hypothesis that the UV hypermutability and the abnormal spectrum of mutations result from abnormal bypass of photoproducts in DNA, we compared extracts from XP variant cells with those from HeLa cells and a fibroblast cell strain, MSU-1.2, for the ability to replicate a UV-irradiated form I M13 phage. The M13 template contains a simian virus 40 origin of replication located directly to the left or to the right of the target gene, lacZα, so that the template for the leading and lagging strands of DNA replication is defined. Reduction of replication to ~37% of the control value required only 1 photoproduct per template for XP variant cell extracts, but ~2.2 photoproducts for HeLa or MSU-1.2 cell extracts. The frequency of mutants induced was four times higher with XP variant cell extracts than with HeLa or MSU-1.2 cell extracts. With XP variant cell extracts, the proportion of C→A transversions reached as high as 43% with either M13 template and arose from photoproducts located in the template for leading-strand synthesis; with HeLa or MSU-1.2 cell extracts, this value was only 5%, and these arose from photoproducts in either strand. With the XP variant extracts, 26% of the substitutions involved thymine, and virtually all were T→A transversions. Sequence analysis of the coding region of the catalytic subunit of DNA polymerase delta in XP variant cell lines revealed two polymorphisms, but these do not account for the reduced bypass fidelity. Our data indicate that the UV hypermutability of XP variant cells results from reduced bypass fidelity and that unlike for normal cells, bypass of photoproducts involving cytosine in the template for the leading strand differs significantly from that of photoproducts in the lagging strand.     

Mutagenicity of a unique thymine-thymine dimer or thymine-thymine pyrimidine pyrimidone (6-4) photoproduct in mammalian cells.

The mutagenic properties of UV-induced photoproducts, both the cis-syn thymine-thymine dimer (TT) and the thymine-thymine pyrimidine pyrimidone (6-4) photoproduct [T(6-4)T] were studied in mammalian cells using shuttle vectors. A shuttle vector able to replicate in both mammalian cells and bacteria was produced in its single-stranded DNA form. A unique photoproduct was inserted at a single restriction site and after recircularization of the single-stranded DNA vector, this latter was transfected into simian COS7 cells. After DNA replication the vector was extracted from cells and used to transform bacteria. Amplified DNA was finally analyzed without any selective screening, DNA from randomly picked bacterial colonies being directly sequenced. Our results show clearly that both lesions are mutagenic, but at different levels. Mutation frequencies of 2 and 60% respectively were observed with the TT dimer and the T(6-4)T. With the TT dimer the mutations were targeted on the 3'-T. With the T(6-4)T a large variety of mutations were observed. A majority of G-->T transversions were semi-targeted to the base before the 5'-T of the photoproduct. These kinds of mutations were not observed when the same plasmid was transfected directly into SOS-induced JM105 bacteria or when the T(6-4)T oligonucleotide inserted in a different plasmid was replicated in SOS-induced SMH10 Escherichia coil bacteria. These semi-targeted mutations are therefore the specific result of bypass of the T(6-4)T lesion in COS7 cells by one of the eukaryotic DNA polymerases.     

Changes in DNA base sequence induced by targeted mutagenesis of lambda phage by ultraviolet light

In targeted mutagenesis of lambda phage by ultraviolet light, the mutations are caused by radiation-induced lesions in the phage DNA. Of 62 mutations in the lambda cI gene that were sequenced, 41 (63%) of the targeted mutations were transitions, with similar numbers of C X G to T X A and T X A to C X G base changes. The remaining 21 mutations were about equally divided among eight transversions, seven frameshifts (5 additions and 2 deletions), and six double events with either two nearby base changes or a base change and a nearby frameshift. Of the 62 mutations, 60 could be associated with -Pyr-Pyr- sequences in the DNA, sites of likely photoproducts. For more information on this point, lambda phage were irradiated with 313 nm light in the presence of acetophenone, for which the major photoproduct is reported to be the thymine-thymine cyclobutyl dimer, with no measurable Pyr(6-4)Pyo photoproducts. Of 22 mutations sequenced, 19 were transversions and only one was a transition, permitting the conclusion that thymine-thymine cyclobutyl dimers are not the primary cause of ultraviolet light-induced transitions. A consideration of all the data strongly suggests that Pyr(6-4)Pyo photoproducts are mutagenic lesions.     

Strand-specific mutation spectra in repair-proficient and repair-deficient hamster cells

The mutation spectrum induced by UV light has been determined at the hprt locus for both cultured normal (AA8) and UV-sensitive (UV-5) Chinese hamster ovary cells to investigate the effect of DNA repair on the nature of induced mutations. DNA base-pair changes of 23 hprt mutants of AA8 and of 28 hprt mutants of UV-5 were determined by sequence analysis of in vitro amplified hprt cDNA. Almost all mutants in AA8 carried single-base substitutions, transitions and transversions accounting for 38% and 62% of the base changes, respectively. In contrast, in repair-deficient cells (UV-5) tandem and nontandem double mutations represented a considerable portion of the mutations observed (30%), whereas the vast majority of base-pair substitutions were GC greater than AT transitions (87%). Moreover, 5 splice mutants and 2 frameshift mutations were found in the UV-5 collection. In almost all mutants analyzed base changes were located at dipyrimidine sites where UV photoproducts could have been formed. In AA8 the photolesions causing mutations were predominantly located in the nontranscribed strand whereas a strong bias for mutation induction towards photolesions in the transcribed strand was found in UV-5. We hypothesize that preferential removal of lesions from the transcribed strand of the hprt gene accounts for the observed DNA strand specificity of mutations in repair-proficient cells. Furthermore, differences in the degree of misincorporation opposite a lesion for lagging and leading strand DNA synthesis may dictate the pattern of UV-induced mutations in the absence of DNA repair.     

Characterization of mutational specificity within the lacI gene for a mutD5 mutator strain of Escherichia coli defective in 3''----5'' exonuclease (proofreading) activity.

The mutD (dnaQ) gene of Escherichia coli codes for the epsilon subunit of the DNA polymerase III holoenzyme which is involved in 3'----5' exonuclease proofreading activity. We determined the mutational specificity of the mutator allele, mutD5, in the lacI gene of E. coli. The mutD5 mutation preferentially produces single base substitutions as judged from the enhanced fraction of lacI nonsense mutations and the spectrum of sequenced dominant lacI (lacId) and constitutive lacO (lacOc) mutations which were predominantly (69/71) single nucleotide substitutions. The distribution of amber lacI and sequenced lacId mutations revealed that transitions occur more frequently than transversions. A . T----G . C and G . C----A . T transitions were equally frequent and, with one major exception, evenly distributed among numerous sites. Among the transversions, A . T----T . A events were the most common, A . T----C . G substitutions were rare, and G . C----C . G changes were not detected. Transversions were unequally distributed among a limited number of sites with obvious hotspots. All 11 sequenced transversions had a consensus neighboring sequence of 5'-C-C-(mutated G or A)-C-3'. Although no large deletions or complex mutational events were recovered, sequencing revealed that mutD5 induced single nucleotide deletions within consecutive G X C sequences. An extraordinary A . T----G . C transition hotspot occurred at nucleotide position +6 in the lac operator region; the mutD5 mutation frequency of this single base pair was calculated to be 1.2 X 10(-3).     

The Role of Pyrimidine Dimers as Premutagenic Lesions: A Study of Targeted VS. Untargeted Mutagenesis in the lacI Gene of ESCHERICHIA COLI

We have employed conjugal transfer of an F' lac episome to examine targeted and untargeted mutagenesis in the lacI gene of Escherichia coli and to determine the relative importance of pyrimidine dimers as premutational UV lesions compared to (6-4) photoproducts that also may have a mutational role. This conjugal system allowed us to assess the premutagenic role of UV lesions independently from any role as inducers of SOS functions. F' DNA was transferred to an SOS-induced recipient strain from: unirradiated donor cells, UV-treated donor cells or donor cells that were irradiated and then exposed to photoreactivating light. The results indicate that SOS-related, untargeted events may account for as much as one-third of the nonsense mutations (i.e., base substitutions) recovered after undamaged F' DNA is transferred to UV-irradiated recipients. When the donor strain also is irradiated, in excess of 90% of the mutations detected following conjugation appear to be targeted. Photoreactivation of the UV-treated donors cells, prior to F' transfer to the SOS-induced recipient strain, demonstrated that in this experimental system virtually all recovered UV-induced mutations are targeted by photoreactivable lesions. We presume that these lesions are pyrimidine dimers because (6-4) photoproducts are not photoreactivable.     

Evidence from mutation spectra that the UV hypermutability of xeroderma pigmentosum variant cells reflects abnormal, error-prone replication on a template containing photoproducts.

Xeroderma pigmentosum (XP) variant patients are genetically predisposed to sunlight-induced skin cancer. Fibroblasts derived from these patients are extremely sensitive to the mutagenic effect of UV radiation and are abnormally slow in replicating DNA containing UV-induced photoproducts. However, unlike cells from the majority of XP patients, XP variant cells have a normal or nearly normal rate of nucleotide excision repair of such damage. To determine whether their UV hypermutability reflected a slower rate of excision of photoproducts specifically during early S phase when the target gene for mutations, i.e., the hypoxanthine (guanine) phosphoribosyltransferase gene (HPRT), is replicated, we synchronized diploid populations of normal and XP variant fibroblasts, irradiated them in early S phase, and compared the rate of loss of cyclobutane pyrimidine dimers and 6-4 pyrimidine-pyrimidones from DNA during S phase. There was no difference. Both removed 94% of the 6-4 pyrimidine-pyrimidones within 8 h and 40% of the dimers within 11 h. There was also no difference between the two cell lines in the rate of repair during G1 phase. To determine whether the hypermutability resulted from abnormal error-prone replication of DNA containing photoproducts, we determined the spectra of mutations induced in the coding region of the HPRT gene of XP variant cells irradiated in early S and G1 phases and compared with those found in normal cells. The majority of the mutations in both types of cells were base substitutions, but the two types of cells differed significantly from each other in the kinds of substitutions, but the two types differed significantly from each other in the kinds of substitutions observed either in mutants from S phase (P < 0.01) or from G1 phase (P = 0.03). In the variant cells, the substitutions were mainly transversions (58% in S, 73% in G1). In the normal cells irradiated in S, the majority of the substitutions were G.C --> A.T, and most involved CC photoproducts in the transcribed strand. In the variant cells irradiated in S, substitutions involving cytosine in the transcribed strand were G.C --> T.A transversions exclusively. G.C --> A.T transitions made up a much smaller fraction of the substitutions than in normal cells (P < 0.02), and all of them involved photoproducts located in the nontranscribed strand. The data strongly suggest that XP variant cells are much less likely than normal cells to incorporate either dAMP or dGMP opposite the pyrimidines involved in photoproducts. This would account for their significantly higher frequency of mutants and might explain their abnormal delay in replicating a UV-damaged template.     

Specificity of spontaneous mutations induced in mutA mutator cells

Escherichia coli cells expressing the mutA allele of a glyV (glycine tRNA) gene express a strong mutator phenotype. The mutA allele differs from the wild type glyV gene by a base substitution in the anticodon such that the resulting tRNA misreads certain aspartate codons as glycine, resulting in random, low-level Asp-->Gly substitutions in proteins. Subsequent work showed that many types of mistranslation can lead to a very similar phenotype, named TSM for translational stress-induced mutagenesis. Here, we have determined the specificity of forward mutations occurring in the lacI gene in mutA cells as well as in wild type cells. Our results show that in comparison to wild type cells, base substitutions are elevated 23-fold in mutA cells, as against a eight-fold increase in insertions and a five-fold increase in deletions. Among base substitutions, transitions are elevated 13-fold, with both G:C-->A:T and A:T-->G:C mutations showing roughly similar increases. Transversions are elevated 35-fold, with G:C-->T:A, G:C-->C:G and A:T-->C:G elevated 28-, 13- and 27-fold, respectively. A:T-->T:A mutations increase a striking 348-fold over parental cells, with most occurring at two hotspot sequences that share the G:C-rich sequence 5'-CCGCGTGG. The increase in transversion mutations is similar to that observed in cells defective for dnaQ, the gene encoding the proofreading function of DNA polymerase III. In particular, the relative proportions and sites of occurrence of A:T-->T:A transversions are similar in mutA and mutD5 (an allele of dnaQ) cells. Interestingly, transversions are also the predominant base substitutions induced in dnaE173 cells in which a missense mutation in the alpha subunit of polymerase III abolishes proofreading without affecting the 3'-->5' exonuclease activity of the epsilon subunit.     

Mutations induced by ultraviolet light

The different ultraviolet (UV) wavelength components, UVA (320-400 nm), UVB (280-320 nm), and UVC (200-280 nm), have distinct mutagenic properties. A hallmark of UVC and UVB mutagenesis is the high frequency of transition mutations at dipyrimidine sequences containing cytosine. In human skin cancers, about 35% of all mutations in the p53 gene are transitions at dipyrimidines within the sequence 5'-TCG and 5'-CCG, and these are localized at several mutational hotspots. Since 5'-CG sequences are methylated along the p53 coding sequence in human cells, these mutations may be derived from sunlight-induced pyrimidine dimers forming at sequences that contain 5-methylcytosine. Cyclobutane pyrimidine dimers (CPDs) form preferentially at dipyrimidines containing 5-methylcytosine when cells are irradiated with UVB or sunlight. In order to define the contribution of 5-methylcytosine to sunlight-induced mutations, the lacI and cII transgenes in mouse fibroblasts were used as mutational targets. After 254 nm UVC irradiation, only 6-9% of the base substitutions were at dipyrimidines containing 5-methylcytosine. However, 24-32% of the solar light-induced mutations were at dipyrimidines that contain 5-methylcytosine and most of these mutations were transitions. Thus, CPDs forming preferentially at dipyrimidines with 5-methylcytosine are responsible for a considerable fraction of the mutations induced by sunlight in mammalian cells. Using mouse cell lines harboring photoproduct-specific photolyases and mutational reporter genes, we showed that CPDs (rather than 6-4 photoproducts or other lesions) are responsible for the great majority of UVB-induced mutations. An important component of UVB mutagenesis is the deamination of cytosine and 5-methylcytosine within CPDs. The mutational specificity of long-wave UVA (340-400 nm) is distinct from that of the shorter wavelength UV and is characterized mainly by G to T transversions presumably arising through mechanisms involving oxidized DNA bases. We also discuss the role of DNA damage-tolerant DNA polymerases in UV lesion bypass and mutagenesis.     

Neighboring base identity affects N-ethyl-N-nitrosourea-induced mutagenesis in Escherichia coli

This study investigated the influence of different neighboring base contexts on the production of base substitutions generated by N-ethyl-N-nitrosourea (ENU). A set of bacterial strains having all possible bases neighboring an ochre (TAA) nonsense mutation in the tyrA gene of Escherichia coli were employed and true reversions of the nonsense mutation were induced by two separate doses of ENU. Base substitution mutations were investigated by direct sequencing methods. These studies revealed that 1) mutations occurring at 5'-purine-T sites were produced better, on average, than mutations involving 5'-pyrimidine-T sites, and 5'-TT sites contributed the least to the formation of mutations, 2) the order of preference for A:T to G:C transitions was 5'-GT>5'-AT, 5'-CT>5'-TT, and 3) A:T to C:G transversions at the first position of the codon (GAA mutations) were produced best at 5'-AT sites, while A:T to T:A transversions at the third position (TAT mutations) occurred more often at 5'-GT sites. These findings suggest that the occurrence of a specific mutation may reflect the sequence-dependent probability of DNA damage at a particular site as well as factors involving preferential DNA repair or differential base selection by DNA polymerase.     

Specificity of mutational DNA sequence changes induced by X-rays in the cloned Escherichia coli crp gene.

Plasmid DNA carrying the adenosine 3',5'-cyclic monophosphate receptor protein (crp) gene of Escherichia coli was irradiated, in solution, with X-rays, and the mutations produced in the crp gene were assayed by transforming the recipient E. coli cells. Ninety-six mutant clones were isolated, and mutational changes were determined by DNA sequencing. Of the 92 mutations thus detected, 74 represented base substitution mutations and the remaining 18 were frameshifts. The base substitutions included 56 G:C to A:T transitions, 10 G:C to T:A transversions and 7 G:C to C:G transversions. An A:T to G:C transition was found only once, and neither an A:T to T:A nor an A:T to C:G transversion was detected. The frameshift mutations consisted of 11 one-base deletions and 7 one-base insertions. Accordingly, G:C to A:T transition was the predominant type of mutation, which constituted 76% (56/74) of the total base substitutions and 60% (56/92) of all detected mutations. Furthermore, of the 56 transitions, about three-quarters (41 clones) clustered at an identical site, a cytosine residue at the 706 position, demonstrating that this site is a distinct hot spot for X-ray mutagenesis. These results raise the possibility that radiation-induced mutations may not necessarily occur randomly, at least in certain cases.     

Polymerase-specific differences in the DNA intermediates of frameshift mutagenesis. In vitro synthesis errors of Escherichia coli DNA polymerase I and its large fragment derivative

The sequences of more than 600 frameshift mutations produced as a consequence of in vitro DNA replication on an oligonucleotide-primed, single-stranded DNA template by the Escherichia coli polymerase I enzyme (PolI) or its large fragment derivative (PolLF) were compared. Four categories of mutants were found: (1) single-base deletions, (2) base substitutions, (3) multiple-base deletions and (4) complex frameshift mutations that change both the base sequence and the number of bases in a concerted mutational process. The template sequence 5'-Py-T-G-3', previously identified as a PolLF hotspot for single-base deletions opposite G, is also a hotspot for PolI. A PolI-specific warm spot for single-base deletions was identified. Among base substitutions, transitions were more frequent than transversions. Transversions were mediated by (template)G.G, (template)G.A, and (template)C.T mispairs. Multiple-base deletions were found only after PolI replication. Although each of these deletions can be explained by a misalignment mediated by directly repeated DNA sequences, deletion frequencies were often different for repeats of the same length. Both PolI and PolLF produced many complex frameshift mutants. The new sequences at the mutant sites are exactly complementary to nearby DNA sequences in the newly synthesized DNA strand. In each case, palindromic complementarity could mediate the misalignment needed to initiate the mutational process. The misaligned DNA synthesis accounts for the nucleotide changes at the mutant site and for homology that could direct realignment of the DNA onto the template. Most of the complex mutant sequences could be initiated by either intramolecular misalignments involving fold-back structures in newly synthesized DNA or by strand-switching during strand-displacement synthesis. The striking differences between the specificities of complex frameshift mutations and multiple-base deletions by PolI and PolLF identify the existence of polymerase-specific determinants that influence the frequency and specificity of misalignment-mediated frameshifts and deletions.     

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.     

DNA base sequence changes in spontaneous and ethyl methanesulfonate-induced mutations of a chromosomally-integrated gene in Chinese hamster ovary cells

A series of spontaneous and ethyl methanesulfonate-induced 6-thioguanine-resistant mutants were isolated in the CHO-10T5 cell line. This cell line was constructed by the introduction of a shuttle vector containing the Escherichia coli gpt gene into a hypoxanthine-guanine phosphoribosyltransferase deficient derivative of the Chinese hamster cell line CHO-K1. Shuttle vector sequences were recovered from many of the mutant cell lines by the COS cell fusion technique and the DNA base sequence of the gpt genes was determined whenever possible.

The base sequences were determined for gpt genes recovered from 29 spontaneous mutants. Of these 29 mutants, 9 have single base substitutions, 1 has a small duplication, 17 have simple deletions, 1 has a deletion with additional bases inserted at the deletion site, and 1 has no change in the gpt coding sequence. Many of the deletions were less than 20 basepairs in length and several occurred in a region previously observed to be a hotspot for spontaneous deletions. The generation of the deletion/insertion mutation may have involved a quasi-palindromic intermediate.

A total of 59 ethyl methansesulfonate-induced mutants were isolated and vector sequences were recovered from 50 mutants. All 50 mutants sequenced had single base substitutions and most (45) were G:C to A:T transitions. While there were no strong hotspots in this collection of mutations, the site distribution was obviously nonrandom. Many of the G:C to A:T transitions either produced a nonsense codon or occurred at glycine codons.     

The (6-4) photoproduct of thymine-thymine induces targeted substitution mutations in mammalian cells.

Two major ultraviolet-induced photolesions of TpT, a (6-4) photoproduct [T(6-4)T] and a cis-syn cyclobutane TT dimer (T=T), were incorporated into a predetermined site of one of the leading and lagging template strands of a double-stranded vector, and the modified DNAs were transfected into simian COS-7 cells. The DNAs replicated in the cells were recovered and were transfected again into Escherichia coli. The DNA replication efficiencies of plasmids containing T(6-4)T and T=T in the template strand for lagging strand synthesis were 93 and 79%, respectively, as compared with the unmodified DNA. Similar inhibitory effects were observed in the cases of the photoproducts in the template strand for leading strand synthesis (71 and 58%, respectively). These results indicated that T(6-4)T blocked DNA replication more weakly than T=T during leading and lagging strand syntheses in mammalian cells. The mutation frequencies of T(6-4)T were 2.3 and 4.7% in the leading and lagging template strands, respectively. The T=T lesion was less mutagenic and induced mutations with 0.2-0.7% frequencies. The T(6-4)T lesion primarily elicited 3'-T-->C substitutions, and T=T induced various types of mutations. These results indicate that T(6-4)T is more mutagenic than T=T during leading and lagging strand syntheses in simian cells. Moreover, this is the first evidence that shows T(6-4)T mainly elicits targeted substitutions at its 3'-T site in mammalian cells.     

Genetic effects of oxidative DNA damages: comparative mutagenesis of the imidazole ring-opened formamidopyrimidines (Fapy lesions) and 8-oxo-purines in simian kidney cells

Fapy.dG and 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxo-dG) are formed in DNA by hydroxyl radical damage. In order to study replication past these lesions in cells, we constructed a single-stranded shuttle vector containing the lesion in 5'-TGT and 5'-TGA sequence contexts. Replication of the modified vector in simian kidney (COS-7) cells showed that Fapy.dG is mutagenic inducing primarily targeted Fapy.G-->T transversions. In the 5'-TGT sequence mutational frequency of Fapy.dG was approximately 30%, whereas in the 5'-TGA sequence it was approximately 8%. In parallel studies 8-oxo-dG was found to be slightly less mutagenic than Fapy.dG, though it also exhibited a similar context effect: 4-fold G-->T transversions (24% versus 6%) occurred in the 5'-TGT sequence relative to 5'-TGA. To investigate a possible structural basis for the higher G-->T mutations induced by both lesions when their 3' neighbor was T, we carried out a molecular modeling investigation in the active site of DNA polymerase beta, which is known to incorporate both dCTP (no mutation) and dATP (G-->T substitution) opposite 8-oxo-G. In pol beta, the syn-8-oxo-G:dATP pair showed greater stacking with the 3'-T:A base pair in the 5'-TGT sequence compared with the 3'-A:T in the 5'-TGA sequence, whereas stacking for the anti-8-oxo-G:dCTP pair was similar in both 5'-TGT and 5'-TGA sequences. Similarly, syn-Fapy.G:dATP pairing showed greater stacking in the 5'-TGT sequence compared with the 5'-TGA sequence, while stacking for anti-Fapy.G:dCTP pairs was similar in the two sequences. Thus, for both lesions less efficient base stacking between the lesion:dATP pair and the 3'-A:T base pair in the 5'-TGA sequence might cause lower G-->T mutational frequencies in the 5'-TGA sequence compared to 5'-TGT. The corresponding lesions derived from 2'-deoxyadenosine, Fapy.dA and 8-oxo-dA, were not detectably mutagenic in the 5'-TAT sequence, and were only weakly mutagenic (<1%) in the 5'-TAA sequence context, where both lesions induced targeted A-->C transversions. To our knowledge this is the first investigation using extrachromosomal probes containing a Fapy.dG or Fapy.dA site-specifically incorporated, which showed unequivocally that in simian kidney cells Fapy.G-->T substitutions occur at a higher frequency than 8-oxo-G-->T and that Fapy.dA is very weakly mutagenic, as is 8-oxo-dA.