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.     

Influence of neighbouring base sequence on N-methyl-N'-nitro-N-nitrosoguanidine mutagenesis in the lacI gene of Escherichia coli

N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)-induced forward mutations within the first 540 base-pairs of the lacI gene of Escherichia coli were cloned and sequenced. In total, 167 MNNG-induced independent mutations were characterized, with G.C to A.T transitions accounting for all but three of the mutations. This mutagenic specificity is consistent with the mispairing predicted by the methylation of the O6 position of guanine. The characterization of such large numbers of mutations permitted an analysis of the influence of local DNA sequence on mutagenesis. This analysis revealed a strong influence by the 5' flanking base. On average, guanine residues preceded (5') by a guanine or an adenine residue were, respectively, nine times and five times more likely to mutate after treatment with MNNG than those preceded by a pyrimidine residue.     

Photoreactivation implicates cyclobutane dimers as the major promutagenic UVB lesions in yeast.

Previously we compared the mutational specificities of polychromatic UVB (285-320 nm) and UVC (254 nm) light in the SUP4-o gene of the yeast Saccharomyces cerevisiae. Striking similarities in the types and distributions of induced SUP4-o mutations were consistent with roles for cyclobutane dimers and pyrimidine(6-4)pyrimidone photoproducts in mutation induction by UVB. To assess the relative importance of cyclobutane dimers, we have now examined the effect of photoreactivation (PR), which specifically reverses these lesions, on UVB and UVC induction of SUP4-o mutations. PR reduced the frequencies of both UVB and UVC mutagenesis by approximately 75%. Collections of 138 and 158 SUP4-o mutants induced by treatment with UVB plus PR or UVC plus PR, respectively, were characterized by DNA sequencing and the results were compared to those for 208 UVB and 211 UVC-induced mutants analyzed earlier. PR decreased the frequency of UVB-induced G.C----A.T transitions by 85%, diminished the substitution frequencies at individual sites by 64% on average, and reduced the mutation frequencies at the five UVB hotspots by 87%. A more detailed examination revealed that the transition frequencies at the 3' base of 5'-TC-3' and 5'-CC-3' sequences were decreased by 90% and 72%, respectively. Finally, PR appeared to occur to the same extent on both the transcribed and non-transcribed strands of SUP4-o. Similar results were obtained for PR following UVC irradiation. Our findings indicate that cyclobutane dimers are responsible for the majority of UVB mutagenesis in yeast.     

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.     

Base-pair substitutions alter the site-specific mutagenicity of UV and MNNG in the SUP4-o gene of yeast

Yeast strains carrying SUP4-o genes that have base-pair substitutions at hotspots for UV or MNNG mutagenesis were treated with these agents. In both cases, the induced mutation frequencies were substantially reduced. Furthermore, specific substitutions at positions in SUP4-o that had not been mutated by MNNG resulted in the recovery of MNNG-induced mutations at these sites. These results demonstrate that base-pair identity is an important factor determining the site-specific mutagenicity of UV and MNNG in yeast. For UV, our findings suggest that the type of lesion that is induced, but not flanking DNA sequences, plays a role in specifying mutability at the sites examined. In contrast, DNA sequence context seems to be an important factor for MNNG mutagenesis.     

Disruption of the Rad52 Gene Alters the Spectrum of Spontaneous Sup4-O Mutations in Saccharomyces Cerevisiae

Defects in the RAD52 gene of the yeast Saccharomyces cerevisiae confer a mutator phenotype. To characterize this effect in detail, a collection of 238 spontaneous SUP4-o mutations arising in a strain having a disrupted RAD52 gene was analyzed by DNA sequencing. The resulting mutational spectrum was compared to that derived from an examination of 222 spontaneous mutations selected in a nearisogenic wild-type (RAD52) strain. This comparison revealed that the mutator phenotype was associated with an increase in the frequency of base-pair substitutions. All possible types of substitution were detected but there was a reduction in the relative fraction of A.T----G.C transitions and an increase in the proportion of G.C----C.G transversions. These changes were sufficient to cause a twofold greater preference for substitutions at G.C sites in the rad52 strain despite a decrease in the fraction of G.C----T.A transversions. There were also considerable differences between the distributions of substitutions within the SUP4-o gene. Base-pair changes occurred at fewer sites in the rad52 strain but the mutated sites included several that were not detected in the RAD52 background. Only two of the four sites that were mutated most frequently in the rad52 strain were also prominent in the wild-type strain and mutation frequencies at almost all sites common to both strains were greater for the rad52 derivative. Although single base-pair deletions occurred in the two strains with similar frequencies, several classes of mutation that were recovered in the wild-type background including multiple base-pair deletions, insertions of the yeast transposable element Ty, and more complex changes, were not detected in the rad52 strain.(ABSTRACT TRUNCATED AT 250 WORDS)     

DNA base changes induced following in vivo exposure of unadapted, adapted or ada- Escherichia coli to N-methyl-N'-nitro-N-nitrosoguanidine

The adaptive response is one of the major repair pathways in Escherichia coli that removes DNA alkylation damage. To investigate the role of the adaptive response in mutagenesis, the E. coli gpt forward mutation assay system was used to determine the mutation spectrum of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) in MNNG-adapted and unadapted GP120 (wild-type) and unadapted PJ5 (ada-5) cells. We observed that 34/37 mutations in the unadapted GP120 cells, 38/40 mutations in the adapted GP120 cells, and 10/10 mutations in the PJ5 cells were GC----AT transitions. The remaining 3/37 mutations in the unadapted GP120 cells were large insertions. The remaining 2/40 mutations in the adapted GP120 cells were transversions with one a GC----CG and the other an AT----CG. A surrounding sequence specificity of mutagenesis was observed for the GC----AT transitions in both the unadapted (GP120 and PJ5) and adapted (GP120) cells, with 70% of the unadapted PJ5, 68% of the unadapted GP120, and 61% of the adapted GP120 mutations occurring at the middle G of the sequence 5'--GG(A or T)--3'. Both strains also displayed a statistically significant preference for mutagenesis at guanine bases in the non-transcribed strand. The overall distribution of mutated sites in the gpt gene in adapted and unadapted cells was similar, although the rate of mutations at certain sites appeared different. These minor differences could result from either non-uniform repair of alkylation damage at different sites on the DNA, or altered processing of the alkylated bases to mutations in the adapted state.(ABSTRACT TRUNCATED AT 250 WORDS)     

Novel mutational spectrum induced by N-methyl-N'-nitro-N-nitrosoguanidine in the coding region of the hypoxanthine (guanine) phosphoribosyltransferase gene in diploid human fibroblasts

The kinds and locations of mutations in the coding region of the hypoxanthine (guanine) phosphoribosyltransferase (hprt) gene of 75 independent mutants, derived from N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)-treated normal human fibroblasts, were characterized by direct sequencing of mRNA-polymerase chain reaction (mRNA-PCR)-amplified cDNA. Treatment of human cells with low (6 or 8 microM) or high (10 or 12 microM) doses of MNNG resulted in 35-fold or 150-fold average increases in mutation frequency, respectively. A high frequency of mutants lacking a complete exon was observed in both groups. Further characterization of half of these mutants by DNA-PCR amplification of intron-exon boundaries showed that they contained base substitutions. The kinds of base substitutions differed distinctly between these two groups. In the low dose group, a broad mutational spectrum was observed: ten out of the 31 base substitutions were A.T to G.C transitions, six contained G.C to A.T transitions, and the other 15 exhibited transversions. In contrast, the majority (84%) of base substitutions among the high dose group were G.C to A.T transitions; the others (16%) were transversions. All of the 32 G.C to A.T transitions were located on the non-transcribed strand, assuming that the causative premutational lesion was O6-methylguanine. These results indicate preferential repair of lesions located on the transcribed strand. In addition, G.C to A.T and A.T to G.C transitions preferentially occurred at positions with guanine and thymine at the adjacent 5' position, respectively.     

The yeast rad18 mutator specifically increases G.C----T.A transversions without reducing correction of G-A or C-T mismatches to G.C pairs.

Inactivation of the Saccharomyces cerevisiae RAD18 gene confers a mutator phenotype. To determine the specificity of this effect, a collection of 212 spontaneous SUP4-o mutants arising in a rad18 strain was characterized by DNA sequencing. Comparison of the resulting mutational spectrum with that for an isogenic wild-type (RAD18) strain revealed that the rad18 mutator specifically enhanced the frequency of single base pair substitutions. Further analysis indicated that an increase in the frequency of G.C----T.A transversions accounted for the elevated SUP4-o mutation frequency. Thus, rad18 is the first eucaryotic mutator found to generate only a particular base pair substitution. The majority of G.C pairs that were not mutated in the rad18 background were at sites where G.C----T.A events can be detected in SUP4-o, suggesting that DNA sequence context influences the rad18 mutator effect. Transformation of heteroduplex plasmid DNAs into the two strains demonstrated that the rad18 mutator did not reduce the efficiency of correcting G-A or C-T mismatches to G.C pairs or preferentially correct the mismatches to A.T pairs. We propose that the RAD18 gene product might contribute to the fidelity of DNA replication in S. cerevisiae by involvement in a process that serves to limit the formation of G-A and C-T mismatches at template guanine and cytosine sites during DNA synthesis.     

N-methyl-N'-nitro-N-nitrosoguanidine-induced mutation in a RecA strain of Escherichia coli

274 N-methyl-N'-nitro-N-nitrosoguanidine (MNNG)-induced forward mutations in the lacI gene of an Escherichia coli RecA- strain were cloned and sequenced. Base substitutions accounted for 264 mutations and consisted of 261 G:C----A:T transitions (including one double mutant with two G:C----A:T transitions separated by 25 base pairs), two A:T----G:C transitions and one A:T----T:A transversion. Therefore, 263 of the 274 mutations (all the transitions) can be explained as a result of the direct mispairing of O6-methylguanine, and O4-methylthymine residues during DNA synthesis. The source of the transversion is not known. The remaining mutations, one 16-base pair deletion, two -1 frameshifts and 7 frameshifts at the lacI frameshift hotspot, are located in runs of identical bases or flanked by directly repeated DNA sequences and can therefore be explained by template slippage events during DNA synthesis. The observed distribution of mutations recovered is identical to that found in a RecA+ background indicating little involvement of RecA function in MNNG-induced mutation. Analysis of neighbouring base sequence revealed that the G:C----A:T transition was 6 times more likely to be recovered if the mutated guanine residue was preceded by a purine rather than a pyrimidine. A most striking aspect of this distribution concerns particular residues in the core domain of the lac repressor protein. Within this domain the great majority of mutations generate nonsense codons or alter Gly codons.