Expression of beta-galactosidase from a hybrid promoter:operator element in Escherichia coli.

A hybrid trpPO:lacO regulatory sequence was cloned upstream of a promoterless lacZ gene and recombined onto a lambda bacteriophage. Escherichia coli lysogens representing the four possible phenotypes for lacI and trpR were constructed and the synthesis of beta-galactosidase was assayed under various growth conditions. The results illustrated that both control elements could be efficiently and independently regulated by the addition or omission of appropriate accessory molecules.

Uracil-DNA glycosylase activity affects the mutagenicity of ethyl methanesulfonate: evidence for an alternative pathway of alkylation mutagenesis.

Mutagenesis induced by the alkylating agent ethyl methanesulfonate (EMS) is thought to occur primarily via mechanisms that involve direct mispairing at alkylated guanines, in particular, O6-ethyl guanine. Recent evidence indicates that alkylation of guanine at the O-6 position might enhance the deamination of cytosine residues in the complementary strand. To determine whether such deamination of cytosine could play a role in the production of mutations by EMS, the efficacy of this agent was tested in uracil-DNA glycosylase deficient (Ung) strains of Escherichia coli. The Ung- strains showed a linear response with increasing doses of EMS. This response was independent of the umuC gene product. In contrast, the Ung+ strains yielded a dose-squared response that became linear at higher doses of EMS when the cells were defective for the umuC gene product. These results support a model for mutagenesis involving the deamination of cytosines opposite O6-alkylated guanines followed by an error-prone repair event.

Missense mutation in the lacI gene of Escherichia coli. Inferences on the structure of the repressor protein.

The lac repressor has been studied extensively but a precise three-dimensional structure remains unknown. Studies using mutational data can complement other information and provide insight into protein structure. We have been using the lacI gene-repressor protein system to study the mutational specificity of spontaneous and induced mutation. The sequencing of over 6000 lacI- mutations has revealed 193 missense mutations generating 189 amino acid replacements at 102 different sites within the lac repressor. Replacement sites are not distributed evenly throughout the protein, but are clustered in defined regions. Almost 40% of all sites and over one-half of all substitutions found occur within the amino-terminal 59 amino acid residues, which constitute the DNA-binding domain. The core domain (residues 60 to 360) is less sensitive to amino acid replacement. Here, substitution is found in regions involved in subunit aggregation and at sites surrounding residues that are implicated in sugar-binding. The distribution and nature of missense mutational sites directs attention to particular amino acid residues and residue stretches.

Asymmetric cytosine deamination revealed by spontaneous mutational specificity in an Ung- strain of Escherichia coli.

A collection of 164 spontaneous lacI- mutations were recovered from a uracil-DNA glycosylase deficient (Ung-) strain of Escherichia coli and analyzed by DNA sequencing. As predicted by genetic studies, G:C----A:T transitions predominated among base substitution events. However, DNA sequence analysis indicated that these events did not occur at random. Of the 31 G:C----A:T transitions recovered, 24 involved cytosine residues located in the nontranscribed strand of the gene and 15 of the 31 transitions occurred at cytosines located on the 3' side of 3 or more A:T base pairs. These differentials likely reflect the more single-stranded character of the non-transcribed strand of the gene and of regions rich in A:T base pairs. In addition, mutation at the frameshift hotspot was altered in the Ung- strain, suggesting a role for DNA repair in the formation of structural intermediates that potentiate these events. Also, the analysis of non-hotspot frameshifts, deletions and duplications showed that many involved local DNA sequence. Specifically, several of the frameshift, deletion and duplication mutations occurred near the sequence 5'-CTGG-3'. Thus, DNA sequence analysis of mutational specificity in an Ung- strain has provided evidence that gene expression, DNA repair and DNA context can all potentially influence the classes and frequencies of spontaneous mutation.

Thermal resistance to photoreactivation of ultraviolet light induced mutations in the lacI gene of E. coli ung.

Ultraviolet light (UV) induced mutations in the lacI gene of Escherichia coli are thought to be targeted by DNA photoproducts. A number of reports suggest that both cyclobutyl pyrimidine dimers and pyrimidine (6-4) pyrimidone photoproducts may be involved. To investigate the potential contribution of each of these DNA photoproducts to mutagenesis in the lacI gene, we held UV-irradiated cells at a temperature of 44 degrees C for 75 min and then exposed them to photoreactivating light (PR). This protocol is expected to preferentially deaminate specifically those cytosines that are contained in cyclobutyl dimers and subsequently monomerize the dimers to yield uracils in the DNA. In a strain deficient for uracil-DNA glycosylase (Ung-), these uracils would not be removed and a G:C----A:T transition would result at the site of the dimer. This protocol resulted in the enhancement of amber nonsense mutations that result from transitions at potential cytosine-containing dimer sites. The enhanced mutation frequencies resulting from this procedure were used to estimate the probability of dimer formation at the individual sites. A comparison of the dimer distribution with the mutation frequencies following UV alone suggests that both cyclobutyl dimers and (6-4) photoproducts contribute to UV-mutagenesis in the lacI gene. In addition, we conclude that the frequency of mutation at any particular site not only reflects the occurrence of DNA damage, but also the action of metabolic processes that are responsible for DNA repair and mutagenesis.

DNA sequence analysis of spontaneous mutation in a PolA1 strain of Escherichia coli indicates sequence-specific effects.

The sequences of a collection of 261 spontaneous lacI- mutants recovered in a PolA- strain of Escherichia coli have indicated an increase in the frequency of most classes of mutation in this strain. Among base substitutions in lacI, a preference for transversions over transitions was observed. In addition, a single transition in the lac operator was enhanced 8-fold. More significantly, of 18 frameshifts, 12 occurred adjacent to a 5'-GTGG-3' sequence. Likewise, 15 of 24 deletions and 2 of 10 duplications had 5'-GTGG-3' sequences at one or both endpoints. We speculate that the prevalence of mutations at these specific sequences reflects the persistence of strand discontinuities that enhance the opportunity for mutagenic mishaps. Further, 5'-GTGG-3' sequences apparently represent sites where DNA polymerase I is involved in some aspect of DNA metabolism. These results strengthen the view that DNA context contributes an important component to spontaneous mutagenesis and indicate an anti-mutagenic role for DNA polymerase I.

Differential enhancement of spontaneous transition mutations in the lacI gene of an Ung- strain of Escherichia coli.

In this communication, the contribution of cytosine deamination to spontaneous mutagenesis in the lacI gene of E. coli was examined. In a wild-type strain, 75% of the amber mutations recovered were G:C----A:T transitions and 60% of these were at the 5-methylcytosine spontaneous hotspots Am6, Am15 and Am34. In a strain deficient for uracil-DNA glycosylase (Ung-), 96% of the amber mutations were G:C----A:T transitions while only 15% of these occurred at the hotspot sites. This shift in the mutational distribution demonstrates that cytosine deamination is a potent mutagenic process, which is enhanced in the absence of glycosylase. Moreover, some amber sites were greatly enhanced in the Ung- strain while others were only slightly enhanced. This result suggests that the rate of cytosine deamination at individual sites may be influenced by surrounding base composition. Therefore, we examined the neighboring sequences and found a strong correlation between the fold-increase in mutation and the A/T richness of the surrounding sequence. It is suggested that A/T-rich regions denature more often, forming transient single strands in which cytosine residues would be expected to deaminate more readily.

Thermal resistance of UV-mutagenesis to photoreactivation in E. coli B/r uvrA ung: estimate of activation energy and further analysis.

Ultraviolet light (UV) induced mutations in the glnU and glnVa tRNA genes in Escherichia coli are thought to be targeted by UV photoproducts. In a previous study with a uracil-DNA glycosylase deficient strain, UV-induced glnU0 and glnV0 tRNA suppressor mutations became resistant to photoreactivation (PR) following thermal treatment. It was proposed that deamination of cytosine in the cytosine-containing cyclobutyl dimers at the sites of these suppressor mutations produced uracil residues in sequence upon PR. In the absence of glycosylase, the C----U conversion yielded the requisite G:C----A:T transitions. In the present study, this thermal resistance of UV-mutagenesis to PR is characterized. It is dependent on the initial UV-fluence and temperature of holding but not on the UmuC+ gene product. The data obtained yield an estimate of an activation energy of 17 +/- 3 kcal/mol for the deamination of cytosines contained in dimers. This compares to 29 kcal/mol for unaffected cytosines in DNA. In addition, an estimate of the probability of cyclobutyl dimer formation at the target sites for glnU0 and glnV0 suppressor mutations indicate that these lesions can not entirely account for the mutation frequencies recovered in the absence of PR. This is interpreted as an indication that, in addition to thymine-cytosine cyclobutyl dimers, other UV-induced lesions, possibly Thy(6-4)Cyt photoproducts, may also target glnU0 and glnV0 suppressor mutations.