Mutation probe of gene structure in E. coli: suppressor mutations in the seven-tRNA operon

Activity-based selection of HIV-1 reverse transcriptase variants with decreased polymerization fidelity

HIV-1 reverse transcriptase (HIV-1 RT) copies the RNA genome of HIV-1 into DNA, thereby committing errors at an exceptionally high frequency. Viral offspring evolve rapidly and consequently are capable of evading the immune response as well as antiviral treatment. However, error-prone viral replication could drive HIV close to extinction owing to an intolerable load of deleterious mutations. We applied a genetic selection scheme to identify variants of HIV-1 RT with a further increased error rate to study the relationship between error rate and viral replication. Using this approach, we identified 16 mutator candidates, two of which were purified and further studiedin vitro. One of these variant enzymes showed a generally increased mutation frequency as compared with the reference enzyme. A single amino acid residue, R448, is probably responsible for the observed effect. Mutation of this residue, which is located within the RNase H domain of HIV-1 RT, seems to perturb the interaction with template RNA and consequently affects polymerase activity and fidelity.

Base excision repair and its role in maintaining genome stability

For all living organisms, genome stability is important, but is also under constant threat because various environmental and endogenous damaging agents can modify the structural properties of DNA bases. As a defense, organisms have developed different DNA repair pathways. Base excision repair (BER) is the predominant pathway for coping with a broad range of small lesions resulting from oxidation, alkylation, and deamination, which modify individual bases without large effect on the double helix structure. As, in mammalian cells, this damage is estimated to account daily for 10(4) events per cell, the need for BER pathways is unquestionable. The damage-specific removal is carried out by a considerable group of enzymes, designated as DNA glycosylases. Each DNA glycosylase has its unique specificity and many of them are ubiquitous in microorganisms, mammals, and plants. Here, we review the importance of the BER pathway and we focus on the different roles of DNA glycosylases in various organisms.

Transcriptional mutagenesis and DNA strand asymmetrical mutations expressed in Escherichia coli under restrictive metabolic conditions

Mutagenesis by C-to-U events specifically in either DNA strand assayed with ung uvrA defective Escherichia coli on a metabolically restrictive medium produces more glutamine tRNA suppressor mutations from U occurring in the non-transcribed DNA strand than from U in the transcribed (template) DNA strand. This bias is the reverse of what might be expected from transcriptional mutagenesis (mutation expression utilizing mutated RNA transcribed from damaged template strand DNA). The results and related ideas are discussed.

A genetic system to identify DNA polymerase beta mutator mutants

DNA polymerase beta (pol beta) is a 39-kDa protein that functions in DNA repair processes in mammalian cells. As a first step toward understanding mechanisms of polymerase fidelity, we developed a genetic method to identify mammalian pol beta mutator mutants. This screen takes advantage of a microbial genetics assay and the ability of rat pol beta to substitute for Escherichia coli DNA polymerase I in DNA replication in vivo. Using this screen, we identified 13 candidate pol beta mutator mutants. Three of the candidate mutator mutants were further characterized in vivo and shown to confer an increased spontaneous mutation frequency over that of wild-type pol beta to our bacterial strain. Purification and subsequent analysis of one of our putative mutator proteins, the pol beta-14 protein, showed that it possesses intrinsic mutator activity in four different assays that measure the fidelity of DNA synthesis. Therefore, residue 265, which is altered in pol beta-14 and another of our mutant proteins, pol beta-166, is probably critical for accurate DNA synthesis by pol beta. Thus, our genetic method of screening for pol beta mutator mutants is useful in identifying active mammalian DNA polymerase mutants that encode enzymes that catalyze DNA synthesis with altered fidelity compared with the wild-type pol beta enzyme.

Spontaneous mutagenesis: experimental, genetic and other factors

Spontaneous mutations are "the net result of all that can go wrong with DNA during the life cycle of an organism" (Glickman et al., 1986). Thus, the types and amounts of spontaneous mutations produced are the resultant of all the cellular processes that are mutagenic and those that are antimutagenic. It is not widely appreciated that the types and frequencies of spontaneous mutations change markedly with subtle changes in experimental conditions. All types of mutations are produced spontaneously, i.e., base substitutions, frameshifts, insertions and deletions. However, very few papers have appeared that are devoted exclusively to the study of the mechanisms of spontaneous mutagenesis, and of the subtle experimental factors that affect the types and frequencies of spontaneous mutations. This is unfortunate because spontaneous mutagenesis appears to play a major role in evolution, aging, and carcinogenesis. This review emphasizes subtle experimental variables that markedly affect the results of a spontaneous mutation experiment. A thorough understanding of these variables eliminates the need for a theory of "directed" mutagenesis. The intrinsic instability of DNA, and the types of normal metabolic lesions that are produced in DNA that lead to mutations via errors made in replication, repair, and recombination are reviewed, as is the genetic control of spontaneous mutagenesis. As with spontaneous mutagenesis, spontaneous carcinogenesis can also be considered to be the net result of all that can go wrong with DNA during the life of an organism.

Inactivation of lacZ gene expression by UV light and bound DNA photolyase implies formation of extended complexes in the genomes of specific Escherichia coli strains

In Escherichia coli strains WU and CS101, UV inactivation of lacZ gene expression is more effective when the cells contain amplified DNA photolyase, and flash photoreactivation (fPR) after 15 min of metabolism does not reverse inactivation by the photolyase-dimer complexes. In other strains, also studied with or without amplified DNA photolyase, there is no differential UV inactivation and fPR reverses inactivation by the complexes regardless of continued metabolism. The irreparable condition in strain WU is not due to dysfunction of photolyase: during post-UV metabolism, fPR still restores viability and dimers are removed from the region of the lac operon. When the wild-type lac promoter is replaced by the UV5 promoter, making expression insensitive to relaxed supercoiling and catabolite repression, inactivation by dimers alone becomes more resistant, i.e. requires higher fluences, but inactivation in WU and CS101 is still exceptionally sensitive to photolyase-dimer complexes. This indicates that dimers external to the wild-type lac operon may inhibit expression by altering supercoiling but that complexes must involve some other mechanism for their special effect in WU and CS101. The exceptionally efficient inactivation and irreparable condition are consistent with the idea that, in two specific laboratory strains, photolyase bound to dimers at a considerable distance from the lac operon may initiate an aggregation of DNA with other cellular molecules that extends to, and inactivates expression from, the operon.

Diverse backmutations at an ochre defect in the tyrA gene sequence of E. coli B/r

A DNA fragment including most of the tyrA gene from E. coli B/r strain WU (Tyr-, Leu-) was amplified in vitro by polymerase chain reaction. The sequence was determined, first, for essentially all of the fragment to locate an ochre nonsense defect, and second, repeatedly for a region of the fragment from several independent isolates containing backmutations at the ochre codon (spontaneous and UV-induced). There were 20 single base differences in the tyrA gene region from the analogous wild-type E. coli K12 sequence: an ochre codon at amino acid position 161, 18 silent changes (1 at the first codon base and 17 at the third) and one replacement of valine by alanine. Different backmutations at the ochre codon encoded lysine, glutamine, glutamic acid, leucine, cysteine, phenylalanine, serine or tyrosine. The diversities of base substitutions at the ochre codon after UV mutagenesis or after mutagenesis where targeting by dimers was reduced or eliminated (after photoreversal of irradiated cells treated with nalidixic acid to induce SOS functions or after UV mutagenesis of cells containing amplified DNA photolyase) were similar (with two notable exceptions). The overall differences between the gene sequences for E. coli K12 or B/r seemed consistent with the neutral theory of molecular evolution.

UV mutagenesis in E. coli with excision repair initiated by uvrABC or denV gene products

Mutation frequency responses produced by ultraviolet light are compared in 4 closely related strains of E. coli B/r having the same tyr(Oc) allele and different excision-repair capabilities: uvr+ (excision repair initiated by wild-type UvrABC activity), uvrA (excision repair defective), uvrA/pdenV-7 (excision repair initiated by endonuclease V of bacteriophage T4, DenV activity), and uvr+/pdenV-7 (excision repair initiated by UvrABC and DenV activities). The production of Tyr+ prototrophic mutants is classified into back-mutations and de novo or converted glutamine tRNA suppressor mutations to indicate different mutation events. Cells transformed with the plasmid pdenV-7 require larger exposures than the parent strains to produce comparable mutation frequency responses, indicating that DenV activity can repair mutagenic photoproducts. When damage reduction by UvrABC or DenV is compared for each of the specific categories of mutation, the results are consistent with the idea that pyrimidine dimers infrequently or never target back-mutations of this allele, frequently target the de novo suppressor mutations, and extensively or exclusively target the converted suppressor mutations. This analysis is based on the distinction that UvrABC-initiated excision repair recognizes dimer and non-dimer (pyrimidine (6-4) pyrimidone) photoproducts but that DenV-initiated repair recognizes only pyrimidine dimers.

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.

Mutation frequency decline in Escherichia coli B/r after mutagenesis with ethyl methanesulfonate

Nonsense-defective auxotrophic strains of Escherichia coli B/r were used to study mutation frequency decline (MFD) after mutagenesis with ethyl methanesulfonate (EMS). The mutation frequencies for prototrophic revertants that were either converted or de novo glutamine tRNA suppressor mutations declined as treated auxotrophic parental cells were incubated with glucose but without required amino acids (a condition typically producing MFD). The decline for converted suppressor mutations was more rapid than the decline for de novo suppressor mutations after low or moderate EMS treatment, but both suppressor mutation types showed the same slow decline after extensive treatment. The declines for both types of suppressor mutation were eliminated in uvrA-defective cells, and the rapid decline seen for converted suppressor mutations appeared as a slow decline in mfd-defective cells. The results are interpreted that true MFD (the rapid process) affects only the EMS-induced converted glutamine tRNA suppressor mutations. This would account for the rapid decline that is blocked in cells with an mfd defect and in cells with deficient excision repair activity (uvrA or excessive DNA damage). In addition, a second non-specific antimutation mechanism is proposed that is dependent on excision repair only and accounts for the slow decline seen with converted suppressor mutations in some instances and with de novo suppressor mutations at all times. The true MFD mechanism may consist of a physiologically dependent facilitated excision repair specifically for premutational residues located in the transcribed strand of the target DNA sequence (for O6-ethylguanine in cells treated with ethyl methanesulfonate or pyrimidine-pyrimidine photoproducts after UV irradiation).

Specificity of mutation by UV light and delayed photoreversal in umuC-defective Escherichia coli K-12: a targeting intermediate at pyrimidine dimers

Prototrophic mutants produced by UV light in Escherichia coli K-12 strains with argE3(Oc) and hisG4(Oc) defects are distinguished as backmutations and specific nonsense suppressor mutations. In strains carrying a umuC defect, mutants are not produced unless irradiated cells are incubated and then exposed to photoreversing light (delayed photoreversal mutagenesis). The mutants thus produced are found to be specifically suppressor mutations and not backmutations. The suppressor mutations are primarily glutamine tRNA ochre suppressor mutations, which have been attributed previously to mutation targeted at T = C pyrimidine dimers. In a lexA51 recA441 strain, where the SOS mutagenesis functions are constitutive, targeting at dimers is confirmed by demonstrating that the induction of glutamine tRNA suppressor mutations is susceptible to photoreversal. In the same strain induction of backmutations is not susceptible to photoreversal. Thus delayed photoreversal mutagenesis produces suppressor mutations that can be targeted at pyrimidine dimers and does not produce backmutations that are not targeted at pyrimidine dimers. This correlation supports the idea that delayed photoreversal mutagenesis in umuC defective cells reflects a mutation process arrested at a targeting pyrimidine dimer photoproduct, which is the immediate cause of both the alteration in DNA sequence and the obstruction (unless repaired) to mutation fixation and ultimate expression.

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.