DNA polymerase III proofreading mutants enhance the expansion and deletion of triplet repeat sequences in Escherichia coli.

The influence of mutations in the 3' to 5' exonucleolytic proofreading epsilon-subunit of Escherichia coli DNA polymerase III on the genetic instabilities of the CGG.CCG and the CTG.CAG repeats that cause human hereditary neurological diseases was investigated. The dnaQ49(ts) and the mutD5 mutations destabilize the CGG.CCG repeats. The distributions of the deletion products indicate that slipped structures containing a small number of repeats in the loop mediate the deletion process. The CTG.CAG repeats were destabilized by the dnaQ49(ts) mutation by a process mediated by long hairpin loop structures (>/=5 repeats). The mutD5 mutator strain stabilized the (CTG.CAG)(175) tract, which contained two interruptions. Since the mutD5 mutator strain has a saturated mismatch repair system, the stabilization is probably an indirect effect of the nonfunctional mismatch repair system in these strains. Shorter uninterrupted tracts expand readily in the mutD5 strain, presumably due to the greater stability of long CTG.CAG tracts (>100 repeats) in this strain. When parallel studies were conducted in minimal medium, where the mutD5 strain is defective in exonucleolytic proofreading but has a functional MMR system, both CTG.CAG and CGG.CCG repeats were destabilized, showing that the proofreading activity is essential for maintaining the integrity of TRS tracts. Thus, we conclude that the expansion and deletion of triplet repeats are enhanced by mutations that reduce the fidelity of replication.

Determining mutation rates in bacterial populations.

When properly determined, spontaneous mutation rates are a more accurate and biologically meaningful reflection of underlying mutagenic mechanisms than are mutant frequencies. Because bacteria grow exponentially and mutations arise stochastically, methods to estimate mutation rates depend on theoretical models that describe the distribution of mutant numbers among parallel cultures, as in the original Luria-Delbr]uck fluctuation analysis. An accurate determination of mutation rate depends on understanding the strengths and limitations of these methods, and how to design fluctuation assays to optimize a given method. In this paper we describe a number of methods to estimate mutation rates, give brief accounts of their derivations, and discuss how they behave under various experimental conditions.

Mechanisms of mutation in nondividing cells. Insights from the study of adaptive mutation in Escherichia coli.

When populations of cells are subjected to nonlethal selection, mutations arise in the absence of cell division, a phenomenon that has been called "adaptive mutation." In a strain of Escherichia coli that cannot metabolize lactose (Lac-) but that reverts to lactose utilization (Lac+) when lactose is its sole energy and carbon source, the mutational process consists of two components. (1) A highly efficient, recombination-dependent mechanism giving rise to mutations on the F' episome that carries the Lac- allele; and (2) a less efficient, unknown mechanism giving rise to mutations elsewhere in the genome. Both selected and nonselected mutations arise in the Lac- population, but nonselected mutations are enriched in Lac+ mutants, suggesting that some Lac+ cells have passed though a transient period of increased mutation. These results have several evolutionary implications. (1) DNA synthesis initiated by recombination could be an important source of spontaneous mutation, particularly in cells that are not undergoing genomic replication. (2) The highly active mutational mechanism on the episome could be important in the horizontal transfer of variant alleles among species that carry and exchange conjugal plasmids. (3) A sub-population of cells in a state of transient mutation could be a source of multiple variant alleles and could provide a mechanism for rapid adaptive evolution under adverse conditions.

DNA-directed mutations. Leading and lagging strand specificity.

The fidelity of replication has evolved to reproduce B-form DNA accurately, while allowing a low frequency of mutation. The fidelity of replication can be compromised, however, by defined order sequence DNA (dosDNA) that can adopt unusual or non B-DNA conformations. These alternative DNA conformations, including hairpins, cruciforms, triplex DNAs, and slipped-strand structures, may affect enzyme-template interactions that potentially lead to mutations. To analyze the effect of dosDNA elements on spontaneous mutagenesis, various mutational inserts containing inverted repeats or direct repeats were cloned in a plasmid containing a unidirectional origin of replication and a selectable marker for the mutation. This system allows for analysis of mutational events that are specific for the leading or lagging strands during DNA replication in Escherichia coli. Deletions between direct repeats, involving misalignment stabilized by DNA secondary structure, occurred preferentially on the lagging strand. Intermolecular strand switch events, correcting quasipalindromes to perfect inverted repeats, occurred preferentially during replication of the leading strand.

The role of transient hypermutators in adaptive mutation in Escherichia coli.

Microbial populations under nonlethal selection can give rise to mutations that relieve the selective pressure, a phenomenon that has come to be called "adaptive mutation." One explanation for adaptive mutation is that a small proportion of the cells experience a period of transient hypermutation, and that these hypermutators account for the mutations that appear. The experiments reported here investigated the contribution that hypermutators make to the mutations occurring in a Lac- strain of Escherichia coli during selection for lactose utilization. A broad mutational screen, loss of motility, was used to compare the frequency of nonselected mutations in starved Lac- cells, in Lac+ revertants, and in Lac+ revertants carrying yet another nonselected mutation. These frequencies allowed us to calculate that the hypermutating subpopulation makes up approximately 0.06% of the population and that its mutation rate is elevated approximately 200-fold. From these numbers we conclude that the hypermutators are responsible for nearly all multiple mutations but produce only approximately 10% of the adaptive Lac+ mutations.

Increased episomal replication accounts for the high rate of adaptive mutation in recD mutants of Escherichia coli.

Adaptive mutation has been studied extensively in FC40, a strain of Escherichia coli that cannot metabolize lactose (Lac-) because of a frameshift mutation affecting the lacZ gene on its episome. recD mutants of FC40, in which the exonuclease activity of RecBCD (ExoV) is abolished but its helicase activity is retained, have an increased rate of adaptive mutation. The results presented here show that, in several respects, adaptive mutation to Lac+ involves different mechanisms in recD mutant cells than in wild-type cells. About half of the apparent increase in the adaptive mutation rate of recD mutant cells is due to a RecA-dependent increase in episomal copy number and to growth of the Lac- cells on the lactose plates. The remaining increase appears to be due to continued replication of the episome, with the extra copies being degraded or passed to recD+ recipients. In addition, the increase in adaptive mutation rate in recD mutant cells is (i) dependent on activities of the single-stranded exonucleases, RecJ and ExoI, which are not required for (in fact, slightly inhibit) adaptive mutation in wild-type cells, and (ii) enhanced by RecG, which opposes adaptive mutation in wild-type cells.

Primer-template misalignments during leading strand DNA synthesis account for the most frequent spontaneous mutations in a quasipalindromic region in Escherichia coli.

Spontaneous mutant sequences which differ from the starting DNA sequence by the specific correction of quasipalindromic to perfect palindromic sequence are hallmarks of mutagenesis mediated by misalignments directed by palindromic complementarity. The mutant sequences are specifically predicted by templated, but ectopic, DNA polymerization on a misaligned DNA substrate. In a previous study, we characterized a spontaneous frameshift hotspot near a 17 bp quasipalindromic DNA sequence within the mutant chloramphenicol acetyl transferase (CAT) gene of plasmid pJT7. A one base-pair insertion hotspot, ectopically templated by misalignment mediated by palindromic complementarity, was shown to occur more frequently during synthesis of the leading than the lagging DNA strand. Here we analyze the misalignment mechanisms that can account for the DNA sequences of 123 additional spontaneous frameshift mutations (22 distinct genotypes) occurring in the same quasipalindromic DNA region in plasmids pJT7 and p7TJ (a pJT7 derivative with the CAT gene in the inverse orientation). Approximately 80% of the small frameshift mutants in each plasmid are predicted by palindromic misalignments of the leading strand. Smaller numbers of mutations are consistent with other DNA misalignments, including those predicted by simple slippage of the nascent DNA strand on its template. The results show that remarkable changes in the mutation spectra of a reporter gene may not be revealed by measurements of mutation frequency.

Levels of the Vsr endonuclease do not regulate stationary-phase reversion of a Lac- frameshift allele in Escherichia coli.

Vsr endonuclease, which initiates very short patch repair, has been hypothesized to regulate mutation in stationary-phase cells. Overexpression of Vsr does dramatically increase the stationary-phase reversion of a Lac- frameshift allele, but the absence of Vsr has no effect. Thus, at least in this case, Vsr has no regulatory role in stationary-phase mutation, and the effects of Vsr overproduction are likely to be artifactual.

Leading strand specific spontaneous mutation corrects a quasipalindrome by an intermolecular strand switch mechanism.

Imperfect inverted repeats or quasipalindromes can undergo spontaneous, often complex mutational events that correct them to perfect palindromes. Two models that depend on the quasipalindrome providing a template for a specific mutational event have been described to explain this mutation: an intramolecular and an intermolecular strand switch model. A 17bp quasipalindrome containing a -1 deletion within the chloramphenicol acetyl transferase (CAT) gene in plasmid pJT7 undergoes a spontaneous +1 frameshift mutation that creates a perfect inverted repeat and a Cm(r) phenotype. By analyzing this mutation frequency in two plasmids that contain the CAT gene in either orientation with respect to the origin of replication, we show that the specific frameshift occurs preferentially in the leading strand during DNA replication. Due to the availability and proximity of the lagging strand template as a single strand during replication of the quasipalindrome in the leading but not lagging strand, we suggest that the specificity for the leading strand correction is due to a leading strand specific intermolecular strand switch rather than an intramolecular strand switch. To test this hypothesis, we have designed a genetic selection to detect a leading strand intermolecular strand switch. This selection utilizes asymmetric quasipalindromes, one of which contains two central stop codons. When cloned into the CAT gene in pJT7, reversion to Cm(r) requires inversion of the stop codons and addition of a +1 frameshift to correct the reading frame. The inversion of the central stop codons, which is predicted by an intermolecular but not an intramolecular strand switch, occurs concomitant with the specific correction of the original 17 bp quasipalindrome. Inversion of an asymmetric center can also be demonstrated when not under selective pressure using a quasipalindrome lacking central stop codons. These results are consistent with the correction of a quasipalindrome occurring predominantly by an intermolecular strand switch during replication of the leading strand.

Relationship between Escherichia coli growth and deletions of CTG.CAG triplet repeats in plasmids.

Instabilities that are intrinsic to natural repetitive DNA sequences produce high frequencies of length changes in vivo. Triplet repeats cloned in plasmids in Escherichia coli undergo expansions and deletions, and this instability is affected by multiple factors. We show that CTG-CAG repeats in plasmids can influence the growth of E. coli, which affects the observed stabilities. At extended growth periods, the observed frequencies of deletions were dramatically increased if the cells passed through stationary phase before subculturing. Deletions were particularly pronounced for a plasmid containing the longest repeat, 525 bp in total, with the CTG sequence as the lagging strand template for replication. Measurements of cell growth showed that the lag phase associated with E. coli growth was increased for cultures containing plasmids with long CTG-CAG repeats, particularly when the CTG-containing strand was the lagging template. High frequencies of deletions were observed because of a growth advantage of cells containing plasmids with deleted triplet repeats. Incubation conditions that reduced the bacterial growth-rate produced a decreased extent of deletions, presumably because they alleviated the growth advantage of cells harboring plasmids with deleted triplet repeats. The experimental observations were simulated by a model in which shorter triplet repeats provided a growth advantage due to a shorter lag phase. We demonstrate that the accumulation of deletions within repeating sequences during growth of E. coli can be prevented, and discuss these findings in relation to the studies of repetitive DNA sequences. These are the first observations to show a direct influence between a plasmid-based DNA sequence or structure and factors controlling bacterial growth.

Single-stranded DNA-binding protein enhances the stability of CTG triplet repeats in Escherichia coli.

The stability of CTG triplet repeats was analyzed in Escherichia coli to identify processes responsible for their genetic instability. Using a biochemical assay for stability, we show that the absence of single-stranded-DNA-binding protein leads to an increase in the frequency of large deletions within the triplet repeats.

Structure-function relationships of the dietary anticarcinogen ellagic acid.

Ellagic acid is a complex planar molecule which demonstrates a variety of anticarcinogenic activities. Ellagic acid has been shown to inhibit the CYP1A1-dependent activation of benzo[a]pyrene; to bind to and detoxify the diolepoxide of benzo[a]pyrene; to bind to DNA and reduce the formation of O6-methylguanine by methylating carcinogens; and to induce the phase II detoxification enzymes glutathione S-transferase Ya and NAD(P)H:quinone reductase. Chemical analogs of ellagic acid were synthesized to examine the relationship between the hydroxyl and lactone groups of the ellagic acid molecule and its different anticarcinogenic activities. These studies demonstrated that both the 3-hydroxyl and the 4-hydroxyl groups were required for ellagic acid to directly detoxify the diolepoxide of benzo[a]pyrene, while only the 4-hydroxyl groups were necessary for ellagic acid to inhibit CYP1A1-dependent benzo[a]pyrene hydroxylase activity. Induction of glutathione S-transferase Ya and NAD(P):quinone reductase required the lactone groups of ellagic acid, but the hydroxyl groups were not required for the induction of these phase II enzymes. In addition, the lactone groups, but not the hydroxyl groups, were required for the analogs to reduce the carcinogen-induced formation of O6-methylguanine. Thus, different portions of the ellagic acid molecule are responsible for its different putative anticarcinogenic activities.

Mismatch repair in Escherichia coli enhances instability of (CTG)n triplet repeats from human hereditary diseases.

Long CTG triplet repeats which are associated with several human hereditary neuromuscular disease genes are stabilized in ColE1-derived plasmids in Escherichia coli containing mutations in the methyl-directed mismatch repair genes (mutS, mutL, or mutH). When plasmids containing (CTG)180 were grown for about 100 generations in mutS, mutL, or mutH strains, 60-85% of the plasmids contained a full-length repeat, whereas in the parent strain only about 20% of the plasmids contained the full-length repeat. The deletions occur only in the (CTG)180 insert, not in DNA flanking the repeat. While many products of the deletions are heterogeneous in length, preferential deletion products of about 140, 100, 60, and 20 repeats were observed. We propose that the E. coli mismatch repair proteins recognize three-base loops formed during replication and then generate long single-stranded gaps where stable hairpin structures may form which can be bypassed by DNA polymerase during the resynthesis of duplex DNA. Similar studies were conducted with plasmids containing CGG repeats; no stabilization of these triplets was found in the mismatch repair mutants. Since prokaryotic and human mismatch repair proteins are similar, and since several carcinoma cell lines which are defective in mismatch repair show instability of simple DNA microsatellites, these mechanistic investigations in a bacterial cell may provide insights into the molecular basis for some human genetic diseases.

Differential DNA secondary structure-mediated deletion mutation in the leading and lagging strands.

The frequencies of deletion of short sequences (mutation inserts) inserted into the chloramphenicol acetyl-transferase (CAT) gene were measured for pBR325 and pBR523, in which the orientation of the CAT gene was reversed, in Escherichia coli. Reversal of the CAT gene changes the relationship between the transcribed strand and the leading and lagging strands of the DNA replication fork in pBR325-based plasmids. Deletion of these mutation inserts may be mediated by slipped misalignment during DNA replication. Symmetrical sequences, in which the same potential DNA structural misalignment can form in both the leading and lagging strands, exhibited an approximately twofold difference in the deletion frequencies upon reversal of the CAT gene. Sequences that contained an inverted repeat that was asymmetric with respect to flanking direct repeats were designed. With asymmetric mutation inserts, different misaligned structural intermediates could form in the leading and lagging strands, depending on the orientation of the insert and/or of the CAT gene. When slippage could be stabilized by a hairpin in the lagging strand, thereby forming a three-way junction, deletion occurred by up to 50-fold more frequently than when this structure formed in the leading strand. These results support the model that slipped misalignment involving DNA secondary structure occurs preferentially in the lagging strand during DNA replication.

Inhibition of rat methylbenzylnitrosamine metabolism by dietary zinc and zinc in vitro.

Methylbenzylnitrosamine is an esophageal-specific carcinogen in the rat, and the incidence of methylbenzylnitrosamine-induced esophageal carcinoma is increased by dietary zinc deficiency. Methylbenzylnitrosamine requires activation by cytochrome P-450 to be mutagenic; the present study examined the role of dietary zinc deficiency and the in vitro addition of zinc on the cytochrome P-450-dependent microsomal metabolism of methylbenzylnitrosamine. Dietary zinc deficiency significantly increased the cytochrome P-450-dependent esophageal and hepatic microsomal metabolism of methylbenzylnitrosamine. These changes occurred without alteration in the specific content of total microsomal cytochrome P-450 of the esophagus or liver. The addition of zinc in vitro, at concentrations found in normal tissues, irreversibly inhibited the esophageal and hepatic cytochrome P-450-dependent microsomal metabolism of methylbenzylnitrosamine. These results suggest that physiological levels of zinc may be an endogenous inhibitor of methylbenzylnitrosamine metabolism. Dietary zinc deficiency appears to reduce this inhibition of cytochrome P-450 activity, resulting in an increase in carcinogen activation.