Adaptive mutation in Escherichia coli

Catastrophe and what to do about it if you are a bacterium: the importance of frameshift mutants

Key problems that bacteria have historically faced are the challenges of the lack of essential nutrients and the presence of antibiotics produced naturally, but there are many other challenges. It appears that for many of these challenges the bacteria have mechanisms encoded in their genomes that are not usually functioning, but may be "turned on" when needed, even if the need only occurs once in hundreds of thousands of generations. Such mechanisms at other times somehow need to be "turned off" because they may cause a slight disadvantage, or even a grave disadvantage to the cell compared with wild-type cells during the time the population is not being challenged. On the other hand, a gene cannot simply be discarded because it might be needed again. How do microorganisms solve the problem of responding to challenges that only occur rarely? I suggest that in most cases, the mutation must occur by the existence of a readily reversible mutation. The mutation in likely the result of a frameshift mutation that caused the response and later another frameshift occurs to return the genome to its original state.

Error-prone replication for better or worse

Precise genome duplication requires accurate copying by DNA polymerases and the elimination of occasional mistakes by proofreading exonucleases and mismatch repair enzymes. The commonly held belief that 'if something is worth doing, then it's worth doing well' normally applies to DNA replication and repair, however, there are exceptions. This review describes elements that are crucial to cell fitness, evolution and survival in the recently discovered error-prone DNA polymerases. Large numbers of errant DNA polymerases, spanning microorganisms to humans, are used to rescue stalled replication forks by copying damaged DNA and even undamaged DNA to generate 'purposeful' mutations that generate genetic diversity in times of stress. Here we focus on low-fidelity polymerases from bacteria, comparing Escherichia coli, archeabacteria and those most recently discovered in Gram-positive Bacilli, Streptococcus, pathogenic Mycobacterium and intein-containing cyanobacteria.

Involvement of error-prone DNA polymerase IV in stationary-phase mutagenesis in Pseudomonas putida

In this work we studied involvement of DNA polymerase IV (Pol IV) (encoded by the dinB gene) in stationary-phase mutagenesis in Pseudomonas putida. For this purpose we constructed a novel set of assay systems that allowed detection of different types of mutations (e.g., 1-bp deletions and different base substitutions) separately. A significant effect of Pol IV became apparent when the frequency of accumulation of 1-bp deletion mutations was compared in the P. putida wild-type strain and its Pol IV-defective dinB knockout derivative. Pol IV-dependent mutagenesis caused a remarkable increase (approximately 10-fold) in the frequency of accumulation of 1-bp deletion mutations on selective plates in wild-type P. putida populations starved for more than 1 week. No effect of Pol IV on the frequency of accumulation of base substitution mutations in starving P. putida cells was observed. The occurrence of 1-bp deletions in P. putida cells did not require a functional RecA protein. RecA independence of Pol IV-associated mutagenesis was also supported by data showing that transcription from the promoter of the P. putida dinB gene was not significantly influenced by the DNA damage-inducing agent mitomycin C. Therefore, we hypothesize that mechanisms different from the classical RecA-dependent SOS response could elevate Pol IV-dependent mutagenesis in starving P. putida cells.

Genetic damage following introduction of DNA in Phycomyces

Introduction of plasmids in Phycomyces blakesleeanus caused extensive changes in the exogenous DNA and in the resident genome. Plasmids with a bacterial gene for geneticin resistance under a Phycomyces promoter were either injected into immature sporangia or incubated with spheroplasts. An improved method produced about one viable spheroplast per cell. Colonies resistant to geneticin were rare and only about 0.1% of their spores grew in the presence of geneticin. The transformation frequency was very low, < or =1 transformed colony per million spheroplasts or per microg DNA. Few nuclei in the transformants contained exogenous DNA, as shown by a selective procedure that sampled single nuclei from heterokaryons. The exogenous DNA was not integrated into the genome and no stable transformants were obtained. The plasmids were replicated in the recipient cells, but their DNA sequences were modified by deletions and rearrangements and the transformed phenotype was eventually lost. The spores developed in injected sporangia were often inviable; a genetic test showed that spore death was caused by impaired nuclear proliferation and induction of lethal mutations. About one-fourth of the viable spores from injected sporangia formed abnormal colonies with obvious changes in shape, texture, or color. The abnormalities that could be investigated were due to dominant mutations. The results indicate that incoming DNA is not only attacked, but signals a situation of stress that leads to increased mutation and nuclear and cellular death.

Error-prone DNA polymerase IV is controlled by the stress-response sigma factor, RpoS, in Escherichia coli

An insertion in rpoS, which encodes the general stress response sigma factor sigma 38, was isolated as an antimutator for 'stationary-phase' or 'adaptive' mutation. In the rpoS mutant strain the levels of error-prone DNA polymerase Pol IV were reduced. Pol IV is encoded by the dinB gene, and the amount of its transcript was also reduced in rpoS mutant cells. In wild-type cells, the levels of Pol IV increased in late stationary phase and stayed elevated for several days of continuous incubation, whereas in rpoS defective cells Pol IV was not induced and declined during prolonged incubation. Even in cells missing LexA, the repressor of dinB, maximum Pol IV expression required RpoS. These results suggest that induction of Pol IV is part of a cellular response to starvation and other stresses.

The dinB operon and spontaneous mutation in Escherichia coli

Apparently conflicting data regarding the role of SOS-inducible, error-prone DNA polymerase IV (DinB) in spontaneous mutation are resolved by the finding that mutation is reduced by a polar allele with which dinB and neighboring yafN are deleted but not by two nonpolar dinB alleles. We demonstrate the existence of a dinB operon that contains four genes, dinB-yafN-yafO-yafP. The results imply a role for yafN, yafO, and/or yafP in spontaneous mutation.

Error-prone polymerase, DNA polymerase IV, is responsible for transient hypermutation during adaptive mutation in Escherichia coli

The frequencies of nonselected mutations among adaptive Lac(+) revertants of Escherichia coli strains with and without the error-prone DNA polymerase IV (Pol IV) were compared. This frequency was more than sevenfold lower in the Pol IV-defective strain than in the wild-type strain. Thus, the mutations that occur during hypermutation are due to Pol IV.

Error-prone repair DNA polymerases in prokaryotes and eukaryotes

DNA repair is crucial to the well-being of all organisms from unicellular life forms to humans. A rich tapestry of mechanistic studies on DNA repair has emerged thanks to the recent discovery of Y-family DNA polymerases. Many Y-family members carry out aberrant DNA synthesis-poor replication accuracy, the favored formation of non-Watson-Crick base pairs, efficient mismatch extension, and most importantly, an ability to replicate through DNA damage. This review is devoted primarily to a discussion of Y-family polymerase members that exhibit error-prone behavior. Roles for these remarkable enzymes occur in widely disparate DNA repair pathways, such as UV-induced mutagenesis, adaptive mutation, avoidance of skin cancer, and induction of somatic cell hypermutation of immunoglobulin genes. Individual polymerases engaged in multiple repair pathways pose challenging questions about their roles in targeting and trafficking. Macromolecular assemblies of replication-repair "factories" could enable a cell to handle the complex logistics governing the rapid migration and exchange of polymerases.

Induction of a DNA nickase in the presence of its target site stimulates adaptive mutation in Escherichia coli

Adaptive mutation to Lac(+) in Escherichia coli strain FC40 depends on recombination functions and is enhanced by the expression of conjugal functions. To test the hypothesis that the conjugal function that is important for adaptive mutation is the production of a single-strand nick at the conjugal origin, we supplied an exogenous nicking enzyme, the gene II protein (gIIp) of bacteriophage f1, and placed its target sequence near the lac allele. When both gIIp and its target site were present, adaptive mutation was stimulated three- to fourfold. Like normal adaptive mutations, gIIp-induced mutations were recA(+) and ruvC(+) dependent and were mainly single-base deletions in runs of iterated bases. In addition, gIIp with its target site could substitute for conjugal functions in adaptive mutation. These results support the hypothesis that nicking at the conjugal origin initiates the recombination that produces adaptive mutations in this strain of E. coli, and they suggest that nicking may be the only conjugal function required for adaptive mutation.

Fidelity of Escherichia coli DNA polymerase IV. Preferential generation of small deletion mutations by dNTP-stabilized misalignment

Escherichia coli DNA polymerase IV (pol IV), a member of the error-prone Y family, predominantly generates -1 frameshifts when copying DNA in vitro. T-->G transversions and T-->C transitions are the most frequent base substitutions observed. The in vitro data agree with mutational spectra obtained when pol IV is overexpressed in vivo. Single base deletion and base substitution rates measured in the lacZalpha gene in vitro are, on average, 2 x 10(-4) and 5 x 10(-5), respectively. The range of misincorporation and mismatch extension efficiencies determined kinetically are 10(-3) to 10(-5). The presence of beta sliding clamp and gamma-complex clamp loading proteins strongly enhance pol IV processivity but have no discernible influence on fidelity. By analyzing changes in fluorescence of a 2-aminopurine template base undergoing replication in real time, we show that a "dNTP-stabilized" misalignment mechanism is responsible for making -1 frameshift mutations on undamaged DNA. In this mechanism, a dNTP substrate is paired "correctly" opposite a downstream template base, on a "looped out" template strand instead of mispairing opposite a next available template base. By using the same mechanism, pol IV "skips" past an abasic template lesion to generate a -1 frameshift. A crystal structure depicting dNTP-stabilized misalignment was reported recently for Sulfolubus solfataricus Dpo4, a Y family homolog of Escherichia coli pol IV.

SOS-induced DNA polymerases enhance long-term survival and evolutionary fitness

Escherichia coli encodes three SOS-induced DNA polymerases: pol II, pol IV, and pol V. We show here that each of these polymerases confers a competitive fitness advantage during the stationary phase of the bacterial life cycle, in the absence of external DNA-damaging agents known to induce the SOS response. When grown individually, wild-type and SOS pol mutants exhibit indistinguishable temporal growth and death patterns. In contrast, when grown in competition with wild-type E. coli, mutants lacking one or more SOS polymerase suffer a severe reduction in fitness. These mutants also fail to express the "growth advantage in stationary phase" phenotype as do wild-type strains, instead expressing two additional new types of "growth advantage in stationary phase" phenotype. These polymerases contribute to survival by providing essential functions to ensure replication of the chromosome and by generating genetic diversity.

Low fidelity DNA synthesis by a y family DNA polymerase due to misalignment in the active site

Sulfolobus solfataricus DNA polymerase IV (Dpo4) is a member of the Y family of DNA polymerases whose crystal structure has recently been solved. As a model for other evolutionarily conserved Y family members that perform translesion DNA synthesis and have low fidelity, we describe here the base substitution and frameshift fidelity of DNA synthesis by Dpo4. Dpo4 generates all 12 base-base mismatches at high rates, 11 of which are similar to those of its human homolog, DNA polymerase kappa. This result is consistent with the Dpo4 structure, implying lower geometric selection for correct base pairs. Surprisingly, Dpo4 generates C.dCMP mismatches at an unusually high average rate and preferentially at cytosine flanked by 5'-template guanine. Dpo4 also has very low frameshift fidelity and frequently generates deletions of even noniterated nucleotides, especially cytosine flanked by a 5'-template guanine. Both unusual features of error specificity suggest that Dpo4 can incorporate dNTP precursors when two template nucleotides are present in the active site binding pocket. These results have implications for mutagenesis resulting from DNA synthesis by Y family polymerases.

The "A" rule revisited: polymerases as determinants of mutational specificity

Organisms control the specificity and frequency with which they mutate via their complement of proteins. The mismatch repair (MMR) proteins correct errors after they are made. The DNA polymerases of the cell determine the response to damaged DNA which has not been repaired by excision. Polymerase action can be considered as consisting of three main steps: addition of a base, proofreading of the added nucleotide and elongation. Each of these steps is kinetically complex and can be modulated. The modulation accounts for different behaviors of organisms in response to stress. The recent findings of DNA polymerases with properties appropriate for dealing with damaged DNA may help to account for the phenomenon of spontaneous mutation and for the hypermutability associated with immunoglobulin maturation and carcinogenesis.

In pursuit of a molecular mechanism for adaptive gene amplification

"Adaptive" or "stationary-phase" mutation is a collection of apparent stress responses in which cells exposed to a growth-limiting environment generate genetic changes, some of which can allow resumption of rapid growth. In the well-characterized Lac system of Escherichia coli, reversions of a lac frameshift allele give rise to adaptive point mutations. Also in this system, adaptive gene amplification has been documented as a separate and parallel response that allows growth on lactose medium without acquisition of a compensatory frameshift mutation. In amplification, the DNA region containing the weakly functional lac allele becomes amplified to multiple copies, which produce sufficient enzyme activity to allow growth on the otherwise growth-limiting lactose medium. The amplifications are "adaptive" in that they occur after cells encounter the growth-limiting environment. Adaptive amplification is a reversible genetic change that allows adaptation and growth. It may be similar to chromosomal instability observed in the origins and progression of many cancers. We explore possible molecular mechanisms of adaptive amplification in the bacterial system and note parallels to chromosomal instability in other systems.

Efficiency and accuracy of SOS-induced DNA polymerases replicating benzo[a]pyrene-7,8-diol 9,10-epoxide A and G adducts

Nucleotide incorporation fidelity, mismatch extension, and translesion DNA synthesis efficiencies were determined using SOS-induced Escherichia coli DNA polymerases (pol) II, IV, and V to copy 10R and 10S isomers of trans-opened benzo[a]pyrene-7,8-diol 9,10-epoxide (BaP DE) A and G adducts. A-BaP DE adducts were bypassed by pol V with moderate accuracy and considerably higher efficiency than by pol II or IV. Error-prone pol V copied G-BaP DE-adducted DNA poorly, forming A*G-BaP DE-S and -R mismatches over C*G-BaP DE-S and -R correct matches by factors of approximately 350- and 130-fold, respectively, even favoring G*G-BaP DE mismatches over correct matches by factors of 2-4-fold. In contrast, pol IV bypassed G-BaP DE adducts with the highest efficiency and fidelity, making misincorporations with a frequency of 10(-2) to 10(-4) depending on sequence context. G-BaP DE-S-adducted M13 DNA yielded 4-fold fewer plaques when transfected into SOS-induced DeltadinB (pol IV-deficient) mutant cells compared with the isogenic wild-type E. coli strain, consistent with the in vitro data showing that pol IV was most effective by far at copying the G-BaP DE-S adduct. SOS polymerases are adept at copying a variety of lesions, but the relative contribution of each SOS polymerase to copying damaged DNA appears to be determined by the lesion's identity.

Resolving a fidelity paradox: why Escherichia coli DNA polymerase II makes more base substitution errors in AT- compared with GC-rich DNA

The activity of DNA polymerase-associated proofreading 3'-exonucleases is generally enhanced in less stable DNA regions leading to a reduction in base substitution error frequencies in AT- versus GC-rich sequences. Unexpectedly, however, the opposite result was found for Escherichia coli DNA polymerase II (pol II). Nucleotide misincorporation frequencies for pol II were found to be 3-5-fold higher in AT- compared with GC-rich DNA, both in the presence and absence of polymerase processivity subunits, beta dimer and gamma complex. In contrast, E. coli pol III holoenzyme, behaving "as expected," exhibited 3-5-fold lower misincorporation frequencies in AT-rich DNA. A reduction in fidelity in AT-rich regions occurred for pol II despite having an associated 3'-exonuclease proofreading activity that preferentially degrades AT-rich compared with GC-rich DNA primer-template in the absence of DNA synthesis. Concomitant with a reduction in fidelity, pol II polymerization efficiencies were 2-6-fold higher in AT-rich DNA, depending on sequence context. Pol II paradoxical fidelity behavior can be accounted for by the enzyme's preference for forward polymerization in AT-rich sequences. The more efficient polymerization suppresses proofreading thereby causing a significant increase in base substitution error rates in AT-rich regions.

Replication restart in UV-irradiated Escherichia coli involving pols II, III, V, PriA, RecA and RecFOR proteins

In Escherichia coli, UV-irradiated cells resume DNA synthesis after a transient inhibition by a process called replication restart. To elucidate the role of several key proteins involved in this process, we have analysed the time dependence of replication restart in strains carrying a combination of mutations in lexA, recA, polB (pol II), umuDC (pol V), priA, dnaC, recF, recO or recR. We find that both pol II and the origin-independent primosome-assembling function of PriA are essential for the immediate recovery of DNA synthesis after UV irradiation. In their absence, translesion replication or 'replication readthrough' occurs approximately 50 min after UV and is pol V-dependent. In a wild-type, lexA+ background, mutations in recF, recO or recR block both pathways. Similar results were obtained with a lexA(Def) recF strain. However, lexA(Def) recO or lexA(Def) recR strains, although unable to facilitate PriA-pol II-dependent restart, were able to perform pol V-dependent readthrough. The defects in restart attributed to mutations in recF, recO or recR were suppressed in a recA730 lexA(Def) strain expressing constitutively activated RecA (RecA*). Our data suggest that in a wild-type background, RecF, O and R are important for the induction of the SOS response and the formation of RecA*-dependent recombination intermediates necessary for PriA/Pol II-dependent replication restart. In con-trast, only RecF is required for the activation of RecA that leads to the formation of pol V (UmuD'2C) and facilitates replication readthrough.

How nucleotide excision repair protects against cancer

Eukaryotic cells can repair many types of DNA damage. Among the known DNA repair processes in humans, one type--nucleotide excision repair (NER)--specifically protects against mutations caused indirectly by environmental carcinogens. Humans with a hereditary defect in NER suffer from xeroderma pigmentosum and have a marked predisposition to skin cancer caused by sunlight exposure. How does NER protect against skin cancer and possibly other types of environmentally induced cancer in humans?

Roles of DNA polymerases V and II in SOS-induced error-prone and error-free repair in Escherichia coli

DNA polymerase V, composed of a heterotrimer of the DNA damage-inducible UmuC and UmuD(2)(') proteins, working in conjunction with RecA, single-stranded DNA (ssDNA)-binding protein (SSB), beta sliding clamp, and gamma clamp loading complex, are responsible for most SOS lesion-targeted mutations in Escherichia coli, by catalyzing translesion synthesis (TLS). DNA polymerase II, the product of the damage-inducible polB (dinA ) gene plays a pivotal role in replication-restart, a process that bypasses DNA damage in an error-free manner. Replication-restart takes place almost immediately after the DNA is damaged (approximately 2 min post-UV irradiation), whereas TLS occurs after pol V is induced approximately 50 min later. We discuss recent data for pol V-catalyzed TLS and pol II-catalyzed replication-restart. Specific roles during TLS for pol V and each of its accessory factors have been recently determined. Although the precise molecular mechanism of pol II-dependent replication-restart remains to be elucidated, it has recently been shown to operate in conjunction with RecFOR and PriA proteins.