Bromouracil mutagenesis and mismatch repair in mutator strains of Escherichia coli.

A screening procedure based on the formation of papillae on individual bacterial colonies was used to isolate mutants of Escherichia coli with high mutation rates in the presence of bromouracil. Most of the mutants obtained had high spontaneous mutation rates and mapped close to the previously known mutators mutT, mutS, mutR, uvrE and mutL. Except for mutants of mutT type, these mutators also showed high mutability by bromouracil. Transfection experiments were performed with heteroduplex lambda DNA to test for mismatch repair. The results suggest a reduced efficiency of repair of mismatched bases in mutators mutS, mutR, uvrE and mutL, whereas mutants mapping as mutT appear normal. The results support a connection between spontaneous and bromouracil-induced mutability and repair of mismatched bases in DNA.     

Multiple genetic switches spontaneously modulating bacterial mutability

Background

All life forms need both high genetic stability to survive as species and a degree of mutability to evolve for adaptation, but little is known about how the organisms balance the two seemingly conflicting aspects of life: genetic stability and mutability. The DNA mismatch repair (MMR) system is essential for maintaining genetic stability and defects in MMR lead to high mutability. Evolution is driven by genetic novelty, such as point mutation and lateral gene transfer, both of which require genetic mutability. However, normally a functional MMR system would strongly inhibit such genomic changes. Our previous work indicated that MMR gene allele conversion between functional and non-functional states through copy number changes of small tandem repeats could occur spontaneously via slipped-strand mis-pairing during DNA replication and therefore may play a role of genetic switches to modulate the bacterial mutability at the population level. The open question was: when the conversion from functional to defective MMR is prohibited, will bacteria still be able to evolve by accepting laterally transferred DNA or accumulating mutations?

Results

To prohibit allele conversion, we "locked" the MMR genes through nucleotide replacements. We then scored changes in bacterial mutability and found that Salmonella strains with MMR locked at the functional state had significantly decreased mutability. To determine the generalizability of this kind of mutability 'switching' among a wider range of bacteria, we examined the distribution of tandem repeats within MMR genes in over 100 bacterial species and found that multiple genetic switches might exist in these bacteria and may spontaneously modulate bacterial mutability during evolution.

Conclusions

MMR allele conversion through repeats-mediated slipped-strand mis-pairing may function as a spontaneous mechanism to switch between high genetic stability and mutability during bacterial evolution.

     

The conserved active site motif A of Escherichia coli DNA polymerase I is highly mutable

Escherichia coli DNA polymerase I participates in DNA replication, DNA repair, and genetic recombination; it is the most extensively studied of all DNA polymerases. Motif A in the polymerase active site has a required role in catalysis and is highly conserved. To assess the tolerance of motif A for amino acid substitutions, we determined the mutability of the 13 constituent amino acids Val(700)-Arg(712) by using random mutagenesis and genetic selection. We observed that every residue except the catalytically essential Asp(705) can be mutated while allowing bacterial growth and preserving wild-type DNA polymerase activity. Hence, the primary structure of motif A is plastic. We present evidence that mutability of motif A has been conserved during evolution, supporting the premise that the tolerance for mutation is adaptive. In addition, our work allows identification of refinements in catalytic function that may contribute to preservation of the wild-type motif A sequence. As an example, we established that the naturally occurring Ile(709) has a previously undocumented role in supporting sugar discrimination.     

A novel mutational hotspot in a natural quasipalindrome in Escherichia coli

We have found that most spontaneous mutations in the thyA gene of Escherichia coli selected for resistance to trimethoprim result from a TA to AT transversion at a single site within an imperfect inverted repeat or quasipalindrome sequence. This natural quasipalindrome within the coding region of thyA contains an extraordinarily potent hotspot for mutation. Our analysis provides evidence that these mutations are templated by nearby sequences by replication within a hairpin structure. Although quasipalindrome-associated mutations have been observed in many organisms, including humans, the cellular avoidance mechanisms for these unusual mutational events have remained unexplored. We find that the mutational hotspot in thyA is dramatically stimulated by inactivation of exonucleases I and VII, which degrade single-strand DNA with a common 3'-5' polarity. We propose that these exonucleases abort the replicative misalignment events that initiate hairpin-templated mutagenesis by degrading displaced nascent DNA strands. Mismatch repair-defective strains also showed increased mutability at the hotspot, consistent with the notion that these mutations arise during chromosomal lagging-strand replication and are often subsequently removed by methyl-directed mismatch repair. The absence of the thyA quasipalindrome sequence from other related bacterial genera suggests that this sequence represents a "selfish" DNA element whose existence itself is driven by this unusual hairpin-templating mechanism.     

Predicting the contribution of novel POLG mutations to human disease through analysis in yeast model

The yeast Saccharomyces cerevisiae was used to validate the pathogenic significance of eight human mutations in the gene encoding for the mitochondrial DNA polymerase gamma, namely G303R, S305R, R386H, R574W, P625R, D930N, K947R and P1073L, among which three are novel and four are of unclear pathological significance. Mitochondrial DNA extended and point mutability as well as dominance/recessivity of each mutation has been evaluated. The analysis in yeast revealed that two mutations, S305R and R386H, cannot be the sole cause of pathology observed in patients. These data led us to search for a second mutation in compound with S305R and we found a mutation, P1073L, missed in the first genetic analysis. Finally, a significant rescue of extended mutability has been observed for several dominant mutations by treatment with mitochondrial antioxidants.     

Spontaneous, ultraviolet and ionizing radiation mutagenesis in two auxotrophic strains of Salmonella typhimurium carrying an R plasmid.

Ultraviolet-induced, gamma-induced and spontaneous mutation yields were studied in two different auxotrophic strains of Salmonella typhimurium in the presence and absence of the UV-protecting drug resistance transfer factor R-Utrecht. One strain, carrying the hisC527 (amber) mutation, showed significantly increased spontaneous, UV- and gamma-induced mutability in the presence of the R-Utrecht plasmid. The other strain, carrying the trpD1 mutation (thought to be a missense mutation), also showed significantly increased UV mutability in the presence of the R-Utrecht plasmid. The other strain, carrying the trpD1 mutation (thought to be a missense mutation), also showed significantly increased UV mutability in the presence of the R factor, but appeared to show no significant increase in spontaneous mutability and only a very slight increase in gamma-mutability when carrying the R factor. These results demonstrate that the R-Utrecht plasmid, known to enhance UV-induced mutation yields in S. typhimurium, can also significantly enhance both spontaneous and gamma-induced mutation yields in this species. The latter effects are not so discernible with all markers, however, as shown by the results with strains carrying the trpD1 mutation. Enhancement of spontaneous mutability thus appears to be correlated with enhancement of gamma-mutability rather than UV mutability.     

Loss of hydrazine-induced mutability in wild-type and excision-repair-defective yeast during post-treatment inhibition ofcell division.

The fate of presumed premutational DNA lesions induced by hydrazine was studied under a variety of post-treatment conditions in wild-type and in excision repair-defective (rad2-1) strains of Saccharomyces cerevisiae. In all strains the full extent of hydrazine-induced, forward mutability from CAN1 to can1 (canavanine resistance) was dependent upon post-treatment cell division in mutagen-free synthetic or complex growth medium before plating on canavanine-containing selective agar and could be blocked by inhibitors of DNA synthesis (hydroxyurea) or protein synthesis (cycloheximide) contained in the growth medium. Following the growth-inhibitory period, cells were permitted to grow in fresh medium lacking inhibitors to determine the level of induced mutation remaining. Nearly all induced mutability was lost after a one-day growth inhibition, compared with mutagen-treated control samples subsequently grown twice in medium lacking inhibitor. In the wild type, half the induced mutability was lost after 3 h. The data suggest that premutational DNA lesions induced by hydrazine were removed, or possibly rendered non-mutagenic, by some error-free repair process that acted before mutation fixation by base mispairing during DNA replication. Since rad2-1 and RAD strains both exhibited loss of mutability, this process is not dependent upon the activity of an intact pyrimidine dimer excision-repair system.     

Radiosensitivity and radiation-induced mutability: An empirical relationship

Summary The total genome size of various species can apparently define the radiation-induced mutability and radiosensitivity for these species. An empirical expression has been derived which relates the radiation-induced mutation rates of different species to their total DNA content and radiation-induced inactivation rates.     

The yeast HSM3 gene acts in one of the mismatch repair pathways.

Mutants with enhanced spontaneous mutability (hsm) to canavanine resistance were induced by N-methyl-N-nitrosourea in Saccharomyces cerevisiae. One bearing the hsm3-1 mutation was used for this study. This mutation does not increase sensitivity to the lethal action of different mutagens. The hsm3-1 mutation produces a mutator phenotype, enhancing the rates of spontaneous mutation to canavanine resistance and reversions of lys1-1 and his1-7. This mutation increases the rate of intragenic mitotic recombination at the ADE2 gene. The ability of the hsm3 mutant to correct DNA heteroduplex is reduced in comparison with the wild-type strain. All these phenotypes are similar to ones caused by pms1, mlhl and msh2 mutations. In contrast to these mutations, hsm3-1 increases the frequency of ade mutations induced by 6-HAP and UV light. Epistasis analysis of double mutants shows that the PMS1 and HSM3 genes control different mismatch repair systems. The HSM3 gene maps to the right arm of chromosome II, 25 cM distal to the HIS7 gene. Strains that bear a deleted open reading frame YBR272c have the genetic properties of the hsm3 mutant. The HSM3 product shows weak similarity to predicted products of the yeast MSH genes (homologs of the Escherichia coli mutS gene). The HSM3 gene may be a member of the yeast MutS homolog family, but its function in DNA metabolism differs from the functions of other yeast MutS homologs.     

Adaptive amplification: an inducible chromosomal instability mechanism

Adaptive mutation is an induced response to environmental stress in which mutation rates rise, producing permanent genetic changes that can adapt cells to stress. This contrasts with neo-Darwinian views of genetic change rates blind to environmental conditions. DNA amplification is a flexible, reversible genomic change that has long been postulated to be adaptive. We report the discovery of adaptive amplification at the lac operon in Escherichia coli. Additionally, we find that adaptive amplification is separate from, and does not lead to, adaptive point mutation. This contradicts a prevailing alternative hypothesis whereby adaptive mutation is normal mutability in amplified DNA. Instead, adaptive mutation and amplification are parallel routes of inducible genetic instability allowing rapid evolution under stress, and escape from growth inhibition.     

Optimal bacteriophage mutation rates for phage therapy

The mutability of bacteriophages offers a particular advantage in the treatment of bacterial infections not afforded by other antimicrobial therapies. When phage-resistant bacteria emerge, mutation may generate phage capable of exploiting and thus limiting population expansion among these emergent types. However, while mutation potentially generates beneficial variants, it also contributes to a genetic load of deleterious mutations. Here, we model the influence of varying phage mutation rate on the efficacy of phage therapy. All else being equal, phage types with historical mutation rates of approximately 0.1 deleterious mutations per genome per generation offer a reasonable balance between beneficial mutational diversity and deleterious mutational load. We determine that increasing phage inoculum density can undesirably increase the peak density of a mutant bacterial class by limiting the in situ production of mutant phage variants. For phage populations with minimal genetic load, engineering mutation rate increases beyond the mutation-selection balance optimum may provide even greater protection against emergent bacterial types, but only with very weak selective coefficients for de novo deleterious mutations (below approximately 0.01). Increases to the mutation rate beyond the optimal value at mutation-selection balance may therefore prove generally undesirable.     

Differential cell mutability during oogenesis and exposure to ethyleneimine and ethylmethane sulfonate in different Drosophila melanogaster lines

The rate of recessive sex-linked lethal mutations (RLM) was estimated by brood pattern method at different stages of oogenesis, initially, in the wild-type R-86 strain of Drosophila melanogaster after treatment with EI and EMS. The former which is known to induce dominant lethals in mature oocytes of the 14th stage with a high frequency was equally effective in inducing RLM in oocytes of different age and in oogonia. EMS which does not induce dominant lethals when used as vapour was shown to increase RLM frequency in mature fraction of oocytes (the 14A stage only). Similar type of different mutability was found in mutagen-sensitive strain mus-201G1 and in the control 3-4 strain having the same genetical background as mus mutation. Female germ cells of mus-201G1 strain appeared to have a higher mutability in the case of EI, though no differences in mutability between these strains after EMS treatment were registered. The data are discussed in view of the specificity of primer damages occurring as a result of comparable mutagens action and participation of different repair systems in elimination of these damages.     

Neighbor effects in the mutation of ochre triplets in the T 4 rII gene

In 15 sites in the T₄rII gene, mutation from the ochre (UAA) codon to amber (UAG), opal (UGA) and the wild-type was measured with and without 2-aminopurine treatment. It is shown that a particular base pair in the DNA may show variable mutability, depending on its nearest neighbors. Also, similar base pairs at different sites in the gene can vary in their mutability despite the fact that they are flanked by similar neighbors.     

Nucleoid-Associated Proteins Affect Mutation Dynamics in E. coli in a Growth Phase-Specific Manner

The binding of proteins can shield DNA from mutagenic processes but also interfere with efficient repair. How the presence of DNA-binding proteins shapes intra-genomic differences in mutability and, ultimately, sequence variation in natural populations, however, remains poorly understood. In this study, we examine sequence evolution in Escherichia coli in relation to the binding of four abundant nucleoid-associated proteins: Fis, H-NS, IhfA, and IhfB. We find that, for a subset of mutations, protein occupancy is associated with both increased and decreased mutability in the underlying sequence depending on when the protein is bound during the bacterial growth cycle. On average, protein-bound DNA exhibits reduced mutability compared to protein-free DNA. However, this net protective effect is weak and can be abolished or even reversed during stages of colony growth where binding coincides – and hence likely interferes with – DNA repair activity. We suggest that the four nucleoid-associated proteins analyzed here have played a minor but significant role in patterning extant sequence variation in E. coli.     

Evidence that stationary-phase hypermutation in the Escherichia coli chromosome is promoted by recombination

Adaptive (or stationary-phase) mutation is a group of phenomena in which mutations appear to occur more often when selected than when not. They may represent cellular responses to the environment in which the genome is altered to allow survival. The best-characterized assay system and mechanism is reversion of a lac allele on an F' sex plasmid in Escherichia coli, in which the stationary-phase mutability requires homologous recombination functions. A key issue has concerned whether the recombination-dependent mutation mechanism is F' specific or is general. Hypermutation of chromosomal genes occurs in association with adaptive Lac(+) mutation. Here we present evidence that the chromosomal hypermutation is promoted by recombination. Hyperrecombinagenic recD cells show elevated chromosomal hypermutation. Further, recG mutation, which promotes accumulation of recombination intermediates proposed to prime replication and mutation, also stimulates chromosomal hypermutation. The coincident mutations at lac (on the F') and chromosomal genes behave as independent events, whereas coincident mutations at lac and other F-linked sites do not. This implies that transient covalent linkage of F' and chromosomal DNA (Hfr formation) does not underlie chromosomal mutation. The data suggest that recombinational stationary-phase mutation occurs in the bacterial chromosome and thus can be a general strategy for programmed genetic change.     

Mutagen sensitivity of Drosophila melanogaster. VI. Evidence from the excision-defective mei-9AT1 mutant for the timing of DNA-repair activity during spermatogenesis

The sex-linked recessive lethal test has been used to compare mutation induction by ethyl methanesulfonate and methyl methanesulfonate in spermatogenic stages of the DNA repair-deficient mei-9AT1 mutant and a repair-proficient control strain. For both agents, the data demonstrate that induced mutation rates are similar in both strains for the meiotic and post-meiotic broods. Conversely, for spermatogonial broods, the data indicate that the excision-deficient strain exhibits a 4-8 fold increase in induced mutation rate in comparison to the excision-proficient control strain. These experiments suggest that the low mutability of gonial cells normally observed for these agents is due to effective excision-repair processes which function until the commencement of meiosis. From alkylation mutagenesis experiments with repair-deficient E. coli strains, we note that the mei-9 strain exhibits pleiotropic mutant phenotypes very similar to those displayed by the uvr D mutant. By analogy with these studies, we speculate that mei-9, like uvr D, is deficient in a DNA unwinding protein.     

Predicting regional mutability in antibody V genes based solely on di- and trinucleotide sequence composition.

Somatic mutations are not distributed randomly throughout Ab V region genes. A sequence-specific target bias is revealed by a defined hierarchy of mutability among di- and trinucleotide sequences located within Ig intronic DNA. Here we report that the di- and trinucleotide mutability preference pattern is shared by mouse intronic JH and Jkappa clusters and by human VH genes, suggesting that a common mutation mechanism exists for all Ig V genes of both species. Using di- and trinucleotide target preferences, we performed a comprehensive analysis of human and murine germline V genes to predict regional mutabilities. Heavy chain genes of both species exhibit indistinguishable patterns in which complementarity-determining region 1 (CDR1), CDR2, and framework region 3 (FR3) are predicted to be more mutable than FR1 and FR2. This prediction is borne out by empirical mutation data from nonproductively rearranged human VH genes. Analysis of light chain genes in both species also revealed a common, but unexpected, pattern in which FR2 is predicted to be highly mutable. While our analyses of nonfunctional Ig genes accurately predicts regional mutation preferences in VH genes, observed relative mutability differences between regions are more extreme than expected. This cannot be readily accounted for by nascent mRNA secondary structure or by a supplemental gene conversion mechanism that might favor nucleotide replacements in CDR. Collectively, our data support the concept of a common mutation mechanism for heavy and light chain genes of mice and humans with regional bias that is qualitatively, but not quantitatively, accounted for by short nucleotide sequence composition.     

Hemoglobin and the genetic code

Summary One-half of the twenty amino acids of the genetic code are just one mutational step away from the chain-terminator codons UAA, UAG, and UGA. It is postulated that somatic mutation to terminator is a hazard to which the organism has had to respond by adjusting certain proteins in the direction of fewer mutable residues. This view is supported by calculations based on the primary structure of five of the human hemoglobin chains. Each chain is scored for mutability to terminator in accord with the numbers and kinds of amino acids present. Among the adult chains, the most essential one, the alpha, has lowest mutability. The beta and delta follow, and in order of the presumed harm to the organism of a shortage of chain copies. Ante-natal chains tend to have higher mutabilities, supporting the view that cumulative mutational change in DNA can do little harm if the gene ceases to transcribe early in life. Two other predictions based on the supposition of effective selection against mutability to terminator are also met: chain length of polypeptides is negatively correlated with their scores for mutability to terminator, and examination of the recently determined sequence of beta messenger RNA shows preferential use of codons that are not readily mutable to terminator.Supported in part by the National Institutes of Health, Grant HL-16005