Oenothera chloroplast DNA polymorphisms associated with plastome mutator activity

Summary Oenothera plants homozygous for a recessive allele at the plastome mutator (pm) locus show non-Mendelian mutation frequencies that are 1000-fold higher than spontaneous levels. Chloroplast DNA (cpDNA) was isolated from nine mutants and two green isolates of the plastome mutator line. cpDNA restriction patterns were compared to cpDNA from a representative of the progenitor Johansen strain, and cpDNAs from all eleven plastome mutator lines show changes of fragment mobility due to deletion events at five discrete regions of the plastome. Most of the mutants have cpDNA restriction patterns identical to that of one of the green isolates from the plastome mutator line, and therefore, most of the differences in fragment length are probably not responsible for the mutant phenotypes. In contrast to the plastome mutator line, cpDNA from several populations of a closely related wild-type Oenothera species have few restriction fragment length polymorphisms. This suggests that both mutation frequencies and site-specific cpDNA deletions are elevated in the plastome mutator line, and implicates a defect in the cpDNA repair or replication machinery.     

Structure and function of dnaQ and mutD mutators of Escherichia coli

Summary The nucleotide sequences of the recessivednaQ49 and the dominantmutD5 mutator were determined. ThednaQ49 mutator has a single base substitution in thednaQ gene, thus causing one amino acid change,₉₆Val (GTG)→ Gly (GGG), in the DnaQ protein (ε subunit of DNA polymerase III holoenzyme). ThemutD5 mutator possesses two base substitutions in the same gene, resulting in two amino acid changes,⁷³Leu (TTG)→Trp (TGG) and¹⁶⁴Ala (GCA)→Val (GTA), which were designated themutD52 andmutD51 mutations, respectively. Construction of chimaeric genes carrying one or two of these mutations revealed: (1) eithermutD51 ormutD52 alone causes the dominant mutator phenotype when present in a multi-copy plasmid; (2)mutD51, but notmutD52, exerts the dominant mutator phenotype when present in a low-copy plasmid; (3) the dominantmutD51 mutator activity is suppressed by thednaQ49 mutation when both mutations are present in the same gene. Based on these findings, we devised a model for the action of these mutators.     

Inefficient mismatch repair: genetic defects and down regulation

The mismatch repair system is involved in the maintenance of genomic integrity by editing DNA replication and recombination. However, although most mutations are neutral or deleterious, a mutator phenotype due to an inefficient mismatch repair may generate advantageous variants and may therefore be selected for. We review the evidence for inefficient mismatch repair due either to genetic defects in mismatch repair genes or to physiological conditions. Among natural isolates ofEscherichia coli andSalmonella enterica, about 1% are mutator bacteria, mostly deficient in mismatch repair (most of them defective in themutS gene). Characterization of mutators derived from laboratory strains led also to the isolation of mismatch repair mutants in which the most frequently found defects are inmutL andmutS. The correlation of the size of the antimutator genes with the frequency of their defective alleles amongE. coli andSalmonella strains reveals thatmutU mutants are underrepresented. Analysis of the progeny of a defined M13 phage heteroduplex DNA transfected intoE. coli cells shows that mismatch repair efficiency progressively decreases from the end of the exponential growth in K-12 and is variable among natural isolates. Implications of this defective mismatch repair activity for evolution and tumorigenesis will be discussed.     

RecB-dependent mutator phenotype in Neisseria meningitidis strains naturally defective in mismatch repair

Several invasive serogroup B meningococcal strains phylogenetically related to the lineage III (ET-24) exhibited a mutator phenotype as shown by mutagenicity assay using rifampicin-resistance as a selection marker. Hypermutation was associated to the presence of defective mutL alleles that were genetically characterized. Interestingly, the mutator phenotype was suppressed when a non-functional recB(ET-37) allele, derived from ET-37 meningococcal strains, replaced the functional recB allele in a lineage III strain. In contrast, the same gene replacement did not affect mutation frequencies in a mismatch repair-proficient strain. These results suggested that in MutL-deficient strains spontaneous mutations mostly arise from post-replicative DNA synthesis associated to the activity of the RecBCD recombination pathway.     

Role of hypermutability on bacterial fitness and emergence of resistance in experimental osteomyelitis due to Staphylococcus aureus

This study was designed to investigate the role of hypermutability of Staphylococcus aureus on bacterial fitness and antibiotic resistance in a model of chronic bone infection. An isogenic pair of strains, S. aureus RN4220 and its mutator counterpart inactivated in the mutL gene were used in a rat model of osteomyelitis of the tibia. The effect of the mutator phenotype in the emergence of antibiotic resistance was assessed in rats infected by each strain separately and treated with rifampicin for 5 days. No difference between the two strains was found in bacterial growth in vitro and in bacterial survival in the animal model, indicating no fitness defect in the mutator strain. In competition studies performed in rats coinfected with the two strains at a same ratio and sacrificed at different times from day 3 to day 42 postinoculation, the mutator strain was clearly disadvantaged because it was found in all rats and at all study times at lower counts (P<0.05 from day 14 to day 42). Two of the 16 rats infected by the mutator strain and none of the 14 rats infected by the wild-type strain had acquired rifampicin-resistant mutants (P=0.4). Data suggest that the S. aureus mutator phenotype was associated with a decreased bacterial fitness in vivo and did not confer significant advantage in the acquisition of antibiotic resistance in a model of chronic bone infection.     

Checkpoint-dependent activation of mutagenic repair in Saccharomyces cerevisiae pol3-01 mutants

The Saccharomyces cerevisiae DNA polymerase delta proofreading exonuclease-defective mutation pol3-01 is known to cause high rates of accumulating mutations. The pol3-01 mutant was found to have abnormal cell cycle progression due to activation of the S phase checkpoint. Inactivation of the S phase checkpoint suppressed both the pol3-01 cell cycle progression defect and mutator phenotype, indicating that the pol3-01 mutator phenotype was dependent on the S phase damage checkpoint pathway. Epistasis analysis suggested that a portion of the pol3-01 mutator phenotype involves members of the RAD6 epistasis group that function in both error-free and error-prone repair. These results indicate that activation of a checkpoint in response to certain types of replicative defects can result in the accumulation of mutations.     

Relocation of urf a from the mitochondrion to the nucleus cures the mitochondrial mutator phenotype in the fission yeast Schizosaccharomyces pombe

In previous papers we have reported the characterisation of mitochondrial mutator mutants of Schizosaccharomyces pombe. In contrast to nuclear mutator mutants known from other eucaryotes, this mutator phenotype correlates with mutations in an unassigned open reading frame (urf a) in the mitochondrial genome. Since an efficient biolistic transformation system for fission yeast mitochondria is not yet available, we relocated the mitochondrial urf a gene to the nucleus. As host strain for the ectopic expression, we used the nonsense mutant ana ^r -6, which carries a premature stop codon in the urf a gene. The phenotype of this mutant is characterised by continuous segregation of progeny giving rise to fully respiration competent colonies, colonies that show moderate growth on glycerol and a fraction of colonies that are unable to grow on glycerol. The phenotype of this mutant provides an excellent tool with which to study the effects on the mutator phenotype of ectopic expression of the urf a gene. Since a UGA codon encoding tryptophan is present in the original mitochondrial gene, we constructed two types of expression cassettes containing either the mitochondrial version of the urf a gene (mt-urf a) or a standard genetic code version (nc-urf a; UGA replaced by UGG) fused to the N-terminal import leader sequence of the cox4 gene of Saccharomyces cerevisiae. We show that the expression of the mt-urf a gene in its new location is able to cure, at least in part, the phenotype of mutant ana ^r -6, whereas the expression of the nc-urf a gene completely restores the wild-type (non-mutator) phenotype. The significant similarity of the urf a gene to the mitochondrial var1 gene of S. cerevisiae and homologous genes in other yeasts suggests that the urf a gene product might be a ribosomal protein with a dual function in protein synthesis and maintenance of mitochondrial DNA integrity. Received: 13 May 1997 / Accepted: 14 January 1998     

In vivo levels of mitochondrial hydrogen peroxide increase with age in mtDNA mutator mice

In mtDNA mutator mice, mtDNA mutations accumulate leading to a rapidly aging phenotype. However, there is little evidence of oxidative damage to tissues, and when analyzed ex vivo, no change in production of the reactive oxygen species (ROS) superoxide and hydrogen peroxide by mitochondria has been reported, undermining the mitochondrial oxidative damage theory of aging. Paradoxically, interventions that decrease mitochondrial ROS levels in vivo delay onset of aging. To reconcile these findings, we used the mitochondria‐targeted mass spectrometry probe MitoB to measure hydrogen peroxide within mitochondria of living mice. Mitochondrial hydrogen peroxide was the same in young mutator and control mice, but as the mutator mice aged, hydrogen peroxide increased. This suggests that the prolonged presence of mtDNA mutations in vivo increases hydrogen peroxide that contributes to an accelerated aging phenotype, perhaps through the activation of pro‐apoptotic and pro‐inflammatory redox signaling pathways.     

Tcl transposition and mutator activity in a Bristol strain of Caenorhabditis elegans

Summary In most strains of Caenorhabditis elegans with a low copy number of Tc1 transposable elements, germline transposition is rare or undetectable. We have observed low-level Tel transposition in the genome of the C. elegans var. Bristol strain KR579 (unc-13[e51]) resulting in an increase in Tc1 copy number and subsequent mutator activity. Examination of genomic blots from KR579 and KR579derived strains revealed that more Tc1-hybridizing bands were present than in other Bristol strains. A novel Tc1-hybridizing fragment was cloned from a KR579-derived strain. Unique sequence DNA flanking the Tc1 element identified a 1.6 kb restriction fragment length difference between the KR579 and N2 strains consistent with a Tc1 insertion at a new genomic site. The site of insertion of this Tel was sequenced and is similar to the published Tel insertion site consensus sequence. Several isolates of KR579 were established and maintained on plates for a period of 3 years in order to determine if Tc1 copy number would continue to increase. In one isolate, KR1787, a further increase in Tc1 copy number was observed. Examination of the KR1787 strain has shown that it also exhibits mutator activity as assayed by the spontaneous mutation frequency at the unc-22 (twitcher) locus. The KR579 strain differs from most low copy number strains in that it exhibits low-level transposition which has developed into mutator activity.     

TheisfA mutation inhibits mutator activity and processing of UmuD protein inEscherichia coli recA730 strains

Further studies on theisfA mutation responsible for anti-SOS and antimutagenic activities inEscherichia coli are described. We have previously shown that theisfA mutation inhibits mutagenesis and other SOS-dependent phenomena, possibly by interfering with RecA coprotease activity. TheisfA mutation has now been demonstrated also to suppress mutator activity inE. coli recA730 andrecA730 lexA51(Def) strains that constitutively express RecA coprotease activity. We further show that the antimutator activity of theisfA mutation is related to inhibition of RecA coprotease-dependent processing of UmuD. Expression of UmuD' from plasmid pGW2122 efficiently restores UV-induced mutagenesis in therecA730 isfA strain and partially restores its mutator activity. On the other hand, overproduction of UmuD'C proteins from pGW2123 plasmid markedly enhances UV sensitivity with no restoration of mutability.     

Mutational specificity of a bacteriophage T4 DNA polymerase mutant, mel88

Summary Several bacteriophage T4 DNA polymerase mutants have been shown to increase the frequency of spontaneous mutations (Speyer et al. 1966; Freese and Freese 1967; de Vries et al. 1972; Reha-Krantz et al. 1986). In order to determine the molecular basis of the mutator phenotype, it is necessary to characterize the types of mutations produced by the mutator DNA polymerases. We show here that at least one DNA polymerase mutator mutant, mel88, induces an increased number of base substitution mutations compared with wild-type.     

Differential effect of ultraviolet light on the induction of simian virus 40 and a cellular mutator phenotype in transformed mammalian cells

UV irradiation of simian virus 40 (SV40)-transformed human and hamster cells induced them both to express a mutator phenotype and to produce SV40. The mutator could also be activated indirectly by transfecting unirradiated cells with UV-damaged calf thymus DNA. In contrast, UV-damaged exogenous DNA failed to rescue SV40 from unirradiated transformed cells. These results suggest that the expression of transforming viruses and of cellular mutator functions is regulated by at least partially independent mechanisms. Unlike the activation of a cellular mutator phenotype, the rescue of SV40 from virus-transformed mammalian cells by UV light might require that the integrated viral DNA and/or specific cellular sequences are directly damaged.     

Selection for β2-microglobulin mutation in mismatch repair-defective colorectal carcinomas

Novel peptide antigens complexed with human leukocyte antigen (HLA) and β₂-microglobulin (β2M) molecules are presented at the cell surface to cytotoxic T lymphocytes (CTLs), provoking lysis of the antigen-presenting cell [1]. In tumour cells, genetically altered or abnormally expressed proteins provide a source of peptides that can be presented to CTLs; the resulting anti-tumour CTL responses may provide part of the body's defence against cancer. Disabling mutations in the HLA and β2M proteins required for peptide presentation allow a tumour cell to escape destruction by CTLs. Cells with deficient DNA mismatch repair have high spontaneous mutation rates [2] and produce many altered proteins that are a potential source of numerous unique peptides. Mutator tumour cells might therefore be particularly vulnerable to immune surveillance and CTL attack. Mutator phenotypes [3] and [4] and loss of β2M (or HLA) expression [5] and [6] are both relatively common among sporadic colorectal tumours. We have compared the frequency of β2M mutations in sporadic colorectal and other tumours with and without a mutator phenotype. Mutations were more frequent among colorectal tumours with the microsatellite instability indicative of a defect in DNA mismatch repair. The inactivating β2M mutations were predominantly frameshifts, which is consistent with the underlying mismatch repair defects. Evasion of immune surveillance by acquiring β2M mutations therefore occurs at high frequency in tumour cells with a mutator phenotype due to defective DNA mismatch repair.     

Mistranslation induced by streptomycin provokes a RecABC/RuvABC-dependent mutator phenotype in Escherichia coli cells.

Translational stress-induced mutagenesis (TSM) refers to the mutator phenotype observed in Escherichia coli cells expressing a mutant allele (mutA or mutC) of the glycine tRNA gene glyV (or glyW). Because of an anticodon mutation, expression of the mutA allele results in low levels of Asp-->Gly mistranslation. The mutA phenotype does not require lexA-regulated SOS mutagenesis functions, and appears to be suppressed in cells defective for RecABC-dependent homologous recombination functions. To test the hypothesis that the TSM response is mediated by non-specific mistranslation rather than specific Asp-->Gly misreading, we asked if streptomycin (Str), an aminoglycoside antibiotic known to promote mistranslation, can provoke a mutator phenotype. We report that Str induces a strong mutator phenotype in cells bearing certain alleles of rpsL, the gene encoding S12, an essential component of the ribosomal 30 S subunit. The phenotype is strikingly similar to that observed in mutA cells in its mutational specificity, as well as in its requirement for RecABC-mediated homologous recombination functions. Expression of Str-inducible mutator phenotype correlates with mistranslation efficiency in response to Str. Thus, mistranslation in general is able to induce the TSM response. The Str-inducible mutator phenotype described here defines a new functional class of rpsL alleles, and raises interesting questions on the mechanism of action of Str, and on bacterial response to antibiotic stress.     

Expression of mutant alanine tRNAs increases spontaneous mutagenesis in Escherichia coli

The expression of mutA, an allele of the glycine tRNA gene glyV, can confer a novel mutator phenotype that correlates with its ability to promote Asp-->Gly mistranslation. Both activities are mediated by a single base change within the anticodon such that the mutant tRNA can decode aspartate codons (GAC/U) instead of the normal glycine codons (GCC/U). Here, we investigate whether specific Asp-->Gly mistranslation is required for the unexpected mutator phenotype. To address this question, we created and expressed 18 individual alleles of alaV, the gene encoding an alanine tRNA, in which the alanine anticodon was replaced with those specifying other amino acids such that the mutant (alaVX) tRNAs are expected to potentiate X-->Ala mistranslation, where X is one of the other amino acids. Almost all alaVX alleles proved to be mutators in an assay that measured the frequency of rifampicin-resistant mutants, with one allele (alaVGlu) being a stronger mutator than mutA. The alaVGlu mutator phenotype resembles that of mutA in mutational specificity (predominantly transversions), as well as SOS independence, but in a puzzling twist differs from mutA in that it does not require a functional recA gene. Our results suggest that general mistranslation (as opposed to Asp-->Gly alone) can induce a mutator phenotype. Furthermore, these findings predict that a large number of conditions that increase translational errors, such as genetic defects in the translational apparatus, as well as environmental and physiological stimuli (such as amino acid starvation or exposure to antibiotics) are likely to activate a mutator response. Thus, both genetic and epigenetic mechanisms can accelerate the acquisition of mutations.     

Interactions between epsilon, the proofreading subunit of DNA polymerase III, and proteins involved in the SOS response of Escherichia coli

Summary Epsilon, a fidelity subunit of Escherichia coli DNA Polymerase III, is encoded by dnaQ ⁺. dnaQ49 is a recessive allele that confers temperature-sensitive and saltsuppressible phenotypes for both replication fidelity and viability. SOS mutagenesis in E. coli is regulated by LexA and requires activated RecA (RecA^*) and the products of the umuDC operon. dnaQ49 strains with various recA, lexA and umuDC alleles were constructed to determine if activities induced as part of the SOS response influence epsilon activity. We found: (1) both UmuDC and RecA^* independently enhance the dnaQ49 mutator phenotype, and (2) expression of RecA^* activity in the absence of UmuDC function increases the temperature sensitivity for viability of dnaQ49. These results support the hypothesis that RecA and one or both of the UmuDC proteins interact with the replication complex during SOS mutagenesis.     

Mutational specificity of a proof-reading defective Escherichia coli dnaQ49 mutator

Summary The dnaQ (mutD) gene product which encodes the -subunit of the DNA polymerase III holoenzyme has a central role in controlling the fidelity of DNA replication because both mutD5 and dnaQ49 mutations severely decrease the 3–5 exonucleolytic editing capacity.It is shown in this paper that more than 95% of all anaQ49-induced base pair substitutions are transversions of the types G:C-T:A and A:T-T:A. Not only is this unusual mutational specificity precisely that observed recently for a number of potent carcinogens such as benzo(a) pyrene diolepoxide (BPDE) and aflatoxin B1 (AFB1), which are dependent on the SOS system to mutagenize bacteria, but it is also seen for the constitutively expressed SOS mutator activity in E. coli tif-1 strains as well as for the SOS mutator activity mediated gap filling of apurinic sites. Because the G:C-T:A and A:T-T:A transversions can either result from the insertion of an adenine across from apurinic sites or arise due to the incorporation of syn-adenine opposite a purine base, we postulate that the DNA polymerase III holoenzyme also has a reduced discrimination ability in a dnaQ49 background.The introduction of a lexA (Ind^-) allele, which prevents the expression of SOS functions, led to a significant reduction in the dnaQ49-caused mutator effect.Both, the mutational specificity observed and the partial lexA ⁺ dependence of the mutator effect provoke a reanalysis of the hypothesis that the DNA polymerase III holoenzyme can be converted into the postulated but until now unidentified SOS polymerase.     

cAMP inhibits bud growth in a yeast strain compromised for Ca2+ influx into the Golgi

Biochemical and physiological studies have implicated cAMP and cAMP-dependent protein kinase (PKA) in a plethora of essential cellular processes. Here we show that yeast cells partially depleted of PKA activity (due to atpk ^w mutation) and bearing a lesion in a Golgi-localized Ca²⁺ pump (Pmr1), arrest division with a small bud. The bud morphology of the arrestedtpk1 ^w pmr1 mutant cells is characteristic of cells in S phase; however, the terminal phenotype of processes such as DNA replication and nuclear division suggests arrest at the G2/M boundary. This small bud, G2-arrest phenotype is similar to that of strains with a defect in cell wall biosynthesis (pkc1) or membrane biogenesis (och1); however, the biochemical defect may be different since thetpk1 ^w pmr1 double mutants retain viability. The growth defect of thetpk1 ^w pmr1 mutant can be alleviated by preventing the increase in cellular cAMP levels that is known to be associated with a decrease in PKA activity, or by supplementing the medium with millimolar amounts of Ca²⁺. Although the biochemical consequences of this increase in cAMP concentration are not known, the small-bud phenotype of the double mutant and the known protein processing defect of thepmr1 lesion suggest that the localization or function of some membrane component might be compromised and susceptible to perturbations in cellular cAMP levels. One candidate for such a protein is the cAMP-binding membrane ectoprotein recently described in yeast.     

Evidence for interplay among yeast replicative DNA polymerases alpha, delta and epsilon from studies of exonuclease and polymerase active site mutations

Background  

DNA polymerase ε (Pol ε) is essential for S-phase replication, DNA damage repair and checkpoint control in yeast. A pol2-Y831A mutation leading to a tyrosine to alanine change in the Pol ε active site does not cause growth defects and confers a mutator phenotype that is normally subtle but strong in a mismatch repair-deficient strain. Here we investigate the mechanism responsible for the mutator effect.     

Retrotransposon Gypsy and genetic instability in Drosophila (review)

The laboratory mutator strain (MS) has properties which can be characterized as genetic instability. It exhibits the high level of gypsy autonomous transposition in somatic and germ cells. This paper summarizes all the data concerning this system and gypsy itself that has been obtained in our works during the last years.