An Oak Ridge legacy: the specific locus test and its role in mouse mutagenesis.

Mutations in the genes encoding single-strand DNA-specific exonucleases (ssExos) of Escherichia coli were examined for effects on mutation avoidance, UV repair, and conjugational recombination. Our results indicate complex and partially redundant roles for ssExos in these processes. Although biochemical experiments have implicated RecJ exonuclease, Exonuclease I (ExoI), and Exonuclease VII (ExoVII) in the methyl-directed mismatch repair pathway, the RecJ- ExoI- ExoVII- mutant did not exhibit a mutator phenotype in several assays for base substitution mutations. If these exonucleases do participate in mismatch excision, other exonucleases in E. coli can compensate for their loss. Frameshift mutations, however, were stimulated in the RecJ- ExoI- ExoVII- mutant. For acridine-induced frameshifts, this mutator effect was due to a synergistic effect of ExoI- and ExoVII- mutations, implicating both ExoI and ExoVII in avoidance of frameshift mutations. Although no single exonuclease mutant was especially sensitive to UV irradiation, the RecJ- ExoVII- double mutant was extremely sensitive. The addition of an ExoI- mutation augmented this sensitivity, suggesting that all three exonucleases play partially redundant roles in DNA repair. The ability to inherit genetic markers by conjugation was reduced modestly in the ExoI- RecJ- mutant, implying that the function of either ExoI or RecJ exonucleases enhances RecBCD-dependent homologous recombination.     

Mismatch Repair in Escherichia coli Cells Lacking Single-Strand Exonucleases ExoI, ExoVII, and RecJ

In vitro, the methyl-directed mismatch repair system of Escherichia coli requires the single-strand exonuclease activity of either ExoI, ExoVII, or RecJ and possibly a fourth, unknown single-strand exonuclease. We have created the first precise null mutations in genes encoding ExoI and ExoVII and find that cells lacking these nucleases and RecJ perform mismatch repair in vivo normally such that triple-null mutants display normal mutation rates. ExoI, ExoVII, and RecJ are either redundant with another function(s) or are unnecessary for mismatch repair in vivo.     

Mutation as an origin of genetic variability in Helicobacter pylori

The availability of two complete Helicobacter pylori genome sequences and recent studies of its population genetics have provided a detailed picture of genetic diversity in this important human gastric pathogen. It is believed that, in addition to genetic recombination, de novo mutation could have a role in generating the high level of genetic variation in H. pylori.     

Mutation induction in Haemophilus influenzae by ICR-191 II. Role of DNA replication and repair

Evidence is presented to show that presumptive frameshift mutations induced in Haemophilus influenzae by ICR-191 are fixed very rapidly, essentially at the time of treatment. DNA synthesis during treatment is essential for fixation, but DNA synthesis after treatment has no effect. The conclusion is drawn that the mutagen acts at the replication fork, possibly to stabilize misannealings arising in association with the discontinuities in the newly synthesized DNA. These results agree with earlier results on Escherichia coli showing that ICR-191 produces peak mutation frequencies in synchronized cultures at times when the replication fork has reached the locus being studied. They are in sharp contrast to the earlier results in H. influenzae with nitroso compounds and hydrazine that suggest these agents produce randomly distributed, reparable pre-mutational damage that still can be fixed (converted to final mutation) for some time after treatment when the replication fork reaches them. No evidence for such persistent pre-mutational lesions was found with ICR-191. A defect in incision appeared to have very little influence on mutation induction by ICR-191 though it caused much more lethality. The interpretation of the mutation data was made somewhat uncertain, however, by an unexplained plating-density effect on the expression of the mutants in this strain. In contrast, incision deficiencies in E. coli and Salmonella typhimurium have been reported to cause a large increase in mutation induction and to allow lesions at some distance from the replication fork to produce mutations.     

DNA Structures Generated during Recombination Initiated by Mismatch Repair of Uv-Irradiated Nonreplicating Phage DNA in Escherichia Coli: Requirements for Helicase, Exonucleases, and Recf and Recbcd Functions

During infection of homoimmune Escherichia coli lysogens (``repressed infections'), undamaged non-replicating λ phage DNA circles undergo very little recombination. Prior UV irradiation of phages dramatically elevates recombinant frequencies, even in bacteria deficient in UvrABC-mediated excision repair. We previously reported that 80-90% of this UvrABC-independent recombination required MutHLS function and unmethylated d(GATC) sites, two hallmarks of methyl-directed mismatch repair. We now find that deficiencies in other mismatch-repair activities--UvrD helicase, exonuclease I, exonuclease VII, RecJ exonuclease--drastically reduce recombination. These effects of exonuclease deficiencies on recombination are greater than previously observed effects on mispair-provoked excision in vitro. This suggests that the exonucleases also play other roles in generation and processing of recombinagenic DNA structures. Even though dsDNA breaks are thought to be highly recombinagenic, 60% of intracellular UV-irradiated phage DNA extracted from bacteria in which recombination is low--UvrD(-), ExoI(-), ExoVII(-), or RecJ(-)--displays (near-)blunt-ended dsDNA ends (RecBCD-sensitive when deproteinized). In contrast, only bacteria showing high recombination (Mut(+) UvrD(+) Exo(+)) generate single-stranded regions in nonreplicating UV-irradiated DNA. Both recF and recB recC mutations strikingly reduce recombination (almost as much as a recF recB recC triple mutation), suggesting critical requirements for both RecF and RecBCD activity. The mismatch repair system may thus process UV-irradiated DNA so as to initiate more than one recombination pathway.     

Role for radA/sms in recombination intermediate processing in Escherichia coli

RadA/Sms is a highly conserved eubacterial protein that shares sequence similarity with both RecA strand transferase and Lon protease. We examined mutations in the radA/sms gene of Escherichia coli for effects on conjugational recombination and sensitivity to DNA-damaging agents, including UV irradiation, methyl methanesulfonate (MMS), mitomycin C, phleomycin, hydrogen peroxide, and hydroxyurea (HU). Null mutants of radA were modestly sensitive to the DNA-methylating agent MMS and to the DNA strand breakage agent phleomycin, with conjugational recombination decreased two- to threefold. We combined a radA mutation with other mutations in recombination genes, including recA, recB, recG, recJ, recQ, ruvA, and ruvC. A radA mutation was strongly synergistic with the recG Holliday junction helicase mutation, producing profound sensitivity to all DNA-damaging agents tested. Lesser synergy was noted between a mutation in radA and recJ, recQ, ruvA, ruvC, and recA for sensitivity to various genotoxins. For survival after peroxide and HU exposure, a radA mutation surprisingly suppressed the sensitivity of recA and recB mutants, suggesting that RadA may convert some forms of damage into lethal intermediates in the absence of these functions. Loss of radA enhanced the conjugational recombination deficiency conferred by mutations in Holliday junction-processing function genes, recG, ruvA, and ruvC. A radA recG ruv triple mutant had severe recombinational defects, to the low level exhibited by recA mutants. These results establish a role for RadA/Sms in recombination and recombinational repair, most likely involving the stabilization or processing of branched DNA molecules or blocked replication forks because of its genetic redundancy with RecG and RuvABC.     

xni-deficient Escherichia coli are proficient for recombination and multiple pathways of repair

Single-strand-dependent DNA exonucleases play important roles in DNA repair and recombination in all organisms. In Escherichia coli the redundant functions provided by the RecJ, ExoI, ExoVII and ExoX exonucleases are required for mismatch repair, UV resistance and homologous recombination. We have examined whether the xni gene product, the single-strand exonuclease ExoIX, is also a member of this group. We find that deletion of xni has no effect on the above processes, or on resistance to oxidative damage, even in combination with other exonuclease mutations. We conclude that the xni gene product does not belong to this group of nucleases that play redundant roles in DNA recombination and repair.     

Mutations in polI but not mutSLH destabilize Haemophilus influenzae tetranucleotide repeats

Haemophilus influenzae (Hi), an obligate upper respiratory tract commensal/pathogen, uses phase variation (PV) to adapt to host environment changes. Switching occurs by slippage of nucleotide repeats (microsatellites) within genes coding for virulence molecules. Most such microsatellites in Hi are tetranucleotide repeats, but an exception is the dinucleotide repeats in the pilin locus. To investigate the effects on PV rates of mutations in genes for mismatch repair (MMR), insertion/deletion mutations of mutS, mutL, mutH, dam, polI, uvrD, mfd and recA were constructed in Hi strain Rd. Only inactivation of polI destabilized tetranucleotide (5'AGTC) repeat tracts of chromosomally located reporter constructs, whereas inactivation of mutS, but not polI, destabilized dinucleotide (5'AT) repeats. Deletions of repeats were predominant in polI mutants, which we propose are due to end-joining occurring without DNA polymerization during polI-deficient Okazaki fragment processing. The high prevalence of tetranucleotides mediating PV is an exceptional feature of the Hi genome. The refractoriness to MMR of hypermutation in Hi tetranucleotides facilitates adaptive switching without the deleterious increase in global mutation rates that accompanies a mutator genotype.     

Improving Lambda Red Genome Engineering in Escherichia coli via Rational Removal of Endogenous Nucleases

Lambda Red recombineering is a powerful technique for making targeted genetic changes in bacteria. However, many applications are limited by the frequency of recombination. Previous studies have suggested that endogenous nucleases may hinder recombination by degrading the exogenous DNA used for recombineering. In this work, we identify ExoVII as a nuclease which degrades the ends of single-stranded DNA (ssDNA) oligonucleotides and double-stranded DNA (dsDNA) cassettes. Removing this nuclease improves both recombination frequency and the inheritance of mutations at the 3' ends of ssDNA and dsDNA. Extending this approach, we show that removing a set of five exonucleases (RecJ, ExoI, ExoVII, ExoX, and Lambda Exo) substantially improves the performance of co-selection multiplex automatable genome engineering (CoS-MAGE). In a given round of CoS-MAGE with ten ssDNA oligonucleotides, the five nuclease knockout strain has on average 46% more alleles converted per clone, 200% more clones with five or more allele conversions, and 35% fewer clones without any allele conversions. Finally, we use these nuclease knockout strains to investigate and clarify the effects of oligonucleotide phosphorothioation on recombination frequency. The results described in this work provide further mechanistic insight into recombineering, and substantially improve recombineering performance.     

Destabilization of tetranucleotide repeats in Haemophilus influenzae mutants lacking RnaseHI or the Klenow domain of PolI

A feature of Haemophilus influenzae genomes is the presence of several loci containing tracts of six or more identical tetranucleotide repeat units. These repeat tracts are unstable and mediate high frequency, reversible alterations in the expression of surface antigens. This process, termed phase variation (PV), enables H.influenzae to rapidly adapt to fluctuations in the host environment. Perturbation of lagging strand DNA synthesis is known to destabilize simple sequence repeats in yeast and Escherichia coli. By using a chromosomally located reporter construct, we demonstrated that the mutation of an H.influenzae rnhA (encoding RnaseHI) homologue increases the mutation rates of tetranucleotide repeats ~3-fold. Additionally, deletion of the Klenow domain of DNA polymerase I (PolI) resulted in a ~35-fold increase in tetranucleotide repeat-mediated PV rates. Deletion of the PolI 5′>3′ exonuclease domain appears to be lethal. The phenotypes of these mutants suggest that delayed or mutagenic Okazaki fragment processing destabilizes H.influenzae tetranucleotide repeat tracts.     

Yeast ARMs (DNA at-risk motifs) can reveal sources of genome instability

The genomes of all organisms contain an abundance of DNA repeats which are at-risk for causing genetic change. We have used the yeast Saccharomyces cerevisiae to investigate various repeat categories in order to understand their potential for causing genomic instability and the role of DNA metabolism factors. Several types of repeats can increase enormously the likelihood of genetic changes such as mutation or recombination when present either in wild type or mutants defective in replication or repair. Specifically, we have investigated inverted repeats, homonucleotide runs, and short distant repeats and the consequences of various DNA metabolism mutants. Because the at-risk motifs (ARMs) that we characterized are sensitive indicators, we have found that they are useful tools to reveal new genetic factors affecting genome stability as well as to distinguish subtle differences between alleles.     

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.     

Fragmentation heterogeneity of 23S ribosomal RNA in Haemophilus species

The fragmentation of 23S rRNA of 22 Haemophilus influenzae strains and eight strains belonging to other Haemophilus species was investigated. Instead of intact molecules, the 23S rRNA molecules were found to be cleaved into two to five smaller conserved fragments in most strains examined, especially in H. influenzae type b (5/6) and nontypeable strains (5/5). One or two conserved potential cleavage sites were identified by PCR analysis of the strains showing a fragmented 23S rRNA pattern. The relevant nucleotide sequences were determined and compared to H. influenzae Rd, which contains intact 23S rRNA molecules. An identical 112 bp long intervening sequence (IVS) at position 542 and a conserved 121–123 bp IVS sequence at position 1171 were found in two H. influenzae type b strains and one nontypeable strain. Among the strains with fragmented 23S rRNA, nearly half showed a heterogeneous cleavage pattern due to the dispersion of IVSs among different 23S rRNA operons. The localization of the conserved H. influenzae IVSs coincided well with the extensively studied IVSs among other bacteria, but differed in nucleotide sequence from any other reported IVSs. Therefore, the IVSs of Haemophilus 23S rRNA may originate from a common source that is independent of other bacteria.     

Poor transformability with novr and eryr donor DNA of some mitomycin-C-sensitive strains of Haemophilus influenzae

Three mitomycin-C-sensitive (MC^s) strains of Haemophilus influenzae, being poorly transformable with DNA carrying the antibiotic resistence markers nov^r and ery^r, were further investigated to determine the cause of their poor transformability. After being genetically integrated into the mutant-recipient genome the donor marker is replicated at the same rate as in the wild type, indicating that recombination in the mutant strains is normal. In the mutants, designated T^d (transformation-deficient), the poor transformability for the nov^r and ery^r markers is due to the lack of phenotypic expression of the markers, because the strains are killed by concentrations of antibiotics normally used to select for nov^r and ery^r transformants. Since the strains exhibit extreme sensitivity both to deoxycholate and osmotic shock in the presence of EDTA, the increased sensitivity to antibiotics (including mitomycin-C) is probably caused by a change in the cell envelope. Although recombination in the mutant strains proceeds normally, the T^d mutation nevertheless decreases both the rate of inactivation and of integration of donor DNA.     

Effects of sequence on repeat expansion during DNA replication

Small DNA repeat tracts are located throughout the human genome. The tracts are unstable, and expansions of certain repeat sequences cause neuromuscular disease. DNA expansions appear to be associated with lagging-strand DNA synthesis and DNA repair. At some sites of repeat expansion, e.g. the myotonic dystrophy type 2 (DM2) tetranucleotide repeat expansion site, more than one repeat tract with similar sequences lie side by side. Only one of the DM2 repeat tracts, however, is found to expand. Thus, DNA base sequence is a possible factor in repeat tract expansion. Here we determined the expansion potential, during DNA replication by human DNA polymerase β, of several tetranucleotide repeat tracts in which the repeat units varied by one or more bases. The results show that subtle changes, such as switching T for C in a tetranucleotide repeat, can have dramatic consequences on the ability of the nascent-strand repeat tract to expand during DNA replication. We also determined the relative stabilities of self-annealed 100mer repeats by melting-curve analysis. The relative stabilities did not correlate with the relative potentials of the analogous repeats for expansion during DNA replication, suggesting that hairpin formation is not required for expansion during DNA replication.     

RecQ-dependent death-by-recombination in cells lacking RecG and UvrD

Maintenance of genomic stability is critical for all cells. Homologous recombination (HR) pathways promote genome stability using evolutionarily conserved proteins such as RecA, SSB, and RecQ, the Escherichia coli homologue of five human proteins at least three of which suppress genome instability and cancer. A previous report indicated that RecQ promotes the net accumulation in cells of intermolecular HR intermediates (IRIs), a net effect opposite that of the yeast and two human RecQ homologues. Here we extend those conclusions. We demonstrate that cells that lack both UvrD, an inhibitor of RecA-mediated strand exchange, and RecG, a DNA helicase implicated in IRI resolution, are inviable. We show that the uvrD recG cells die a “death-by-recombination” in which IRIs accumulate blocking chromosome segregation. First, their death requires RecA HR protein. Second, the death is accompanied by cytogenetically visible failure to segregate chromosomes. Third, FISH analyses show that the unsegregated chromosomes have completed replication, supporting the hypothesis that unresolved IRIs prevented the segregation. Fourth, we show that RecQ and induction of the SOS response are required for the accumulation of replicated, unsegregated chromosomes and death, as are RecF, RecO, and RecJ. ExoI exonuclease and MutL mismatch-repair protein are partially required. This set of genes is similar but not identical to those that promote death-by-recombination of ΔuvrD Δruv cells. The data support models in which RecQ promotes the net accumulation in cells of IRIs and RecG promotes resolution of IRIs that form via pathways not wholly identical to those that produce the IRIs resolved by RuvABC. This implies that RecG resolves intermediates other than or in addition to standard Holliday junctions resolved by RuvABC. The role of RecQ in net accumulation of IRIs may be shared by one or more of its human homologues.     

Modulation of recombination and DNA repair by the RecG and PriA helicases of Escherichia coli K-12.

The RecG protein of Escherichia coli is a structure-specific DNA helicase that targets strand exchange intermediates in genetic recombination and drives their branch migration along the DNA. Strains carrying null mutations in recG show reduced recombination and DNA repair. Suppressors of this phenotype, called srgA, were located close to metB and shown to be alleles of priA. Suppression depends on the RecA, RecBCD, RecF, RuvAB, and RuvC recombination proteins. Nine srgA mutations were sequenced and shown to specify mutant PriA proteins with single amino acid substitutions located in or close to one of the conserved helicase motifs. The mutant proteins retain the ability to catalyze primosome assembly, as judged by the viability of recG srgA and srgA strains and their ability to support replication of plasmids based on the ColE1 replicon. Multicopy priA+ plasmids increase substantially the recombination- and repair-deficient phenotype of recG strains and confer similar phenotypes on recG srgA double mutants but not on ruvAB or wild-type strains. The multicopy effect is eliminated by K230R, C446G, and C477G substitutions in PriA. It is concluded that the 3'-5' DNA helicase/translocase activity of PriA inhibits recombination and that this effect is normally countered by RecG.     

Redundant exonuclease involvement in Escherichia coli methyl-directed mismatch repair.

Previous biochemical analysis of Escherichia coli methyl-directed mismatch repair implicates three redundant single-strand DNA-specific exonucleases (RecJ, ExoI, and ExoVII) and at least one additional unknown exonuclease in the excision reaction (Cooper, D. L., Lahue, R. S., and Modrich, P. (1993) J. Biol. Chem. 268, 11823-11829). We show here that ExoX also participates in methyl-directed mismatch repair. Analysis of the reaction with crude extracts and purified components demonstrated that ExoX can mediate repair directed from a strand signal 3' of a mismatch. Whereas extracts of all possible single, double, and triple exonuclease mutants displayed significant residual mismatch repair, extracts deficient in RecJ, ExoI, ExoVII, and ExoX exonucleases were devoid of normal repair activity. The RecJ(-) ExoVII(-) ExoI(-) ExoX(-) strain displayed a 7-fold increase in mutation rate, a significant increase, but less than that observed for other blocks of the mismatch repair pathway. This elevation is epistatic to deficiency for MutS, suggesting an effect via the mismatch repair pathway. Our other work (Burdett, V., Baitinger, C., Viswanathan, M., Lovett, S. T., and Modrich, P. (2001) Proc. Natl. Acad. Sci. U. S. A. 98, 6765-6770) suggests that mutants are under-recovered in the exonuclease-deficient strain due to loss of viability that is triggered by mismatched base pairs in this genetic background. The availability of any one exonuclease is enough to support full mismatch correction, as evident from the normal mutation rates of all triple mutants. Because three of these exonucleases possess a strict polarity of digestion, this suggests that mismatch repair can occur exclusively from a 3' or a 5' direction to the mismatch, if necessary.     

A new source of polymorphic DNA markers for sperm typing: analysis of microsatellite repeats in single cells.

We show that dinucleotide and tetranucleotide repeat polymorphisms can be analyzed in single cells without using radioactivity or denaturing gels. This provides a rich new source of DNA polymorphisms for genetic mapping by sperm typing. The recombination fraction between two CA repeat polymorphisms was determined after whole genome amplification of single sperm, followed by typing of two different aliquots, one aliquot for each polymorphic locus. Single-cell analysis of microsatellites may also be valuable both for preimplantation genetic disease diagnosis based on single-blastomere or polar-body analysis and for the typing of forensic or ancient DNA samples containing very small amounts of nucleic acid.     

Arabidopsis mitochondrial single-stranded DNA-binding proteins SSB1 and SSB2 are essential regulators of mtDNA replication and homologous recombination

Faithful DNA replication is one of the most essential processes in almost all living organisms. However, the proteins responsible for organellar DNA replication are still largely unknown in plants. Here, we show that the two mitochondrion-targeted single-stranded DNA-binding (SSB) proteins SSB1 and SSB2 directly interact with each other and act as key factors for mitochondrial DNA (mtDNA) maintenance, as their single or double loss-of-function mutants exhibit severe germination delay and growth retardation. The mtDNA levels in mutants lacking SSB1 and/or SSB2 function were two- to four-fold higher than in the wild-type (WT), revealing a negative role for SSB1/2 in regulating mtDNA replication. Genetic analysis indicated that SSB1 functions upstream of mitochondrial DNA POLYMERASE IA (POLIA) or POLIB in mtDNA replication, as mutation in either gene restored the high mtDNA copy number of the ssb1-1 mutant back to WT levels. In addition, SSB1 and SSB2 also participate in mitochondrial genome maintenance by influencing mtDNA homologous recombination (HR). Additional genetic analysis suggested that SSB1 functions upstream of ORGANELLAR SINGLE-STRANDED DNA-BINDING PROTEIN1 (OSB1) during mtDNA replication, while SSB1 may act downstream of OSB1 and MUTS HOMOLOG1 for mtDNA HR. Overall, our results yield new insights into the roles of the plant mitochondrion-targeted SSB proteins and OSB1 in maintaining mtDNA stability via affecting DNA replication and DNA HR.