A Sister-Strand Exchange Mechanism for Reca-Independent Deletion of Repeated DNA Sequences in Escherichia Coli

In the genomes of many organisms, deletions arise between tandemly repeated DNA sequences of lengths ranging from several kilobases to only a few nucleotides. Using a plasmid-based assay for deletion of a 787-bp tandem repeat, we have found that a recA-independent mechanism contributes substantially to the deletion process of even this large region of homology. No Escherichia coli recombination gene tested, including recA, had greater than a fivefold effect on deletion rates. The recA-independence of deletion formation is also observed with constructions present on the chromosome. RecA promotes synapsis and transfer of homologous DNA strands in vitro and is indispensable for intermolecular recombination events in vivo measured after conjugation. Because deletion formation in E. coli shows little or no dependence on recA, it has been assumed that homologous recombination contributes little to the deletion process. However, we have found recA-independent deletion products suggestive of reciprocal crossovers when branch migration in the cell is inhibited by a ruvA mutation. We propose a model for recA-independent crossovers between replicating sister strands, which can also explain deletion or amplification of repeated sequences. We suggest that this process may be initiated as post-replicational DNA repair; subsequent strand misalignment at repeated sequences leads to genetic rearrangements.     

Unraveling a Region-Specific Hyper-Recombination Phenomenon: Genetic Control and Modalities of Terminal Recombination in Escherichia Coli

The propensity of the terminus of the Escherichia coli chromosome for recombination has been further explored, using a test based on the selectable loss of a λ prophage inserted between repeated sequences from Tn10. Terminal recombination appears region-specific and unrelated to replication termination in a strain harboring a major chromosomal rearrangement. It requires RecBC(D) activity and must therefore occur between sister chromosomes, to conserve genomic integrity in spite of DNA degradation by RecBCD. Terminal recombination is maximal in the dif region and its intensity on either side of this recombination site depends on the orientation of the repeated sequences, probably because of the single χ site present in each repeat. Additional observations support the model that the crossover is initiated by single-strand invasion between sister chromosomes followed by RecBCD action as a consequence of DNA breakage due to the initial invasion event. Crossover location within repeats inserted at dif position supports the possibility that sister chromosomes are tightly paired in the centre of the terminal recombination zone. These data reinforce the model that postreplicative reconstruction of nucleoid organization creates a localized synapsis between the termini of sister chromosomes.     

Quasi-Adaptive Response to Alkylating Agents in <Emphasis Type="Italic">Escherichia coli</Emphasis>: A New Phenomenon

An original hypothesis of a quasi-adaptive response to nitrosomethylurea (NMU) in Escherichia coli cells was verified experimentally. In contrast to the true Ada response, which is induced in cells pretreated with a sublethal dose of NMU, a quasi-adaptive response was induced using NO-containing dinitrosyl iron complex with glutathione (DNIC_glu). Quasi-adaptation increased expression of the Ada regulon and cell resistance to the cytotoxic and mutagenic effects of NMU. The levels of alkA, alkB, and aidB gene expression in quasi-adaptation were higher than in the true Ada response. Thus, experimental evidence was obtained for the alternative mechanism regulating the function of the Ada sensory protein in controlling expression of the Ada regulon during the adaptive response. The free iron—chelating agent o-phenanthroline (OP) facilitated degradation of DNIC_glu (by electron paramagnetic resonance (EPR) spectra) and considerably or completely inhibited gene expression in the quasi-adaptive response. The new phenomenon extends the functional range of NO compounds to include a role in genetic signal transduction within the Ada response system in addition to similar roles in the SoxRS, SOS, and OxyR systems in E. coli.__________Translated from Genetika, Vol. 41, No. 5, 2005, pp. 607–613.Original Russian Text Copyright © 2005 by Vasilieva, Moschkovskaya.     

The Mechanism of Reca Pola Lethality: Suppression by Reca-Independent Recombination Repair Activated by the Lexa(def) Mutation in Escherichia Coli

The mechanism of recA polA lethality in Escherichia coli has been studied. Complementation tests have indicated that both the 5' -> 3' exonuclease and the polymerization activities of DNA polymerase I are essential for viability in the absence of RecA protein, whereas the viability and DNA replication of DNA polymerase I-defective cells depend on the recombinase activity of RecA. An alkaline sucrose gradient sedimentation analysis has indicated that RecA has only a minor role in Okazaki fragment processing. Double-strand break repair is proposed for the major role of RecA in the absence of DNA polymerase I. The lexA(Def)::Tn5 mutation has previously been shown to suppress the temperature-sensitive growth of recA200(Ts) polA25::spc mutants. The lexA(Def) mutation can alleviate impaired DNA synthesis in the recA200(Ts) polA25::spc mutant cells at the restrictive temperature. recF(+) is essential for this suppression pathway. recJ and recQ mutations have minor but significant adverse effects on the suppression. The recA200(Ts) allele in the recA200(Ts) polA25::spc lexA(Def) mutant can be replaced by δrecA, indicating that the lexA(Def)-induced suppression is RecA independent. lexA(Def) reduces the sensitivity of δrecA polA25::spc cells to UV damage by ~10(4)-fold. lexA(Def) also restores P1 transduction proficiency to the δrecA polA25::spc mutant to a level that is 7.3% of the recA(+) wild type. These results suggest that lexA(Def) activates a RecA-independent, RecF-dependent recombination repair pathway that suppresses the defect in DNA replication in recA polA double mutants.     

Mutation Induction by Difunctional Alkylating Agents in NEUROSPORA CRASSA

The genetic characterization of ad-3 mutants of Neurospora crassa induced by two carcinogenic difunctional akylating agents, 1,2,4,5-diepoxypentane (DEP) and 1,2,7,8-diepoxyoctane (DEO), has shown that point mutations at the ad-3B locus have similar complementation patterns. In addition to the induction of point mutations, DEP induces a low frequency (7.5%) of multilocus deletions, whereas DEO induces an extremely high frequency (42.0%). The distribution of the different classes of ad-3 mutants and the frequency of multilocus deletion mutants among DEP-induced mutants are not significantly different from those induced by the monofunctional alkylating agents EI, EMS and ICR-177 at comparable forward-mutation frequencies. Moreover, the frequencies of DEP-induced ad-3B mutants showing allelic completion or having nonpolarized complementation patterns are similar to those of ad-3B mutants induced by monofunctional agents. It is suggested, therefore, that the mechanism of mutation-induction by DEP in N. crassa is similar to that of monofunctional alkylating agents. Mutation-induction by DEO probably results both from the mechanism of action of monofunctional alkylating agents and from inter-strand cross-linkage of the DNA molecular by the two functional epoxy groups.     

Serine Protease EspP from Enterohemorrhagic Escherichia Coli Is Sufficient to Induce Shiga Toxin Macropinocytosis in Intestinal Epithelium

Life-threatening intestinal and systemic effects of the Shiga toxins produced by enterohemorrhagic Escherichia coli (EHEC) require toxin uptake and transcytosis across intestinal epithelial cells. We have recently demonstrated that EHEC infection of intestinal epithelial cells stimulates toxin macropinocytosis, an actin-dependent endocytic pathway. Host actin rearrangement necessary for EHEC attachment to enterocytes is mediated by the type 3 secretion system which functions as a molecular syringe to translocate bacterial effector proteins directly into host cells. Actin-dependent EHEC attachment also requires the outer membrane protein intimin, a major EHEC adhesin. Here, we investigate the role of type 3 secretion in actin turnover occurring during toxin macropinocytosis. Toxin macropinocytosis is independent of EHEC type 3 secretion and intimin attachment. EHEC soluble factors are sufficient to stimulate macropinocytosis and deliver toxin into enterocytes in vitro and in vivo; intact bacteria are not required. Intimin-negative enteroaggregative Escherichia coli (EAEC) O104:H4 robustly stimulate Shiga toxin macropinocytosis into intestinal epithelial cells. The apical macropinosomes formed in intestinal epithelial cells move through the cells and release their cargo at these cells’ basolateral sides. Further analysis of EHEC secreted proteins shows that a serine protease EspP alone is able to stimulate host actin remodeling and toxin macropinocytosis. The observation that soluble factors, possibly serine proteases including EspP, from each of two genetically distinct toxin-producing strains, can stimulate Shiga toxin macropinocytosis and transcellular transcytosis alters current ideas concerning mechanisms whereby Shiga toxin interacts with human enterocytes. Mechanisms important for this macropinocytic pathway could suggest new potential therapeutic targets for Shiga toxin-induced disease.     

The Saccharomyces Cerevisiae Rad30 Gene, a Homologue of Escherichia Coli Dinb and Umuc, Is DNA Damage Inducible and Functions in a Novel Error-Free Postreplication Repair Mechanism

Damage-inducible mutagenesis in prokaryotes is largely dependent upon the activity of the UmuD'C-like proteins. Since many DNA repair processes are structurally and/or functionally conserved between prokaryotes and eukaryotes, we investigated the role of RAD30, a previously uncharacterized Saccharomyces cerevisiae DNA repair gene related to the Escherichia coli dinB, umuC and S. cerevisiae REV1 genes, in UV resistance and UV-induced mutagenesis. Similar to its prokaryotic homologues, RAD30 was found to be damage inducible. Like many S. cerevisiae genes involved in error-prone DNA repair, epistasis analysis clearly places RAD30 in the RAD6 group and rad30 mutants display moderate UV sensitivity reminiscent of rev mutants. However, unlike rev mutants, no defect in UV-induced reversion was seen in rad30 strains. While rad6 and rad18 are both epistatic to rad30, no epistasis was observed with rev1, rev3, rev7 or rad5, all of which are members of the RAD6 epistasis group. These findings suggest that RAD30 participates in a novel error-free repair pathway dependent on RAD6 and RAD18, but independent of REV1, REV3, REV7 and RAD5.     

Transduction, Restriction and Recombination Patterns in Escherichia Coli

Chromosomal DNA from several Escherichia coli reference (ECOR) strains was transduced by bacteriophage P1 into E. coli strain K12 W3110 trpA33. Recombination patterns of the transductants were determined by restriction fragment length polymorphism over a 40-kb region centering on a single marker (trpA(+)) in the tryptophan operon. These experiments demonstrate that transduction between different strains of E. coli can result in recombinational replacements that are small in comparison to the entrant molecule (replacements average 8-14 kb, whereas P1 packages ~ 100 kb) often in a series of discrete segments. The transduction patterns generated resemble the natureal mosaic sequence patterns of the ECOR strains described in previous work. Extensive polymorphisms in the restriction-modification systems of the ECOR strains are a possible explanation for the sequence patterns in nature. To test this possibility, two transductants were back-transduced into strain K12 W3110 trpA33. The resulting patterns were strikingly different from the original transductions. The size of the replacements was greater, and no multiple replacements were observed, suggesting a role for restriction-modification systems in the transduction patterns and perhaps for the mosaic sequence patterns in nature.     

Mutagenesis by Cytostatic Alkylating Agents in Yeast Strains of Differing Repair Capacities

Reversion of two nulcear ochre nonsense alleles and cell inactivation induced by mono-, bi-, and tri-functional alkylating agents and by UV has been investigated in stationary-phase haploid cells of yeast strains with differing capacities for DNA repair. The ability to survive alkylation damage is correlated with UV repair capacity, a UV-resistant and UV-mutable strain (RAD REV) being least and a UV-sensitive and UV-nonmutable strain (radi rev3) most sensitive. Mutagenicity of alkylating agents is highest in the former and is abolished in the latter strain. Deficiency in excision repair (rad1 rad2) or in the RAD18 function does not lead to enhanced mutability. Mutagenesis by the various agents is characterized by a common pattern of induction of locus-specific revertants and suppressor mutants. Induction kinetics are mostly linear, but UV-induced reversion in the RAD REV strain follows higher-than-linear (probably "quadratic") kinetics. The alkylating agent cyclophosphamide, usually considered inactive without metabolic conversion, reduces colony-forming ability and induces revertants in a manner similar but not identical to the other chemicals tested. These findings are taken to support the concept of mutagenesis by misrepair after alkylation, which albeit sharing common features with the mechanism of UV-induced reversion, can be distinguished therefrom.