Movement and resolution of Holliday junctions by enzymes from E. coli

Implication of RuvABC and RecG in homologous recombination in Streptomyces ambofaciens

Most bacterial organisms rely on homologous recombination to repair DNA double-strand breaks and for the post-replicative repair of DNA single-strand gaps. Homologous recombination can be divided into three steps: (i) a pre-synaptic step in which the DNA 3'-OH ends are processed, (ii) a recA-dependent synaptic step allowing the invasion of an intact copy and the formation of Holliday junctions, and (iii) a post-synaptic step consisting of migration and resolution of these junctions. Currently, little is known about factors involved in homologous recombination, especially for the post-synaptic step. In Escherichia coli, branch migration and resolution are performed by the RuvABC complex, but could also rely on the RecG helicase in a redundant manner. In this study, we show that recG and ruvABC are well-conserved among Streptomyces. ΔruvABC, ΔrecG and ΔruvABC ΔrecG mutant strains were constructed. ΔruvABC ΔrecG is only slightly affected by exposure to DNA damage (UV). We also show that conjugational recombination decreases in the absence of RuvABC and RecG, but that intra-chromosomal recombination is not affected. These data suggest that RuvABC and RecG are indeed involved in homologous recombination in Streptomyces ambofaciens and that alternative factors are able to take over Holliday junction in Streptomyces.

Change is good: variations in common biological mechanisms in the epsilonproteobacterial genera Campylobacter and Helicobacter

Microbial evolution and subsequent species diversification enable bacterial organisms to perform common biological processes by a variety of means. The epsilonproteobacteria are a diverse class of prokaryotes that thrive in diverse habitats. Many of these environmental niches are labeled as extreme, whereas other niches include various sites within human, animal, and insect hosts. Some epsilonproteobacteria, such as Campylobacter jejuni and Helicobacter pylori, are common pathogens of humans that inhabit specific regions of the gastrointestinal tract. As such, the biological processes of pathogenic Campylobacter and Helicobacter spp. are often modeled after those of common enteric pathogens such as Salmonella spp. and Escherichia coli. While many exquisite biological mechanisms involving biochemical processes, genetic regulatory pathways, and pathogenesis of disease have been elucidated from studies of Salmonella spp. and E. coli, these paradigms often do not apply to the same processes in the epsilonproteobacteria. Instead, these bacteria often display extensive variation in common biological mechanisms relative to those of other prototypical bacteria. In this review, five biological processes of commonly studied model bacterial species are compared to those of the epsilonproteobacteria C. jejuni and H. pylori. Distinct differences in the processes of flagellar biosynthesis, DNA uptake and recombination, iron homeostasis, interaction with epithelial cells, and protein glycosylation are highlighted. Collectively, these studies support a broader view of the vast repertoire of biological mechanisms employed by bacteria and suggest that future studies of the epsilonproteobacteria will continue to provide novel and interesting information regarding prokaryotic cellular biology.

Expanding AAV packaging capacity with trans-splicing or overlapping vectors: a quantitative comparison

Recombinant adeno-associated (rAAV) viral vectors hold great therapeutic potential for human diseases. However, a relatively small packaging capacity (less than 5 kb) has limited the application of rAAV for certain diseases such as cystic fibrosis and Duchenne muscular dystrophy. Here we compared two mechanistically distinct approaches to overcome packaging restraints with rAAV vectors. The trans-splicing approach reconstitutes gene expression from two independent rAAV vectors, each encoding unique, nonoverlapping halves of a transgene. This process requires intermolecular concatamerization and subsequent splicing between independent vectors. A distinct overlapping vector approach uses homologous recombination between overlapping regions in two independent vectors. Using the beta-galactosidase gene as template, trans-splicing approaches were threefold (in primary fibroblasts) and 12-fold (in muscle tissue) more effective in generating full-length transgene products than the overlapping vector approach. Nevertheless, the efficiency of trans-splicing remained moderate at approximately 4.3% (for muscle) and 7% (for fibroblasts) of that seen with a single vector encoding the full-length transgene. The efficiency of trans-splicing was augmented 1185-fold by adenoviral E4, but not E2a, gene products. This augmentation was much less pronounced with the overlapping vectoring approach (12-fold). Trans-splicing and overlapping vector approaches are two viable alternatives to expand rAAV packaging capacity.

Regulation of homologous recombination: Chi inactivates RecBCD enzyme by disassembly of the three subunits

We report here an unusual mechanism for enzyme regulation: the disassembly of all three subunits of RecBCD enzyme after its interaction with a Chi recombination hot spot. The enzyme, which is essential for the major pathway of recombination in Escherichia coli, acts on linear double-stranded DNA bearing a Chi site to produce single-stranded DNA substrates for strand exchange by RecA protein. We show that after reaction with DNA bearing Chi sites, RecBCD enzyme is inactivated and the three subunits migrate as separate species during glycerol gradient ultracentrifugation or native gel electrophoresis. This Chi-mediated inactivation and disassembly of purified RecBCD enzyme can account for the previously reported Chi-dependent loss of Chi activity in E. coli cells containing broken DNA. Our results support a model of recombination in which Chi regulates one RecBCD enzyme molecule to make a single recombinational exchange ('one enzyme-one exchange' hypothesis).

Y'-Help1, a DNA helicase encoded by the yeast subtelomeric Y' element, is induced in survivors defective for telomerase

The yeast Y' element is a highly polymorphic repetitive sequence present in the subtelomeric regions of many yeast telomeres. The Y' element is classed as either Y'-L or Y'-S, depending on its length. It has been reported that survivors arising from telomerase-deficient yeast mutants compensate for telomere loss by the amplification of Y' elements. The total Saccharomyces cerevisiae genome DNA data base was searched for Y' elements, and 11 Y'-Ls and eight Y'-Ss were identified. As reported previously, many of the sequences were found to contain long open reading frames which potentially encode helicase. We examined the expression of the Y' elements in telomerase-deficient Deltatlc1 survivors, in which the TLC1 gene encoding the yeast telomerase template RNA had been disrupted, and found that the Y' element is highly expressed in the survivors, but not in the wild-type cells. Moreover, we demonstrated that the survivors produce a Y'-encoded protein designated as Y'-Help1 (Y'-helicase protein 1), and that this protein possesses helicase activity. Therefore, we suggest that the Y' element has a novel and potentially important role in trans, in addition to the well characterized role in cis, in telomerase-independent telomere maintenance in yeast.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Processing of recombination intermediates by the RuvABC proteins

The RuvA, RuvB, and RuvC proteins in Escherichia coli play important roles in the late stages of homologous genetic recombination and the recombinational repair of damaged DNA. Two proteins, RuvA and RuvB, form a complex that promotes ATP-dependent branch migration of Holliday junctions, a process that is important for the formation of heteroduplex DNA. Individual roles for each protein have been defined, with RuvA acting as a specificity factor that targets RuvB, the branch migration motor to the junction. Structural studies indicate that two RuvA tetramers sandwich the junction and hold it in an unfolded square-planar configuration. Hexameric rings of RuvB face each other across the junction and promote a novel dual helicase action that "pumps" DNA through the RuvAB complex, using the free energy provided by ATP hydrolysis. The third protein, RuvC endonuclease, resolves the Holliday junction by introducing nicks into two DNA strands. Genetic and biochemical studies indicate that branch migration and resolution are coupled by direct interactions between the three proteins, possibly by the formation of a RuvABC complex.

Strand specificity of nicking of DNA at Chi sites by RecBCD enzyme. Modulation by ATP and magnesium levels

RecBCD enzyme is essential for the major pathway of homologous recombination of linear DNA in Escherichia coli. It is a potent nuclease and helicase and, during its unwinding of double-stranded DNA, makes single-strand scissions in the vicinity of Chi recombination hot spots. We report here that both the strand that is cut and the position of the cuts relative to Chi depended on the ATP to Mg2+ ratio. With ATP in excess, Chi-dependent nicks occurred, as we have previously reported, four to six nucleotides to the 3'-side of the Chi octamer (5'-GCTGGTGG-3') and were detected only on the strand bearing that sequence. Three differences were seen with Mg2+ in excess. 1) Chi-dependent 3'-ends were produced on the GCTGGTGG-containing strand closer to and within the Chi octamer. 2) Chi-dependent cuts occurred on the complementary DNA strand. 3) RecBCD enzyme destroyed the 3'-terminated strand of DNA from its entry point up to the vicinity of the Chi site, as others have previously reported. We show here that, with Mg2+ in excess, the enzyme continued to travel along DNA, after encountering a Chi site, releasing both strands of the DNA distal to Chi as single strands. We discuss potential biological consequences of these two modes of RecBCD enzyme-Chi interaction.

Molecular mechanisms of Holliday junction processing in Escherichia coli

Recent genetic and biochemical studies revealed the mechanisms of late stage of homologous recombination in E. coli. A central intermediate of recombination called "Holliday structure", in which two homologous duplex DNA molecules are linked by a single-stranded crossover, is formed by the functions of RecA and several other proteins. The products of the ruvA and ruvB genes, which constitute an SOS regulated operon, form a functional complex that promotes migration of Holliday junctions by catalyzing strand exchange reaction, thus enlarging the heteroduplex region. RuvA is a DNA-binding protein specific for these junctions, and RuvB is a motor molecule for branch migration providing energy by hydrolyzing ATP. The product of the ruvC gene, which is not regulated by the SOS system, resolves Holiday junctions by introducing nicks at or near the crossover junction in strands with the same polarity at the same sites. The recombination reaction is completed by sealing the nicks with DNA ligase, resulting in spliced or patched recombinants. The product of the recG gene provides an alternative route for resolving Holliday junctions. RecG has been proposed to promote branch migration in the opposite direction to that promoted by RecA protein. The atomic structure of RuvC protein revealed by crystallographic study, when combined with mutational analysis of RuvC, provides mechanistic insights into the interactions of RuvC with Holliday junction.

Ruv and recG genes and the induced precise excision of Tn10 in Escherichia coli

Induction of precise excision of Tn10 by UV or mitomycin C (MMC) is dependent on the expression of the SOS system. Ruv mutants of Escherichia coli, which are defective in DNA repair and recombination, showed diminished frequencies of both spontaneous and UV- or MMC-induced excision of Tn10 inserted in gal. RecG mutants, which are also defective in DNA repair and recombination, showed decreased induction of Tn10 excision with MMC, but not after UV treatment. A recG ruv double mutant showed a greater decrease in induction of excision with MMC than either single mutant. One can speculate that the Ruv proteins, which are known to be involved in the resolution of Holliday junctions, might also be involved in the resolution of putative intermediates generated during the precise excision of Tn10. RecG protein, whose function partially overlaps those of Ruv proteins, might also have some role in this process.

Holliday junction cleavage by yeast Rad1 protein

In Saccharomyces cerevisiae, of the many genes required for excision repair of ultraviolet-damaged DNA, only RAD1 and RAD10 also function in genetic recombination. Complex formation between the RAD1 and RAD10 gene products activates an endonucleolytic function that nicks single-stranded DNA and negatively supercoiled double-stranded DNA. To characterize the recombination role of the proteins Rad1 and Rad10, we have investigated their interaction with the Holliday junction, a four-stranded structure that results from single-stranded crossover between two duplex DNA molecules and whose resolution is obligatory for the generation of mature recombinants. We show that Rad1 binds specifically to a Holliday junction and, in the presence of magnesium, catalyses the endonucleolytic cleavage of the junction. Junction cleavage by Rad1 proceeds sufficiently without Rad10, thus identifying Rad1 as the catalytic subunit of Rad1/Rad10 endonuclease.

Biochemistry of homologous recombination in Escherichia coli

Homologous recombination is a fundamental biological process. Biochemical understanding of this process is most advanced for Escherichia coli. At least 25 gene products are involved in promoting genetic exchange. At present, this includes the RecA, RecBCD (exonuclease V), RecE (exonuclease VIII), RecF, RecG, RecJ, RecN, RecOR, RecQ, RecT, RuvAB, RuvC, SbcCD, and SSB proteins, as well as DNA polymerase I, DNA gyrase, DNA topoisomerase I, DNA ligase, and DNA helicases. The activities displayed by these enzymes include homologous DNA pairing and strand exchange, helicase, branch migration, Holliday junction binding and cleavage, nuclease, ATPase, topoisomerase, DNA binding, ATP binding, polymerase, and ligase, and, collectively, they define biochemical events that are essential for efficient recombination. In addition to these needed proteins, a cis-acting recombination hot spot known as Chi (chi: 5'-GCTGGTGG-3') plays a crucial regulatory function. The biochemical steps that comprise homologous recombination can be formally divided into four parts: (i) processing of DNA molecules into suitable recombination substrates, (ii) homologous pairing of the DNA partners and the exchange of DNA strands, (iii) extension of the nascent DNA heteroduplex; and (iv) resolution of the resulting crossover structure. This review focuses on the biochemical mechanisms underlying these steps, with particular emphases on the activities of the proteins involved and on the integration of these activities into likely biochemical pathways for recombination.

A plasmid system to monitor gene conversion and reciprocal recombination in vitro

A plasmid system allowing for the detection of recombinagenic activities in cell-free extracts is described. Two truncated alleles of the bacterial neomycin resistance gene (neo), differing from each other at a polymorphic restriction site, were constructed. Recombinations involving both alleles mediated by Drosophila embryo nuclear protein extracts or Drosophila larva whole cell protein extracts were selected by their ability to confer kanamycin resistance to E. coli. Restriction analysis of plasmids recovered from E. coli transformants allowed the monitoring of the two molecular mechanisms which can lead to functional neo genes, gene conversion and reciprocal recombination. A dose dependent increase in the recombination frequency with increasing amounts of cell extract was observed. Recombination was further increased by linearizing one of the two substrate plasmids. The Drosophila cell extracts catalyzed recombination in vitro since after incubation a recombination product could be identified by polymerase chain reaction (PCR) technology. The recombination was absolutely dependent on the presence of an active cell extract, since no diagnostic PCR product was detected in a reaction where extract was omitted. Analysis of a representative number of recombinant plasmids by restriction analysis revealed that in the absence of an exogenous recombinational system less than 2% of kanamycin resistant recombinant plasmids occurred by gene conversion upon transformation into E. coli. In contrast, recombinants exhibiting restriction patterns diagnostic for gene conversion were observed at frequencies between 5.1% and 9.8% after incubation with Drosophila larva cell extracts. These results strongly argued that gene conversion is a prominent mechanism of recombination in Drosophila mitotic cells.

RuvA, RuvB and RuvC proteins: cleaning-up after recombinational repairs in E. coli

After the completion of RecA protein-mediated recombinational repair of daughter-strand gaps in E. coli, participating chromosomes are held together by Holliday junctions. Until recently, it was not known how the cell disengages the connected chromosomes. Accumulating genetic data suggested that the product of the ruv locus participates in recombinational repair and acts after the formation of Holliday junctions. Molecular characterization of the locus revealed that there are three genes--ruvA, ruvB and ruvC; mutations in any one of the genes confer the same phenotype. Recently, the RuvC protein was found to be a Holliday junction resolvase. At first glance, the resolving activity of RuvC alone would appear to be sufficient for the separation of recombining chromosomes. However, in vitro studies show that the filament of RecA protein is unable to dissociate from the products of the recombination reaction. Thus, in vivo, even if the Holliday junctions are resolved by RuvC, RecA filament must be holding two DNA duplexes together. New findings about enzymatic activities of RuvA and RuvB proteins foster the hope that the machinery for removing the RecA filament from DNA has been found.

Replication of damaged DNA and the molecular mechanism of ultraviolet light mutagenesis

On UV irradiation of Escherichia coli cells, DNA replication is transiently arrested to allow removal of DNA damage by DNA repair mechanisms. This is followed by a resumption of DNA replication, a major recovery function whose mechanism is poorly understood. During the post-UV irradiation period the SOS stress response is induced, giving rise to a multiplicity of phenomena, including UV mutagenesis. The prevailing model is that UV mutagenesis occurs by the filling in of single-stranded DNA gaps present opposite UV lesions in the irradiated chromosome. These gaps can be formed by the activity of DNA replication or repair on the damaged DNA. The gap filling involves polymerization through UV lesions (also termed bypass synthesis or error-prone repair) by DNA polymerase III. The primary source of mutations is the incorporation of incorrect nucleotides opposite lesions. UV mutagenesis is a genetically regulated process, and it requires the SOS-inducible proteins RecA, UmuD, and UmuC. It may represent a minor repair pathway or a genetic program to accelerate evolution of cells under environmental stress conditions.

Escherichia coli RuvA and RuvB proteins specifically interact with Holliday junctions and promote branch migration

The Escherichia coli ruvA and ruvB genes are involved in DNA repair and in the late step of homologous genetic recombination. We have demonstrated previously that the RuvA-RuvB protein complex in the presence of ATP promotes reabsorption of cruciform structures extruded from a supercoiled plasmid with an inverted repeat sequence. Because the cruciform structure is topologically analogous to the Holiday structure, we have proposed that the role of the RuvA and RuvB proteins in recombination is to promote a strand exchange reaction at the Holliday junction. Here, we studied the specific interaction of the RuvA-RuvB complex with the Holliday structure using synthetic analogs prepared by annealing four oligonucleotides. The affinities of the RuvA protein for synthetic Holliday junctions are much higher (> 20-fold) than for duplex DNA, and the affinities of the RuvA protein for the junctions are further enhanced (> 4-fold) by the interaction with the RuvB protein. The RuvA-RuvB protein complex in the presence of ATP promotes dissociation of the synthetic Holliday junction with homology in the central core into two halves by catalyzing branch migration to the DNA ends, but it does not affect the structure of the synthetic Holliday junction without the homology. The separation of the synthetic Holliday junction is a result of the activity of the RuvA-RuvB complex that promotes strand exchange and DNA unwinding. Furthermore, RuvA and RuvB promote the strand exchange reaction at the Holliday junctions made by RecA. These results provide further evidence that the RuvA-RuvB complex recognizes the Holliday junction and promotes branch migration in homologous recombination.