Short-homology-independent illegitimate recombination in Escherichia coli: distinct mechanism from short-homology-dependent illegitimate recombination

Tandem gene duplication selected by activation of horizontally transferred gene in bacteria

Horizontal gene transfer occurs frequently in bacteria, but the mechanism driving activation and optimization of the expression of horizontally transferred genes (HTGs) in new recipient strains is not clear. Our previous study found that spontaneous tandem DNA duplication resulted in rapid activation of HTGs. Here, we took advantage of this finding to develop a novel technique for tandem gene duplication, named tandem gene duplication selected by activation of horizontally transferred gene in bacteria (TDAH), in which tandem duplication was selected by the activation of horizontally transferred selectable marker gene. TDAH construction does not contain any reported functional elements based on homologous or site-specific recombination and DNA amplification. TDAH only contains an essential selectable marker for copy number selection and 9-bp-microhomology border sequences for precise illegitimate recombination. One transformation and 3 days were enough to produce a high-copy strain, so its procedure is simple and fast. Without subsequent knockout of the endogenous recombination system, TDAH could also generate the relatively stable high-copy tandem duplication for plasmid-carried and genome-integrated DNA. TDAH also showed an excellent capacity for increase gene expression and worked well in different industrial bacteria. We also applied TDAH to select the optimal high copy number of ribA for vitamin B2 production in E. coli; the yield was improved by 3.5 times and remained stable even after 12 subcultures. TDAH is a useful tool for recombinant protein production and expression optimization of biosynthetic pathways. KEY POINTS: • We develop a novel and efficient technique (TDAH) for tandem gene duplication in bacterium. TDAH is based on the mechanism of HTG rapid activation. TDAH does not contain any reported functional elements based on homologous recombination and DNA amplification. TDAH only contains an essential selectable marker for copy number selection, so its construction and procedure are very simple and fast. • TDAH is the first reported selected and stable tandem-gene-duplication technique in which the selected high-copy plasmid-carried and genome-integrated DNA could remain stable without the subsequent knockout of recombination system. • TDAH showed an excellent capacity for regulating gene expression and worked well in different industrial bacteria, indicating it is a useful tool for recombinant protein production and expression optimization of biosynthetic pathways. • TDAH was applied to select the optimal high copy number of ribA for vitamin B2 production in E. coli; the yield was improved by 3.5-fold and remained stable even after 12 subcultures.

Mycoplasma Chromosomal Transfer: A Distributive, Conjugative Process Creating an Infinite Variety of Mosaic Genomes

The capacity of Mycoplasmas to engage in horizontal gene transfers has recently been highlighted. Despite their small genome, some of these wall-less bacteria are able to exchange multiple, large portions of their chromosome via a conjugative mechanism that does not conform to canonical Hfr/oriT models. To understand the exact features underlying mycoplasma chromosomal transfer (MCT), extensive genomic analyses were performed at the nucleotide level, using individual mating progenies derived from our model organism, Mycoplasma agalactiae. Genome reconstruction showed that MCT resulted in the distributive transfer of multiple chromosomal DNA fragments and generated progenies composed of a variety of mosaic genomes, each being unique. Analyses of macro- and micro-events resulting from MCT revealed that the vast majority of the acquired fragments were unrelated and co-transferred independently from the selection marker, these resulted in up to 17% of the genome being exchanged. Housekeeping and accessory genes were equally affected by MCT, with up to 35 CDSs being gained or lost. This efficient HGT process also created a number of chimeric genes and genetic micro-variations that may impact gene regulation and/or expression. Our study unraveled the tremendous plasticity of M. agalactiae genome and point toward MCT as a major player in diversification and adaptation to changing environments, offering a significant advantage to this minimal pathogen.

A novel gene amplification causes upregulation of the PatAB ABC transporter and fluoroquinolone resistance in Streptococcus pneumoniae

Overexpression of the ABC transporter genes patA and patB confers efflux-mediated fluoroquinolone resistance in Streptococcus pneumoniae and is also linked to pneumococcal stress responses. Although upregulation of patAB has been observed in many laboratory mutants and clinical isolates, the regulatory mechanisms controlling expression of these genes are unknown. In this study, we aimed to identify the cause of high-level constitutive overexpression of patAB in M184, a multidrug-resistant mutant of S. pneumoniae R6. Using a whole-genome transformation and sequencing approach, we identified a novel duplication of a 9.2-kb region of the M184 genome which included the patAB genes. This duplication did not affect growth and was semistable with a low segregation rate. The expression levels of patAB in M184 were much higher than those that could be fully explained by doubling of the gene dosage alone, and inactivation of the first copy of patA had no effect on multidrug resistance. Using a green fluorescent protein reporter system, increased patAB expression was ascribed to transcriptional read-through from a tRNA gene upstream of the second copy of patAB. This is the first report of a large genomic duplication causing antibiotic resistance in S. pneumoniae and also of a genomic duplication causing antibiotic resistance by a promoter switching mechanism.

Small variable segments constitute a major type of diversity of bacterial genomes at the species level

BACKGROUND

Analysis of large scale diversity in bacterial genomes has mainly focused on elements such as pathogenicity islands, or more generally, genomic islands. These comprise numerous genes and confer important phenotypes, which are present or absent depending on strains. We report that despite this widely accepted notion, most diversity at the species level is composed of much smaller DNA segments, 20 to 500 bp in size, which we call microdiversity.

RESULTS

We performed a systematic analysis of the variable segments detected by multiple whole genome alignments at the DNA level on three species for which the greatest number of genomes have been sequenced: Escherichia coli, Staphylococcus aureus, and Streptococcus pyogenes. Among the numerous sites of variability, 62 to 73% were loci of microdiversity, many of which were located within genes. They contribute to phenotypic variations, as 3 to 6% of all genes harbor microdiversity, and 1 to 9% of total genes are located downstream from a microdiversity locus. Microdiversity loci are particularly abundant in genes encoding membrane proteins. In-depth analysis of the E. coli alignments shows that most of the diversity does not correspond to known mobile or repeated elements, and it is likely that they were generated by illegitimate recombination. An intriguing class of microdiversity includes small blocks of highly diverged sequences, whose origin is discussed.

CONCLUSIONS

This analysis uncovers the importance of this small-sized genome diversity, which we expect to be present in a wide range of bacteria, and possibly also in many eukaryotic genomes.

Mechanisms of change in gene copy number

Deletions and duplications of chromosomal segments (copy number variants, CNVs) are a major source of variation between individual humans and are an underlying factor in human evolution and in many diseases, including mental illness, developmental disorders and cancer. CNVs form at a faster rate than other types of mutation, and seem to do so by similar mechanisms in bacteria, yeast and humans. Here we review current models of the mechanisms that cause copy number variation. Non-homologous end-joining mechanisms are well known, but recent models focus on perturbation of DNA replication and replication of non-contiguous DNA segments. For example, cellular stress might induce repair of broken replication forks to switch from high-fidelity homologous recombination to non-homologous repair, thus promoting copy number change.

Translesion DNA polymerases are required for spontaneous deletion formation in Salmonella typhimurium

How spontaneous deletions form in bacteria is still a partly unresolved problem. Here, we show that deletion formation in Salmonella typhimurium requires the presence of functional translesion polymerases. First, in wild-type bacteria, removal of the known translesion DNA polymerases, PolII (polB), PolIV (dinB), PolV (umuDC), and SamAB (samAB), resulted in a 10-fold decrease in the deletion rate, indicating that 90% of all spontaneous deletions require these polymerases for their formation. Second, overexpression of these polymerases by derepression of the DNA damage-inducible LexA regulon caused a 25-fold increase in deletion rate that depended on the presence of functional translesion polymerases. Third, overexpression of the polymerases PolII and PolIV from a plasmid increased the deletion rate 12- to 30-fold, respectively. Last, in a recBC(-) mutant where dsDNA ends are stabilized due to the lack of the end-processing nuclease RecBC, the deletion rate was increased 20-fold. This increase depended on the translesion polymerases. In lexA(def) mutant cells with constitutive SOS expression, a 10-fold increase in DNA breaks was observed. Inactivation of all 4 translesion polymerases in the lexA(def) mutant reduced the deletion rate 250-fold without any concomitant reduction in the amount of DNA breaks. Mutational inactivation of 3 endonucleases under LexA control reduced the number of DNA breaks to the wild-type level in a lexA(def) mutant with a concomitant 50-fold reduction in deletion rate. These findings suggest that the translesion polymerases are not involved in forming the DNA breaks, but that they require them to stimulate deletion formation.

A microhomology-mediated break-induced replication model for the origin of human copy number variation

Chromosome structural changes with nonrecurrent endpoints associated with genomic disorders offer windows into the mechanism of origin of copy number variation (CNV). A recent report of nonrecurrent duplications associated with Pelizaeus-Merzbacher disease identified three distinctive characteristics. First, the majority of events can be seen to be complex, showing discontinuous duplications mixed with deletions, inverted duplications, and triplications. Second, junctions at endpoints show microhomology of 2–5 base pairs (bp). Third, endpoints occur near pre-existing low copy repeats (LCRs). Using these observations and evidence from DNA repair in other organisms, we derive a model of microhomology-mediated break-induced replication (MMBIR) for the origin of CNV and, ultimately, of LCRs. We propose that breakage of replication forks in stressed cells that are deficient in homologous recombination induces an aberrant repair process with features of break-induced replication (BIR). Under these circumstances, single-strand 3′ tails from broken replication forks will anneal with microhomology on any single-stranded DNA nearby, priming low-processivity polymerization with multiple template switches generating complex rearrangements, and eventual re-establishment of processive replication.

Mutagenicity of tamoxifen DNA adducts in human endometrial cells and in silico prediction of p53 mutation hotspots

Tamoxifen elevates the risk of endometrial tumours in women and alpha-(N(2)-deoxyguanosinyl)-tamoxifen adducts are reportedly present in endometrial tissue of patients undergoing therapy. Given the widespread use of tamoxifen there is considerable interest in elucidating the mechanisms underlying treatment-associated cancer. Using a combined experimental and multivariate statistical approach we have examined the mutagenicity and potential consequences of adduct formation by reactive intermediates in target uterine cells. pSP189 plasmid containing the supF gene was incubated with alpha-acetoxytamoxifen or 4-hydroxytamoxifen quinone methide (4-OHtamQM) to generate dG-N(2)-tamoxifen and dG-N(2)-4-hydroxytamoxifen, respectively. Plasmids were replicated in Ishikawa cells then screened in Escherichia coli. Treatment with both alpha-acetoxytamoxifen and 4-OHtamQM caused a dose-related increase in adduct levels, resulting in a damage-dependent increase in mutation frequency for alpha-acetoxytamoxifen; 4-OHtamQM had no apparent effect. Only alpha-acetoxytamoxifen generated statistically different supF mutation spectra relative to the spontaneous pattern, with most mutations being GC-->TA transversions. Application of the LwPy53 algorithm to the alpha-acetoxytamoxifen spectrum predicted strong GC-->TA hotspots at codons 244 and 273. These signature alterations do not correlate with current reports of the mutations observed in endometrial carcinomas from treated women, suggesting that dG-N(2)-tam adduct formation in the p53 gene is not a prerequisite for endometrial cancer initiation in women.

Double illegitimate recombination events integrate DNA segments through two different mechanisms during natural transformation of Acinetobacter baylyi

Acquisition of foreign DNA by horizontal gene transfer is seen as a major source of genetic diversity in prokaryotes. However, strongly divergent DNA is not genomically integrated by homologous recombination and would depend on illegitimate recombination (IR) events which are rare. We show that, by two mechanisms, during natural transformation of Acinetobacter baylyi two IR events can integrate DNA segments. One mechanism is double illegitimate recombination (DIR) acting in the absence of any homology (frequency: 7 x 10(-13) per cell). It occurs about 10(10)-fold less frequent than homologous transformation. The other mechanism is homology-facilitated double illegitimate recombination (HFDIR) being about 440-fold more frequent (3 x 10(-10) per cell) than DIR. HFDIR depends on a homologous sequence located between the IR sites and on recA(+). In HFDIR two IR events act on the same donor DNA molecule as shown by the joint inheritance of molecular DNA tags. While the IR events in HFDIR occurred at microhomologies, in DIR microhomologies were not used. The HFDIR phenomenon indicates that a temporal recA-dependent association of donor DNA at a homology in recipient DNA may facilitate two IR events on the 5' and 3' heterologous parts of the transforming DNA molecule.

The role of UvrD in RecET-mediated illegitimate recombination in Escherichia coli

To study the mechanism of RecET-mediated illegitimate recombination, we examined the formation of lambdabio-transducing phage in Escherichia coli in the presence or absence of UV irradiation. We have previously reported that coexpression of RecE and RecT enhances the frequency of recA-independent illegitimate recombination. RecJOR proteins are required for this RecET-mediated illegitimate recombination, and RecQ suppresses it. Here, we showed that the frequencies of both spontaneous and UV-induced RecET-mediated illegitimate recombination events are reduced by a uvrD mutation. It should be noted that UvrD is required for illegitimate recombination only in the presence, but not in the absence, of RecET. In contrast, frequencies of RecET-mediated illegitimate recombination were not affected by ruvAB, ruvC, recG, and recN mutations. The frequency of spontaneous and UV-induced illegitimate recombination in the uvrD recR double mutant was comparable to that of the uvrD single mutant, suggesting that UvrD works at the same step as RecR in the RecET-mediated recombination pathway. Nucleotide sequence analyses of the recombination junctions showed that RecET-mediated illegitimate recombination detected in UvrD-deficient strain is short-homology-dependent. Based on these and previous results, we propose a model for the role of UvrD on RecET-mediated illegitimate recombination.

An exonuclease I-sensitive DNA repair pathway in Deinococcus radiodurans: a major determinant of radiation resistance

Deinococcus radiodurans R1 recovering from acute dose of gamma radiation shows a biphasic mechanism of DNA double-strand break repair. The possible involvement of microsequence homology-dependent, or non-homologous end joining type mechanisms during initial period followed by RecA-dependent homologous recombination pathways has been suggested for the reconstruction of complete genomes in this microbe. We have exploited the known roles of exonuclease I in DNA recombination to elucidate the nature of recombination involved in DNA double-strand break repair during post-irradiation recovery of D. radiodurans. Transgenic Deinococcus cells expressing exonuclease I functions of Escherichia coli showed significant reduction in gamma radiation radioresistance, while the resistance to far-UV and hydrogen peroxide remained unaffected. The overexpression of E. coli exonuclease I in Deinococcus inhibited DNA double-strand break repair. Such cells exhibited normal post-irradiation expression kinetics of RecA, PprA and single-stranded DNA-binding proteins but lacked the divalent cation manganese [(Mn(II)]-dependent protection from gamma radiation. The results strongly suggest that 3' (rho) 5' single-stranded DNA ends constitute an important component in recombination pathway involved in DNA double-strand break repair and that absence of sbcB from deinococcal genome may significantly aid its extreme radioresistance phenotype.

Rep helicase suppresses short-homology-dependent illegitimate recombination in Escherichia coli

To study roles of Rep helicase in short-homology-dependent illegitimate recombination, we examined the effect of a rep mutation on illegitimate recombination and found that the frequency of spontaneous illegitimate recombination is enhanced by the rep mutation. In addition, illegitimate recombination was synergistically enhanced by the rep mutation and UV irradiation, showing that Rep helicase plays a role in suppression of spontaneous as well as UV-induced illegitimate recombination. The defect in RecQ helicase also has a synergistic effect on the increased illegitimate recombination in the rep mutant. It was also found that the illegitimate recombination induced by the rep mutation is independent of the RecA function with or without UV irradiation. Nucleotide sequence analyses of the recombination junctions showed that the illegitimate recombination induced by the rep mutation mostly takes place between short homologous sequences. Based on the fact that the defect of Rep helicase induces replication arrest during replication, resulting in the formation of DNA double-strand breaks, we propose a model for illegitimate recombination, in which double-strand breaks caused by defect of Rep helicase promotes illegitimate recombination via short-homology-dependent-end-joining. In addition, the mechanism of synergistic action between the rep mutation and UV irradiation on illegitimate recombination is discussed.

Different foreign genes incidentally integrated into the same locus of the Streptococcus suis genome

Some strains of Streptococcus suis possess a type II restriction-modification (RM) system, whose genes are thought to be inserted into the genome between purH and purD from a foreign source by illegitimate recombination. In this study, we characterized the purHD locus of the S. suis genomes of 28 serotype reference strains by DNA sequencing. Four strains contained the RM genes in the locus, as described before, whereas 11 strains possessed other genetic regions of seven classes. The genetic regions contained a single gene or multiple genes that were either unknown or similar to hypothetical genes of other bacteria. The mutually exclusive localization of the genetic regions with the atypical G+C contents indicated that these regions were also acquired from foreign sources. No transposable element or long-repeat sequence was found in the neighboring regions. An alignment of the nucleotide sequences, including the RM gene regions, suggested that the foreign regions were integrated by illegitimate recombination via short stretches of nucleotide identity. By using a thermosensitive suicide plasmid, the RM genes were experimentally introduced into an S. suis strain that did not contain any foreign genes in that locus. Integration of the plasmid into the S. suis genome did not occur in the purHD locus but occurred at various chromosomal loci, where there were 2 to 10 bp of nucleotide identity between the chromosome and the plasmid. These results suggest that various foreign genes described here were incidentally integrated into the same locus of the S. suis genome.

Gene amplification involves site-specific short homology-independent illegitimate recombination in Acinetobacter sp. strain ADP1

A system for studying gene amplification in the bacterium Acinetobacter sp. strain ADP1 was used to isolate 105 spontaneous mutants. The method selects for the elevated expression of neighboring transcriptional units in a parent strain lacking its normal transcriptional activators. Gene amplification can compensate for the activator loss by increasing the copy number of seven weakly expressed genes. Mutant colonies arose from the parent strain at a frequency of 10(-8) within three weeks. All but one of these mutants carried tandem head-to-tail repeats of a chromosomal segment (amplicon). These amplicons varied in size from approximately 12-290 kb and ranged in copy number from 3 to more than 30. Gene amplification involved a two-step process in which duplications formed independently of recA. Illegitimate recombination fused normally distant chromosomal regions to create novel DNA duplication junctions. These junctions were isolated from amplification mutants using an assay that exploits Acinetobacter natural transformability. Sequence analysis of 72 junctions revealed little identity in the recombining regions. Furthermore, multiple independently isolated mutants contained identical junctions. Six different junctions, each found in two to six mutants, revealed that some recombination events are site-specific. Several recurring junctions were studied using PCR. In each case, the identical duplication present in the mutant was estimated to have occurred in as many as one in a million cells in populations of strains never exposed to selective conditions. These duplications appeared to form spontaneously by a novel type of short homology-independent, site-specific process. However, in the absence of recA, mutant colonies were not selected from parent cells containing these duplications. Thus, the second gene amplification step most likely depends on homologous recombination to increase amplicon copy number. These studies support the theory that gene amplification is a driving force in the evolution of functionally related gene clusters.

Characterization and mutational analysis of the RecQ core of the bloom syndrome protein

Bloom syndrome protein forms an oligomeric ring structure and belongs to a group of DNA helicases showing extensive homology to the Escherichia coli DNA helicase RecQ, a suppressor of illegitimate recombination. After over-production in E.coli, we have purified the RecQ core of BLM consisting of the DEAH, RecQ-Ct and HRDC domains (amino acid residues 642-1290). The BLM(642-1290) fragment could function as a DNA-stimulated ATPase and as a DNA helicase, displaying the same substrate specificity as the full-size protein. Gel-filtration experiments revealed that BLM(642-1290) exists as a monomer both in solution and in its single-stranded DNA-bound form, even in the presence of Mg(2+) and ATPgammaS. Rates of ATP hydrolysis and DNA unwinding by BLM(642-1290) showed a hyperbolic dependence on ATP concentration, excluding a co-operative interaction between ATP-binding sites. Using a lambda Spi(-) assay, we have found that the BLM(642-1290) fragment is able to partially substitute for the RecQ helicase in suppressing illegitimate recombination in E.coli. A deletion of 182 C-terminal amino acid residues of BLM(642-1290), including the HRDC domain, resulted in helicase and single-stranded DNA-binding defects, whereas kinetic parameters for ATP hydrolysis of this mutant were close to the BLM(642-1290) values. This confirms the prediction that the HRDC domain serves as an auxiliary DNA-binding domain. Mutations at several conserved residues within the RecQ-Ct domain of BLM reduced ATPase and helicase activities severely as well as single-stranded DNA-binding of the enzyme. Together, these data define a minimal helicase domain of BLM and demonstrate its ability to act as a suppressor of illegitimate recombination.

Mechanisms of homology-facilitated illegitimate recombination for foreign DNA acquisition in transformable Pseudomonas stutzeri

Intra- and interspecific natural transformation has been observed in many prokaryotic species and is considered a fundamental mechanism for the generation of genetic variation. Recently, it has been described in detail how, in transformable Acinetobacter BD413 and Streptococcus pneumoniae, long stretches of nucleotides lacking homology were integrated into recipient genomes when they were linked on one side to a small piece of DNA with homology to resident DNA serving as a recA-dependent recombination anchor. Now, such homology-facilitated illegitimate recombination (HFIR) has also been detected in transformable Pseudomonas stutzeri. However, analysis of the recombinants revealed qualitative and quantitative differences in their generation compared with that in Acinetobacter BD413. In P. stutzeri, foreign DNA with an anchor sequence was integrated 105- to 106-fold less frequently than fully homologous DNA, but still at least 200-fold more frequently than without the anchor. The anchor sequence could be as small as 311 bp. Remarkably, in 98% of the events, the 3' end was integrated within the homologous anchor, whereas the 5' end underwent illegitimate fusion. Moreover, about one-third of the illegitimate fusion sites shared no or only a single identical basepair in foreign and resident DNA. The other fusions occurred within microhomologies of up to 6 bp with a higher GC content on average than the interacting nucleotide sequences. Foreign DNA of 69-1903 bp was integrated, and resident DNA of 22-2345 bp was lost. In a recA mutant, HFIR was not detectable. The findings suggest that genomic acquisition of foreign DNA by HFIR during transformation occurs widely in prokaryotes, but that details of the required recombination and strand fusion mechanisms may differ between organisms from different genera.

Tandem amplification of a 28-kilobase region from the Yersinia enterocolitica chromosome containing the blaA gene

Most Yersinia enterocolitica strains are resistant to beta-lactam antibiotics due to the production of one or two chromosomally encoded beta-lactamases. Strain Y56 is a Y. enterocolitica O:3 serotype natural isolate that is resistant to moderate amounts of penicillins and that produces a single class A beta-lactamase. To select mutants with increased levels of resistance to beta-lactam antibiotics, strain Y56 was grown on plates containing increasing amounts of ampicillin, and variants resistant to up to 500 micro g of ampicillin per ml were obtained. Chromosomal DNA from hyperresistant isolates was analyzed by Southern hybridization with a blaA-specific probe to detect gene rearrangements. The use of pulsed-field gel electrophoresis revealed that the increase in the resistance level correlated with the amplification in tandem of a DNA fragment of about 28 kb containing the blaA gene. The phenotype of these isolates was not stable, and they recovered the basal low resistance level when the ampicillin used for selection was withdrawn from the growth medium. This loss of resistance was followed by the recovery of the original chromosomal structure. To understand this amplification process, the 28-kb amplification unit was cloned, and the ends were sequenced. The analysis of these sequences did not reveal the presence of either repeats or transposable elements to explain this process. However, we found short sequences similar to some DNA gyrase target sequences that have been described. In addition, we observed that the frequency of appearance of ampicillin-hyperresistant isolates by amplification of the blaA locus was lowered in the presence of the gyrase inhibitor novobiocin. These findings suggest that the DNA gyrase could be involved in this amplification event.

Roles of RecJ, RecO, and RecR in RecET-mediated illegitimate recombination in Escherichia coli

We analyzed effects of overexpression of RecE and RecT on illegitimate recombination during prophage induction in Escherichia coli and found that frequencies of spontaneous and UV-induced illegitimate recombination are enhanced by coexpression of RecE and RecT in the wild type, but the enhanced recombination was reduced by recJ, recO, or recR mutation. The results indicated that RecET-mediated illegitimate recombination depends on the functions of RecJ, RecO, and RecR, suggesting that the RecE and RecJ exonucleases play different roles in this recombination pathway and that the RecO and RecR proteins also play important roles in the recombination. On the other hand, the frequency of the RecET-mediated illegitimate recombination was enhanced by a recQ mutation, implying that the RecQ protein plays a role in suppression of RecET-mediated illegitimate recombination. It was also found that RecET-mediated illegitimate recombination is independent of the RecA function with UV irradiation, but it is enhanced by the recA mutation without UV irradiation. Based on these results, we propose a model for the roles of RecJOR on RecET-mediated illegitimate recombination.

Effect of the DNA topoisomerase II inhibitor VP-16 on illegitimate recombination in yeast chromosomes

Etoposide and teniposide, derivatives of podophyllotoxin, are inhibitors of DNA topoisomerase II and are potent anticancer agents. An adverse effect linked to the use of these drugs is the development of acute myeloid leukemia, a disorder usually associated with chromosomal translocation. To examine podophyllotoxin-induced DNA rearrangement, we developed an assay system to measure illegitimate recombination in Saccharomyces cerevisiae chromosomes. This approach uses juxtaposed CAN1-CYH2 negative selection markers that are introduced into the LEU2 locus, which is located on chromosome III, in a yeast strain carrying the mutated can1 and cyh2 genes. Upon formation of a deletion over the active CAN1-CYH2 genes, a cell becomes resistant to both canavanine and cycloheximide. To introduce drugs into the cell, we used a yeast strain carrying an ISE2 mutation, thereby making the cell drug-permeable. Here we show that treatment of cells with etoposide (VP-16) increases the rate of illegitimate recombination in yeast, indicating that VP-16 stimulates DNA topoisomerase-mediated illegitimate recombination. Structural analysis of the resulting recombinants indicate that most are formed by deletion mutations on chromosome III, which take place between short homologous regions of DNA. We propose a model for illegitimate recombination, in which VP-16 facilitates formation of a cleavable complex between DNA topoisomerase II and DNA, thus promoting DNA double-strand breakage with the resulting DNA ends joined by a non-homologous mechanism.

Integration of foreign DNA during natural transformation of Acinetobacter sp. by homology-facilitated illegitimate recombination

The active uptake of extracellular DNA and its genomic integration is termed natural transformation and constitutes a major horizontal gene-transfer mechanism in prokaryotes. Chromosomal DNA transferred within a species can be integrated effectively by homologous recombination, whereas foreign DNA with low or no sequence homology would rely on illegitimate recombination events, which are rare. By using the nptII(+) gene (kanamycin resistance) as selectable marker, we found that the integration of foreign DNA into the genome of the Gram-negative Acinetobacter sp. BD413 during transformation indeed was at least 10(9)-fold lower than that of homologous DNA. However, integration of foreign DNA increased at least 10(5)-fold when it was linked on one side to a piece of DNA homologous to the recipient genome. Analysis of foreign DNA integration sites revealed short stretches of sequence identity (3-8 bp) between donor and recipient DNA, indicating illegitimate recombination events. These findings suggest that homologous DNA served as a recombinational anchor facilitating illegitimate recombination acting on the same molecule. Homologous stretches down to 183 nucleotides served as anchors. Transformation with heteroduplex DNA having different nucleotide sequence tags in the strands indicated that strands entered the cytoplasm 3' to 5' and that strands with either polarity were integrated by homologous recombination. The process led to the genomic integration of thousands of foreign nucleotides and often was accompanied by deletion of a roughly corresponding length of recipient DNA. Homology-facilitated illegitimate recombination would explain the introgression of DNA in prokaryotic genomes without the help of mobile genetic elements.

Role of DnaB helicase in UV-induced illegitimate recombination in Escherichia coli

To study the involvement of DNA replication in UV-induced illegitimate recombination, we examined the effect of temperature-sensitive dnaB mutations on illegitimate recombination and found that the frequency of illegitimate recombination was reduced by an elongation-deficient mutation, dnaB14, but not by an initiation-deficient mutation, dnaB252. This result indicates that DNA replication is required for UV-induced illegitimate recombination. In addition, the dnaB14 mutation also affected spontaneous or UV-induced illegitimate recombination enhanced by the recQ mutation. Nucleotide sequence analyses of the recombination junctions showed that DnaB-mediated illegitimate recombination is short homology dependent. Previously, Michel et al. (B. Michel, S. Ehrlich, and M. Uzest, EMBO J. 16:430--438, 1997) showed that thermal treatment of the temperature-sensitive dnaB8 mutant induces double-stranded breaks, implying that induction of illegitimate recombination occurs. To explain the discrepancy between the observations, we propose a model for DnaB function, in which the dnaB mutations may exhibit two types of responses, early and late responses, for double-stranded break formation. In the early response, replication forks stall at damaged DNA, resulting in the formation of double-stranded breaks, and the dnaB14 mutation reduces the double-stranded breaks shortly after temperature shift-up. On the other hand, in the late response, the arrested replication forks mediated by the dnaB8 mutation may induce double-stranded breaks after prolonged incubation.

Role of DNA ligase in the illegitimate recombination that generates lambdabio-transducing phages in Escherichia coli

We studied the role of DNA ligase in illegitimate recombination in Escherichia coli. A temperature-sensitive mutation in the lig gene reduced the frequency with which lambdabio-transducing phages were generated to 10-14% of that of wild type under UV irradiation. Reintroduction of the lig gene into this mutant restored the frequency of recombinant phage generation to that of wild type. Furthermore, overexpression of DNA ligase enhanced illegitimate recombination by 10-fold with or without UV irradiation. In addition, when DNA ligase was present in only limited amounts, UV-induced or spontaneous illegitimate recombination occurred exclusively at hotspot sites that have relatively long sequences of homology (9 or 13 bp). However, when DNA ligase was overexpressed, most of the illegitimate recombination took place at non-hotspot sites having only short sequences of homology (<4 bp). Thus, the level of ligase activity affects the frequency of illegitimate recombination, the length of sequence homology at the recombination sites, and the preference for recombination at hotspots, at least after UV irradiation. These observations support our hypothesis that the illegitimate recombination that generates lambdabio-transducing phages is mediated by the DNA break-and-join mechanism.

Cloning and sequencing of defective particles derived from the autonomous parvovirus minute virus of mice for the construction of vectors with minimal cis-acting sequences

The production of wild-type-free stocks of recombinant parvovirus minute virus of mice [MVM(p)] is difficult due to the presence of homologous sequences in vector and helper genomes that cannot easily be eliminated from the overlapping coding sequences. We have therefore cloned and sequenced spontaneously occurring defective particles of MVM(p) with very small genomes to identify the minimal cis-acting sequences required for DNA amplification and virus production. One of them has lost all capsid-coding sequences but is still able to replicate in permissive cells when nonstructural proteins are provided in trans by a helper plasmid. Vectors derived from this particle produce stocks with no detectable wild-type MVM after cotransfection with new, matched, helper plasmids that present no homology downstream from the transgene.

UvrA and UvrB suppress illegitimate recombination: synergistic action with RecQ helicase

Illegitimate recombination is a major cause of genetic instability in prokaryotes as well as in eukaryotes. This recombination usually occurs at a low frequency, but it is greatly enhanced by UV irradiation or other environmental stresses. DNA damages produced by these environmental stresses are thought to induce DNA double-strand breaks, leading to illegitimate recombination. In this paper we show that UV-induced illegitimate recombination is enhanced by mutations of nucleotide excision repair genes, uvrA or uvrB, and partially by uvrC mutation, but not by uvrD mutation. Unexpectedly, the recombination was enhanced by the uvrA uvrB double mutation even without UV irradiation, but the uvrB uvrC double mutation has not shown this effect, suggesting that illegitimate recombination is mostly suppressed by UvrA and UvrB. Moreover, illegitimate recombination was synergistically enhanced by the recQ uvrA double mutation. In addition, overproduction of the UvrA protein suppressed the hyperrecombination phenotype of the recQ or uvrB mutant, but it did not affect the UV-sensitive phenotype of the uvrB mutant. We concluded that the UvrAB complex suppresses illegitimate recombination in a pathway shared with RecQ helicase. In addition, UvrA protein alone can suppress illegitimate recombination in the pathway, in which RecQ helicase and UvrAB complex work. Possible functions of the proteins involved in these pathways are also discussed.

Control of genetic stability in Escherichia coli: the SbcB 3'-5' exonuclease suppresses illegitimate recombination promoted by the RecE 5'-3' exonuclease

BACKGROUND

The Escherichia coli sbcB gene, which codes for a 3'-5' exonuclease, ExoI, is known to suppress illegitimate recombination. In contrast, the recE gene, which codes for a 5'-3' exonuclease, Exo VIII promotes joining between DNA ends having short stretches of homology. Therefore, it seems likely that the 3'-5' and 5'-3' exonucleases regulate genetic instability that is mediated by illegitimate recombination. However, there has been little evidence to substantiate the involvement of exonuclease activity in the promotion and suppression of illegitimate recombination.

RESULTS

Using a plasmid system for the analysis of deletion formation, we first demonstrated that deletion formation is increased by the sbcA mutation, which activates the expression of RecE 5'-3' exonuclease. It is thought that DNA ends having 3'-single stranded overhangs are important for illegitimate recombination. Next, we found that a large supply of SbcB 3'-5' exonuclease suppresses the deletion formation enhanced by the RecE exonuclease. Moreover, the SbcB exonuclease even suppressed deletion formation in cells not expressing RecE exonuclease.

CONCLUSION

We conclude that DNA ends with 3'-overhangs produced by 5'-3' dsDNA exonuclease activity are proficient for illegitimate recombination, while blunt DNA ends produced by 3'-5' ssDNA exonuclease activity are deficient for illegitimate recombination. Therefore, both exonucleases may play important roles in genetic stability by controlling end-joining between DNA molecules.

Visualization of repair of double-strand breaks in the bacteriophage T7 genome without normal DNA replication

An in vitro system based on extracts of Escherichia coli infected with bacteriophage T7 is able to repair double-strand breaks in a T7 genome with efficiencies of 20% or more. To achieve this high repair efficiency it is necessary that the reaction mixtures contain molecules of donor DNA that bracket the double-strand break. Gaps as long as 1,600 nucleotides are repaired almost as efficiently as simple double-strand breaks. DNA synthesis was measured while repair was taking place. It was found that the amount of DNA synthesis associated with repair of a double-strand break was below the level of detection possible with this system. Furthermore, repair efficiencies were the same with or without normal levels of T7 DNA polymerase. However, the repair required the 5'-->3' exonuclease encoded by T7 gene 6. The high efficiency of DNA repair allowed visualization of the repaired product after in vitro repair, thereby assuring that the repair took place in vitro rather than during an in vivo growth step after packaging.

Importance of illegitimate recombination and transposition in IS30-associated excision events

In the present study we report on the excision of IS30 elements and IS30-derived composite transposons. Frequent loss of IS30 was observed during dissolution of dimeric IS30 structures, containing IR-IR junctions, leading to resealed donor molecules. In contrast, unambiguous transpositional excision resulting in resealed remainder products could not be identified in the case of a monomeric element. The bias in the excision of monomeric and dimeric IS30 structures indicates a difference in the molecular mechanism of transposition of IS30 monomers and dimers. Sequence data on the rarely detected plasmids missing full IS or Tn copies rather suggest that all products were derived from illegitimate recombination. The reaction occurred between short homologies and was independent of the transposase activity. Similar IS30 excision events accompanied by multiple plasmid or genome rearrangements were detected in Pseudomonas putida and Rhizobium meliloti, yielding stable replicons that retained the selective marker gene of the transposon. We provide evidence that both transposition and illegitimate recombination can contribute to the stabilization of replicons through the elimination of IS elements, which emphasizes the evolutionary significance of these events.

Illegitimate recombination induced by overproduction of DnaB helicase in Escherichia coli

Illegitimate recombination that usually takes place at a low frequency is greatly enhanced by treatment with DNA-damaging agents. It is thought that DNA double-strand breaks induced by this DNA damage are important for initiation of illegitimate recombination. Here we show that illegitimate recombination is enhanced by overexpression of the DnaB protein in Escherichia coli. The recombination enhanced by DnaB overexpression occurred between short regions of homology. We propose a model for the initiation of illegitimate recombination in which DnaB overexpression may excessively unwind DNA at replication forks and induce double-strand breaks, resulting in illegitimate recombination. The defect in RecQ has a synergistic effect on the increased illegitimate recombination in cells containing the overproduced DnaB protein, implying that DnaB works in the same pathway as RecQ does but that they work at different steps.

Mechanism and application of genetic recombination in herpesviruses

Herpes simplex virus type 1 (HSV-1) is a ubiquitous human pathogen that latently infects sensory ganglia and encodes over 80 genes in a 152 kbp DNA genome. This well characterised virus provides a model for analysing genetic recombination in herpesviruses, a fundamental biological process by which new combinations of genetic materials are generated. The frequency of homologous recombination was estimated to be 0.0048-0.007 (0.48%-0.7%)/kb of the HSV-1 genome, determined using physical markers. The double-strand break repair model, the current model of homologous recombination, adequately explains L-S inversion of herpesvirus genomes and the recombinogenicity of the a sequence. Several herpesvirus genomes, including HSV-1 consist of a unique sequence bracketed by a pair of inverted repeat sequences. This arrangement is attributed to illegitimate recombination between molecules arranged in an inverse orientation. Junctions of unique and repeated sequences that correspond to the crossover site of illegitimate recombination are recombinogenic. Recombination is important for virus evolution, construction of mutated virus, gene therapy and vaccination in which the potential for recombination between engineered input virus and wild type virus has to be considered.

Escherichia coli mutM suppresses illegitimate recombination induced by oxidative stress

DNA damage by oxidative stress is one of the causes of mutagenesis. However, whether or not DNA damage induces illegitimate recombination has not been determined. To study the effect of oxidative stress on illegitimate recombination, we examined the frequency of lambdabio transducing phage in the presence of hydrogen peroxide and found that this reagent enhances illegitimate recombination. To clarify the types of illegitimate recombination, we examined the effect of mutations in mutM and related genes on the process. The frequency of lambdabio transducing phage was 5- to 12-fold higher in the mutM mutant than in the wild type, while the frequency in the mutY and mutT mutants was comparable to that of the wild type. Because 7,8-dihydro-8-oxoguanine (8-oxoG) and formamido pyrimidine (Fapy) lesions can be removed from DNA by MutM protein, these lesions are thought to induce illegitimate recombination. Analysis of recombination junctions showed that the recombination at Hotspot I accounts for 22 or 4% of total lambdabio transducing phages in the wild type or in the mutM mutant, respectively. The preferential increase of recombination at nonhotspot sites with hydrogen peroxide in the mutM mutant was discussed on the basis of a new model, in which 8-oxoG and/or Fapy residues may introduce double-strand breaks into DNA.

Escherichia coli HU protein suppresses DNA-gyrase-mediated illegitimate recombination and SOS induction

BACKGROUND

The HU protein is an abundant DNA binding protein of bacteria and is a major constituent of the bacterial nucleoid. HU protein is known to be involved in several fundamental biological functions, including DNA supercoiling, DNA replication, site-specific DNA inversion, and transposition. It is generally thought that a functional relationship exists between HU protein and DNA gyrase.

RESULTS

We found that an hupA hupB double mutant displays enhanced spontaneous illegitimate recombination during the formation of lambdabio transducing phage in Escherichia coli. Nucleotide sequence analysis of the resulting transducing phages showed that the E. coli bio and lambda recombination sites did not have any homologous sequence. This mutation also enhanced the spontaneous expression of SOS functions. Furthermore, either overproduced GyrA protein or a temperature-sensitive gyrB mutation suppressed the illegitimate recombination enhanced by the defect of HU protein.

CONCLUSION

These results show that the defect of HU induces illegitimate recombination and SOS response, which are probably mediated by DNA gyrase, implying that HU protein plays roles in suppression of illegitimate recombination and SOS response through interaction with DNA gyrase.

Isolation of a Schizosaccharomyces pombe rad21ts mutant that is aberrant in chromosome segregation, microtubule function, DNA repair and sensitive to hydroxyurea: possible involvement of Rad21 in ubiquitin-mediated proteolysis

The fission yeast DNA repair gene rad21+ is essential for cell growth. To investigate the function essential for cell proliferation, we have isolated a temperature-sensitive mutant of the rad21+ gene. The mutant, rad21-K1, showed abnormal mitosis at the nonpermissive temperature. Some cells contained abnormal nuclear structures, such as condensed chromosomes with short spindles, or chromosomes stretched or unequally separated by elongating spindles. Other cells exhibited the displaced nucleus or a cut-like phenotype. Similar abnormalities were observed when the Rad21 protein was depleted from cells. We therefore concluded that Rad21 is essential for proper segregation of chromosomes. Moreover, the rad21-K1 mutant is sensitive not only to UV and gamma-ray irradiation but to thiabendazole and hydroxyurea, indicating that Rad21 plays important roles in microtubule function, DNA repair, and S phase function. The relation to the microtubule function was further confirmed by the fact that rad21+ genetically interacts with tubulin genes, nda2+ and nda3+. Finally, the growth of the rad21-K1 mutant was inhibited at the permissive temperature by introduction of another mutation in the cut9+ gene, coding for a component of the 20S cyclosome/anaphase promoting complex, which is involved in ubiquitin-mediated proteolysis. The results suggest that these diverse functions of Rad21 may be facilitated through ubiquitin-mediated proteolysis.

Fis is required for illegitimate recombination during formation of lambda bio transducing phage

Specialized transducing particles of phage lambda are formed by illegitimate recombination during prophage induction. We examined the effects of an Esherichia coli int, xis, himA, himD, or fis mutation on illegitimate recombination during formation of lambda Spi- phage, a class of lambda bio transducing phage. This type of phage is distinguishable from the docL and docR particles, which contain one cohesive end and are formed by cutting of the cos site, by plaque formation of lambda bio on Escherichia coli P2 lysogens. The yields of lambda Spi- phage in the int, xis, int-xis deletion, and b2 deletion mutants were about 50- to 200-fold higher than that of the wild-type prophage when bacteria were irradiated with UV light. This result indicates that Int and Xis functions, and the att site, are not required for illegitimate recombination. The yield of lambda Spi- phage in the himA, himD, or fis mutant carrying lambda delta int-xis prophage was 2.6-, 3.3-, or 17-fold lower, respectively, than that in the wild-type bacteria under UV irradiation. Analysis of the nucleotide sequences of the junctions of the transducing phages indicates that recombination at the hotspots, as well as at non-hotspots, takes place between short homologous sequences. Because the growth of infecting phages was not suppressed by the himA, himD, or fis mutation, we conclude that Fis is required, but IHF is only partially required, for short-homology-dependent illegitimate recombination during the formation of lambda bio transducing phage.

RecQ DNA helicase is a suppressor of illegitimate recombination in Escherichia coli

Bloom syndrome and Werner syndrome are genetic disorders in which an increased rate of chromosomal abnormality is observed. The genes responsible for these diseases, BLM and WRN, have been cloned and identified as homologs of the Escherichia coli recQ genes. We studied the effect of recQ mutations on illegitimate recombination, which is an aberrant biological event related to the chromosomal abnormality in humans, and found that a variety of recQ mutations increased spontaneous illegitimate recombination by 20- to 300-fold and increased UV light-induced illegitimate recombination by 10- to 100-fold. Most lambda bio or lambda pro transducing phages are formed by the recombination events at several hot spots, which are enhanced by the recQ mutation. The analysis of nucleotide sequences at the recombination junction in the transducing phages indicates that recombination at the hot spot sites as well as the non-hot spot sites takes place between short homologous sequences. Enhancement of the recombination in the recQ mutants also occurs in the recA, recBC sbcBC, or recBC sbcA backgrounds, indicating that these recombination events are mediated by none of the known recombination pathways, RecBC, RecF, and RecE. We therefore concluded that the RecQ function suppresses illegitimate recombination that depends on short homologous regions. We discuss a model, based on the 3'-to-5' helicase activity of RecQ, to explain the role of this protein as a suppressor of illegitimate recombination.