<Emphasis Type="Italic">Deinococcus radiodurans</Emphasis> RecX and <Emphasis Type="Italic">Escherichia coli</Emphasis> RecX proteins are capable to replace each other in vivo and in vitro

A plasmid carrying the Deinococcus radiodurans recX gene under the control of a lactose promoter decreases the Escherichia coli cell resistance to UV irradiation and γ irradiation and also influences the conjugational recombination process. The D. radiodurans RecX protein functions in the Escherichia coli cells similarly to the E. coli RecX protein. Isolated and purified D. radiodurans RecX and E. coli RecX proteins are able to replace each other interacting with the E. coli RecA and D. radiodurans RecA proteins in vitro. Data obtained demonstrated that regulatory interaction of RecA and RecX proteins preserves a high degree of conservatism despite all the differences in the recombination reparation system between E. coli and D. radiodurans.     

Characterization of the Minimal Replicon of a Cryptic Deinococcus radiodurans SARK Plasmid and Development of Versatile Escherichia coli-D. radiodurans Shuttle Vectors

The nucleotide sequence of a 12-kb fragment of the cryptic Deinococcus radiodurans SARK plasmid pUE10 was determined, in order to direct the development of small, versatile cloning systems for Deinococcus. Annotation of the sequence revealed 12 possible open reading frames. Among these are the repU and resU genes, the predicted products of which share similarity with replication proteins and site-specific resolvases, respectively. The products of both genes were demonstrated using an overexpression system in Escherichia coli. RepU was found to be required for replication, and ResU was found to be required for stable maintenance of pUE10 derivatives. Gel shift analysis using purified His-tagged RepU identified putative binding sites and suggested that RepU may be involved in both replication initiation and autoregulation of repU expression. In addition, a gene encoding a possible antirestriction protein was found, which was shown to be required for high transformation frequencies. The arrangement of the replication region and putative replication genes for this plasmid from D. radiodurans strain SARK is similar to that for plasmids found in Thermus but not to that for the 45.7-kb plasmid found in D. radiodurans strain R1. The minimal region required for autonomous replication in D. radiodurans was determined by sequential deletion of segments from the 12-kb fragment. The resulting minimal replicon, which consists of approximately 2.6 kb, was used for the construction of a shuttle vector for E. coli and D. radiodurans. This vector, pRAD1, is a convenient general-purpose cloning vector. In addition, pRAD1 was used to generate a promoter probe vector, and a plasmid containing lacZ and a Deinococcus promoter was shown to efficiently express LacZ.     

The resistances of Micrococcus radiodurans to killing and mutation by agents which damage DNA

The resistance of Micrococcus radiodurans to the lethal and mutagenic action 3f ultraviolet (UV) light, ionising (γ) radiation, mitomycin C (MTC), nitrous acid (NA), hydroxylamine (HA), N-methyl-N′-nitro-N-nitrosoguanidine (NG), ethylmethanesulphonate (EMS) and β-propiolactone (βPL) has been compared with that of Escherichia coli B/r.M. radiodurans was much more resistant than E. coli B/r to the lethal effects of UV light (by a factor of 33), γ-radiation (55), NG (15) and NA (62), showed intermediate resistance to MTC (4) and HA(7), but was sensitive to EMS (1) and βPL (2). M. radiodurans was very resistant to mutagens producing damage which can be repaired by a recombination system, indicating that it possesses an extremely efficient recombination repair mechanism.Both species were equally sensitive to mutation to trimethoprim resistance by NG, but M. radiodurans was more resistant the E. coli B/r to the other multagens tested, being non-mutable by UV light, γ-radiation, MTC and HA, and only slightly sensitive to mutation by NA, EMS, and βPL. The resistance of M. radiodurans to mutation by UV-light, γ-radiation and MTC is consistent with an hypothesis that recombination repair in M. radiodurans is accurate since these mutagens may depend on an “error-prone” recombination system for their mutagenic effect in E. coli B/r. However, because M. radiodurans is also resistant to mutagens such as HA and EMS, which are mutagenic in E. coli in the absence of an “error-prone” system, we propose that all the mutagens tested may have a common mode of action in E. coli B/r, but that this mutagenic pathway is missing in M. radiodurans.     

Recombination hotspots flank the Cryptococcus mating-type locus: implications for the evolution of a fungal sex chromosome

Recombination increases dramatically during meiosis to promote genetic exchange and generate recombinant progeny. Interestingly, meiotic recombination is unevenly distributed throughout genomes, and, as a consequence, genetic and physical map distances do not have a simple linear relationship. Recombination hotspots and coldspots have been described in many organisms and often reflect global features of chromosome structure. In particular, recombination frequencies are often distorted within or outside sex-determining regions of the genome. Here, we report that recombination is elevated adjacent to the mating-type locus (MAT) in the pathogenic basidiomycete Cryptococcus neoformans. Among fungi, C. neoformans has an unusually large MAT locus, and recombination is suppressed between the two >100-kilobase mating-type specific alleles. When genetic markers were introduced at defined physical distances from MAT, we found the meiotic recombination frequency to be ~20% between MAT and a flanking marker at 5, 10, 50, or 100 kilobases from the right border. As a result, the physical/genetic map ratio in the regions adjacent to MAT is distorted ~10- to 50-fold compared to the genome-wide average. Moreover, recombination frequently occurred on both sides of MAT and negative interference between crossovers was observed. MAT heterozygosity was not required for enhanced recombination, implying that this process is not due to a physical distortion from the two non-paired alleles and could also occur during same-sex mating. Sequence analysis revealed a correlation between high G + C content and these hotspot regions. We hypothesize that the presence of recombinational activators may have driven several key events during the assembly and reshaping of the MAT locus and may have played similar roles in the origins of both metabolic and biosynthetic gene clusters. Our findings suggest that during meiosis the MAT locus may be exchanged onto different genetic backgrounds and therefore have broad evolutionary implications with respect to mating-type switching in both model and pathogenic yeasts.     

Mutants of the Killer Plasmid of SACCHAROMYCES CEREVISIAE Dependent on Chromosomal Diploidy for Expression and Maintenance

Mutants of the killer plasmid of Saccharomyecs cerevisiae have been isolated that depend upon chromosomal diploidy for the expression of plasmid functions and for replication or maintenance of the plasmid itself. These mutants are not defective in any chromosomal gene needed for expression or replication of the killer plasmid.—Haploids carrying these mutant plasmids (called d for diploid-dependent) are either unable to kill or unable to resist being killed or both and show frequent loss of the plasmid. The wild-type phenotype (K⁺R⁺) is restored by mating the d plasmid-carrying strain with either (a) a wild-type sensitive strain which apparently has no killer plasmid; (b) a strain which has been cured of the killer plasmid by growth at elevated temperature; (c) a strain which has been cured of the plasmid by growth in the presence of cycloheximide; (d) a strain which has lost the plasmid because it carries a mutation in a chromosomal mak gene; or (e) a strain of the opposite mating type which carries the same d plasmid and has the same defective phenotype, indicating that the restoration of the normal phenotype is not due to recombination between plasmid genomes or complementation of plasmid or chromosomal genes.—Sporulation of the phenotypically K⁺R⁺ diploids formed in matings between d and wild-type nonkiller strains yields tetrads, all four of whose haploid spores are defective for killing or resistance or maintenance of the plasmid or a combination of these. Every defective phenotype may be found among the segregants of a single diploid clone carrying a d plasmid. These defective segregants resume the normal killer phenotype in the diploids formed when a second round of mating is performed, and the segregants from a second round of meiosis and sporulation are again defective.     

Analysis of Gene Targeting and Intrachromosomal Homologous Recombination Stimulated by Genomic Double-Strand Breaks in Mouse Embryonic Stem Cells

To investigate the effects of in vivo genomic DNA double-strand breaks on the efficiency and mechanisms of gene targeting in mouse embryonic stem cells, we have used a series of insertion and replacement vectors carrying two, one, or no genomic sites for the rare-cutting endonuclease I-SceI. These vectors were introduced into the hypoxanthine phosphoribosyltransferase (hprt) gene to produce substrates for gene-targeting (plasmid-to-chromosome) or intrachromosomal (direct repeat) homologous recombination. Recombination at the hprt locus is markedly increased following transfection with an I-SceI expression plasmid and a homologous donor plasmid (if needed). The frequency of gene targeting in clones with an I-SceI site attains a value of 1%, 5,000-fold higher than that in clones with no I-SceI site. The use of silent restriction site polymorphisms indicates that the frequencies with which donor plasmid sequences replace the target chromosomal sequences decrease with distance from the genomic break site. The frequency of intrachromosomal recombination reaches a value of 3.1%, 120-fold higher than background spontaneous recombination. Because palindromic insertions were used as polymorphic markers, a significant number of recombinants exhibit distinct genotypic sectoring among daughter cells from a single clone, suggesting the existence of heteroduplex DNA in the original recombination product.     

Differential Radio-Tolerance of Nutrition-Induced Morphotypes of Deinococcus radiodurans R1

Deinococcus radiodurans R1 is a highly radio-tolerant bacterium. Depending on the nutrient availability D. radiodurans R1 exists in three morphologies viz. monococcal, diplococcal and tetracoccal. In this study, we examined whether nutrition-induced morphotypes of D. radiodurans showed similar DNA damage upon gamma radiation exposure. Total DNA damage after radiation exposure was estimated by comparing percent double-strand breaks (DSBs) in genomic DNA. It was found that all three morphotypes exhibited different radiation tolerances which were also dependent on the radiation dose given. Monococcal forms were found to be most radio-tolerant at most of the tested radiation doses. Results showed that these nutrient-starved-condition induced morphotypes show lesser DNA DSBs upon irradiation, hence show higher radio-tolerance.     

RecE independent deletions of recombinant plasmids in Bacillus subtilis

Fragments from the Bacillus bacteriophage φ105 have been cloned in recE⁺ and recE^? bacteria lysogenic and nonlysogenic for the phage. Recombination between homologous DNA in the plasmid and the prophage occurs only in the rec⁺ strain at a low frequency of around 4%. After prolonged cultivation with selective pressure on the antibiotic resistance gene of the vector, the bacteria contained only plasmids with various deletions. This process is recE independent and occurs irrespective of whether base pair homology exists between chromosomal and plasmid DNA. The rate of spontaneous curing of the plasmid decreases in parallel to the appearance of deletions, presumably due to higher stability of the small plasmids.     

High Frequency Plasmid Recombination Mediated by 28 bp Direct Repeats

The stability in Escherichia coli of a mammalian expression vector (pCIneo) and its derivative candidate DNA vaccine (pGPV-PV) is described. These multicopy pMB1-type plasmids were found to recombine in several recA E. coli strains due to the presence of two 28 bp direct repeats flanking intervening sequences of 1.6 kb (pCIneo) and 3.2 kb (pGPV-PV). In this recombination event, one of the direct repeats and the intervening sequence were deleted or duplicated, originating monomeric or/and hetero-dimeric plasmid forms, respectively. Additionally, the plasmid rearrangement led to the acquisition of a kanamycin resistance phenotype. Recombination frequencies between 7.8 × 10⁻⁷ and 3.1 × 10⁻⁵ were determined for DH5α and JM109(DE3) strains, respectively. Higher recombination frequencies were found in cells previously grown up to stationary growth phase being the monomeric plasmid form the prevalent one. Real-time PCR quantification revealed the presence of approximately 1.5 × 10⁴ recombined molecules per 2 × 10⁵ cells pre-kanamycin exposure. Under selective pressure of this antibiotic, the number of recombined molecules increased approximately 2,000-fold in a 48-h period replacing the original plasmid form. The high frequency, at which deletion-duplication occurred in the absence of kanamycin selective pressure, should be regarded as a safety concern. This work highlights the impact of mutational hot spots on expression and cloning plasmid vectors and the need to carefully design plasmid vectors. Sofia C. Ribeiro and Pedro H. Oliveira contributed equally to this work.     

DdrB stimulates single-stranded DNA annealing and facilitates RecA-independent DNA repair in Deinococcus radiodurans

The bacterium Deinococcus radiodurans can survive extremely high exposure to ionizing radiation. The repair mechanisms involved in this extraordinary ability are still being investigated. ddrB is one gene that is highly up-regulated after irradiation, and it has been proposed to be involved in RecA-independent repair in D. radiodurans. Here we cloned, expressed and characterized ddrB in order to define its roles in the radioresistance of D. radiodurans. DdrB preferentially binds to single-stranded DNA. Moreover, it interacts directly with single-stranded binding protein of D. radiodurans DrSSB, and stimulates single-stranded DNA annealing even in the presence of DrSSB. The post-irradiation DNA repair kinetics of a ddrB/recA double mutant were compared to ddrB and recA single mutants by pulsed-field gel electrophoresis (PFGE). DNA fragment rejoining in the ddrB/recA double mutant is severely compromised, suggesting that DdrB-mediated single-stranded annealing plays a critical role in the RecA-independent DNA repair of D. radiodurans.     

Identification of plasmid and Bacillus subtilis chromosomal recombination sites used for pE194 integration.

The plasmid pE194 (3.7 kilobases) is capable of integrating into the genome of the bacterial host Bacillus subtilis in the absence of the major homology-dependent RecE recombination system. Multiple recombination sites have been identified on both the B. subtilis chromosome and pE194 (J. Hofemeister, M. Israeli-Reches, and D. Dubnau, Mol. Gen. Genet. 189:58-68, 1983). The B. subtilis chromosomal recombination sites were recovered by genetic cloning, and these sites were studied by nucleotide sequence analysis. Recombination had occurred between regions of short nucleotide homology (6 to 14 base pairs) as indicated by comparison of the plasmid and the host chromosome recombination sites with the crossover sites of the integration products. Recombination between the homologous sequences of the plasmid and the B. subtilis genome produced an integrated pE194 molecule which was bounded by direct repeats of the short homology. These results suggest a recombination model involving a conservative, reciprocal strand exchange between the two recombination sites. A preferred plasmid recombination site was found to occur within a 70-base-pair region which contains a GC-rich dyad symmetry element. Five of seven pE194-integrated strains analyzed had been produced by recombination at different locations within this 70-base-pair interval, located between positions 860 and 930 in pE194. On the basis of these data, mechanisms are discussed to explain the recombinational integration of pE194.     

Analysis of the recJ gene and protein from Deinococcus radiodurans

The mechanism by which double-strand DNA breaks are repaired in the radiation-resistant bacterium Deinococcus radiodurans is not well understood. This organism lacks the RecBCD helicase/nuclease, which processes broken DNA ends in other bacteria. The RecF pathway is an alternative pathway for recombination and DNA repair in E. coli, when RecBCD is absent due to mutation, and D. radiodurans may rely on enzymes of this pathway for double-strand break repair. The RecJ exonuclease is thought to process broken DNA ends for the RecF pathway. We attempted to delete the recJ gene from D. radiodurans, using homologous recombination to replace the gene with a streptomycin-resistance cassette. We were unable to obtain a complete deletion mutant, in which the gene is deleted from all of the chromosome copies in this polyploid organism. Quantitative real-time PCR shows that the heterozygous mutants have a recJ gene copy that is ca. 10–30% that of the wild-type. Mutants with reduced recJ gene copy grow slowly and are more sensitive than wild-type to UV irradiation, gamma irradiation, and hydrogen peroxide. The mutants are as resistant as wild-type to methyl-methanesulfonate. The D. radiodurans RecJ protein was expressed in E. coli and purified under denaturing conditions. The re-folded protein has nuclease activity on single-stranded DNA with specificity similar to that of E. coli RecJ exonuclease.     

Interplasmidic and intraplasmidic recombination in Escherichia coli K-12

Summary The construction of plasmids which facilitate the study of interplasmidic and intraplasmidic recombination is described. In this system, a single recombination event between two mutated Te^r genes on separate plasmids or on one plasmid leads to a change in the host phenotype from sensitivity to resistance to tetracycline.Recombination proficiencies have been determined for different E. coli K-12 strains: both interplasmidic and intraplasmidic recombination are independent of the recBC gene product. RecA mutations decrease the proficiency of plasmidic recombination 40–100 fold. Intraplasmidic and interplasmidic recombination via the recE pathway are more efficient than via the recBC pathway. Intraplasmidic recombination, but not interplasmidic recombination via the recE pathway is independent of a functional recA product.     

In vivo construction of recombinant molecules within the Caenorhabditis elegans germ line using short regions of terminal homology

Homologous recombination provides a means for the in vivo construction of recombinant DNA molecules that may be problematic to assemble in vitro. We have investigated the efficiency of recombination within the Caenorhabditis elegans germ line as a function of the length of homology between recombining molecules. Our findings indicate that recombination can occur between molecules that share only 10 bp of terminal homology, and that 25 bp is sufficient to mediate relatively high levels of recombination. Recombination occurs with lower efficiency when the location of the homologous segment is subterminal or internal. As in yeast, recombination can also be mediated by either single- or double-stranded bridging oligonucleotides. We find that ligation between cohesive ends is highly efficient and does not require that the ends be phosphorylated; furthermore, precise intermolecular ligation between injected molecules that have blunt ends can also occur within the germ line.     

Electron microscope heteroduplex studies of sequence relations among plasmids of Escherichia coli. IV. The F sequences in F14

The structure of F14, in particular the arrangement of the F sequences on this plasmid, has been studied by the electron microscope heteroduplex method. F14 has a molecular size of 311 ± 10 kilobase pairs (M = (206 ± 8) × 10⁶daltons). It contains all of F (94.5 kilobases). A sequence of length 5.7 kilobases, which occurs once in F (with co-ordinates 2.8 to 8.5F), is directly repeated in F14. It occurs at the two junctions of F DNA with chromosomal DNA. Thus, F14 contains about 211 ± 10 kilobases of chromosomal DNA. A previously unidentified direct repeat has also been discovered on F itself; the sequence with co-ordinates 93.2 to 94.5F is directly repeated at 13.7 to 15.0F. Physical observations indicate that the population of closed circular plasmid molecules extracted from F14-containing strains is heterogeneous. In addition to F14 itself, molecules the size of F and 2.3 times the size of F were found. The latter molecules contain all the chromosomal sequences of F14 and one copy of the 2.8 to 8.5F segment. Such heterogeneity was observed in both recA^? and recA⁺ backgrounds. It is proposed that this heterogeneity is due to intramolecular recombination events occurring within F14 between the duplicated 2.8 to 8.5F sequences. Such recombination can account for the previously observed genetic instability of F14. Another F prime plasmid, F186, independently isolated from the Hfr parent of AB313, was found to be identical to F14.     

One step construction of PCR mutagenized libraries for genetic analysis by recombination cloning

Recombination cloning encompasses a set of technologies that transfer gene sequences between vectors through site-specific recombination. Due in part to the instability of linear DNA in bacteria, both the initial capture and subsequent transfer of gene sequences is often performed using purified recombination enzymes. However, we find linear DNAs flanked by loxP sites recombine efficiently in bacteria expressing Cre recombinase and the lambda Gam protein, suggesting Cre/lox recombination of linear substrates can be performed in vivo. As one approach towards exploiting this capability, we describe a method for constructing large (>1 × 10⁶ recombinants) libraries of gene mutations in a format compatible with recombination cloning. In this method, gene sequences are cloned into recombination entry plasmids and whole-plasmid PCR is used to produce mutagenized plasmid amplicons flanked by loxP. The PCR products are converted back into circular plasmids by transforming Cre/Gam-expressing bacteria, after which the mutant libraries are transferred to expression vectors and screened for phenotypes of interest. We further show that linear DNA fragments flanked by loxP repeats can be efficiently recombined into loxP-containing vectors through this same one-step transformation procedure. Thus, the approach reported here could be adapted as general cloning method.     

PprA Contributes to Deinococcus radiodurans Resistance to Nalidixic Acid,Genome Maintenance after DNA Damage and Interacts with Deinococcal Topoisomerases

PprA is known to contribute to Deinococcus radiodurans'' remarkable capacity to survive a variety of genotoxic assaults. The molecular bases for PprA''s role(s) in the maintenance of the damaged D. radiodurans genome are incompletely understood, but PprA is thought to promote D. radiodurans''s capacity for DSB repair. PprA is found in a multiprotein DNA processing complex along with an ATP type DNA ligase, and the D. radiodurans toposiomerase IB (DraTopoIB) as well as other proteins. Here, we show that PprA is a key contributor to D. radiodurans resistance to nalidixic acid (Nal), an inhibitor of topoisomerase II. Growth of wild type D. radiodurans and a pprA mutant were similar in the absence of exogenous genotoxic insults; however, the pprA mutant exhibited marked growth delay and a higher frequency of anucleate cells following treatment with DNA-damaging agents. We show that PprA interacts with both DraTopoIB and the Gyrase A subunit (DraGyrA) in vivo and that purified PprA enhances DraTopoIB catalysed relaxation of supercoiled DNA. Thus, besides promoting DNA repair, our findings suggest that PprA also contributes to preserving the integrity of the D. radiodurans genome following DNA damage by interacting with DNA topoisomerases and by facilitating the actions of DraTopoIB.     

Single Strand Annealing Plays a Major Role in RecA-Independent Recombination between Repeated Sequences in the Radioresistant Deinococcus radiodurans Bacterium

The bacterium Deinococcus radiodurans is one of the most radioresistant organisms known. It is able to reconstruct a functional genome from hundreds of radiation-induced chromosomal fragments. Our work aims to highlight the genes involved in recombination between 438 bp direct repeats separated by intervening sequences of various lengths ranging from 1,479 bp to 10,500 bp to restore a functional tetA gene in the presence or absence of radiation-induced DNA double strand breaks. The frequency of spontaneous deletion events between the chromosomal direct repeats were the same in recA+ and in ΔrecA, ΔrecF, and ΔrecO bacteria, whereas recombination between chromosomal and plasmid DNA was shown to be strictly dependent on the RecA and RecF proteins. The presence of mutations in one of the repeated sequence reduced, in a MutS-dependent manner, the frequency of the deletion events. The distance between the repeats did not influence the frequencies of deletion events in recA ⁺ as well in ΔrecA bacteria. The absence of the UvrD protein stimulated the recombination between the direct repeats whereas the absence of the DdrB protein, previously shown to be involved in DNA double strand break repair through a single strand annealing (SSA) pathway, strongly reduces the frequency of RecA- (and RecO-) independent deletions events. The absence of the DdrB protein also increased the lethal sectoring of cells devoid of RecA or RecO protein. γ-irradiation of recA ⁺ cells increased about 10-fold the frequencies of the deletion events, but at a lesser extend in cells devoid of the DdrB protein. Altogether, our results suggest a major role of single strand annealing in DNA repeat deletion events in bacteria devoid of the RecA protein, and also in recA ⁺ bacteria exposed to ionizing radiation.     

A plasmid model to study genetic recombination in yeast

Chimeric plasmids have been constructed containing two heteroallelic mutant copies of the yeast HIS3 gene as an inverted repetition. Intramolecular exchange events between these two allelic mutant copies are capable of generating a wild-type allele. Plasmids containing two mutant heteroalleles have been transformed into appropriate his3^? yeast strains, and the frequency of exchange events generating His⁺ prototrophs has been measured during mitotic division. After 20 generations of growth under nonselective conditions, between 0.1 and 1 % of the transformed yeast cells become His⁺ prototrophs. This percentage decreases at least ten-fold in a strain with a rad52 mutation. Plasmid molecules having undergone exchange events have been isolated from yeast cells and have been examined after transfer to Escherichia coli. Physical examination shows that less than 10 % of the plasmids having undergone genetic exchange have also undergone an internal reciprocal recombination event as evidenced by reorientation of linked restriction sites. The remainder of the plasmids having undergone genetic exchange do not exhibit reciprocal recombination. Characterization of the individual allelic copies within a plasmid having undergone exchange reveals that in 24 of 25 examples only one of the two HIS3 copies has become wild type, and that either copy is equally likely to become wild type. We conclude that the model plasmid we have constructed undergoes intramolecular genetic exchange events and will be useful for studying genetic recombination.