High frequency excision of Ty elements during transformation of yeast.

Yeast (Saccharomyces cerevisiae) transposons (Ty elements) are excised from up to 20% of supercoiled plasmids during transformation of yeast cells. The excision occurs by homologous recombination across the direct terminal repeats (deltas) of the Ty element, leaving behind a single delta in the transforming plasmid. Only the initial transforming plasmid is susceptible to excision, and no high frequency excision is observed in plasmids that have become established in transformed cells or in plasmids that are resident in cells undergoing transformation. High frequency excision from plasmids during yeast transformation is not specific for Ty elements and can be observed with other segments of plasmid DNA bounded by direct repeats. The frequency of Ty excision from supercoiled plasmids is greatly reduced when the host yeast cells contain the rad52 mutation, a defect in double-strand DNA repair. When linear or ligated-linear plasmid DNAs containing a Ty element are used for transformation, few or no excision plasmids are found among the transformant colonies. These results suggest that when a yeast cell is transformed with a supercoiled plasmid, the plasmid DNA is highly susceptible to homologous recombination for a short period of time.     

Plasmid inverted repeats provide for duplication or precise excision of DNA inserts

A plasmid containing inverted repeats is constructed in Bacillus subtilis. Insertion of DNA fragments into the plasmid inverted repeats results either in the precise excision of the insert or in its duplication in the opposite inverted repeat. These rearrangements are due to the presence of inverted repeats only. Two recombination events are possibly responsible for these phenomena. During the first step of the recombination two plasmid monomers form a dimer molecule. During the second step the intramolecular recombination between the direct repeats in the dimer structure leads to the formation of two rearranged plasmid monomers devoid of insertion or containing two DNA inserts. Proposed dimeric intermediate is unstable in B. subtilis. However, it is isolated from Escherichia coli recA, cells. Plasmids containing the inverted repeats can serve as a model to study plasmid recombination in B. subtilis cells.     

Microcin H47 system: an Escherichia coli small genomic island with novel features

Genomic islands are DNA regions containing variable genetic information related to secondary metabolism. Frequently, they have the ability to excise from and integrate into replicons through site-specific recombination. Thus, they are usually flanked by short direct repeats that act as attachment sites, and contain genes for an integrase and an excisionase which carry out the genetic exchange. These mobility events would be at the basis of the horizontal transfer of genomic islands among bacteria.Microcin H47 is a ribosomally-synthesized antibacterial peptide that belongs to the group of chromosome-encoded microcins. The 13 kb-genetic system responsible for its production resides in the chromosome of the Escherichia coli H47 strain and is flanked by extensive and imperfect direct repeats. In this work, both excision and integration of the microcin H47 system were experimentally detected. The analyses were mainly performed in E. coli K12 cells carrying the microcin system cloned in a multicopy plasmid. As expected of a site-specific recombination event, the genetic exchange also occurred in a context deficient for homologous recombination. The DNA sequence of the attachment sites resulting from excision were hybrid between the sequences of the direct repeats. Unexpectedly, different hybrid attachment sites appeared which resulted from recombination in four segments of identity between the direct repeats. Genes encoding the trans-acting proteins responsible for the site-specific recombination were shown to be absent in the microcin H47 system. Therefore, they should be provided by the remaining genetic context, not only in the H47 strain but also in E. coli K12 cells, where both excision and integration occurred. Moreover, a survey of the attachment sites in data banks revealed that they are widely spread among E. coli strains. It is concluded that the microcin system is a small island -H47 genomic island- that would employ a parasitic strategy for its mobility.     

Theta-type DNA replication stimulates homologous recombination in the Bacillus subtilis chromosome

To test the effects of theta-type replication on homologous DNA recombination, we integrated in the chromosome of Bacillus subtilis a structure comprising a conditional replication region and direct repeats of ∼ 4 kb. The replicon was derived from a broad-host-range plasmid, pAMβ1, which replicates by a unidirectional theta mechanism and is thermosensitive. The direct repeats were derived from plasmid pBR322 and flanked the chloramphenicol-resistance gene of plasmid pC194. Recombination between the repeats could therefore lead to a loss of the resistance gene or the appearance of additional repeats. The integrated replicon was active at the permissive temperature, and ∼ 25% of the integrated plasmids could be isolated as Y-shaped molecules after restriction, having a branch at the replication origin. Replicon activity stimulated recombination four- to fivefold, as estimated from the proportion of chloramphenicol-sensitive cells at the restrictive and permissive temperature, and also led to the appearance of additional direct repeats. We conclude that theta-type replication stimulates homologous recombination and suggest that many or even most recombination events between long homologous sequences present in a bacterial genome may be the consequence of DNA replication.     

A Replicational Model for DNA Recombination between Direct Repeats

DNA rearrangement (recombination) mediated by direct repeats is a major cause of genome instability. InEscherichia coli, direct repeats in close proximity can mediate efficientrecA-independent intramolecular recombi nation, which produces multiple products. Using plasmid substrates, three basic forms of products have been revealed: the monomeric deletion product and two dimeric products. The frequency of recombination has been shown to be affected by structural factors such as the length of the repeat and the distance between the repeats. We show here that these factors also affect the relative abundance of each form of product. Recombination between very short tandem repeats yields exclusively the monomeric product. Lengthening the repeats increases the abundance of the dimeric products. Increasing the distance separating the repeats sharply reduces the formation of the monomeric product. These results can be explained by a model for DNA rearrangement (recombination) involving DNA replication. We propose that misalignment of the repeats at the replication fork creates a recombinogenic intermediate that can be differentially processed to form the three basic products. The proposed sister-strand recombination mediated by direct repeats might be a general mechanism for deletion and/or amplification of repeated sequences in both prokaryotic and eukaryotic genomes.     

The RecE recombination pathway mediates recombination between partially homologous DNA sequences: structural analysis of recombination products

Escherichia coli generalized recombination, utilizing the RecA RecB recombination pathway, requires large stretches (70-200 bp) of complete DNA sequence homology. In contrast, we have found that the RecE pathway can promote recombination between DNA with only short stretches of homology. A plasmid containing 10 partially homologous direct repeats was linearized by digestion with specific restriction enzymes. After transformation, a RecE+ (sbcA) host was able to circularize the plasmid by recombination between partially homologous direct repeat sequences. Recombination occurred in regions of as little as 6 bp of perfect homology. Recombination was enhanced in the regions adjacent to restriction sites used to linearize the plasmid, consistent with a role of double-strand breaks in promoting recombination. A mechanism is proposed in which the 5' exonuclease, ExoVIII, produces 3' single-stranded ends from the linearized plasmid. These pair with other sequences of partial homology. Partial homologies in the sequences flanking the actual join serve to stabilize this recombination intermediate. Recombination is completed by a process of "copy and join." This recombination mechanism requires less homology to stabilize intermediates than the degree of homology needed for mechanisms involving strand invasion. Its role in nature may be to increase genomic diversity, for example, by enhancing recombination between bacteriophages and regions of the bacterial chromosome.     

Intramolecular recombination during plasmid transformation of Bacillus subtilis competent cells.

We have constructed plasmids carrying direct internal repeats 260-2000 bp long. Monomers of such plasmids transformed Bacillus subtilis competent cells. The efficiency of transformation varied with the square of the length of repeats. The transformed clones harbored either the entire transforming plasmid and the plasmid arising by recombination between the repeats, or only the latter plasmid. Internally-repeated plasmids linearized by in vitro cleavage with restriction endonuclease could transform, yielding clones which exclusively harbored a plasmid resulting from recombination between the repeats. When the transforming plasmid carried repeats which differed slightly, conversion of one repeat into the other could occur. The following model of plasmid transformation accounts for these data: (1) plasmid DNA is cleaved and rendered linear in contact with competent cells; (2) a linear, at least partially double-stranded plasmid molecule is introduced or formed by repair within the cell; (3) a circular viable plasmid is produced by recombination between repeats carried on this molecule; (4) alternatively, a viable plasmid is produced by repairing the cut within one of the repeats by DNA synthesis which uses the other repeat as a template.     

Breakage--reunion and copy choice mechanisms of recombination between short homologous sequences.

To study recombination between short homologous sequences in Escherichia coli we constructed plasmids composed of the pBR322 replicon, M13 replication origin and a recombination unit inserted within and inactivating a gene encoding chloramphenicol resistance. The unit was composed of short direct repeats (9, 18 or 27 bp) which flanked inverted repeats (0, 8 or 308 bp) and a gene encoding kanamycin resistance. Recombination between direct repeats restored a functional chloramphenicol resistance gene, and could be detected by a simple phenotype test. The plasmids replicated in a double-stranded form, using the pBR322 replicon, and generated single-stranded DNA when the M13 replication origin was activated. The frequency of chloramphenicol-resistant cells was low (10(-8)-10(-4] when no single-stranded DNA was synthesized but increased greatly (to 100%) after induction of single-stranded DNA synthesis. Recombination between 9 bp direct repeats entailed no transfer of DNA from parental to recombinant plasmids, whereas recombination between 18 or 27 bp repeats entailed massive transfer. The presence or length of inverted repeats did not alter the pattern of DNA transfer. From these results we propose that direct repeats of 9 bp recombine by a copy choice process, while those greater than or equal to 18 bp can recombine by a breakage-reunion process. Genome rearrangements detected in many organisms often occur by recombination between sequences less than 18 bp, which suggests that they may result from copy choice recombination.     

Plasmid deletion formation between short direct repeats in Bacillus subtilis is stimulated by single-stranded rolling-circle replication intermediates

Summary The effects of the rolling-circle mode of replication and the generation of single-stranded DNA (ss DNA) on plasmid deletion formation between short direct repeats in Bacillus subtilis were studied. Deletion units consisting of direct repeats (9, 18, or 27 bp) that do or do not flank inverted repeats (300 bp) were introduced into various plasmid replicons that generate different amounts of ss DNA (from 0% to 40% of the total plasmid DNA). With ss DNA-generating rolling-circle-type plasmids, deletion frequencies between the direct repeats were 3- to 13-fold higher than in plasmids not generating ss DNA. When the direct repeats flanked inverted repeats the deletion frequencies in ss DNA-generating plasmids were increased by as much as 20- to 140-fold. These results support models for deletion formation based on template-switching errors during complementary strand synthesis of rolling-circle-type plasmids. The structural instability (deletion formation between short direct repeats) of the ss DNA-generating plasmid pTA1060 in B. subtilis was very low in the presence of a functional initiation site for complementary strand synthesis (minus origin). This observation suggests that it will be possible to develop stable host-vector cloning systems for B. subtilis.     

Structural plasmid instability in Bacillus subtilis: Effect of direct and inverted repeats

Summary Using precise excision as a model system, we have quantified the effect of direct repeats, inverted repeats and the size of the spacer between the repeats in the process of deletion formation in Bacillus subtilis. Both in the presence and absence of inverted repeats, the frequency of precise excision was strongly dependent on the direct repeat length. By increasing the direct repeat length from 9 bp to 18 and 27 bp, the precise excision frequency was raised by 3 and 4 orders of magnitude, respectively. In addition, irrespective of the direct repeat length, the presence of flanking inverted repeats enhanced the excision frequency by 3 orders of magnitude. Varying the inverted repeat length and the spacer size over a wide range did not significantly affect the excision frequencies. These results fit well into a model for deletion formation by slipped mispairing during replication of single-stranded plasmid DNA.     

Homologous Recombination as the Main Mechanism for DNA Integration and Cause of Rearrangements in the Filamentous Ascomycete Ashbya Gossypii

A slow and a fast growth phenotype were observed after transformation of the phytopathogenic fungus Ashbya gossypii using a plasmid carrying homologous DNA and as selectable marker the Tn903 aminoglycoside resistance gene expressed from a strong A. gossypii promoter. Transformations with circular plasmids yielded slowly and irregularly growing geneticin-resistant mycelia in which 1% of nuclei contained plasmid sequences. Occasionally, fast growing sectors appeared which were shown to be initiated by homologous integration of the transforming DNA. Transformants obtained with plasmids linearized within the homology region immediately exhibited fast radial growth. In all 28 transformants analyzed plasmid DNA was integrated homologously. Such apparent lack of nonhomologous recombination has so far not been observed in filamentous ascomycetes. In 14 transformants two to four tandemly integrated plasmid copies were found. They underwent several types of genetic changes, mainly in the older mycelium: excision of whole plasmid copies and rearrangements within the integrated DNA (inversions and deletions). These internal rearrangements involved 360-bp inverted repeats, remnants of IS-elements flanking the resistance gene, and 156-bp direct repeats, originating from the strong A. gossypii promoter. Improved vectors lacking sequence repetitions were constructed and used for stable one-step gene replacement in A. gossypii.     

Actinomycetes--the test-organisms of genetic engineering

The paper contains a short review of the data on using the methods of genetic engineering in studies of genetics and molecular biology in Streptomyces. The techniques of DNA introduction into actinomycetes and wide-spread vectors are briefly described. The origin of the actinomycete plasmids as chromosomal segments capable of autonomous replication is discussed. In this view, it is suggested that genetic instability in actinomycetes is connected with excision of specific DNA sequences from the chromosome at frequencies characteristic of recombination events. Also, amplification of short DNA segments within the chromosome resulting in tandem repeats is a consequence of unequal crossing over between direct repeats flanking the amplifying DNA and, possibly, of induction of replication of this DNA. The data on molecular cloning of actinomycete genes for primary metabolism and those for resistance to and biosynthesis of antibiotics, on using actinomycetes as the hosts for foreign genes to be expressed, as well as on analysis of nucleotide sequences of actinomycete DNA, are presented.     

The kanamycin resistance transposon Tn2680 derived from the R plasmid Rts1 and carried by phage P1Km has flanking 0.8-kb-long direct repeats

Phage P1Km carries within the invertible DNA segment a 5-kb insertion with 0.8-kb terminal direct repeats flanking the kanamycin resistance determinant. The same structure was also found on the R plasmid Rts1, from which the Km resistance segment of P1Km was derived. Obviously, this Km resistance segment translocated as a unit to the P1 genome and it is therefore called Tn2680. Loss of the Km resistance determinant due to recombination between the flanking direct repeats occurs during vegetative growth of P1Km. Amplification of Tn2680 to tandem oligomers is documented and is thought to result from recombination between the flanking direct repeats. The flanking 0.8-kb repeats are different from known IS elements.     

Analysis of DNA repeats in bacterial plasmids reveals the potential for recurrent instability events

Structural instability has been frequently observed in natural plasmids and vectors used for protein expression or DNA vaccine development. However, there is a lack of information concerning hotspot mapping, namely, DNA repeats or sequences identical to the host genome. This led us to evaluate the abundance and distribution of direct, inverted, and tandem repeats with high recombination potential in 36 natural plasmids from ten bacterial genera, as well as in several widely used bacterial and mammalian expression vectors. In natural plasmids, we observed an overrepresentation of close direct repeats in comparison to inverted ones and a preferential location of repeats with high recombination potential in intergenic regions, suggesting a highly plastic and dynamic behavior. In plasmid vectors, we found a high density of repeats within eukaryotic promoters and non-coding sequences. As a result of this in silico analysis, we detected a spontaneous recombination between two 21-bp direct repeats present in the human cytomegalovirus early enhancer/promoter (huCMV EEP) of the pCIneo plasmid. This finding is of particular importance, as the huCMV EEP is one of the most frequently used regulatory elements in plasmid vectors. Because pDNA integration into host gDNA can have adverse consequences in terms of plasmid processing and host safety, we also mapped several regions with high probability to mediate integration into the Escherichia coli or human genomes. Like repeated regions, some of these were located in non-coding regions of the plasmids, thus being preferential targets to be removed.     

Homologous plasmid recombination is elevated in immortally transformed cells.

The levels of intramolecular plasmid recombination, following transfection of a plasmid substrate for homologous recombination into normal and immortally transformed cells, have been examined by two independent assays. In the first assay, recovered plasmid was tested for DNA rearrangements which regenerate a functional neomycin resistance gene from two overlapping fragments. Following transformation of bacteria, frequencies of recombinationlike events were determined from the ratio of neomycin-resistant (recombinant) colonies to ampicillin-resistant colonies (indicating total plasmid recovery). Such events, yielding predominantly deletions between the directly repeated sequences, were substantially more frequent in five immortal cell lines than in any of three normal diploid cell strains tested. Effects of plasmid replication or interaction with T antigen and of bacterially mediated rejoining of linear molecules generated in mammalian cells were excluded by appropriate controls. The second assay used limited coamplification of a control segment of plasmid DNA, and of the predicted recombinant DNA region, primed by two sets of flanking oligonucleotides. Each amplified band was quantitated by reference to a near-linear standard curve generated concurrently, and recombination frequencies were determined from the ratio of recombinant/control DNA regions. The results confirmed that recombinant DNA structures were generated within human cells at direct repeats in the transfected plasmid and were markedly more abundant in an immortal cell line than in the diploid normal cells from which that line was derived.     

The Influence of Primary and Secondary DNA Structure in Deletion and Duplication between Direct Repeats in Escherichia Coli

We describe a system to measure the frequency of both deletions and duplications between direct repeats. Short 17- and 18-bp palindromic and nonpalindromic DNA sequences were cloned into the EcoRI site within the chloramphenicol acetyltransferase gene of plasmids pBR325 and pJT7. This creates an insert between direct repeated EcoRI sites and results in a chloramphenicol-sensitive phenotype. Selection for chloramphenicol resistance was utilized to select chloramphenicol resistant revertants that included those with precise deletion of the insert from plasmid pBR325 and duplication of the insert in plasmid pJT7. The frequency of deletion or duplication varied more than 500-fold depending on the sequence of the short sequence inserted into the EcoRI site. For the nonpalindromic inserts, multiple internal direct repeats and the length of the direct repeats appear to influence the frequency of deletion. Certain palindromic DNA sequences with the potential to form DNA hairpin structures that might stabilize the misalignment of direct repeats had a high frequency of deletion. Other DNA sequences with the potential to form structures that might destabilize misalignment of direct repeats had a very low frequency of deletion. Duplication mutations occurred at the highest frequency when the DNA between the direct repeats contained no direct or inverted repeats. The presence of inverted repeats dramatically reduced the frequency of duplications. The results support the slippage-misalignment model, suggesting that misalignment occurring during DNA replication leads to deletion and duplication mutations. The results also support the idea that the formation of DNA secondary structures during DNA replication can facilitate and direct specific mutagenic events.     

Hdf1, a yeast Ku-protein homologue, is involved in illegitimate recombination, but not in homologous recombination.

Hdf1 is the yeast homologue of the mammalian 70 kDa subunit of Ku-protein, which has DNA end-binding activity and is involved in DNA double-strand break repair and V(D)J recombination. To examine whether Hdf1 is involved in illegitimate recombination, we have measured the rate of deletion mutation caused by illegitimate recombination on a plasmid in an hdf1 disruptant. The hdf1 mutation reduced the rate of deletion formation by 20-fold, while it did not affect mitotic and meiotic homologous recombinations between two heteroalleles or homologous recombination between direct repeats. Hence Hdf1 participates in illegitimate recombination, but not in homologous recombination, in contrast to Rad52, Rad50, Mre11 and Xrs2, which are involved in both homologous and illegitimate recombination. The illegitimate recombination in the hdf1 disruptant took place between recombination sites that shared short regions of homology (1-4 bp), as was observed in the wild-type. Based on the DNA end-binding activity of Hdf1, we discuss models in which Hdf1 plays an important role in the late step of illegitimate recombination.     

Jekyll, a family of phage-plasmid shuttle vectors

A series of shuttle vectors has been constructed, which consist of a plasmid carrying a polylinker sequence and an M13 origin integrated into a lambda vector. A short direct repeat flanking the plasmid allows plasmid excision by homologous recombination. Sequences are cloned into unique restriction sites within the plasmid, and can be recovered either in phage or plasmid form, or can be packaged further as single-stranded DNA phage. These vectors therefore combine the efficiency of phage lambda cloning and screening with the ease of handling or analysing plasmid or M13 clones.     

Amplification of drug resistance genes flanked by inversely repeated IS1 elements: involvement of IS1-promoted DNA rearrangements before amplification.

Tn2653 contains one copy of the tet gene and two copies of the cat gene derived from plasmid pBR325 and is flanked by inverted repeats of IS1. Transposed onto the P1-15 prophage, it confers a chloramphenicol resistance phenotype to the Escherichia coli host. Because the prophage is perpetuated as a plasmid at about one copy per host chromosome, the host cell is still tetracycline sensitive even though P1-15 is carrying one copy of the tet gene. We isolated P1-15::Tn2653 mutants conferring a tetracycline resistance phenotype, in which the whole transposon and variable flanking P1-15 DNA segments were amplified. Amplification was most probably preceded by IS1-mediated DNA rearrangements which led to long direct repeats containing Tn2653 sequences and P1-15 DNA. Subsequent recombination events between these direct repeats led to amplification of a segment containing the tetracycline resistance gene in tandem arrays.     

Homologous sequences other than insertion elements can serve as recombination sites in plasmid drug resistance gene amplification.

A plasmid (pRR983) was constructed which has a gene coding for neomycin and kanamycin resistance flanked by direct repeats of regions of homology which contain no known insertion sequences. pRR983 does not have any homologous IS1 sequences. Growth of Proteus mirabilis harboring pRR983 in medium containing high concentration of neomycin resulted in cells which were highly resistant to both neomycin and kanamycin. Plasmid DNA was analyzed by using restriction endonucleases. In most cases the neomycin resistance gene had been tandemly duplicated by using the homologous DNA sequences flanking the resistance gene as recombination sites. This is analogous to tandem duplication of drug resistance genes on NR1 using the two direct repeats of IS1 as recombination sites. The amplified plasmid DNA returned to its original structure by the deletion of amplified neomycin resistance determinants when the host cells were cultured without selection for high resistance to neomycin.