A site-specific recombination function in Staphylococcus aureus plasmids.

All known small staphylococcal plasmids possess one or two recombination sites at which site-specific cointegrate formation occurs. One of these sites, RSA, is present on two small multicopy plasmids, pT181 and pE194; it consists of 24 base pairs of identity in the two plasmids, the "core," flanked by some 50 base pairs of decreasing homology. Here we show that recombination at RSA is recA independent and is mediated by a plasmid-encoded, trans-acting protein, Pre (plasmid recombination). Pre-mediated recombination is site specific in that it occurs within the core sequence of RSA in a recA1 host. Recombination also occurs between two intramolecular RSA sites. Unlike site-specific recombination systems encoded by other plasmids, Pre-RSA is not involved in plasmid maintenance.     

Regulation of copy number and stability of phage λ derived pTCλ1 plasmid in the light of the dimer/multimer catastrophe hypothesis

The dimer catastrophe hypothesis has been proposed previously to explain instability of multicopy plasmids whose partitioning is random, contrary to low copy number plasmids which are stably maintained and actively partitioned. Until now, this hypothesis has been investigated using multicopy ColE1 plasmids. However, for more detailed testing of the dimer/multimer catastrophe hypothesis, one should use a plasmid which can be maintained at either low or high copy number and still possesses the same mechanism of replication regulation. Here we used a modified lambda plasmid, pTC lambda 1. The advantage of this plasmid is that it can be maintained at different copy numbers depending on the concentration of an inducer which stimulates the initiation of plasmid replication. Results obtained with this plasmid in recombination proficient and deficient cells generally support the dimer/multimer catastrophe hypothesis, but also suggest some modification in the model.     

Characteristics of RecA-independent recombination of plasmids in E. coli cells producing restriction endonuclease EcoRI

The restriction endonuclease EcoRI dependent recombination of compatible plasmids has been studied in RecA cells of Escherichia coli. Plasmid RP4 and the isogenic ColE1 type plasmids pSA14 or pSA25, differing in restriction-modification RM EcoRI genes, have been used to study this type of recombination. EcoRI dependent recombination of plasmids is demonstrated in RecA cells and, thus, is independent of general system of homologous recombination. The classes of recombinant plasmids isolated from RecA cells differ from the classes isolated from wild type cells. Levels of tetracycline resistance conferred by plasmid RP4 are shown to be dependent on the alleles of RecA+ gene, being extremely low in RecA cells. This property is demonstrated to be useful for obtaining the multicopy recombinant plasmids resulting from EcoRI dependent recombination in RecA cells of Escherichia coli.     

Site-specific recombination between ColE1 tcer and NTP16 nmr sites in vivo

The site-specific recombination system used by multicopy plasmids of the ColE1 family uses two identical plasmid-encoded recombination sites and four bacterial proteins to catalyze the recombination reaction. In the case of the Escherichia coli plasmid ColE1, the recombination site, cer, is a 280 by DNA sequence which is acted on by the products of the argR, pepA, xerC and xerD genes. We have constructed a model system to study this recombination system, using tandemly repeated recombination sites from the plasmids ColE1 and NTP16. These plasmids have allowed us precisely to define the region of strand exchange during site-specific recombination, and to derive a model for cer intramolecular site-specific recombination.     

Site-specific recombination between ColE1 tcer and NTP16 nmr sites in vivo

The site-specific recombination system used by multicopy plasmids of the ColE1 family uses two identical plasmid-encoded recombination sites and four bacterial proteins to catalyze the recombination reaction. In the case of the Escherichia coli plasmid ColE1, the recombination site, cer, is a 280 by DNA sequence which is acted on by the products of the argR, pepA, xerC and xerD genes. We have constructed a model system to study this recombination system, using tandemly repeated recombination sites from the plasmids ColE1 and NTP16. These plasmids have allowed us precisely to define the region of strand exchange during site-specific recombination, and to derive a model for cer intramolecular site-specific recombination.     

Plasmid recombination stimulated by restriction endonuclease EcoRI in vivo: formation of recombinant plasmids in recA+-cells of E. coli

The possible participation of restriction endonuclease EcoRI in recombination of compatible nonhomologous plasmids in E. coli cells has been studied. To study the process, plasmids RP4 and R245 have been transferred by conjugation into the recipient cells of E. coli harbouring one of isogenic plasmids, pSA14 and pSA25, different for the genes coding restriction endonuclease EcoRI. The genetic analysis of transconjugant phenotypes, coded by the plasmids, has permitted to register the recombinant plasmids after compatibility of parent plasmids in E. coli cells. Recombination of plasmid RP4 with the plasmid pSA14, carrying EcoRI genes, has been registered in E. coli cells, producing the restriction endonuclease, while plasmid recombination has not been found in the cells harbouring plasmid pSA25, isogenic for all genes, except for EcoRI genes, with plasmid pSA14. Restriction endonuclease EcoRI is concluded to stimulate site specific recombination of nonhomologous compatible plasmids in vivo. EcoRI-mediated recombination of plasmid R245 with plasmid pSA14 is discussed.     

Escherichia coli XerC recombinase is required for chromosomal segregation at cell division

XerC is a site-specific recombinase of the bacteriophage lambda integrase family that is encoded by xerC at 3700 kbp on the genetic map of Escherichia coli. The protein was originally identified through its role in converting multimers of plasmid ColE1 to monomers; only monomers are stably inherited. Here we demonstrate that XerC also has a role in the segregation of replicated chromosomes at cell division. xerC mutants form filaments with aberrant nucleotides that appear unable to partition correctly. A DNA segment (dif) from the replication terminus region of the E. coli chromosome binds XerC and acts as a substrate for XerC-mediated site-specific recombination when inserted into multicopy plasmids. This dif segment contains a region of 28 bp with sequence similarity to the crossover region of ColE1 cer. The cell division phenotype of xerC mutants is suppressed in strains deficient in homologous recombination, suggesting that the role of XerC/dif in chromosomal metabolism is to convert any chromosomal multimers (arising through homologous recombination) to monomers.     

In vivo transfer of chromosomal mutations onto multicopy plasmids by transduction with bacteriophage P1

A technique is presented by which chromosomal mutations may be efficiently transferred onto chimeric multicopy plasmids in vivo. The technique employs the transduction of plasmids using bacteriophage P1 as vector. The utility of this method was demonstrated by cloning a chromosomal ompR mutation of Escherichia coli K-12. The high-frequency transduction of the chimeric plasmid appeared to be dependent on its integration into the chromosome by homologous recombination. The results also suggest that the plasmid was transduced as part of the chromosome and resolved from its integrated state in the recipient cell, resulting in a high yield of mutant plasmid segregants.     

Formation of Rhizobium phaseoli symbiotic plasmids by genetic recombination

We report here the formation of symbiotic plasmids (pSyms), by genetic recombination between rearranged pSyms, which lack symbiotic information, and resistance plasmids carrying parts of different symbiotic plasmids (R's). This recombination was found to occur both between plasmids derived from different Rhizobium phaseoli isolates, and between plasmids derived from strains obtained from the same original isolate. We also present evidence on the formation of a functional symbiotic plasmid by recombination of an R', carrying nif and nod genes from strain CFN42, and an indigenous plasmid present in this strain (pCFN42e), which was thought to be unrelated to its symbiotic plasmid (pCFN42d). These data are discussed with respect to the stability and transfer of Rhizobium symbiotic information.     

In vivo intermolecular recombination in Escherichia coli: application to plasmid constructions

Repair of a double-strand break (DSB) was investigated by intermolecular recombination in Escherichia coli (Ec) recBC sbcBC cells with restriction enzyme-cleaved model plasmids. Circular plasmids were generated when a linearized plasmid (vector) containing an origin of replication was co-transformed with a DNA fragment (template) containing a homologous sequence. The influence of the position of the DSB in the vector was analyzed using templates which contain various genetic markers, non-homologous sequences and/or deletions relative to the vector. In all cases, when a DSB occurs within a marker, this marker is lost in the resulting plasmid, whereas markers flanked by homologous regions located in the vicinity of a DSB are transmitted. Insertions (deletions), substitutions and shuffling of genetic markers are possible by in vivo recombination using Ec and can be applied to plasmid constructions. It is shown that recombination can occur from both template ends or from one vector and one template end. A D-loop nuclease is suggested to participate in the resolution of the recombination intermediates     

Use of interplasmid recombination to generate stable selectable markers for yeast transformation: application to studies of actin gene control

A plasmid recombination system has been developed that relies upon interplasmid exchanges for yeast cell viability. Two types of plasmids, one carrying the LEU2 allele inserted within yeast actin gene sequences and the other carrying 2-microns plasmid DNA and an intact actin gene, were constructed. Neither plasmid alone yielded transformants in the haploid Leu- strain AH22, but when cotransformed, a number of colonies were obtained. Southern blot analysis revealed that transformants arose because of recombination events within the homologous actin sequences that transferred the LEU2 gene to the actin gene on the 2-microns plasmid. The recombinant plasmids could be recovered, and sequence analysis of one recombination site revealed that the exchange event was faithful at the nucleotide level. The resulting recombinant plasmids carried a defective actin gene and presumably arose because of a double-crossover event. Deletion mutations that prevented actin gene expression on one donor plasmid enabled the recovery at a high frequency of transformants resulting primarily from single-crossover events between the two plasmids. This was presumably because such events no longer generated an intact actin gene on a multicopy plasmid. Infrequently a transformant from a plasmid with an intact gene was recovered, but in these cases the plasmid was not present in multiple copies. These cells exhibited a slower growth rate, and Northern blot analysis revealed an elevated level of actin mRNA.     

Structural plasmid evolution as a result of coupled recombinations at bom and cer sites

We have studied the recombination of plasmids bearing bom and cer sites. The bom ( basis of mobilization) site is required for conjugative transfer, while the cer ( Col E1 resolution) site is involved in the resolution of plasmid multimers, which increases plasmid stability. We constructed a pair of parent plasmids in such a way as to allow us select clones containing recombinant plasmids directly. Clone selection was based on the McrA sensitivity of recipient host DNA modified by M. Ecl18kI, which is encoded by one of the parent plasmids. The recombinant plasmid contains segments originating from both parental DNAs, which are bounded by bom and cer sites. Its structure is in accordance with our previously proposed model for recombination mediated by bom and cer sequences. The frequency of recombinant plasmid formation coincided with the frequency of recombination at the bom site. We also show that bom-mediated recombination in trans, unlike in cis, is independent of other genetic determinants on the conjugative plasmids.     

Polyphosphate kinase is a component of the Escherichia coli RNA degradosome

Xer site-specific recombination functions in the stable inheritance of circular plasmids and bacterial chromosomes. Two related recombinases, XerC and XerD, mediate this recombination, which 'undoes' the potential damage of homologous recombination. Xer recombination on natural plasmid sites is preferentially intramolecular, converting plasmid multimers to monomers. In contrast, recombination at the Escherichia coli recombination site, dif , occurs both intermolecularly and intramolecularly, at least when dif is inserted into a multicopy plasmid. Here the DNA sequence features of a family of core recombination sites in which the XerC- and XerD-binding sites, which are separated by 6 bp, were analysed in order to ascertain what determines whether recombination will be preferentially intramolecular, or will occur both within and between molecules. Sequence changes in either the XerC- or XerD-binding site can alter the recombination outcome. Preferential intramolecular recombination between a pair of recombination sites requires additional accessory DNA sequences and accessory recombination proteins and is correlated with reduced affinities of recombinase binding to recombination core sites, reduced XerC-mediated cleavage in vitro , and an apparent increased overall bending in recombinase–core-site complexes.     

Five genes involved in self-transmission of pSN22, a Streptomyces plasmid.

An 11-kbp multicopy plasmid, pSN22, was isolated from Streptomyces nigrifaciens SN22. pSN22 is self-transmissible (conjugative), is maintained stably in S. lividans, and forms pocks in a wide range of Streptomyces strains. Mutational analyses showed that a fragment of pSN22 contained five genes involved in plasmid transfer and pock formation. traB was essential for plasmid transfer. traA was required for pock formation, but not for plasmid transfer. spdA or spdB were concerned with pock size; mutations in these genes decreased pock size. The fifth gene, traR, could be deleted together with other genes to give nontransmissible plasmids, but plasmids with insertions or deletions only within traR became nonviable. traR is probably needed to counterbalance the lethal effects of another plasmid gene. Transfer of pSN22 promoted the cotransfer of nontransmissible plasmids and enhanced chromosome recombination between the host and recipient strains, suggesting that plasmid transfer accompanies cytoplasmic mixing.     

Recombination within the yeast plasmid 2mu circle is site-specific

The multicopy yeast plasmid, 2mu circle, encodes a specialized recombination system. It contains two regions, each 599 bp in length, that are precise inverted repeats of each other and between which recombination occurs readily. In addition, this recombination requires the product of a 2mu circle gene, designated FLP. By examining the products of FLP-mediated recombination of plasmids containing single insertions within one of the repeated regions, we show that this recombination occurs only at a specific site within the repeat. This result was confirmed from analysis of the ability of plasmids containing various deletions within one of the repeated regions to serve as substrates for FLP-mediated recombination. These experiments limit the recombination site to a sequence of less than 65 bp. In addition, by mutational analysis of the recombination potential of a hybrid plasmid containing the entire 2mu circle genome, we have shown that FLP is only the 2mu circle gene necessary for this site-specific recombination. Finally, we describe a sensitive assay for recombination between the repeated sequences of 2mu circle; using it, we demonstrate that even in the absence of FLP gene product, recombination between the repeats occurs at a low but detectable level during meiosis.     

Multicopy single-stranded DNA of Escherichia coli enhances mutation and recombination frequencies by titrating MutS protein

Multicopy single-stranded DNA (msDNA) molecules consist of single-stranded DNA covalently linked to RNA. In Escherichia coli , such molecules are encoded by genetic elements called retrons. The DNA moieties of msDNAs have characteristic stem-loop structures, and most of these structures contain mismatched base pairs. Previously, we showed that retrons encoding msDNAs with mismatched base pairs are mutagenic when present in multicopy plasmids. In this study we show that such msDNAs, in a similar manner to genetic defects in mismatch repair, increase the frequency of interspecies recombination in matings between Salmonella typhimurium and E. coli . To demonstrate interference with mismatch repair by msDNA, we show that the addition of a plasmid containing the gene for MutS protein suppresses the mutagenic and recombinogenic effects of msDNAs. We also show that in mutS mutants, msDNA does not increase the frequency of either mutations or interspecies recombination. We conclude from these findings that the mutagenic and recombinogenic effects of msDNAs are due to titrating out MutS protein.     

Epstein-Barr virus-derived plasmids replicate only once per cell cycle and are not amplified after entry into cells.

Some possible ways in which replication of plasmids containing the Epstein-Barr virus (EBV) plasmid maintenance origin, oriP, might be controlled were investigated. Virtually all plasmid molecules were found to replicate no more than once per cell cycle, whether replication was observed after stable introduction of the plasmids into cells by drug selection or during the first few cell divisions after introducing the DNA into cells. The presence in the cells of excess amounts of EBNA1, the only viral protein needed for oriP function, did not increase the number of oriP-replicated plasmids maintained by cells under selection. In the cell lines studied, EBNA1 and oriP seem to lack the capacity to override the cellular controls that limit DNA replication to one initiation event per DNA molecule per S phase. The multicopy status of EBV-derived, selectable plasmids appears to result from the initial uptake by cells of large numbers of plasmid molecules, the efficient maintenance of these plasmids, and the pressure of genetic selection against plasmid loss. Other unknown controls must be responsible for the amplification of EBV genomes soon after latent infection of cells.