R46 encodes a site-specific recombination system interchangeable with the resolution function of TnA

Transposition of TnA onto the IncN plasmid R46 generates unstable DNA molecules. The R46::TnA recombinant plasmids undergo further DNA rearrangements which depend on the orientation in which the TnA element is inserted into the plasmid, and deletions and inversions of R46 and TnA sequences have been observed. Both types of rearrangement have the same specific endpoints, one within TnA and one located between the R46 coordinates, 36.0 and 37.0. The results are consistent with the operation of arecA-independent, site-specific recombination system utilizing, at least in part, the transposon cointegrate resolution system of TnA, together with R46-encoded functions. Data are presented that indicate that R46 encodes analogs of both theres site of TnA and itstnpR gene, although little homology between this element and the plasmid is apparent. Models for the TnA-induced generation of site-specific deletions and inversions upon transposition of TnA to R46 are presented.     

The R46 site-specific recombination system is a homologue of the Tn3 and gamma delta (Tn1000) cointegrate resolution system

The nucleotide sequence of the R46 site-specific recombination system has been determined. The organization of the recombination gene (perR46) and the site at which it acts (per site), together with the extensive sequence homology displayed with the tnpR genes and res sites of the transposons Tn3 and gamma delta (Tn1000), suggests that they have been derived from a Tn3-like element. These site-specific recombination functions of R46 play a role in plasmid maintenance.     

Chromosome engineering in Saccharomyces cerevisiae by using a site-specific recombination system of a yeast plasmid.

We have developed an effective method to delete or invert a chromosomal segment and to create reciprocal recombination between two nonhomologous chromosomes in Saccharomyces cerevisiae, using the site-specific recombination system of pSR1, a circular cryptic DNA plasmid resembling 2 microns DNA of S. cerevisiae but originating from another yeast, Zygosaccharomyces rouxii. A 2.1-kilobase-pair DNA fragment bearing the specific recombination site on the inverted repeats of pSR1 was inserted at target sites on a single or two different chromosomes of S. cerevisiae by using integrative vectors. The cells were then transformed with a plasmid bearing the R gene of pSR1, which encodes the site-specific recombination enzyme and is placed downstream of the GAL1 promoter. When the transformants were cultivated in galactose medium, the recombination enzyme produced by expression of the R gene created the modified chromosome(s) by recombination between two specific recombination sites inserted on the chromosome(s).     

Conjugation-independent, site-specific recombination at the oriT of the IncW plasmid R388 mediated by TrwC.

Plasmids containing a direct repeat of plasmid R388 oriT are capable of site-specific recombination, which results in deletion of the intervening DNA. This reaction occurs in the presence, but not in the absence, of the region of R388 implicated in DNA processing during conjugation. This region contains three genes, trwA, trwB, and trwC. By using mutants of each of the three genes, it was demonstrated that only trwC is required for the oriT-specific recombination. Further analysis showed that the N-terminal 272 amino acids of the protein are sufficient to catalyze recombination. TrwC is also capable of promoting intermolecular recombination between two plasmids containing oriT, suggesting that double-strand breaks in both plasmid DNAs are involved in the process. Additionally, intramolecular recombination between R388 oriT and R46 oriT did not occur in the presence of both nickases. This suggests that the half-reactions at each oriT are not productive if they occur separately; therefore, an interaction between the recombination complexes formed at each recombining site is required. This is the first report in which a nicking-closing enzyme involved in conjugal DNA transfer promotes oriT-specific recombination of double-stranded DNA in the absence of conjugation.     

Direct repetition of a 1.2 Md DNA sequence is involved in site-specific recombination by the P1 plasmid R68

R68.45, a mutant R68 plasmid, carries a 1.5 Md DNA insertion near its kanamycin-resistance region. This DNA consists of a 1.2 Md DNA repetition of neighbouring R68-DNA and a 0.3 Md “foreign” DNA fragment that is flanked by this direct DNA repeat. This fragment seems to be involved in the formation of R'68.45 plasmids. Duplication of the 1.2 Md DNA sequence is also involved in site-specific recombination events of RP4. This 1.2 Md DNA fragment has the properties of an IS sequence and is denoted IS8.     

Mutations in the DNA gyrB gene that are temperature sensitive for lambda site-specific recombination, Mu growth, and plasmid maintenance.

We report the isolation of two mutations in the gyrB gene of Escherichia coli K12 obtained from an initial selection for resistance to coumermycin A1 and a subsequent screening for bacteria that fail to support site-specific recombination of phage lambda, i.e., Him-. These two mutations have a temperature-sensitive Him- phenotype, supporting site-specific recombination efficiently at low temperature, but inefficiently at high temperatures. Like other Him mutants, the gyrB-him mutants fail to plate phage Mu; again this defect is observed only at high temperatures. Additional thermally sensitive characteristics have also been observed; growth of lambda as well as maintenance of the plasmids pBR322 and F' gal are reduced at high temperature. Restriction of foreign DNA imposed by a P1 prophage is also reduced in these mutants. The temperature-sensitive phenotypic characteristics imposed by both the gyrB-him-230(Ts) and gyrB-him-231(Ts) mutations correlate with in vitro studies that show decreased gyrase activity, especially at higher temperatures, and in vivo studies showing reduced supercoiling of lambda DNA in the mutants at high temperature.     

Transposon-mediated site-specific recombination: A defined in vitro system

Transposition of the insertion element γδ is thought to involve formation of intermediates in which the element is present at each junction between donor and target replicons. In vivo these cointegrate structures are rapidly converted to the end products of transposition by site-specific recombination at a defined sequence, res, that is present in each directly repeated γδ element. Resolvase, an element encoded protein of molecular weight 21,000 is required for cointegrate resolution. I have demonstrated site-specific recombination in vitro using purified resolvase and a cointegrate analog substrate. The required components of the system described here are resolvase, negatively supercoiled substrate DNA, buffer and Mg²⁺. Neither host-encoded products nor high energy cofactors appear to be required for resolution in vitro. Catenated, resolved molecules are the major products of the reaction. Elimination of Mg²⁺ from the reaction yields different product molecules. The in vitro system described here provides an opportunity for detailed study of the resolution reaction.     

Dissection of the transposition process: A transposon-encoded site-specific recombination system

Summary Deletions of transposons Tn1 and Tn3 that extend into a region of the transposon that specifies a 19,000 molecular weight protein, are unable to resolve presumptive transposition intermediates in recA strains of Escherichia coli. For example, when transposition of such mutant transposons occurs from replicon A to replicon B, cointegrate molecules containing A and B separated by directly repeated copies of the transposons are efficiently produced. Such cointegrates are stable in a recA strain, but are resolved within a recA ⁺ host into replicons A and B each containing a copy of the transposon. One mutant gives cointegrates that can be complemented to resolve when a wild type Tn3 is present in the same recA cell, whereas another gives cointegrates that cannot be resolved by complementation in trans. We suggest that the first such mutant still carries the sequences necessary for the recombination event whereas the latter has lost them.The presence of a Tn1/3 specified site-specific recombination system was confirmed by showing that naturally-occurring multimers of a Tn3 derivative of plasmid pMB8 can be efficiently resolved to monomers in a recA ^- strain, whereas dimers of pMB9 (a Tc^r derivative of pMB8) and two deleted Tn3 derivatives of pMB8 that are defective in the production of the 19,000 molecular weight protein, were both stably maintained as dimers in a recA ^- strain. Analysis of the ability of multimeric forms of other pMB8::Tn3 deletion derivatives to be stably propagated in a recA ^- strain, has allowed the localization of the Tn3 sequences necessary for the recombination event.     

Intragenic variation by site-specific recombination in the cryptic plasmid of Neisseria gonorrhoeae.

Cryptic plasmid DNA of Neisseria gonorrhoeae was found integrated into the gonococcal chromosome in both plasmid-bearing strains and plasmid-free strains. At several chromosomal locations only segments of the plasmid were found. However, in at least two strains an intact copy of the plasmid seemed to be present with the joints between the plasmid and the chromosomal DNA being located within the cppB gene of the cryptic plasmid. The cppB gene was shown to undergo a sequence-specific intragenic deletion. The deletion removed 54 base pairs, representing 18 amino acids, and did not affect the reading frame. It is proposed that the cryptic plasmid integrates into the chromosome and other gonococcal plasmids within this site-specific deletion region. Models for the site-specific recombination are presented.     

Cloning of industrial Saccharomyces 2-microns plasmid variants by in vivo site-specific recombination

Southern analyses defined several industrial Saccharomyces yeast strains with extensive 2-microns DNA polymorphism. Variants included insertions and deletions up to several hundred base pairs. To facilitate the investigation of yeast plasmid evolution we developed a novel method of cloning 2-microns plasmids by taking advantage of 2-microns circle in vivo site-specific recombination and an SMRI gene as a dominant selectable marker. This method can be applied to other organisms for the isolation of plasmid variants and provides a new approach to in vivo plasmid construction.     

A physical and genetic map of the IncN plasmid R46

A combined physical and genetic map of the conjugative IncN plasmid R46 was obtained by restriction endonuclease cleavage analysis, followed by the construction and analysis of deletion and recombinant derivatives. The genetic determinants for the antibiotic resistance and uv-protection phenotypes were located, as well as the regions necessary for plasmid replication and for conjugal transfer. The end points of the deletion giving rise to the R46 derivative pKM101 were localized.     

Development of disease-resistant marker-free tomato by R/RS site-specific recombination

The selection marker genes, imparting antibiotic or herbicide resistance, in the final transgenics have been criticized by the public and considered a hindrance in their commercialization. Multi-auto-transformation (MAT) vector system has been one of the strategies to produce marker-free transgenic plants without using selective chemicals and plant growth regulators (PGRs). In the study reported here, isopentenyltransferase (ipt) gene was used as a selection marker and wasabi defensin (WD) gene, isolated from Wasabia japonica as a target gene. WD was cloned from the binary vector, pEKH-WD to an ipt-type MAT vector, pMAT21 by gateway cloning and transferred to Agrobacterium tumefaciens strain EHA105. Infected cotyledons of tomato cv. Reiyo were cultured on PGR- and antibiotic-free MS medium. Adventitious shoots were developed by the explants infected with the pMAT21/wasabi defensin. The same PGR- and antibiotic-free MS medium was used in subcultures of the adventitious shoot lines (ASLs) to produce ipt and normal shoots. Approximately, 6 months after infection morphologically normal shoots were produced. Molecular analyses of the developed shoots confirmed the integration of gene of interest (WD) and excision of the selection marker (ipt). Expression of WD was confirmed by Northern blot and Western blot analyses. The marker-free transgenic plants exhibited enhanced resistance against Botrytis cinerea (gray mold), Alternaria solani (early blight), Fusarium oxysporum (Fusarium wilt) and Erysiphe lycopersici (powdery mildew).     

Location and cloning of the ultraviolet-sensitizing function from the chromosomally associated IncJ group plasmid, R391

The IncJ plasmid R391, which specifies a uv-sensitizing function, has been shown to be associated with chromosomal DNA. Deletions originating from Tn10 insertion into the kanamycin-resistance determinant of plasmid R391 gave rise to uv-resistant derivatives. This apparent linkage between the kanamycin-resistance determinant and the uv-sensitizing gene(s) was used to clone the uv-sensitizing function from plasmid R391 into pUR222. A recombinant plasmid containing both functions (KanR and Uvs+) was obtained. The uv-sensitizing function was mapped to a 4-kb EcoRI fragment.     

Characterization of the maintenance functions of IncFIV plasmid R124

The genetic arrangement of the regions involved in R124 replication and incompatibility have been located and their homology to the IncFI basic replicons has been assessed. We show that R124 has homology with all three basic replicons, RepFIA, RepFIB, and RepFIC, and that these regions, FIVA, RepFIVB, and RepFIVC, are widely separated on the R124 genome. Cloning of autonomously replicating fragments has shown that RepFIVB and RepFIVC are functional in R124 and express incompatibility. The FIVA region was unable to form a functional replicon and when cloned into pUC8 lacked incompatibility activity. A fourth region of R124 was identified, which although not essential for replication stabilized mini-R124 plasmid replication and exhibited incompatibility with R124. This region, designated IncIV, showed no homology to RepFIA, RepFIB, or RepFIC. Incompatibility expression of IncIV required only the EcoRI fragment E13 but the strength of the reaction was modified in the presence of other fragments. The replication and incompatibility properties of an R124 deletion derivative indicated that R124 can switch its replication to either RepFIVB or RepFIVC when in the presence of an incompatible plasmid. The ambiguous incompatibility reactions reported for R124 is a result of the expression of the two functional replicons, RepFIVB and RepFIVC, and that expressed by IncIV.     

Generation of selectable marker-free transgenic eggplant resistant to Alternaria solani using the R/RS site-specific recombination system

Key message

Marker-free transgenic eggplants, exhibiting enhanced resistance to Alternaria solani , can be generated on plant growth regulators (PGRs)- and antibiotic-free MS medium employing the multi-auto-transformation (MAT) vector, pMAT21 - wasabi defensin , wherein isopentenyl transferase ( ipt ) gene is used as a positive selection marker.

Abstract

Use of the selection marker genes conferring antibiotic or herbicide resistance in transgenic plants has been considered a serious problem for environment and the public. Multi-auto-transformation (MAT) vector system has been one of the tools to excise the selection marker gene and produce marker-free transgenic plants. Ipt gene was used as a selection marker gene. Wasabi defensin gene, isolated from Wasabia japonica (a Japanese horseradish which has been a potential source of antimicrobial proteins), was used as a gene of interest. Wasabi defensin gene was cloned from the binary vector, pEKH-WD, to an ipt-type MAT vector, pMAT21, by gateway cloning technology and transferred to Agrobacterium tumefaciens strain EHA105. Infected cotyledon explants of eggplant were cultured on PGRs- and antibiotic-free MS medium. Extreme shooty phenotype/ipt shoots were produced by the explants infected with the pMAT21-wasabi defensin (WD). The same PGRs- and antibiotic-free MS medium was used in subcultures of the ipt shoots. Subsequently, morphologically normal shoots emerged from the Ipt shoots. Molecular analyses of genomic DNA from transgenic plants confirmed the integration of the WD gene and excision of the selection marker (ipt gene). Expression of the WD gene was confirmed by RT-PCR and Northern blot analyses. In vitro whole plant and detached leaf assay of the marker-free transgenic plants exhibited enhanced resistance against Alternaria solani.