Xer site-specific recombination. DNA strand rejoining by recombinase XerC

Xer site-specific recombination functions in the stable maintenance of circular replicons in Escherichia coli. Each of two related recombinase proteins, XerC and XerD, cleaves a specific pair of DNA strands, exchanges them, and rejoins them to the partner DNA molecule during a complete recombination reaction. The rejoining activity of recombinase XerC has been analyzed using isolated covalent XerC-DNA complexes resulting from DNA cleavage reactions upon Holliday junction substrates. These covalent protein-DNA complexes are competent in the rejoining reaction, demonstrating that covalently bound XerC can catalyze strand rejoining in the absence of other proteins. This contrasts with a recombinase-mediated cleavage reaction, which requires the presence of both recombinases, the recombinase mediating catalysis at any given time requiring activation by the partner recombinase. In a recombining nucleoprotein complex, both cleavage and rejoining can occur prior to dissociation of the complex.     

Visualization of site-specific recombination catalyzed by a recombinase from Zygosaccharomyces rouxii in Arabidopsis thaliana

Excision of a DNA segment can occur in Arabidopsis thaliana by reciprocal recombination between two specific recombination sites (RSs) when the recombinase gene (R) from Zygosaccharomyces rouxii is expressed in the plant. To monitor recombination events, we generated several lines of transgenic Arabidopsis plants that carried a cryptic β-glucuronidase (GUS) reporter gene which was designed in such a way that expression of the reporter gene could be induced by R gene-mediated recombination. We also made several transgenic lines with an R gene linked to the 35S promoter of cauliflower mosaic virus. Each transgenic line carrying the cryptic reporter gene was crossed with each line carrying the R gene. Activity of GUS in F₁ and F₂ progeny was examined histochemically and recombination between two RSs was analyzed by Southern blotting and the polymerase chain reaction. In seedlings and plantlets of F₁ progeny and most of the F₂ progeny, a variety of patterns of activity of GUS, including sectorial chimerism in leaves, was observed. A small percentage of F₂ individuals exhibited GUS activity in the entire plant. This pattern of expression was ascribed to germinal recombination in the F₁ generation on the basis of an analysis of DNA structure by Southern blotting. These results indicate that R gene-mediated recombination can be induced in both somatic and germ cells of A. thaliana by cross-pollination of parental transgenic lines.     

The FLP recombinase of yeast catalyzes site-specific recombination in the Drosophila genome

We have transferred the site-specific recombination system of the yeast 2 micron plasmid, the FLP recombinase and its recombination targets (FRTs), into the genome of Drosophila. Flies were transformed with an FLP gene under the control of hsp70 regulatory sequences and with a white gene flanked by FRTs. The heat-induced recombinase catalyzes recombination between FRTs, causing loss of white (seen somatically as white patches in the eye) and, less frequently, gain of white (seen as dark-red patches). Loss and gain frequencies vary with the severity of the heat shock, and patterns of mosaicism vary with the developmental stage at which the heat shock is applied. The recombinase is also active in the germline, producing white-eyed and dark-red-eyed progeny.     

Engineering the mouse genome by site-specific recombination.

Site-specific recombination systems are powerful tools for introducing predetermined modifications into eukaryotic genomes. Recent advances allow the manipulation of chromosomal DNA in a spatially and temporally controlled manner in mice, offering unprecedented possibilities for studying mammalian genome function and for generating animal models for human diseases.     

Bacteriophage P1 site-specific recombination. Purification and properties of the Cre recombinase protein

Bacteriophage P1 encodes a site-specific recombination system that consists of a site (loxP) at which recombination occurs and a gene, cre, whose protein product is essential for recombination. The loxP-Cre recombination event can be studied in greater detail by the use of an in vitro system that efficiently carries out recombination between two loxP sites. This paper presents a purification and characterization of the Cre protein (Mr = 35,000), which is the only protein required for the in vitro reaction. No high energy cofactors are needed. The purified Cre protein binds to loxP-containing DNA and makes complexes that are resistant to heparin. Cre efficiently converts 70% of the DNA substrate to products and appears to act stoichiometrically. The action of Cre on a loxP2 supercoiled substrate containing two directly repeated loxP sites results in product molecules that are topologically unlinked. Several models to account for the ability of Cre to produce free supercoiled products are discussed.     

The Gin recombinase of phage Mu can catalyse site-specific recombination in plant protoplasts

Summary A mutant Gin recombinase of the phage Mu DNA inversion system was successfully expressed in Arabidopsis thaliana and tobacco protoplasts. Site-specific recombination was monitored both physically and biologically with the help of a recombination assay system in which expression of a -glucuronidase (gus) gene requires Gin-mediated recombination. We demonstrate that the wild-type Gin protein is not able to promote recombination in plant protoplasts, presumably because plant cells do not contain a protein that can substitute for the Escherichia coli FIS protein needed for full activity of wild-type Gin in E. coli. A FIS-independent Gin mutant protein on the other hand was efficient in promoting recombination on recombination substrates introduced transiently and on substrates stably integrated into the plant genome. We discuss the various advantages this system can provide for genetic manipulation of plant cells.     

Maternally expressed PGK-Cre transgene as a tool for early and uniform activation of the Cre site-specific recombinase

A transgenic mouse strain with early and uniform expres sion of the Cre site-specific recombinase is described. In this strain, PGK-Crem, Cre is driven by the early acting PGK-1 promoter, but, probably due to cis effects at the integration site, the recombinase is under dominant maternal control. When Cre is transmitted by PGK-Crem females mated to males that carry a reporter transgene flanked by loxP sites, even offspring that do not inherit PGK-Cre delete the target gene. It follows that in the PGK-Crem female Cre activity commences in the diploid phase of oogenesis. In PGK-Crem crosses complete recombination was observed in all organs, including testis and ovary. We prepared a mouse stock that is homozygous for PGK-Crem and at the albino (c) locus. This strain will be useful for the early and uniform induction of ectopic and dominant negative mutations, for the in vivo removal of selective elements from targeted mutations and in connection with the manipulation of targeted loci in 'knock in' and related technologies     

Cre/ lox site-specific recombination controls the excision of a transgene from the rice genome

The Cre/lox site-specific recombination controls the excision of a target DNA segment by recombination between two lox sites flanking it, mediated by the Cre recombinase. We have studied the functional expression of the Cre/lox system to excise a transgene from the rice genome. We developed transgenic plants carrying the target gene, hygromycin phosphotransferase (hpt) flanked by two lox sites and transgenic plants harboring the Cre gene. Each lox plant was crossed with each Cre plant reciprocally. In the Cre/lox hybrid plants, the Cre recombinase mediates recombination between two lox sites, resulting in excision of the hpt gene. The recombination event could be detected because it places the CaMV 35S promoter of the hpt gene adjacent to a promoterless gusA gene; as a result the gusA gene is activated and its expression could be visualized. In 73 Cre/lox hybrid plants from various crosses of T0 transgenic plants, 19 expressed GUS, and in 132 Cre/lox hybrid plants from crosses of T2 transgenic plants, 77 showed GUS expression. Molecular data proved the excision event occurred in all the GUS⁺ plants. Recombination occurred with high efficiency at the early germinal stage, or randomly during somatic development stages. Received. 2 April 2001 / Accepted: 29 June 2001     

Efficient gene-specific expression of cre recombinase in the mouse embryo by targeted insertion of a novel IRES-Cre cassette into endogenous loci.

Site specific recombinases have provided the experimental strategy necessary to modulate the expression of gene products in the mouse embryo. In this study we have exploited Cre recombinase to develop a widely applicable cell marking system which functions efficiently even at early post-implantation embryonic stages. Importantly, the techniques and reagents derived in this study are generally applicable to any recombinase driven approach, including strategies to temporally and spatially modulate endogenous or ectopic gene expression in the embryo. The cell marking scheme has two essential components which were derived as separate mouse lines. The first line carries a universal conditional lacZ reporter (UCR) locus which was prepared by using gene targeting in a novel approach to modify a ubiquitously expressed retroviral lacZ promoter trap insertion. The UCR locus is silent until it undergoes a Cre mediated DNA rearrangement to restore lacZ expression. To generate the Cre expressing allele, we outline a flexible strategy which requires the introduction of a novel IRES-Cre cassette into exon sequence of an endogenous locus by gene targeting. We successfully demonstrate this approach by generating a Cre expressing allele of the EphA2 gene, an Eph receptor protein tyrosine kinase expressed early in development. Analysis of double heterozygote embryos clearly demonstrates that Cre recombinase is expressed in vivo from the EphA2 IRES-Cre allele, and that the conditional reporter locus is efficiently restored in EphA2-expressing cells as early as 7.5 dpc. This cell marking experiment establishes the feasibility of expressing Cre recombinase from a single copy allele in the embryo and demonstrates the utility of the conditional reporter mouse which can be used in the analysis of any Cre expressing allele.     

A single vector containing modified cre recombinase and LOX recombination sequences for inducible tissue-specific amplification of gene expression

The selective alteration of the genome using Cre recombinase to target the rearrangement of genes flanked by LOX recognition sequences has required the use of two separate genetic constructs in trans, one containing cre and the other containing the gene of interest flanked by LOX sites. We have developed a strategy in which both the cre recombinase gene and LOX recombination sites may be cloned within a single vector in cis. This method uses a modified form of Cre (CREM) that contains alterations to the 5′ region including the introduction of a Kozak consensus sequence and insertion of a functional intron. This system allows for the inducible, tissue-specific activation or inactivation of gene expression in a single vector and can be utilized for the 300-fold amplification of gene expression from a weak promoter. This approach can be applied to targeting strategies for generating genetically altered mice and gene therapy.     

Xer site-specific recombination in vitro.

Two related recombinases, XerC and XerD, belonging to the lambda integrase family of enzymes, are required for Xer site-specific recombination in vivo. In order to understand the roles of these proteins in the overall reaction mechanism, an in vitro recombination system using a synthetic Holliday junction-containing substrate has been developed. Recombination of this substrate is efficient and requires both XerC and XerD. However, only exchange of one pair of strands, the one corresponding to the conversion of the Holliday junction intermediate back to the substrate, has been observed. Recombination reactions using XerC and XerD derivatives that are mutant in their presumptive catalytic residues, or are maltose-binding fusion recombinase derivatives, have demonstrated that this pair of strand exchanges is catalysed by XerC. The site of XerC-mediated cleavage has been located to between the last nucleotide of the XerC binding site and the first nucleotide of the central region. Cleavage at this site generates a free 5'-OH and a covalent complex between XerC and the 3' end of the DNA.     

Use of a yeast site-specific recombinase to generate embryonic mosaics in Drosophila.

An efficient method for generating embryonic mosaics using a yeast site-specific recombinase (FLP), under the control of a heat shock promoter, is described. FLP-recombinase can promote mitotic exchange between homologous chromosomes that contain FRT (FLP Recombination Target) sequences. To demonstrate the efficiency of FLP-recombinase to generate embryonic mosaics, clones of the recessive and cell autonomous mutation armadillo (arm), detected by their ability to differentiate ectopic denticles in the naked cuticle of each abdominal segment, have been induced. We have analyzed the parameters of FLP-recombinase induced embryonic mitotic recombination and have demonstrated that clones can be efficiently induced during the postblastoderm mitotic divisions. We discuss applications of this technique for the analyses of the roles of various mutations during embryonic patterning.     

Ligation activity of FLP recombinase. The strand ligation activity of a site-specific recombinase using an activated DNA substrate.

The FLP protein of the 2-microns plasmid of yeast belongs to the integrase family of site-specific recombinases whose members form a covalent bond between a conserved tyrosine of the recombinase and the 3'-phosphoryl group at the site of cleavage. We have made an activated DNA substrate and have shown that FLP can promote efficient strand ligation without forming a covalent intermediate with the DNA substrate. The strand ligation activity of FLP is independent of its ability to cleave DNA. Since site-specific recombinases are members of the larger class of topoisomerases, these findings may be generally applicable to other members of this class of enzymes.     

Cre-mediated somatic site-specific recombination in mice.

Conditional mutant mice equipped with heterologous recombination systems (Cre/lox or Flp/frt) are promising for studying tissue-specific gene function and for designing better models of human diseases. The utility of these mice depends on the cell target specificity, on the efficiency and on the control over timing of gene (in)activation. We have explored the utility of adenoviral vectors and transgenic mice expressing Cre under the control of tissue-specific promoters to achieve Cre/lox-mediated somatic recombination of the LacZ reporter gene, using a newly generated flox LacZ mouse strain. When adeno Cre viruses were administered via different routes, recombination and expression of LacZ was detected in a wide range of tissues. Whereas in liverbeta-galactosidase activity was quickly lost by turnover of expressing cells, even though the recombined allele was retained,beta-galactosidase in other tissues persisted for many months. Our data indicate that the flox LacZ transgenic line can be utilized effectively to monitor the level and functionality of Cre protein produced upon infection with adeno Cre virus or upon crossbreeding with different Cre transgenic lines.     

Characterization of site-specific recombination mediated by Cre recombinase during the development of erythropoietin producing CHO cell lines

The establishment of erythropoietin (EPO) producing Chinese hamster ovary (CHO) cell lines was conducted using Cre-mediated cassette exchange. The characterization of site-specific recombination mediated by Cre-recombinase during the cell line development was also performed. A total of six parental clones, which had various green fluorescence levels ranging from high to low and containing a single copy of insertion vector (pEGFP-m2), were screened. The EPO targeting vector (pIC-m2-EPO) was targeted into the 6 parental clones by Cre-mediated cassette exchange. Correctly targeted clones were obtained from 4 out of 6 parental clones with 0∼15% of targeting efficiencies. Moreover, there was a positive relationship (R² = 0.87) between fluorescence levels of the parental clones before Cre-mediated cassette exchange and specific EPO productivities (q _EPO ) of the correctly targeted clones after Cre-mediated cassette exchange. Therefore, it was verified that the chromosomal loci’s characteristic gene expression level was not modified even after cassette exchange mediated by Cre recombinase during the development of EPO producing CHO cell lines. This finding implies that the reproducible development of CHO cell lines largely producing a desired protein is expected to be achieved by Cre-mediated cassette exchange.     

Excision of the Frt-flanked neo (R) cassette from the CD19cre knock-in transgene reduces Cre-mediated recombination

Intercross of mice transgenic for Flp-recombinase with the CD19cre mouse strain leads to excision of the Frt-flanked neo ^R cassette from the CD19cre knock-in transgene. This significantly reduces the expression level of Cre by the CD19cre transgene and consequently decreases the extent of Cre-mediated recombination of loxP-flanked alleles, most likely due to the fact that this neo ^R cassette contains polyoma enhancer sequences. We wish to draw attention to this finding, since the Flp-deleter mouse strain is commonly used to remove Frt-flanked selection cassettes in vivo from conditional alleles. Therefore conditional alleles have to be separated from the Flp-deleter transgene by breeding before crosses with CD19cre mice are initiated. In addition our findings suggest that gene expression from the CD19 locus can be increased by the insertion of exogenous enhancer sequences, without compromising B cell specificity.