A genome-wide analysis of FRT-like sequences in the human genome

Efficient and precise genome manipulations can be achieved by the Flp/FRT system of site-specific DNA recombination. Applications of this system are limited, however, to cases when target sites for Flp recombinase, FRT sites, are pre-introduced into a genome locale of interest. To expand use of the Flp/FRT system in genome engineering, variants of Flp recombinase can be evolved to recognize pre-existing genomic sequences that resemble FRT and thus can serve as recombination sites. To understand the distribution and sequence properties of genomic FRT-like sites, we performed a genome-wide analysis of FRT-like sites in the human genome using the experimentally-derived parameters. Out of 642,151 identified FRT-like sequences, 581,157 sequences were unique and 12,452 sequences had at least one exact duplicate. Duplicated FRT-like sequences are located mostly within LINE1, but also within LTRs of endogenous retroviruses, Alu repeats and other repetitive DNA sequences. The unique FRT-like sequences were classified based on the number of matches to FRT within the first four proximal bases pairs of the Flp binding elements of FRT and the nature of mismatched base pairs in the same region. The data obtained will be useful for the emerging field of genome engineering.     

Site-specific cassette exchange and germline transmission with mouse ES cells expressing phiC31 integrase

Currently two site-specific recombinases are available for engineering the mouse genome: Cre from P1 phage and Flp from yeast. Both enzymes catalyze recombination between two 34-base pair recognition sites, lox and FRT, respectively, resulting in excision, inversion, or translocation of DNA sequences depending upon the location and the orientation of the recognition sites. Furthermore, strategies have been designed to achieve site-specific insertion or cassette exchange. The problem with both recombinase systems is that when they insert a circular DNA into the genome (trans event), two cis-positioned recognition sites are created, which are immediate substrates for excision. To stabilize the trans event, functional mutant recognition sites had to be identified. None of the systems, however, allowed efficient selection-free identification of insertion or cassette exchange. Recently, an integrase from Streptomyces phage phiC31 has been shown to function in Schizosaccharomyces pombe and mammalian cells. This enzyme recombines between two heterotypic sites: attB and attP. The product sites of the recombination event (attL and attR) are not substrates for the integrase. Therefore, the phiC31 integrase is ideal to facilitate site-specific insertions into the mammalian genome.     

Recombinase-mediated cassette exchange (RMCE) and BAC engineering via VCre/VloxP and SCre/SloxP systems

Site-specific recombination is a powerful biotechnological tool for genome engineering. We previously reported two novel site-specific recombination systems, VCre/VloxP and SCre/SloxP, that do not cross-react with Cre/loxP and Flp/FRT in culture cells and mouse embryonic stem (ES) cells. In this study, a site-specific recombination assay in Escherichia coli was used to examine the activity of mutant VCre (H314L and Y349F) and mutant SCre (H317L and Y352F), in which both mutated residues lie within the active center of Cre recombination. The site-specific recombination activity of both mutants was significantly decreased. Recombinase-mediated cassette exchange (RMCE) using VloxP and the Vlox2272 mutant site was performed in E. coli by introducing a cassette bearing VloxP and Vlox2272 into a recipient plasmid bearing the same sites. RMCE using SloxP and Slox2272 was also performed by SCre recombinase. Moreover, BAC engineering via Red recombination and VCre/VloxP were demonstrated. First, the DNA cassette for modification was introduced into a BAC clone via Red recombination; second, the antibiotics resistance gene flanked by VloxP was removed from the BAC clone by induction of VCre recombinase. Such site-specific recombination systems may effectively be used in combination with other site-specific recombination systems or engineering tools (e.g., Red recombination).     

VCre/VloxP and SCre/SloxP: new site-specific recombination systems for genome engineering

We developed two new site-specific recombination systems named VCre/VloxP and SCre/SloxP for genome engineering. Their recognition sites are different from Cre recognition sites because VCre and SCre recombinases share less protein similarity with Cre, even though the basic 13-8-13 structures of their recognition sites are identical. Mutant VloxP and SloxP, which have the same uses as mutant loxP, were also developed. VCre/VloxP and SCre/SloxP in combination with Cre/loxP and Flp/FRT systems can serve as powerful tools for genome engineering, especially when used to genetically modify both alleles of a single gene in mouse and human cells.     

Geometry of site alignment during int family recombination: antiparallel synapsis by the Flp recombinase

The Flp site-specific recombinase functions in the copy number amplification of the yeast 2 microm plasmid. The recombination reaction is catalyzed by four monomers of Flp bound to two separate, but identical, recombination sites (FRT sites) and occurs in two sequential pairs of strand exchanges. The relative orientation of the two recombination sites during synapsis was examined. Topoisomerase relaxation and nick ligation were used to detect topological nodes introduced by the synapse prior to the chemical steps of recombination. A single negative supercoil was found to be trapped by Flp in substrates with inverted FRT sites whereas no trapped supercoils were observed with direct repeats. The topology of products resulting from Flp-mediated recombination adjacent to a well characterised synapse, that of Tn3 resolvase/res, was analyzed. The deletion and inversion reactions yielded the four noded catenane and the three noded knot, respectively, as the simplest and the most abundant products. The linking number change introduced by the Flp-mediated inversion reaction was determined to be +/-2. The most parsimonious explanation of these results is that Flp aligns its recombination sites with antiparallel geometry. The majority of synapses appear to occur without entrapment of additional random plectonemic DNA supercoils between the sites and no additional crossings are introduced as a result of the chemical steps of recombination.     

Involvement of the inverted repeat of the yeast 2-micron plasmid in Flp site-specific and RAD52-dependent homologous recombination

Site-specific recombination within the Saccharomyces cerevisiae 2-micron DNA plasmid is catalyzed by the Flp recombinase at specific Flp Recognition Target (FRT) sites, which lie near the center of two precise 599-bp Inverted Repeats (IRs). However, the role of IR DNA sequences other than the FRT itself for the function of the Flp reaction in vivo is not known. In the present work we report that recombination efficiency differs depending on whether the FRT or the entire IR serves as the substrate for Flp. We also provide evidence for the involvement of the IR in RAD52-dependent homologous recombination. In contrast, the catalysis of site-specific recombination between two FRTs does not require the function of RAD52. The efficiency of Flp site-specific recombination between two IRs cloned in the same orientation is about one hundred times higher than that obtained when only the two FRTs are present. Moreover, we demonstrate that a single IR can activate RAD52-dependent homologous recombination between two flanking DNA regions, providing new insights into the role of the IR as a substrate for recombination and a new experimental tool with which to study the molecular mechanism of homologous recombination. Received: 14 June 1999 / Accepted: 3 November 1999     

Symmetric DNA sites are functionally asymmetric within Flp and Cre site-specific DNA recombination synapses

Flp and Cre-mediated recombination on symmetrized FRT and loxP sites, respectively, in circular plasmid substrates yield both DNA inversion and deletion. However, upon sequestering three negative supercoils outside the recombination complex using the resII-resIII synapse formed by Tn3 resolvase and the LER synapse formed by phage Mu transposase in the case of Flp and Cre, respectively, the reactions are channeled towards inversion at the expense of deletion. The inversion product is a trefoil, its unique topology being conferred by the external resolvase or LER synapse. Thus, Flp and Cre assign their symmetrized substrates a strictly antiparallel orientation with respect to strand cleavage and exchange. These conclusions are supported by the product profiles from tethered parallel and antiparallel native FRT sites in dilution and competition assays. Furthermore, the observed recombination bias favoring deletion over inversion in a nicked circular substrate containing two symmetrized FRT sites is consistent with the predictions from Monte Carlo simulations based on antiparallel synapsis of the DNA partners.     

Specific targeted integration of kanamycin resistance-associated nonselectable DNA in the genome of the yeast Saccharomyces cerevisiae

Sophisticated genome manipulation requires the possibility to modify any intergenic or intragenic DNA sequence at will, without leaving large amounts of undesired vector DNA at the site of alteration. To this end, a series of vectors was developed from a previous gene knockout plasmid system to integrate nonselectable foreign DNA at any desired genomic location in yeast, with a minimum amount of residual plasmid DNA. These vectors have two mutated Flp recognition targets (FRT) sequences flanking the KanMX4 gene and multiple sites for subcloning the DNA fragment to be integrated. The selectable marker can be recycled by Flp site-specific excision between the identical FRTs, thereby allowing the integration of further DNA fragments. With this system, the NLS-tetR-GFP and DsRed genes were successfully integrated at the thr1 locus, and the RVB1 gene was tagged at the C-terminus with the V5-epitope-6-histidine tag. This plasmid system provides for a new molecular tool to integrate any DNA fragment at any genome location in [cir+] yeast strains. Moreover, the system can be extrapolated to other eukaryotic cells in which the FLP/FRT system functions efficiently.     

Activity of yeast FLP recombinase in maize and rice protoplasts.

We have demonstrated that a yeast FLP/FRT site-specific recombination system functions in maize and rice protoplasts. FLP recombinase activity was monitored by reactivation of beta-glucuronidase (GUS) expression from vectors containing the gusA gene inactivated by insertion of two FRTs (FLP recombination targets) and a 1.31 kb DNA fragment. The stimulation of GUS activity in protoplasts cotransformed with vectors containing FRT inactivated gusA gene and a chimeric FLP gene depended on both the expression of the FLP recombinase and the presence and structure of the FRT sites. The FLP enzyme could mediate inter- and intramolecular recombination in plant protoplasts. These results provide evidence that a yeast recombination system can function efficiently in plant cells, and that its performance can be manipulated by structural modification of the FRT sites.     

A broad-host-range in vivo pop-out and amplification system for generating large quantities of 50-to 100-kb genomic fragments for direct DNA sequencing

A prerequisite for sequencing large genomes is to obtain 30- to 150-kb genomic DNA fragments in adequate quantity. Previously, we developed a system which enables one to excise and amplify in vivo such segments directly from the Escherichia coli genome. This system, which employed the yeast Flp/FRTelements for excision and the plasmid R6K-based replication machinery for DNA amplification, permits one to bypass conventional cloning [Pósfai et al. (1994) Nucleic Acids Res. 22, 2392–2398]. To extend the applicability of such a system to many species, we describe here a broad-host-range (bhr) system in which the amplification of the excised DNA fragment depends on the oriV element and the Rep (TrfA) protein from the promiscuous RK2/RP4 plasmid.We have constructed insertion plasmids which carry the FRT and oriV sites. To introduce such plasmids into the appropriate position in the host genome, a short genomic sequence homologous to this position was cloned into the multiple cloning site (MCS) of the FRT/oriVinsertion plasmid and then recombined into this position in the genome by RecA-mediated recombination. In such a manner, many strains with single FRT/oriV insertions at various positions could be generated. Subsequent genetic crosses or phage transduction allow two neighboring FRT/oriVsites (less than 150 kb apart) to be brought into a single genome. In the present report, the lacZ and phoB sites, which are 51 kb apart in the E. coli genome, were used for the introduction of the FRT/oriV sites.To deliver the Flp (excision) and Rep (amplification) functions in trans, the yeast FLP and RK2 plasmid trfA genes were placed under the control of the P_tet promoter/operator which is tightly regulated by the TetR repressor. The addition of heated chlortetracycline (cTc) inactivates TetR, turning on the synthesis of Flp and TrfA, which respectively, execute (i) excision of the 51-kb genomic segment between the two FRTsites (in lacZ and in phoB), and (ii) its amplification.     

phiC31-integrase-mediated, site-specific integration of transgenes in the silkworm, Bombyx mori (Lepidoptera: Bombycidae)

Transgenic silkworms can be useful for investigating the functions of genes in the post-genomic era. However, the common method of using a transposon as an insertion tool may result in the random integration of a foreign gene into the genome and suffer from a strong position effect. To overcome these problems, it is necessary to develop a site-specific integration system. It is known that phiC31 integrase has the capacity to mediate recombination between the target sequences attP and attB. To test the availability of site-specific integration in the silkworm, we first examined the efficiency of recombination between the target sites of the two plasmids in silkworm embryos and found that the frequency of recombination was very high. Then we constructed a host strain that possessed the target sequence attP using the common method. We injected the donor plasmid together with the phiC31 integrase mRNA into the embryos of the host strain and obtained positive lines. Structural analysis of the lines showed that site-specific integration occurred by recombination between the genomic attP site and the attB site of the donor plasmid. We can conclude from the results that phiC31 integrase has the ability to mediate the site-specific integration of transgenes into the silkworm chromosome.     

Use of green fluorescent protein/Flp recombinase fusion protein and flow cytometric sorting to enrich for cells undergoing Flp-mediated recombination

Flp recombinase has been used extensively for in vivo manipulation of eukaryotic DNA at specific sequences designated as FRT sites. We developed a method to use Flp-mediated recombination without the need for drug resistance or metabolic selection of cells in which recombination has occurred. We generated expression plasmids directing expression of fusion proteins consisting of Flp recombinase and green fluorescent protein (GFP) coding sequences. When the plasmids were introduced into K562 cells containing Flp recombinase substrates and transfected cells were selected for by flow cytometric sorting, GFP-positive cells were enriched 5- to 30-fold for Flp-mediated recombination events compared with unsorted cells. These studies demonstrate the usefulness of GFP/Flp recombinase fusion proteins to manipulate chromosomal DNA in vivo without requiring drug resistance or metabolic marker genes.     

FLP recombinase-mediated site-specific recombination in silkworm, Bombyx mori

A comprehensive understanding of gene function and the production of site-specific genetically modified mutants are two major goals of genetic engineering in the post-genomic era. Although site-specific recombination systems have been powerful tools for genome manipulation of many organisms, they have not yet been established for use in the manipulation of the silkworm Bombyx mori genome. In this study, we achieved site-specific excision of a target gene at predefined chromosomal sites in the silkworm using a FLP/FRT site-specific recombination system. We first constructed two stable transgenic target silkworm strains that both contain a single copy of the transgene construct comprising a target gene expression cassette flanked by FRT sites. Using pre-blastoderm microinjection of a FLP recombinase helper expression vector, 32 G3 site-specific recombinant transgenic individuals were isolated from five of 143 broods. The average frequency of FLP recombinase-mediated site-specific excision in the two target strains genome was approximately 3.5%. This study shows that it is feasible to achieve site-specific recombination in silkworms using the FLP/FRT system. We conclude that the FLP/FRT system is a useful tool for genome manipulation in the silkworm. Furthermore, this is the first reported use of the FLP/FRT system for the genetic manipulation of a lepidopteran genome and thus provides a useful reference for the establishment of genome manipulation technologies in other lepidopteran species.     

Mammalian genomes contain active recombinase recognition sites

Recombinases derived from microorganisms mediate efficient site-specific recombination. For example, the Cre recombinase from bacteriophage P1 efficiently carries out recombination at its loxP target sites. While this enzyme can function in mammalian cells, the 34bp loxP site is expected to be absent from mammalian genomes. We have discovered that sequences from the human and mouse genomes surprisingly divergent from loxP can support Cre-mediated recombination at up to 100% of the efficiency of the native loxP site in bacterial assays. Transient assays in human cells demonstrate that such pseudo-lox sites also support Cre-mediated integration and excision in the human cell environment. Pseudo sites for Cre and other recombinases may be useful for site-specific insertion of exogenous genes into mammalian genomes during gene therapy and other genetic engineering processes.     

An Escherichia coli system for assay of Flp site-specific recombination on substrate plasmids

We have developed an Escherichia coli system for testing the behaviour of plasmids carrying target sites for the Flp site-specific recombinase. The E. coli strain BL-FLP is described, which carries a chromosomally integrated bacteriophage T7 RNA polymerase gene expressed from a lac promoter, and harbours the plasmid pMS40. pMS40 has the features: (i) it carries the FLP recombinase gene under the control of a bacteriophage T7 promoter, (ii) it confers kanamycin resistance, and (iii) it uses an R6K origin of replication; these two latter features make it compatible with most conventional cloning vectors. Substrate plasmids carrying Flp-recognition targets (FRT) are transformed into BL-FLP, and the consequences of Flp-mediated recombination can be analysed after subsequent extraction of plasmid DNA. We show that this system is capable of base-perfect Flp-mediated recombination on plasmid substrates. We also present a corrected sequence of the commonly used Flp substrate plasmid, pNEOβGAL (O'Gorman et al. (1991) Science 251, 1351–1355).     

Chemical probe and missing nucleoside analysis of Flp recombinase bound to the recombination target sequence.

The Flp protein catalyzes a site-specific recombination reaction between two 47 bp DNA sites without the assistance of any other protein or cofactor. The Flp recognition target (FRT) site consists of three nearly identical sequences, two of which are separated by an 8 bp spacer sequence. In order to gain insight into this remarkable protein-DNA interaction we used a variety of chemical probe methods and the missing nucleoside experiment to examine Flp binding. Hydroxyl radical footprints of Flp bound to a recombinationally-competent site fall on opposite faces of canonical B-DNA. The 8 bp spacer region between the two Flp binding sites becomes reactive towards 5-phenyl-1,10-phenanthroline.copper upon Flp binding, indicating that once bound by Flp, this segment of DNA is not in the B-form. Missing nucleoside analysis reveals that within each binding site the presence of two nucleosides on the top strand and four on the bottom, are required for formation of a fully-occupied FRT site. In contrast, loss of any nucleoside in the three binding sites in the FRT interferes with formation of lower-occupancy complexes. DNA molecules with gaps in the 8 bp spacer region are over-represented in complexes with either two or three binding sites occupied by Flp, evidence that DNA flexibility facilitates the cooperative interaction of Flp protomers bound to a recombinationally-active site.     

Characterization of CHO XPF mutant UV41: influence of XPF heterozygosity on double-strand break-induced intrachromosomal recombination

The UV hypersensitive CHO cell mutant UV41 is the archetypal XPF mammalian cell mutant, and was essential for cloning the human nucleotide excision repair (NER) gene XPF by DNA transfection and rescue. The ERCC1 and XPF genes encode proteins that form the heterodimer responsible for making incisions required in NER and the processing of certain types of recombination intermediates. In this study, we cloned and sequenced the CHO cell XPF cDNA, determining that the XPF mutation in UV41 is a +1 insertion in exon 8 generating a premature stop codon at amino acid position 499; however, the second allele of XPF is apparently unaltered in UV41, resulting in XPF heterozygosity. XPF expression was found to be several-fold lower in UV41 compared to its parental cell line, AA8. Using approaches we previously developed to study intrachromosomal recombination in CHO cells, we modified UV41 and its parental cell line AA8 to allow site-specific gene targeting at a Flp recombination target (FRT) in intron 3 of the endogenous adenine phosphoribosyltransferase (APRT) locus. Using FLP/FRT targeting, we integrated a plasmid containing an I-SceI endonuclease sequence into this site in the paired cell lines to generate a heteroallelic APRT duplication. Frequencies of intrachromosomal recombination between APRT heteroalleles and the structures of resulting recombinants were analyzed after I-SceI induction of site-specific double-strand breaks (DSBs) in a non-homologous insertion contained within APRT homology. Our results show that I-SceI induced a small proportion of aberrant recombinants reflecting DSB-induced deletions/rearrangements in parental, repair-proficient AA8 cells. However, in XPF mutant UV41, XPF heterozygosity is responsible for a similar, but much more pronounced genomic instability phenotype, manifested independently of DSB induction. In addition, gene conversions were suppressed in UV41 cells compared to wild-type cells. These observations suggest that UV41 exhibits a genomic instability phenotype of aberrant recombinational repair, confirming a critical role for XPF in mammalian cell recombination.     

The Flp recombinase cleaves Holliday junctions in trans

The Flp site-specific recombinase is encoded by the 2 µm plasmid of Saccharomyces cerevisiae and is a member of the integrase family of recombinases. Like all members of the integrase family studied, Flp mediates recombination in two steps. First, a pair of strand exchanges creates a Holliday-like intermediate; second, this intermediate is resolved to recombinant products by a second pair of strand exchanges.
Evidence derived from experiments using linear substrates indicates that Flp's active site is composed of two Flp protomers. One binds to the Flp recognition target site (FRT site) and activates the scissile phosphodiester bond for cleavage. Another molecule of Flp bound elsewhere in the synaptic complex ( in trans ) donates the nucleophilic tyrosine that executes cleavage and thereby becomes covalently attached to the 3' phosphoryl group at the cleavage site.
It has previously been shown that Flp efficiently resolves synthetic, Holliday-like (χ) structures to linear products. In this paper, we examined whether resolution of χ structures by Flp also occurs via the trans cleavage mechanism. We used in vitro complementation studies of mutant Flp proteins as well as nicked χ structures to show that Flp resolves χ structures by trans cleavage. We propose a model for Flp-mediated recombination that incorporates trans cleavage at both the initial and resolution steps of strand exchange.     

Consecutive gene deletions in Mycobacterium smegmatis using the yeast FLP recombinase

Mycobacteria contain a large number of redundant genes whose functions are difficult to analyze in mutants, because there are only two efficient resistance markers available for allelic exchange experiments. We have established a system based on the Flp recombinase of the yeast Saccharomyces cerevisiae for use in the nonpathogenic model organism Mycobacterium smegmatis. This system consists of a hygromycin resistance cassette flanked by two Flp recognition targets (FRT) in direct orientation and a curable plasmid for expression of the flp gene. The FRT-hyg-FRT cassette was used on a suicide plasmid and on a conditionally replicating plasmid to delete two of the four known porin genes of M. smegmatis, mspA and mspC, respectively, by homologous recombination. The hyg gene was specifically removed from the chromosome of both mutants upon expression of the flp gene. Based on the marker-less mspC mutant strain, a double knock-out mutant lacking also mspA was obtained using the same strategy. Thus, by a fast and efficient two-step procedure, each of the porin genes was replaced by a single FRT site, which can be further used for site-specific integration. These results show that the Flp/FRT system is a suitable genetic tool for constructing unmarked mutations and for the analysis of redundant genes by consecutive gene deletions in M. smegmatis.