FRT Sites Research Articles

Site-specific targeting of exogenous DNA into the genome of Candida albicans using the FLP recombinase.

We have created a system that utilizes the FLP recombinase of Saccharomyces cerevisiae to reversibly introduce exogenous cloned DNA at defined locations into the Candida albicans genome. Recombination target (FRT) sites and the FLP gene can be introduced permanently at defined locations using homologous recombination. FLP recombinase is provided as needed through the regulated expression of its gene using the MAL2 promoter. Exogenous DNA is introduced on a cloning vector that is unable to replicate in C. albicans, and contains an FRT site and a selectable marker (URA3). Transformation by the lithium acetate or electroporation procedure is sufficient to obtain site-specific integration. This system permits rapid and precise excision of the introduced DNA when needed. It should facilitate studies on C. albicans genome structure and function, simplifying a wide range of chromosomal cloning applications, and generally enhancing the utility of C. albicans as a model organism for the study of fungal pathogenicity.

Cell ablation using wild-type and cold-sensitive ricin-A chain in Drosophila embryonic mesoderm.

genesisVolume 34, Issue 1-2 p. 132-134 Technology DevelopmentFree Access Cell ablation using wild-type and cold-sensitive ricin-a chain in drosophila embryonic mesoderm Marcus J. Allen, Corresponding Author Marcus J. Allen M.J.Allen@ukc.ac.uk Department of Biological Sciences, University of Warwick, Coventry, UKResearch School of Biosciences, University of Kent at Canterbury, Canterbury, CT2 7NJ, UKSearch for more papers by this authorCahir J. O'Kane, Cahir J. O'Kane Department of Biological Sciences, University of Warwick, Coventry, UKSearch for more papers by this authorKevin G. Moffat, Kevin G. Moffat Department of Biological Sciences, University of Warwick, Coventry, UKSearch for more papers by this author Marcus J. Allen, Corresponding Author Marcus J. Allen M.J.Allen@ukc.ac.uk Department of Biological Sciences, University of Warwick, Coventry, UKResearch School of Biosciences, University of Kent at Canterbury, Canterbury, CT2 7NJ, UKSearch for more papers by this authorCahir J. O'Kane, Cahir J. O'Kane Department of Biological Sciences, University of Warwick, Coventry, UKSearch for more papers by this authorKevin G. Moffat, Kevin G. Moffat Department of Biological Sciences, University of Warwick, Coventry, UKSearch for more papers by this author First published: 12 September 2002 https://doi.org/10.1002/gene.10129Citations: 9AboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onFacebookTwitterLinked InRedditWechat No abstract is available for this article.Citing Literature Volume34, Issue1-2Special Issue: GAL4/UAS in Drosophila September ‐ October 2002Pages 132-134 ReferencesRelatedInformation

Tools for characterization of Escherichia coli genes of unknown function.

Despite the power of sequencing and of emerging high-throughput technologies to collect data rapidly, the definitive functional characterization of unknown genes still requires biochemical and genetic analysis in case-by-case studies. This often involves the deletion of target genes and phenotypic characterization of the deletants. We describe here modifications of an existing deletion method which facilitates the deletion process and enables convenient analysis of the expression properties of the target gene by replacing it with an FRT-lacZ-aph-P(lac)-FRT cassette. The lacZ gene specifically reports the activity of the deleted gene and therefore allows the determination of the conditions under which it is actively expressed. The aph gene, encoding resistance to kanamycin, provides a selectable means of transducing a deleted locus between strains so that the deletion can be combined with other relevant mutations. The lac promoter helps to overcome possible polar effects on downstream genes within an operon. Because the cassette is flanked by two directly repeated FRT sites, the cassette can be excised by the Flp recombinase provided in trans. Removing the cassette leaves an in-frame deletion with a short scar which should not interfere with downstream expression. Replacements of yacF, yacG, yacH, yacK (cueO), yacL, ruvA, ruvB, yabB, and yabC made with the cassette were used to verify its properties.

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.

A dual reporter screening system identifies the amino acid at position 82 in Flp site-specific recombinase as a determinant for target specificity.

We have developed a dual reporter screen in Escherichia coli for identifying variants of the Flp site-specific recombinase that have acquired reactivity at an altered target site (mFRT). In one reporter, the lacZalpha gene segment is flanked by mFRTs in direct orientation. In the other, the red fluorescence protein (RFP) gene is flanked by the native FRTs. Hence, the color of a colony on an X-gal indicator plate indicates the recombination potential of the variant Flp protein expressed in it: blue if no recombination or only FRT recombination occurs, red if only mFRT recombination occurs and white if both FRT and mFRT recombinations occur. The scheme was validated by identification and in vivo characterization of Flp variants that show either relaxed specificity (active on FRT and mFRT) or moderately shifted specificity toward mFRT. We find that alteration of Lys-82 to Met, Thr, Arg or His enables the corresponding Flp variants to recombine FRT sites as well as altered FRT sites containing a substitution of G-C by C-G at position 1 of the Flp binding element (mFRT11). In contrast, wild-type Flp has no detectable activity on mFRT11. When Lys-82 is replaced by Tyr, the resulting Flp variant shows a small but reproducible preference for mFRT11 over FRT. However, this preference for mFRT11 is nearly lost when Tyr-82 is substituted by Phe.

Conditional mutagenesis of CamKIV

Ca /Calmodulin-dependent kinase IV (CamKIV) has been suggested to be involved in multiple physiological processes including male and female fertility, T-cell maturation, and long-term memory (Corcoran and Means, 2001). It is activated in response to Ca /calmodulin and by phosphorylation of Ca /Calmodulin-dependent kinase. CREB (cAMP response element binding protein) is one of the best defined substrates of this kinase. CamKIV activates CREB-dependent transcription via phosphorylation of serine 133 in the CREB protein (Corcoran and Means, 2001). Inactivation of the CamKIV (Camk4) gene has been reported by two independent groups. Interestingly, in one study the inactivation of CamKIV shows a severe phenotype consisting of impaired viability, male and female infertility, and neurological disorders (Ribar et al., 2000; Wu et al., 2000; Wu et al., 2000), whereas only a mild neurological phenotype was observed in an independent study (Ho et al., 2000). The discrepancy in the phenotypes of the two knockouts could be due to the different placement of the PGKneo cassette into the targeting constructs. It has been shown that the presence of the PGKneo cassette can influence the phenotype of knockout mice (Scacheri et al., 2001). Thus, the generation of CamKIV conditional knockout mice using the Cre/loxP system is an attractive alternative since it allows the generation of a null mutation that lacks the PGKneo cassette (Gu et al., 1994). A fragment of DNA containing the ATP binding domain of the CamKIV gene (exon III) was isolated from a 129-PAC genomic library. Since it has previously been shown that mutation of lysine 71 in the ATP binding domain abolishes kinase activity (Chatila et al., 1996), we chose to flank exon III, which contains this residue with two loxP sites. In addition, deletion of this exon should create a frame shift that prevents translation of the rest of the protein. The targeting construct was generated using ET-cloning (Angrand et al., 1999; Zhang et al., 1998). In the first round of ET-cloning, a loxP site was introduced downstream of exon III of the targeting construct (Fig. 1A). In the second round, the loxP●FRT●PGKTn5neo●FRT cassette was introduced upstream of exon III (Fig. 1A). Finally, the TK gene was introduced in the targeting construct by standard cloning procedures to generate a TK/neo fusion gene (PGKTK/neo). A total of 129 ES cells were electroporated with 20 g of linearized construct. ES cell clones were analysed for the correct homologous recombination event by Southern blot analyses using a 5 external probe (Fig. 1B), a 3 external probe (Fig. 1C) and an internal probe (data not shown). The FRT●PGKTn5TK/neo●FRT cassette was removed from correctly targeted ES cell clones by electroporation of the FLPe-expressing plasmid pCAGGS-FLPe (Fig. 1A) (Schaft et al., 2001). From 200 gancyclovirresistant clones, two were positive for excision of the FRT●PGKTn5TK/neo●FRT cassette as determined by Southern blot analysis. Chimeric animals were generated by blastocyst injection of positive ES cell clones and mated to C57BL/6 animals for germ-line transmission. In order to validate the functionality of the loxP sites in vivo, CamKIV flox animals (CamKIV) were mated with transgenic mice expressing the Cre recombinase under the control of a CamKII BAC (CamKII iCre) (Casanova et al., 2001). Double-transgenic animals CamKIV, CamKII iCre (CamKIV ) showed selective loss of the CamKIV protein only in those regions where the Cre recombinase is expressed. Specifically, CamKIV expression was lost from hippocampus, striatum, and cortex but not cerebellum (Fig. 2). In summary, we have generated mice with a conditional CamKIV allele using a combination of ET-cloning and the Cre/loxP and FLP/FRT systems, which allows the rapid generation of targeting constructs. Furthermore, the ET-cloning technique allows the introduction of loxP and FRT sites into DNA which is independent of restric-

A Highly Efficient Escherichia coli-Based Chromosome Engineering System Adapted for Recombinogenic Targeting and Subcloning of BAC DNA

Recently, a highly efficient recombination system for chromosome engineering in Escherichia coli was described that uses a defective λ prophage to supply functions that protect and recombine a linear DNA targeting cassette with its substrate sequence (Yu et al., 2000, Proc. Natl. Acad. Sci. USA 97, 5978–5983). Importantly, the recombination is proficient with DNA homologies as short as 30–50 bp, making it possible to use PCR-amplified fragments as the targeting cassette. Here, we adapt this prophage system for use in bacterial artificial chromosome (BAC) engineering by transferring it to DH10B cells, a BAC host strain. In addition, arabinose inducible cre and flpe genes are introduced into these cells to facilitate BAC modification using loxP and FRT sites. Next, we demonstrate the utility of this recombination system by using it to target cre to the 3′ end of the mouse neuron-specific enolase (Eno2) gene carried on a 250-kb BAC, which made it possible to generate BAC transgenic mice that specifically express Cre in all mature neurons. In addition, we show that fragments as large as 80 kb can be subcloned from BACs by gap repair using this recombination system, obviating the need for restriction enzymes or DNA ligases. Finally, we show that BACs can be modified with this recombination system in the absence of drug selection. The ability to modify or subclone large fragments of genomic DNA with precision should facilitate many kinds of genomic experiments that were difficult or impossible to perform previously and aid in studies of gene function in the postgenomic era.

A highly efficient ligand-regulated Cre recombinase mouse line shows that LoxP recombination is position dependent.

Conditional gene inactivation using the Cre/loxP system is widely used, but the difficulty in properly regulating Cre expression remains one of the bottlenecks. One approach to regulate Cre activity utilizes a mutant estrogen hormone-binding domain (ERT) to keep Cre inactive unless the non-steroidal estrogen analog 4-hydroxytamoxifen (OHT) is present. Here we describe a mouse strain expressing Cre-ERT from the ubiquitously expressed ROSA26 (R26) locus. We demonstrate efficient temporal and spatial regulation of Cre recombination in vivo and in primary cells derived from these mice. We show the existence of marked differences in recombination frequencies between different substrates within the same cell. This has important consequences when concurrent switching of multiple alleles within the same cell is needed, and highlights one of the difficulties that may be encountered when using reporter mice as indicator strains.

Embryonal recombination and germline inheritance of recombined FRT loci mediated by constitutively expressed FLP in tobacco.

FLP site-specific recombination has been shown in transgenic plants to excise DNA sequences between target FRT sites, and thereby activate transgenes in plants. In previous reports, crossing of tobacco plants expressing FLP recombinase from a CaMV-35s promoter with plants containing the target FRT sites, hybrid plants with deletion sectors were generated, which were infrequently transmitted to progeny. In this report we evaluate the occurrence of recombination in F1 hybrid seed derived from crosses of different FLP and FRT-reporter target lines and the germinal transmission of recombined loci from these hybrids to F2 progeny. Twenty hybrids were generated from crosses of independent five FLP-active lines and four FRT-reporter target lines. In one hybrid, FLP deletions occurred at an early stage, prior to seed maturation, and the deletions from this hybrid were more efficiently transmitted to F2 progeny. The demonstration of FLP-mediated recombination activity and germinal inheritance of the recombined FRT loci are supported by both molecular and enzymatic evidence.

Differences in insulator properties revealed by enhancer blocking assays on episomes.

Insulators are genomic elements that define domains of transcriptional autonomy. Although a large number of insulators have been isolated, it is unclear whether these elements function by shared molecular mechanisms. Novel applications of FLP recombinase technology were used to dissect and compare the function of the Drosophila: gypsy and scs insulators. Inter actions between FLP monomers bound to chromosomally integrated FRT sites were unimpeded by either insulator, demonstrating that these insulators do not establish a chromosomal environment capable of disrupting all types of protein-protein interactions. The gypsy insulator blocked enhancer-activated transcription on FLP-generated extra-chromosomal episomes, whereas the scs insulator displayed silencing effects. These data indicate that these insulators differ in the mechanisms used to prevent enhancer function. That the gypsy insulator blocked enhancer-promoter communication within small episomes suggests that these effects may be accomplished without a global reorganization of chromatin structure. Instead, the gypsy insulator may disrupt enhancer-activated transcription by direct interference with transmission of the enhancer signal to the promoter.

P element homing to the Drosophila bithorax complex.

P elements containing a 7 kb DNA fragment from the middle of the Drosophila bithorax complex insert preferentially into the bithorax complex or into the adjacent chromosome regions. This 'homing' property is similar to that reported for the engrailed promoter (Hama, C., Ali, Z. and Kornberg, T. B. (1990) Genes Dev. 4, 1079-1093). The 7 kb fragment does not contain any known promoter, but it acts as a boundary element separating adjacent segmental domains. An enhancer-trap P element was constructed with the homing fragment and the selectable marker flanked by FRT sites. P insertions can be trimmed down by Flp-mediated recombination to just the lacZ reporter, so that the (beta)-galactosidase pattern is not influenced by sequences inside the P element. Twenty insertions into the bithorax complex express (beta)-galactosidase in segmentally limited patterns, reflecting the segmental domains of the bithorax complex where the elements reside. The mapping of segmental domains has now been revised, with enlargement of the abx/bx, bxd/pbx, and the iab-3 domains. The FRT sites in the P elements permit recombination between pairs of elements on opposite chromosomes, to generate duplications or deletions of the DNA between the two insertion sites. Using this technique, the length of the Ultrabithorax transcription unit was varied from 37 to 138 kb, but there was surprisingly little effect on Ultrabithorax function.

FLP-mediated recombination for use in hybrid plant production.

We have studied the feasibility in Arabidopsis of using a site-specific recombination system FLP/FRT, from the 2 microm plasmid of yeast, for making plant hybrids. Initially, Arabidopsis plants expressing the FLP site-specific recombinase were crossed with plants transformed with a vector containing kanamycin-resistance gene (npt) flanked by FRT sites, which also served to separate the CaMV35S promoter from a promoterless gusA. Hybrid progeny were tested for excision of the npt gene and the positioning of 35S promoter proximal to gusA. GUS activity was observed in the progeny of all crosses, but not in the progeny derived from the self-pollinated homozygous parents. We then induced male sterility in Arabidopsis plants using the antisense expression of a pollen- and tapetum-specific gene, bcp1, flanked by FRT sites. Upon cross-pollination of flowers on the same male-sterile plants with pollen from FLP-containing plants, viable seeds were produced and the progeny hybrid plants developed normally. Molecular analyses revealed that the antisense expression cassette of bcp1 had been excised in these plants. These results show for the first time that a site-specific recombinase can be used to restore fertility in male-sterile plants, providing an alternative method for the production of hybrid seeds and plants.

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.

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 μm 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.

Site-specific integration of targeted DNA into animal cell genomes

Novel genetically engineered retroviral vectors and targeting plasmids are described that enable the site-specific targeting of exogenous DNA into the genomes of cultured animal cells. The protocol involves the transduction of competent cells by a chimeric retroviral vector containing a transcription unit composed of two linked cassettes: an upstream marker gene under the control of the viral 5′ LTR; and a downstream reporter trap containing a strong promoter 5′ to a 48 bp yeast FRT element. When cells containing such integrated units are co-transfected with a plasmid encoding yeast FLP recombinase and a promoterless targeting plasmid containing a reporter cDNA tract 3′ to an homologous FRT element, the targeting plasmid recombines at the chromosomally preconfigured FRT site, and a new hemizygous function is introduced into the downstream cassette. These reagents provide a new portable system for site-specific targeting of chemically modified genes into uniform and unique sites in genomically integrated transcription units.

Establishment and application of both FLP and Cre site-specific recombination systems at the same position in the genome

Both FRT-FRT and LoxP-LoxP sites that are the target sequences of site-specific recombinases have been constructed in a vector, called C4LFY, using the recombinant DNA technique. C4LFY also contains P elements, 2 exons and 1 intron of Drosophilayellow gene,yellow promoter and enhancers, and flanking DNA. Since C4LFY made use of two pairs of FRT and LoxP sites, this vector included two site-specific recombination systems. C4LFY was then integrated into Drosophila genome by P-element-mediated germ line transformation. In the presence of the FLP or Cre recombinase, either FLP/FRT or Cre/LoxP recombination reaction was successfully created at the same position in the genome. Using this system, the molecular basis ofyellow gene expression and regulation during development have been investigated. Results indicate that the tissue-specific expression ofyellow gene is directly regulated by transcriptional enhancers. In addition, the 5′ and 3′ genomic sequences flanking theyellow gene have been preliminarily studied and their potential role is discussed.

RAD52-dependent and -independent homologous recombination initiated by Flp recombinase at a single FRT site flanked by direct repeats.

We have devised a system for isolating yeast DNA sequences that are able to act as initiators of recombination leading to deletions in mitotically growing yeast cells. This system has allowed us to identify the FRT site of the 2-micron site-specific recombinase Flp as such a sequence. We show that Flp is able to initiate recombination leading to deletions at a single FRT site in cir(o) strains. These results indicate that Flp is able to cleave a single FRT site, supporting the observation that the mechanism of cleavage by Flp is trans-horizontal. Interestingly, Flp can induce homologous recombination in both a RAD52-dependent and RAD52-independent manner. Our work provides a new system for the study of homologous recombination leading to deletions, in which the initiation step can be efficiently controlled. We discuss the possibility that Flp-induced, RAD52-independent events occur by single-strand annealing.

DNA-sequence asymmetry directs the alignment of recombination sites in the FLP synaptic complex

The FLP recombinase promotes site-specific recombination in the 2 μm circle of Saccharomyces cerevisiae. FLP recognizes a 48 bp target site (FLP recombination target, or FRT) consisting of three 13 bp protein binding sites, or symmetry elements, flanking an 8 bp spacer region. Efficient recombination also occurs with DNA substrates that have minimal FRT sites, consisting only of the spacer and two surrounding 13 bp symmetry elements arranged in inverse orientation; thus, the wild-type spacer sequence is the main asymmetric feature of the minimal recombination site. FLP carries out recombination with many minimal target sites bearing symmetric or asymmetric mutant spacer sequences; however, the overall directionality of recombination defined in terms of inversion or excision of a DNA domain is determined by spacer-sequence asymmetry. In order to evaluate the potential influence of spacer-sequence asymmetry on structures formed during early steps in recombination, we used electron microscopy to investigate the structure of the FLP synaptic complex, which is the intermediate protein-DNA complex involved in site pairing and strand exchange. Using linear substrate DNAs that have minimal FRTs with wild-type spacer sequences, we find that 85 to 90 % of the FLP synaptic complexes examined contain the two FRTs aligned in parallel. This strong preference for parallel site alignment stands in contrast with prevailing models for λ integrase-class recombination systems, which postulate antiparallel site alignment, and results from biophysical studies on synthetic, immobile four-way DNA junctions. Our results show that the strong preference for parallel alignment can be attributed to conformational preferences of Holliday junctions present in the synaptosome.

Targeting and retrofitting pre-existing libraries of transposon insertions with FRT and oriV elements for in-vivo generation of large quantities of any genomic fragment.

A procedure is described that converts the pre-existing transposon insertion libraries to a collection of 'pop-out' strains, each allowing generation of 20- to 100-kb genomic fragments directly from the genome. The procedure consists of two steps: (1) single transposon insertions are targeted and retrofitted with excision and amplification elements (FRT and oriV), by homologous recombination with an FRT-oriV-carrying plasmid; and (2) two retrofitted neighbouring transposons are brought together by P1 transduction. From each strain, a 20- to 100-kb genomic fragment, bound by a pair of retrofitted transposons, could be excised and amplified upon supplying in trans the excision (Flp) and replication (TrfA) functions. To enhance the efficiency of crossing-in the FRT-oriV cassette, we transiently increased the copy number of our retrofitting plasmids using a temperature-sensitive TrfA-supplying helper plasmid. Using FRT-oriV and helper plasmids, we retrofitted four Tn10KmR and three Tn10CmR insertions. Subsequently, the FRT-oriV retrofitted insertions were crossed with each other in pairs (KmRxCmR), using P1 phage transductions. The resulting CmRFRT-[28-65-kb]-KmRFRT strains were transformed with a plasmid expressing FLP and trfA genes from the tightly controlled Ptet promoter. Induction of this tightly repressed promoter by autoclaved chlortetracycline (cTc) resulted in the efficient excision and amplification of genomic fragments located between FRT sites, but only in productive strains, i.e. having two parallel FRTs. We have shown that genomic fragments of 28-, 40-, 50- and 65-kb were efficiently excised and amplified. Furthermore, we could convert non-productive strains (having FRTs in non-parallel orientation), to productive combination of parallel FRTs, because one of the FRT elements was flanked by two convergent loxP sites, and thus could be inverted by the Cre function delivered either by the P1 phage or by a specially constructed temperature-sensitive Plac-cre plasmid. Although several microbial genomes were recently sequenced, the described method will help in supplying large quantities of any genomic fragment (prepared without the conventional cloning and its artifacts) for refined sequence comparison among strains and species, and for further analysis of uncharacterized ORFs, various mutations, and regulatory elements or functions. The excised and circularized DNA fragments (plasmids) could be propagated like any other large plasmids but only in hosts that could supply the appropriate Rep function. Our original 'pop-out' method [Pósfai et al. (1994) Nucleic Acids Res. 22, 2392-2398] was already employed for sequencing of the E. coli genome [Blattner et al. (1997) Science 277, 1453-1462]. Moreover, the Flp-mediated recombination between two FRT elements resulted in bacterial strains with large deletions (for parallel FRT orientations) or with large inversions (for inverted FRT orientations).

Flp-mediated tissue-specific inactivation of the retinoblastoma tumor suppressor gene in the mouse.

The yeast-derived Flp-frt site-specific DNA recombination system was used to achieve pituitary-specific inactivation of the retinoblastoma (Rb) tumor suppressor gene. Whereas mice carrying only frt sites in both alleles of Rb remain tumor free, tumorigenesis ensues when the Flp recombinase is expressed. The rate of tumorigenesis in these mice depends both on the expression level of the Flp recombinase and on the presence of frt sites in one or both Rb alleles. This permitted a more accurate definition of the consecutive steps in pituitary tumorigenesis. Our study illustrates the potential of this approach for studying sporadic cancer in a defined mouse model.