Directionality in FLP protein-promoted site-specific recombination is mediated by DNA-DNA pairing

The 2 mu plasmid of the yeast Saccharomyces cerevisiae encodes a site-specific recombination system consisting of plasmid-encoded FLP protein and two recombination sites on the plasmid. The recombination site possesses a specific orientation, which is determined by an asymmetric 8-base pair spacer sequence separating two 13-base pair inverted repeats. The outcome or directionality of site-specific recombination is defined by the alignment of two sites in the same orientation during the reaction. Sites containing point mutations or 1-base pair insertions or deletions within the spacer generally undergo recombination with unaltered sites at reduced levels. In contrast, recombination between the two identical mutant sites (where homology is restored) proceeds efficiently in all cases. Sites containing spacer sequences of 10 base pairs or more are nonfunctional under all conditions. A recombination site in which 5 base pairs are changed to yield an entirely symmetrical spacer sequence again recombines efficiently, but only with an identical site. This reaction, in addition, produces a variety of new products which can only result from random alignment of the two sites undergoing recombination, i.e. the reaction no longer exhibits directionality. These and other results demonstrate that both the efficiency and directionality of site-specific recombination is dependent upon homology between spacer sequences of the two recombining sites. This further implies that critical DNA-DNA interactions between the spacer region of the two sites involved in the reaction occur at some stage during site-specific recombination in this system. The specific spacer sequence itself appears to be unimportant as long as homology is maintained; thus, these sequences are probably not involved in recognition by FLP protein.     

Determination of DNA sequences essential for FLP-mediated recombination by a novel method

The yeast 2-micron circle plasmid encodes a protein, FLP, that mediates site-specific recombination across the two FLP-binding sites of the plasmid. We have used a novel technique, "exonuclease-treated substrate analysis," to determine the minimal duplex DNA sequence needed for this recombination event. A linear DNA containing two FLP sites in a direct orientation was treated with the double-strand specific 3'-exonuclease, exonuclease III, to generate molecules with a nested set of single-strand deletions that extended into one of the FLP sites. The DNA was then end-labeled at the sites of the deletions and used as a substrate for recombination in vitro. FLP-mediated recombination between two FLP sites excised a restriction endonuclease cleavage site from the DNA. Comparison of the fragments produced by restriction enzyme digestion of untreated and FLP-treated DNA showed to the nucleotide the duplex DNA sequence required for FLP-mediated recombination. To examine essential sequences in the opposite DNA strand, similar experiments were done using the 5'-exonuclease encoded by phage T7. The minimal essential duplex DNA sequence lies within the region of the FLP site that was previously shown to be protected from nuclease digestion in the presence of FLP. A modified form of this technique can be used to study the minimal sequence requirements of site-specific DNA binding proteins.     

Interaction of the FLP recombinase of the Saccharomyces cerevisiae 2 micron plasmid with mutated target sequences.

The 2 micron plasmid of Saccharomyces cerevisiae codes for a site-specific recombinase, the FLP protein, that catalyzes efficient recombination across two 599-base-pair (bp) inverted repeats of the plasmid DNA both in vivo and in vitro. We analyzed the interaction of the purified FLP protein with the target sequences of two point mutants that exhibit impaired FLP-mediated recombination in vivo. One mutation lies in one of the 13-bp repeat elements that had been previously shown to be protected from DNase digestion by the FLP protein. This mutation dramatically reduces FLP-mediated recombination in vitro and appears to act by reducing the binding of FLP protein to its target sequence. The second mutation lies within the 8-bp core region of the FLP target sequence. The FLP protein introduces staggered nicks surrounding this 8-bp region, and these nicks are thought to define the sites of strand exchange. The mutation in the core region abolishes recombination with a wild-type site. However, recombination between two mutated sites is very efficient. This result suggests that proper base pairing between the two recombining sites is an important feature of FLP-mediated recombination.     

A Cre::FLP fusion protein recombines FRT or loxP sites in transgenic maize plants

SUMMARY: The coding sequences of Cre (site-specific recombinase from bacteriophage P1) and FLP (yeast 2-microm plasmid site-specific recombinase) were fused in frame to produce a novel, dual-function, site-specific recombinase gene. Transgenic maize plants containing the Cre::FLP fusion expression vector were crossed to transgenic plants containing either the loxP or FRT excision substrate. Complete and precise excisions of chromosomal fragments flanked by the respective target sites were observed in the F1 and F2 progeny plants. The episomal DNA recombination products were frequently lost. Non-recombined FRT substrates found in the F1 plants were recovered in the F2 generation after the Cre::FLP gene segregated out. They produced the recombination products in the F3 generation when crossed back to the FLP-expressing plants. These observations may indicate that the efficiency of site-specific recombination is affected by the plant developmental stage, with site-specific recombination being more prevalent in developing embryos. The Cre::FLP fusion protein was also tested for excisions catalysed by Cre. Excisions were identified in the F1 plants and verified in the F2 plants by polymerase chain reaction and Southern blotting. Both components of the fusion protein (FLP and Cre) were functional and acted with similar efficiency. The crossing strategy proved to be suitable for the genetic engineering of maize using the FLP or Cre site-specific recombination system.     

Studies on the properties of P1 site-specific recombination: evidence for topologically unlinked products following recombination

Bacteriophage P1 encodes its own site-specific recombination system consisting of a site at which recombination takes place called loxP and a recombinase called Cre. A number of lambda and plasmid substrates containing two loxP sites have been constructed. Using these substrates we have shown both in vivo and in vitro that a fully functional loxP site is composed of no more than 60 bp. In vitro, when an extract containing Cre is used, recombination between loxP sites on supercoiled, nicked-circle or linear DNA occurs efficiently. The most surprising result from the in vitro studies is that 50% of the products of recombination between loxP sites on a supercoiled DNA substrate are present as free supercoiled circles. The ability to produce free products starting with a supercoiled substrate suggests a rather unique property of Cre-mediated lox recombination, the implications of which are discussed in terms of possible effects of the protein on the topology of the DNA molecule.     

DNA recognition by the FLP recombinase of the yeast 2 mu plasmid. A mutational analysis of the FLP binding site

The 2 mu plasmid of the yeast Saccharomyces cerevisiae encodes a site-specific recombination system consisting of the FLP protein and two inverted recombination sites on the plasmid. The minimal fully functional substrate for in-vitro recombination in this system consists of two FLP protein binding sites separated by an eight base-pair spacer sequence. We have used site-directed mutagenesis to generate every possible mutation (36 in all) within 11 base-pairs of one FLP protein binding site and the base-pair immediately flanking it. The base-pairs within the binding site can be separated into three classes on the basis of these results. Thirty of the 36 sequence changes, including all three at seven different positions (class I) produce a negligible or modest effect on FLP protein-promoted recombination. In particular, most transition mutations are well-tolerated in this system. In only one case do all three possible mutations produce large effects (class II). At three positions, clustered near the site at which DNA is cleaved by FLP protein, one of the two possible transversions produces a large effect on recombination, while the other two changes produce modest effects (class III). For seven mutants for which FLP protein binding was measured, a direct correlation between decreases in recombination activity and in binding was observed. Positive effects on the reaction potential of mutant sites are observed when the other FLP binding site in a single recombination site is unaltered or when the second recombination site in a reaction is wild-type. This suggests a functional interaction between FLP binding sites both in cis and in trans. When two mutant recombination sites (each with 1 altered FLP binding site) are recombined, the relative orientation of the mutations (parallel or antiparallel) has no effect on the result. These results provide an extensive substrate catalog to complement future studies in this system.     

The FLP protein of the 2-micron plasmid of yeast. Inter- and intramolecular reactions

We have studied the mechanism of reaction of the FLP protein of the yeast 2-micron plasmid on linear substrates. The products of the reaction are dependent upon the concentration of FLP protein. At low concentrations of FLP, products resulting from intramolecular recombination between two FLP target sites accumulate. At higher concentrations of FLP, intermolecular recombination results in the accumulation of products which are larger than the starting substrate. At higher concentrations still, FLP-promoted recombination is inhibited. Potassium chloride (0.15 M) inhibits the intermolecular reaction and also prevents the inhibition of FLP-mediated recombination caused by high concentrations of FLP protein. We present a model that explains these findings.     

The FLP protein contacts both major and minor grooves of its recognition target sequence.

The FLP protein of the 2 microns plasmid of Saccharomyces cerevisiae promotes conservative site-specific recombination between DNA sequences that contain the FLP recognition target (FRT). FLP binds to each of the three 13 base pair symmetry elements in the FRT site in a site-specific manner. We have probed both major and minor groove contacts of FLP using dimethyl sulphate, monoacetyl-4-hydroxyaminoquinoline 1-oxide and potassium permanganate and find that the protein displays extensive interactions with residues of both the major and minor grooves of 10 base pairs of each symmetry element. We find no evidence that the FRT site assumes a single-stranded conformation upon FLP binding.     

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

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

Identification of the crossover site during FLP-mediated recombination in the Saccharomyces cerevisiae plasmid 2 microns circle.

The FLP protein of the Saccharomyces cerevisiae plasmid 2 microns circle catalyzes site-specific recombination between two repeated segments present on the plasmid. In this paper we present results of experiments we performed to define more precisely the features of the FLP recognition target site, which we propose to designate FRT, and to determine the actual recombination crossover point in vivo. We found that essential sequences for the recombination event are limited to an 8-base-pair core sequence and two 13-base-pair repeated units immediately flanking it. This is the region identified as the FLP binding site in vitro and at which FLP protein promotes specific single-strand cleavages (B. J. Andrews, G. A. Proteau, L. G. Beatty, and P. D. Sadowski, Cell 40:795-803, 1985; J. F. Senecoff, R. C. Bruckner, and M. M. Cox, Proc. Natl. Acad. Sci. USA 82:7270-7274, 1985). Mutations within the core domain can be suppressed by the presence of the identical mutation in the chromatid with which it recombines. However, mutations outside the core are not similarly suppressed. We found that strand exchange during FLP recombination occurs most of the time within the core region, proceeding through a heteroduplex intermediate. Finally, we found that most FLP-mediated events are reciprocal exchanges and that FLP-catalyzed gene conversions occur at low frequency. The low level of gene conversion associated with FLP recombination suggests that it proceeds by a breakage-joining reaction and that the two events are concerted.     

The minimal duplex DNA sequence required for site-specific recombination promoted by the FLP protein of yeast in vitro.

The 2-micron plasmid of the yeast Saccharomyces cerevisiae codes for a site-specific recombinase ('FLP') that efficiently catalyses recombination across the plasmid's two 599 bp repeats both in vivo and in vitro. We have used the partially purified FLP protein to define the minimal duplex DNA sequence required for intra- and intermolecular recombination in vitro. Previous DNase footprinting experiments had shown that FLP protected 50 bp of DNA around the recombination site. We made BAL31 deletions and synthetic FLP sites to show that the minimal length of the site that was able to recombine with a wild-type site was 22 bp. The site consists of two 7 bp inverted repeats surrounding an 8 bp core region. We also showed that the deleted sites recombined with themselves and that one of three 13 bp repeated elements within the FLP target sequence was not necessary for efficient recombination in vitro. Mutants lacking this redundant 13 bp element required a lower amount of FLP recombinase to achieve maximal yield of recombination than the wild type site. Finally, we discuss the structure of the FLP site in relation to the proposed function of FLP recombination in copy number amplification of the 2-micron plasmid in vivo.     

FLP recombinase of the 2 microns circle plasmid of Saccharomyces cerevisiae bends its DNA target. Isolation of FLP mutants defective in DNA bending

The FLP recombinase is encoded by the yeast plasmid 2 microns circle and catalyses a site-specific recombination reaction that results in inversion of a segment of the 2 micron plasmid. We describe a method for the isolation of inactivating mutations in the FLP gene. The analysis of the recombination and binding activity of defective FLP proteins in vitro resulted in the identification of two classes of mutations: those that completely abolish FLP function by interfering with DNA binding and others that block recombination after the binding step. We have shown that FLP-mediated recombination is accompanied by bending of the DNA target and that mutations in the FLP recombinase that block bending also eliminate recombination.     

Mutagenesis of a conserved region of the gene encoding the FLP recombinase of Saccharomyces cerevisiae. A role for arginine 191 in binding and ligation.

The FLP recombinase from the 2 microns plasmid of Saccharomyces cerevisiae contains a region from amino acid 185 to 203 that is conserved among several FLP-like proteins from different yeasts. Using site-directed mutagenesis, we have made mutations in this region of the FLP gene. Five of twelve mutations in the region yielded proteins that were unable to bind to the FLP recombination target (FRT) site. A change of arginine at position 191 to lysine resulted in a protein (FLP-R191K) that could bind to the FRT site but could not catalyze recombination. This mutant protein accumulated as a stable protein-DNA complex in which one of the two bound FLP proteins was covalently attached to the DNA. FLP-R191K was defective in strand exchange and ligation and was unable to promote protein-protein interaction with half-FRT sites. The conservation of three residues in all members of the integrase family of site-specific recombinases (His305, Arg308, Tyr343 in FLP) implies a common mechanism of recombination. The conservation of arginine 191 and the properties of the FLP-R191K mutant protein suggest that this arginine also plays an important role in the mechanism of FLP-mediated site-specific recombination.     

FLP-mediated recombination of FRT sites in the maize genome.

Molecular evidence is provided for genomic recombinations in maize cells induced by the yeast FLP/FRT site-specific recombination system. The FLP protein recombined FRT sites previously integrated into the maize genome leading to excision of a selectable marker, the neo gene. NPTII activity was not observed after the successful recombination process; instead, the gusA gene was activated by the removal of the blocking DNA fragment. Genomic sequencing in the region of the FRT site (following the recombination reaction) indicated that a precise rearrangement of genomic DNA sequences had taken place. The functional FLP gene could be either expressed transiently or after stable integration into the maize genome. The efficiency of genomic recombinations was high enough that a selection for recombination products, or for FLP expression, was not required. The results presented here establish the FLP/FRT site-specific recombination system as an important tool for controlled modifications of maize genomic DNA.     

Purification and characterization of the R64 shufflon-specific recombinase

The shufflon, a multiple DNA inversion system in plasmid R64, consists of four invertible DNA segments which are separated and flanked by seven 19-bp repeat sequences. The product of a site-specific recombinase gene, rci, promotes site-specific recombination between any two of the inverted 19-bp repeat sequences of the shufflon. To analyze the molecular mechanism of this recombination reaction, Rci protein was overproduced and purified. The purified Rci protein promoted the in vitro recombination reaction between the inverted 19-bp repeats of supercoiled DNA of a plasmid carrying segment A of the R64 shufflon. The recombination reaction was enhanced by the bacterial host factor HU. Gel electrophoretic analysis indicated that the Rci protein specifically binds to the DNA segments carrying the 19-bp sequences. The binding affinity of the Rci protein to the four shufflon segments as well as four synthetic 19-bp sequences differed greatly: among the four 19-bp repeat sequences, the repeat-a and -d sequences displayed higher affinity to Rci protein. These results suggest that the differences in the affinity of Rci protein for the 19-bp repeat sequences determine the inversion frequencies of the four segments.     

利用FLP/frt重组系统产生无选择标记的转基因烟草植株

在植物转基因植株产生过程中,对转化细胞进行抗性筛选是通用程序,转化细胞的抗性一般是抗生素抗性或除草剂抗性,将赋予转化细胞抗性的选择标记基因删除是提高转基因植物生物安全性的重要措施。来自于啤酒酵母的FLP/frt位点特异性重组系统可有效删除同向定点重组位点frt之间的基因。通过多步骤重组,建立了可在植物中广泛应用的FLP/frt位点特异性重组系统。该系统包括含有frt位点的植物表达载体pCAMBIA1300-betA-frt-als-frt和含有由热诱导启动子hsp启动的FLP重组酶基因的植物表达载体pCAMBIA1300-hsp-FLP-hpt。利用二次转化的方式将二者先后转入烟草植株,热激处理后,热诱导型启动子hsp调控的重组酶FLP基因的表达催化位于选择标记基因als两侧同向frt位点间的重组反应,有效地删除了选择标记基因als。41%的经热激处理的二次转化植株发生了选择标记基因的删除,表明该系统在获得无选择标记基因的转基因植株中有很好的应用价值。     

Substrate recognition by the 2 micron circle site-specific recombinase: effect of mutations within the symmetry elements of the minimal substrate.

The minimal substrate for the 2 microns circle site-specific recombinase FLP consists of a nearly perfect 13-base-pair dyad symmetry with an 8-base-pair core. By using a series of chemically synthesized FLP substrates in in vitro FLP recombination and FLP-binding assays, we have identified four positions within each of the symmetry elements that are important contact points for the FLP protein. Furthermore, the binding and recombination data provide evidence for cooperativity between the two symmetry elements of a substrate and between the symmetry elements of two partner substrates during FLP recombination.     

The FLP protein of the 2-micron plasmid of yeast. Purification of the protein from Escherichia coli cells expressing the cloned FLP gene

Most laboratory strains of the yeast Saccharomyces cerevisiae contain many copies of an autonomously replicating plasmid called 2-micron circle DNA. This plasmid codes for a site-specific recombinase, the FLP protein which promotes recombination across two 599-base pair inverted repeats of the plasmid DNA. We have cloned the FLP gene under the control of a strong Escherichia coli promoter and have hyperproduced the protein in that organism. Cell-free extracts from this source promote highly efficient site-specific recombination in vitro and we have used this activity to purify the FLP protein substantially. The enzyme acts efficiently on circular and linear substrates and requires only monovalent or divalent cations for activity.     

Phage P1 Cre-loxP site-specific recombination. Effects of DNA supercoiling on catenation and knotting of recombinant products

Bacteriophage P1 contains a site-specific recombination system consisting of a site, loxP, and a recombinase protein Cre. We have shown that with purified Cre protein we can carry out recombination between two loxP sites in vitro. When that recombination occurs between two sites in direct orientation on the same DNA molecule, we observed the production of free and catenated circular molecules. In this paper we show that recombination between sites in opposite orientation leads to both knotted and unknotted circular products. We also demonstrate that the production of catenanes and knots is influenced by two factors: (1) supercoiling in the DNA substrate, supercoiled DNA substrates yield significantly more catenated and knotted products than nicked circular substrates; and (2) mutations in the loxP site, a class of mutations have been isolated that carry out recombination but result in a distribution of products in which the ratio of catenanes to free circles is increased over that observed with a wild-type site. A more detailed analysis of the products from recombination between wild-type sites indicates: (1) that the catenanes or knots produced by recombination are both simple and complex; (2) that the ratio of free products to catenanes is independent of the distance between the two directly repeated loxP sites; and (3) that for DNA substrates with four loxP sites significant recombination between non-adjacent sites occurs to give free circular products. These observations provide insights into how two loxP sites are brought together during recombination.