Half-site recombinations mediated by yeast site-specific recombinases Flp and R.

The Flp recombinase of Saccharomyces cerevisae and the related R recombinase of Zygosaccharomyces rouxii can efficiently catalyze strand cleavage and strand exchange reactions in half recombination sites. A half-site consists of one recombinase binding element, a recombinase cleavage site on one strand and a 5' spacer hydroxyl group on the other that can initiate the strand exchange reaction. We have studied the various types of strand exchanges that half-sites can participate in. Reaction between a left half-site and a right half-site generates a full recombination site. Strand transfer between two left half-sites or between two right half-sites produces pseudo-full-sites. Strand transfer within a half-site results in a stem-loop or hairpin product. The half-site strand transfer reaction is fairly indifferent to the spacer sequence of the substrate per se and is less sensitive to variations in spacer lengths than a full-site recombination reaction. The optimal spacer length of eight to ten nucleotides observed for the Flp half-site reaction likely permits the most productive catalytic interactions between two Flp monomers bound to each of two partner half-sites. When reacted with a full-site, the half-site can give rise to a normal or reverse recombinant, corresponding to homologous or non-homologous alignments of the spacer sequences during substrate synapsis. The contrary recombination (resulting from non-homologous spacer alignment), whose level is low relative to normal recombination, is partly suppressed when the half-site spacer ends in a 5'-phosphate rather than a 5'-hydroxyl group. Thus, the early steps of recombination, namely synapsis and initial stand transfer, are not dependent on complete spacer homology between the two recombining substrates. The selection of properly aligned substrate partners must occur at the homology dependent branch migration step. In reactions containing a mixture of Flp and R half-sites, Flp and R catalyze strand transfer, almost exclusively, within or between their respective cognate substrates. However, under conditions where self-crosses are inhibited, strand exchange between a Flp half-site and an R half-site appears to be stimulated by a combination of R and Flp.     

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.     

Half-site strand transfer by step-arrest mutants of yeast site-specific recombinase Flp.

The Flp recombinase of Saccharomyces cerevisae can mediate strand transfer within a half-site, between two half-sites and between a half-site and a full-site. The ability of "step-arrest" mutants of Flp to partake in half-site reactions has been examined. Arg308 variants of Flp, which show little or no strand cleavage in reactions with normal full-sites, execute significant levels of strand transfer in half-site reactions. On the other hand, His305 variants of Flp, which normally accumulate the strand cleavage product from full-sites but do not complete strand transfer, yield only minute amounts of strand transfer products from half-sites. As would be predicted, the step-arrest mutants are unable to produce "normal" or "reverse" recombinants between a half-site and a full-site. The Flp protein is able to form higher-order complexes in association with a half-site. The step-arrest mutants of Flp show specific defects in forming these complexes.     

Bending-incompetent variants of Flp recombinase mediate strand transfer in half-site recombinations: role of DNA bending in recombination.

One key feature of the interaction of Flp recombinase with its target site (FRT) is the large bend introduced in the substrate as a result of protein binding. The extent of bending was found to depend on the phasing and spacing of the Flp monomers occupying the two Flp-binding elements (FBE) bordering the strand-exchange region (spacer) of the substrate. The relative mobilities of the Flp complexes formed by the two permuted substrate fragments, containing the FRT site near the end or in the middle, corresponded to a DNA bend of approx. 140 degrees when each of the two FBEs flanking the spacer was occupied by a protein monomer. The estimated bend angle was the same when the reference DNA fragment with the FRT site at the end was substituted by one with the site in the middle, but containing a 4-bp insertion within the spacer. We used a combination of wild-type Flp and Flp variants that were competent or incompetent in DNA bending, together with full, or half FRT sites, to ask whether bending is a conformational requirement for catalysis, namely cleavage and exchange of strands. We obtained the following results: in full-site (FRT) vs. full-site recombinations or in full-site vs. half-site (half FRT) recombinations, there was a large difference in the reactivity between Flp and a bending-incompetent Flp variant. This difference virtually disappeared when reactions were done with half-FRT sites. We conclude that bending is not a prerequisite for catalysis, but represents the manner in which the substrate accommodates the Flp protomer-protomer interactions that are pertinent to catalysis.     

Protein-based asymmetry and protein-protein interactions in FLP recombinase-mediated site-specific recombination

When the FLP recombination target (FRT) is cut in half so that only one FLP protein-binding site is present, FLP protein forms a complex in which two such sites are linked head to head. Although held together exclusively by noncovalent interactions, this complex survives electrophoresis in an agarose gel and exhibits a half-life that can be measured in hours. Characterization of this complex indicates that a very stable, asymmetric dimeric complex of FLP protein monomers bound to the FRT is a likely early intermediate in FLP-mediated site-specific recombination. The apparent asymmetry is a property of the protein components of the complex. Even though the DNA components form a perfect palindrome, only one of the two possible DNA cleavage steps takes place in the course of complex formation. Formation of this complex does not occur with half-FRT site DNA substrates that preclude head to head monomer contact or when a FLP mutant protein is used that binds the FRT site but cannot cleave it. Trimeric and tetrameric complexes are also observed, the latter at very low frequency. These results are discussed in terms of an expanded model for early events in FLP-mediated site-specific recombination.     

Reactions between half- and full-FLP recombination target sites. A model system for analyzing early steps in FLP protein-mediated site-specific recombination.

The FLP recombination target (FRT) can be cut in half so that only one FLP protein binding site is present (a "half site"). FLP protein binds the half sites and joins them into dimeric, asymmetric head-to-head complexes held together chiefly by strong noncovalent interactions. These complexes react with full (normal) FRT sites to generate a variety of products. Analysis of these DNA species reveals that the reaction follows a well-defined reaction pathway that generally parallels the normal reaction pathway. The system is useful in analyzing early steps in recombination, since the identity of the products in a given recombination event unambiguously pinpoints the order in which the cleavage and strand exchange reactions occur. Two conclusions are derived from the present study: (i) Formation of the dimeric head-to-head complex of half sites is a prerequisite to further steps in recombination. (ii) The identity of the base pairs at positions 6 and -6 within the FRT site has a subtle effect in directing the first strand exchange event in the reaction to predominantly one of two possible cleavage sites. In addition, results are presented that suggest that a DNA-DNA pairing intermediate involving only two base pairs of the core sequence is formed prior to the first cleavage and strand exchange. DNA-DNA interactions may therefore not be limited to the isomerization step that follows the first strand exchange.     

Homologous recombination in real time: DNA strand exchange by RecA

Homologous recombination, the exchange of strands between different DNA molecules, is essential for proper maintenance and accurate duplication of the genome. Using magnetic tweezers, we monitor RecA-driven homologous recombination of individual DNA molecules in real time. We resolve several key aspects of DNA structure during and after strand exchange. Changes in DNA length and twist yield helical parameters for the protein-bound three-stranded structure in conditions in which ATP was not hydrolyzed. When strand exchange was completed under ATP hydrolysis conditions that allow protein dissociation, a "D wrap" structure formed. During homologous recombination, strand invasion at one end and RecA dissociation at the other end occurred at the same rate, and our single-molecule analysis indicated that a region of only about 80 bp is actively involved in the synapsis at any time during the entire reaction involving a long ( approximately 1 kb) region of homology.     

The FLP recombinase of the 2 micron circle DNA of yeast: interaction with its target sequences

We have studied the interaction of purified FLP protein with restriction fragments from the substrate 2mu circle DNA of yeast. We find that FLP protects about 50 bp of DNA from nonspecific nuclease digestion. The protected site consists of two 13 bp inverted repeat sequences separated by an 8 bp spacer region. A third 13 bp element is also protected by binding of the FLP protein. We demonstrate that FLP introduces single- and double-strand breaks into the substrate DNA. This site-specific cleavage occurs at the margins of the spacer region, generating 8 bp 5' protruding ends with 5'-OH and 3'-protein-bound termini. Binding to mutant sites and half-sites demonstrates that the third symmetry element is not important for binding and cleavage by the FLP protein. The integrity of the core region is important for the cleavage activity of FLP.     

Real-time observation of strand exchange reaction with high spatiotemporal resolution

RecA binds to single-stranded (ss) DNA to form?a helical filament that catalyzes strand exchange with a homologous double-stranded (ds) DNA. The study of strand exchange in ensemble assays is limited by the diffusion limited homology search process, which masks the subsequent strand exchange reaction. We developed a single-molecule fluorescence assay with a few base-pair and millisecond resolution that can separate initial docking from the subsequent propagation of joint molecule formation. Our data suggest that propagation occurs in 3?bp increments with destabilization of the incoming dsDNA and concomitant pairing with the reference ssDNA. Unexpectedly, we discovered the formation of?a dynamic complex between RecA and the displaced DNA that remains bound transiently after joint molecule formation. This finding could have important implications for the irreversibility of strand exchange. Our model for strand exchange links structural models of RecA to its catalytic function.     

DNA重组酶FLP原核表达与多步法纯化及其活性检测

DNA重组酶FLP存在于酵母2μ质粒上,能识别34bp的FRT位点,并根据2个FRT位点的相对方向完成位点间DNA序列的交换、重组、删除与逆转,在现代分子生物学理论研究与基因工程技术开发中具有广泛应用。构建了在原核大肠杆菌中高效表达FLP重组酶的表达载体pQE32-flpe并建立起相应的原核高效表达体系,在原核细菌大肠杆菌M15菌株中实现FLP酶蛋白的高效表达,同时建立了相应的纯化方法。纯化时先用硫酸铵沉淀法富集FLP酶蛋白,经透析脱盐后再用镍离子鳌合微柱(0.5~1.0mL)亲合层析梯度洗脱的方法获得纯化的FLP酶蛋白。通过构建含有2个方向相同的FRT序列位点的质粒pUC18-FRT-gfp-FRT和含有1个FRT位点的表达载体pET30a-FRT,并分别以其为底物来检测FLP重组酶的删除、交换与重组功能的活性。结果表明,该方法不仅能有效表达FLP酶蛋白,并能行之有效地纯化FLP酶蛋白,以及检测纯化的FLP酶蛋白对DNA序列的删除、重组与交换功能。该方法简单易行并能获得有活性的FLP酶蛋白,为深入研究其机理以及研发相应的DNA重组技术提供重要参考。     

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.     

A complex mechanism determines polarity of DNA replication fork arrest by the replication terminator complex of Bacillus subtilis

Two dimers of the replication terminator protein (RTP) of Bacillus subtilis bind to a chromosomal DNA terminator site to effect polar replication fork arrest. Cooperative binding of the dimers to overlapping half-sites within the terminator is essential for arrest. It was suggested previously that polarity of fork arrest is the result of the RTP dimer at the blocking (proximal) side within the complex binding very tightly and the permissive-side RTP dimer binding relatively weakly. In order to investigate this "differential binding affinity" model, we have constructed a series of mutant terminators that contain half-sites of widely different RTP binding affinities in various combinations. Although there appeared to be a correlation between binding affinity at the proximal half-site and fork arrest efficiency in vivo for some terminators, several deviated significantly from this correlation. Some terminators exhibited greatly reduced binding cooperativity (and therefore have reduced affinity at each half-site) but were highly efficient in fork arrest, whereas one terminator had normal affinity over the proximal half-site, yet had low fork arrest efficiency. The results show clearly that there is no direct correlation between the RTP binding affinity (either within the full complex or at the proximal half-site within the full complex) and the efficiency of replication fork arrest in vivo. Thus, the differential binding affinity over the proximal and distal half-sites cannot be solely responsible for functional polarity of fork arrest. Furthermore, efficient fork arrest relies on features in addition to the tight binding of RTP to terminator DNA.     

Estrogen receptor alpha interaction with estrogen response element half-sites from the rat prolactin gene

Estrogen regulation of the rat prolactin gene requires sequences within the DNase I hypersensitive site II (HSII). We have used overexpressed mouse estrogen receptor alpha (ERalpha) protein to study interactions of ERalpha with an imperfect estrogen response element (ERE) and four ERE half-site sequences from HSII. We confirmed that ERalpha has higher affinity for ERE half-sites than for the imperfect ERE. As expected, the imperfect ERE formed a complex with ERalpha similar to that between mERalpha and a consensus ERE in gel shift assays. The ERalpha complex with half-sites, however, had faster mobility on a 4% polyacrylamide gel than the ERalpha complex with a consensus ERE, indicating that the complexes had different compositions. Ferguson analysis revealed that the ERalpha/half-site complex had a larger molecular weight and higher negative charge than the ERalpha/consensus ERE complex. Similar results were observed with purified human ERalpha, showing that the ERalpha/half-site complex contained only ERalpha and oligonucleotides. These results are best explained by a model in which a dimer of ERalpha is bound to two half-site oligonucleotides. We propose that two ERalpha dimers may interact with the four ERE half-sites in HSII to influence estrogen regulation of this gene.     

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.     

DNA sequence determinant for Flp-induced DNA bending

The Flp site-specific recombinase from Saccharomyces cerevisiae induces DNA bending upon interaction with the Flp recognition target (FRT) site. The minimal FRT site comprises the inverted a and b binding elements, which flank a central 8 bp core region. The DNA bend in a complex of two Flp monomers bound to the FRT site is located in the middle of the core region. When the central AT basepair was replaced with a CG, the DNA bend was positioned at the outside end of the core region adjacent to the a binding element. The other basepairs surrounding the central AT basepair were not important to the position of Flp-induced bends. The change also decreased Flp-mediated cleavage of the top strand of the FRT site and increased Flp-mediated cleavage of the bottom strand. The overall recombination proficiency of the site was impaired. We conclude that the central AT basepair provides a point of flexure in the FRT site, which Flp uses to position the bend in dimeric Flp–DNA complexes, and that the structure of the core DNA influences the functionality of the site.     

The poor homology stringency in the heteroduplex allows strand exchange to incorporate desirable mismatches without sacrificing recognition in vivo

RecA family proteins are responsible for homology search and strand exchange. In bacteria, homology search begins after RecA binds an initiating single-stranded DNA (ssDNA) in the primary DNA-binding site, forming the presynaptic filament. Once the filament is formed, it interrogates double-stranded DNA (dsDNA). During the interrogation, bases in the dsDNA attempt to form Watson–Crick bonds with the corresponding bases in the initiating strand. Mismatch dependent instability in the base pairing in the heteroduplex strand exchange product could provide stringent recognition; however, we present experimental and theoretical results suggesting that the heteroduplex stability is insensitive to mismatches. We also present data suggesting that an initial homology test of 8 contiguous bases rejects most interactions containing more than 1/8 mismatches without forming a detectable 20 bp product. We propose that, in vivo, the sparsity of accidental sequence matches allows an initial 8 bp test to rapidly reject almost all non-homologous sequences. We speculate that once the initial test is passed, the mismatch insensitive binding in the heteroduplex allows short mismatched regions to be incorporated in otherwise homologous strand exchange products even though sequences with less homology are eventually rejected.     

The bZIP targets overlapping DNA subsites within a half-site, resulting in increased binding affinities

We previously reported that the wt bZIP, a hybrid of the GCN4 basic region and C/EBP leucine zipper, not only recognizes GCN4 cognate site AP-1 (TGACTCA) but also selectively targets noncognate DNA sites, in particular the C/EBP site (TTGCGCAA). In this work, we used electrophoretic mobility shift assay and DNase I footprinting to investigate the factors driving the high affinity between the wt bZIP and the C/EBP site. We found that on each strand of the C/EBP site, the wt bZIP recognizes two 4 bp subsites, TTGC and TGCG, which overlap to form the effective 5 bp half-site (TTGCG). The affinity of the wt bZIP for the overall 5 bp half-site is >or=10-fold stronger than that for either 4 bp subsite. Our results suggest that interactions of the wt bZIP with both subsites contribute to the strong affinity at the overall 5 bp half-site and, consequently, the C/EBP site. Accordingly, we propose that the wt bZIP undergoes conformational changes to slide between the two overlapping subsites on the same DNA strand and establish sequence-selective contacts with the different subsites. The proposed binding mechanism expands our understanding of what constitutes an actual DNA target site in protein-DNA interactions.