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.     

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.     

Roles of DNA looping in enhancer-blocking activity

Enhancer-promoter interactions in eukaryotic genomes are often controlled by sequence elements that block the actions of enhancers. Although the experimental evidence suggests that those sequence elements contribute to forming loops of chromatin, the molecular mechanism of how such looping affects the enhancer-blocking activity is still largely unknown. In this article, the roles of DNA looping in enhancer blocking are investigated by numerically simulating the DNA conformation of a prototypical model system of gene regulation. The simulated results show that the enhancer function is indeed blocked when the enhancer is looped out so that it is separated from the promoter, which explains experimental observations of gene expression in the model system. The local structural distortion of DNA caused by looping is important for blocking, so the ability of looping to block enhancers can be lost when the loop length is much larger than the persistence length of the chain.     

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.     

The FLP recombinase of the Saccharomyces cerevisiae 2 microns plasmid attaches covalently to DNA via a phosphotyrosyl linkage.

The FLP recombinase, encoded by the 2 micron plasmid of Saccharomyces cerevisiae, promotes efficient recombination in vivo and in vitro between its specific target sites (FLP sites). It was previously determined that FLP interacts with DNA sequences within its target site (B. J. Andrews, G. A. Proteau, L. G. Beatty, and P. D. Sadowski. Cell 40:795-803, 1985), generates a single-stranded break on both DNA strands within the FLP site, and remains covalently attached to the 3' end of each break. We now show that the FLP protein is bound to the 3' side of each break by an O-phosphotyrosyl residue and that it appears that the same tyrosyl residue(s) is used to attach to either DNA strand within the FLP site.     

Effects of nucleoid proteins on DNA repression loop formation in Escherichia coli

The intrinsic stiffness of DNA limits its ability to be bent and twisted over short lengths, but such deformations are required for gene regulation. One classic paradigm is DNA looping in the regulation of the Escherichia coli lac operon. Lac repressor protein binds simultaneously to two operator sequences flanking the lac promoter. Analysis of the length dependence of looping-dependent repression of the lac operon provides insight into DNA deformation energetics within cells. The apparent flexibility of DNA is greater in vivo than in vitro, possibly because of host proteins that bind DNA and induce sites of flexure. Here we test DNA looping in bacterial strains lacking the nucleoid proteins HU, IHF or H-NS. We confirm that deletion of HU inhibits looping and that quantitative modeling suggests residual looping in the induced operon. Deletion of IHF has little effect. Remarkably, DNA looping is strongly enhanced in the absence of H-NS, and an explanatory model is proposed. Chloroquine titration, psoralen crosslinking and supercoiling-sensitive reporter assays show that the effects of nucleoid proteins on looping are not correlated with their effects on either total or unrestrained supercoiling. These results suggest that host nucleoid proteins can directly facilitate or inhibit DNA looping in bacteria.     

Replacement of integration host factor protein-induced DNA bending by flexible regions of DNA

The Escherichia coli integration host factor (IHF) protein is required for site-specific recombination of bacteriophage lambda DNA. Previously, we had shown that alternative modules of static DNA curvature could partially replace IHF in recombination. Now we use regions of single-stranded DNA as a flexible tether to address whether the function of IHF in recombination is simply to reduce persistence length. Although we find that these modules clearly enhance recombination in the absence of IHF, they are not perfect replacements. In addition, evidence is presented that the efficacy of a flexibility swap is specific to a particular IHF site. This may indicate that additional functions beyond simple deformation of DNA are required of IHF. During the course of these experiments we discovered that these flexible sequences are still specific sites for IHF binding and function.     

DNA looping and the helical repeat in vitro and in vivo: effect of HU protein and enhancer location on Hin invertasome assembly.

Site-specific DNA inversion by the Hin recombinase requires the formation of a multicomponent nucleo-protein structure called an invertasome. In this structure, the two recombination sites bound by Hin are assembled together at the Fis-bound recombinational enhancer with the requisite looping of the intervening DNA segments. We have analyzed the role of the HU protein in invertasome assembly when the enhancer is located at variable positions close to one of the recombination sites. In the absence of HU in vitro and in hupA hupB mutant cells in vivo, invertasome assembly is very inefficient when there is < 104 bp of DNA between the enhancer and recombination site. Invertasome assembly in the presence of HU in vitro or in vivo displayed a periodicity beginning with 60 bp of intervening DNA that reflected its helical repeat. The average helical repeat for this DNA region was calculated by autocorrelation and Fourier transformation to be 11.2 bp per turn for supercoiled DNA both in the presence of HU in vitro and in hup+ cells in vivo. HU is the only protein in Escherichia coli that can promote invertasome formation with short DNA lengths between the enhancer and recombination sites. However, the presence of certain polyamines and a protein activity present in HeLa nuclear extracts can efficiently substitute for HU in invertasome assembly. These data support a model in which HU binds non-specifically to the DNA between the enhancer and recombination site to facilitate DNA looping.     

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.     

Analysis of DNA looping interactions by type II restriction enzymes that require two copies of their recognition sites

Before cleaving DNA substrates with two recognition sites, the Cfr10I, NgoMIV, NaeI and SfiI restriction endonucleases bridge the two sites through 3D space, looping out the intervening DNA. To characterise their looping interactions, the enzymes were added to plasmids with two recognition sites interspersed with two res sites for site-specific recombination by Tn21 resolvase, in buffers that contained either EDTA or CaCl2 so as to preclude DNA cleavage by the endonuclease; the extent to which the res sites were sequestered into separate loops was evaluated from the degree of inhibition of resolvase. With Cfr10I, a looped complex was detected in the presence but not in the absence of Ca(2+); it had a lifetime of about 90 seconds. Neither NgoMIV nor NaeI gave looped complexes of sufficient stability to be detected by this method. In contrast, SfiI with Ca(2+) produced a looped complex that survived for more than seven hours, whereas its looping interaction in EDTA lasts for about four minutes. When resolvase was added to a SfiI binding reaction in EDTA followed immediately by CaCl2, the looped DNA was blocked from recombination while the unlooped DNA underwent recombination. By measuring the distribution between looped and unlooped DNA at various SfiI concentrations, and by fitting the data to a model for DNA binding by a tetrameric protein to two sites in cis, an equilibrium constant for the looping interaction was determined. The equilibrium constant was essentially independent of the length of DNA between the SfiI sites.     

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.     

DNA communications by Type III restriction endonucleases--confirmation of 1D translocation over 3D looping

DNA cleavage by Type III restriction enzymes is governed strictly by the relative arrangement of recognition sites on a DNA substrate—endonuclease activity is usually only triggered by sequences in head-to-head orientation. Tens to thousands of base pairs can separate these sites. Long distance communication over such distances could occur by either one-dimensional (1D) DNA translocation or 3D DNA looping. To distinguish between these alternatives, we analysed the activity of EcoPI and EcoP15I on DNA catenanes in which the recognition sites were either on the same or separate rings. While substrates with a pair of sites located on the same ring were cleaved efficiently, catenanes with sites on separate rings were not cleaved. These results exclude a simple 3D DNA-looping activity. To characterize the interactions further, EcoPI was incubated with plasmids carrying two recognition sites interspersed with two 21res sites for site-specific recombination by Tn21 resolvase; inhibition of recombination would indicate the formation of stable DNA loops. No inhibition was observed, even under conditions where EcoPI translocation could also occur.     

Specific contacts between the FLP protein of the yeast 2-micron plasmid and its recombination site

Contact points between the FLP protein of the yeast 2-micron plasmid and its recombination site have been defined. Important features of the region previously defined as the minimal recombination site in vitro include a pair of 13-base pair inverted repeats separated by an 8-base pair spacer. The two FLP protein-binding sites within this region are 12 base pairs in length. In each case they include the internal 11 base pairs of one of the 13-base pair repeats, as well as the adjacent base pair within the spacer. The internal 6 base pairs within the spacer are not involved in binding or recognition by FLP protein. When the size of the spacer is increased or decreased by one base pair, the distance between the cleavage points is also increased or decreased correspondingly by one base pair. Points of cleavage are unaffected by changes in the spacer sequence. Specific contact points involving purine residues, identified by methylation protection and recombination interference experiments, are located in both the major and minor grooves of the DNA. Additional contact points between FLP protein and phosphate groups in the phosphate-deoxyribose backbone are clustered near the cleavage sites.     

Gene repression by minimal lac loops in vivo

The inflexibility of double-stranded DNA with respect to bending and twisting is well established in vitro. Understanding apparent DNA physical properties in vivo is a greater challenge. Here, we exploit repression looping with components of the Escherichia coli lac operon to monitor DNA flexibility in living cells. We create a minimal system for testing the shortest possible DNA repression loops that contain an E. coli promoter, and compare the results to prior experiments. Our data reveal that loop-independent repression occurs for certain tight operator/promoter spacings. When only loop-dependent repression is considered, fits to a thermodynamic model show that DNA twisting limits looping in vivo, although the apparent DNA twist flexibility is 2- to 4-fold higher than in vitro. In contrast, length-dependent resistance to DNA bending is not observed in these experiments, even for the shortest loops constraining <0.4 persistence lengths of DNA. As observed previously for other looping configurations, loss of the nucleoid protein heat unstable (HU) markedly disables DNA looping in vivo. Length-independent DNA bending energy may reflect the activities of architectural proteins and the structure of the DNA topological domain. We suggest that the shortest loops are formed in apical loops rather than along the DNA plectonemic superhelix.     

DNA modeling reveals an extended lac repressor conformation in classic in vitro binding assays

Protein-mediated DNA looping, such as that induced by the lactose repressor (LacI) of Escherichia coli, is a well-known gene regulation mechanism. Although researchers have given considerable attention to DNA looping by LacI, many unanswered questions about this mechanism, including the role of protein flexibility, remain. Recent single-molecule observations suggest that the two DNA-binding domains of LacI are capable of splaying open about the tetramerization domain into an extended conformation. We hypothesized that if recent experiments were able to reveal the extended conformation, it is possible that such structures occurred in previous studies as well. In this study, we tested our hypothesis by reevaluating two classic in vitro binding assays using a computational rod model of DNA. The experiments and computations evaluate the looping of both linear DNA and supercoiled DNA minicircles over a broad range of DNA interoperator lengths. The computed energetic minima align well with the experimentally observed interoperator length for optimal loop stability. Of equal importance, the model reveals that the most stable loops for linear DNA occur when LacI adopts the extended conformation. In contrast, for DNA minicircles, optimal stability may arise from either the closed or the extended protein conformation depending on the degree of supercoiling and the interoperator length.