Parallel helical domains in DNA branched junctions containing 5',5' and 3',3' linkages.

The Holliday junction is a central intermediate in genetic recombination. It contains four strands of DNA that are paired into four double helical arms that flank a branch point. In the presence of Mg2+, the four arms are known to stack in pairs forming two helical domains whose orientations are antiparallel but twisted by about 60 degrees. The basis for the antiparallel orientation of the domains could be either junction structure or the effect of electrostatic repulsion between domains. To discriminate between these two possibilities, we have constructed and characterized an analogue, called a bowtie junction, in which one strand contains a 3',3' linkage at the branch point, the strand opposite it contains a 5',5' linkage, and the other two strands contain conventional 3',5' linkages. Electrostatic effects are expected to lead to an antiparallel structure in this system. We have characterized the molecule in comparison with a conventional immobile branched junction by Ferguson analysis and by observing its thermal transition profile; the two molecules behave virtually identically in these assays. Hydroxyl radical autofootprinting has been used to establish that the unusual linkages occur at the branch point and that the arms stack to form the same domains as the conventional junction. Cooper-Hagerman gel mobility analyses have been used to determine the relative orientations of the helical domains. Remarkably, we find them to be closer to parallel than to antiparallel, suggesting that the preferred structure of the branch point dominates over electrostatic repulsion. We have controlled for the number of available bonds in the branch point, for gel concentration, and for the role of divalent cations. This finding suggests that control of branch point structure alone can lead to parallel domains, which are generally consistent with recombination models derived from genetic data.

Triple-helical DNA as a reversible block of the branch point in a partially symmetrical DNA four-arm junction.

DNA branch migration is a fundamental process in genetic recombination. A new model system has been developed for studying branch migration in a small synthetic four-arm junction. A mathematical method for describing branch-point movement by discrete steps in such junctions is also presented. The key to our experimental system is the ability to fix the location of the branch point during the assembly of the junction with a reversible block. The block is provided by a short oligonucleotide that forms triplex DNA adjacent to the initial location branch point at low pH. Raising the pH causes the triplex strand to dissociate, making the branch point free to migrate. Once mobile, the branch point can run off the end of the junction. The time-course for this runoff is consistent with a random walk of the branch point. If it is assumed that one migration step moves the branch point one base-pair, the time-course gives a rate constant for one step of 1.4 second-1 at 37 degrees C in 10 mM MgCl2, 50 mM NaCl. These values are consistent with other measurements of non-enzymatic branch migration. We have also monitored the spread of the branch points directly with T4 endonuclease VII. Using EcoRI restriction endonuclease, we have shown that the binding of this protein to the arms of the junction essentially blocks branch migration through the binding site. In these experiments Ca2+ replaces Mg2+, and the enzyme does not cleave the DNA. In vivo there must be a special process to get branch points to migrate past bound proteins.

Characterization of the interaction between the lambda intasome and attB.

Bacteriophage lambda DNA integrates into the chromosome of Escherichia coli by first forming an intasome at the phage attachment site on the phage DNA with the integrase Int and integration host factor. This intasome searches the host chromosome for the bacterial attachment site (attB) and then orchestrates two sequential strand exchange reactions to achieve integration. This study characterizes the weak interaction of the intasome and attB. The hypothesis that all of the proteins necessary for integration are brought to the reaction site by the intasome is given additional support by showing that the concentration of phage attachment site and not attB determines the optimal concentration of proteins for integration. The value of the dissociation constant of the complex formed between the intasome and attB is determined in two different ways. First, the rate of the integration reaction is measured as a function of the attB DNA concentration. The saturation constant reflects the dissociation constant of the complex. Second, a recombination reaction is inhibited by the introduction of varying amounts of a second attB with a sequence change that blocks recombination with this site. The inhibition constant reflects the dissociation constant of the intasome and altered attB in this experiment. The two methods agree and give a dissociation constant of approximately 300 nM. attB contains two core binding sites for the intasome; it is shown that both are necessary for efficient capture. The value of the dissociation constants are considerably lower when a mutant integrase, IntE174K, is used. This increased affinity for core sites can explain how IntE174K can function in the absence of integration host factor. The inhibition constants also show dependence on the exact sequence of the inhibiting attB. Possible implications of this dependence are discussed.

DNA-binding properties of the Hin recombinase.

The recombinase of the Salmonella inversion system, Hin, mediates site-specific recombination between two 26 base pairs (bp) inverted repeat sequences (hixL and hixR) which flank a 993-bp DNA segment. We have investigated Hin recognition of, and association with, the hix recombination sites. Nuclease and chemical protection studies with linear and supercoiled DNA substrates demonstrate that Hin initially binds hixL and hixR independently of binding of the other protein components of the inversion system, Fis and HU. DNA-binding assays with mutant recombination sites and methylation interference experiments indicate that the critical bases for Hin recognition of its DNA-binding site are within an 8-bp sequence covering adjacent major and minor grooves of the DNA helix in each of the 12-bp half-sites of the hix recombination sites. The nature of the Hin-hix complexes in these binding studies and the results of gel filtration assays with purified Hin suggests that Hin binds the recombination sites as a dimer. The implications of the nature of the interactions of Hin with its recombination sites on the mechanism of the recombination reaction and on the novel features of DNA recognition by Hin are discussed.

Intermediates in Hin-mediated DNA inversion: a role for Fis and the recombinational enhancer in the strand exchange reaction.

The site-specific inversion reaction controlling flagellin synthesis in Salmonella involves the function of three proteins: Hin, Fis and HU. The DNA substrate must be supercoiled and contain a recombinational enhancer sequence in addition to the two recombination sites. Using mutant substrates or modified reaction conditions, large amounts of complexes can be generated which are recognized by double-stranded breaks within both recombination sites upon quenching. The cleaved molecules contain 2-bp staggered cuts within the central dinucleotide of the recombination site. Hin is covalently associated with the 5' end while the protruding 3' end contains a free hydoxyl. We demonstrate that complexes generated in the presence of an active enhancer are intermediates that have advanced past the major rate limiting step(s) of the reaction. In the absence of a functional enhancer, Hin is also able to assemble and catalyze site-specific cleavages within the two recombination sites. However, these complexes are kinetically distinct from the complexes assembled with a functional enhancer and cannot generate inversion without an active enhancer. The results suggest that strand exchange leading to inversion is mediated by double-stranded cleavage of DNA at both recombination sites followed by the rotation of strands to position the DNA into the recombinant configuration. The role of the enhancer and DNA supercoiling in these reactions is discussed.

Synthesis of a sequence-specific DNA-cleaving peptide.

A synthetic 52-residue peptide based on the sequence-specific DNA-binding domain of Hin recombinase (139-190) has been equipped with ethylenediaminetetraacetic acid (EDTA) at the amino terminus. In the presence of Fe(II), this synthetic EDTA-peptide cleaves DNA at Hin recombination sites. The cleavage data reveal that the amino terminus of Hin(139-190) is bound in the minor groove of DNA near the symmetry axis of Hin recombination sites. This work demonstrates the construction of a hybrid peptide combining two functional domains: sequence-specific DNA binding and DNA cleavage.

Fis binding to the recombinational enhancer of the Hin DNA inversion system.

The recombinational enhancer of the Hin inversion system in Salmonella stimulates recombination in vitro 150-fold in the presence of the Escherichia coli host factor Fis. To gain an understanding of the roles of the enhancer and Fis in stimulating the Hin-mediated inversion reaction, we have used nuclease and chemical protection/interference studies and gel retardation assays to examine the interactions between Fis and the recombinational enhancer. These studies combined with mutational analysis defined the enhancer sequences required for Fis binding and function. Fis binds with different affinities to two domains within the enhancer sequence. The binding of Fis at each domain is independent of the occupancy of the other domain and appears to be to opposite faces of the DNA helix. These results support a model for the role of the recombinational enhancer in Hin-mediated inversion in which the interaction between Hin bound at recombination sites and Fis bound to each domain of the recombinational enhancer results in a structure with the proper alignment and topology to promote DNA inversion.

Synthesis of a site-specific DNA-binding peptide.

The Hin recombinase binds to specific sites on DNA and mediates a recombination event that results in DNA inversion. In order to define the DNA-binding domain of the Hin protein two peptides 31 and 52 amino acids long were synthesized. Even though the 31mer encompassed the sequence encoding the putative helix-coil-helix-binding domain, it was not sufficient for binding to the 26-base pair DNA crossover site. However, the 52mer specifically interacted with the site and also effectively inhibited the Hin-mediated recombination reaction. The 52mer bound effectively to both the 26-base pair complete site and to a 14-base pair "half site." Nuclease and chemical protection studies with the 52mer helped to define the DNA base pairs that contributed to the specificity of binding. The synthetic peptide provides opportunities for new approaches to the study of the nature of protein-DNA interaction.

Host protein requirements for in vitro site-specific DNA inversion.

Flagellar phase variation is mediated by a recombination event that occurs at specific sites leading to inversion of a chromosomal segment of DNA. The presence of a 60 bp recombinational enhancer sequence on the DNA substrate molecule results in a 150-fold stimulation in the initial rate of inversion. The protein components required for inversion have been purified. They include the 21,000 dalton recombinase (Hin), a 12,000 dalton host protein (Factor II), and one of the major histone-like proteins of E. coli HU. The dependence of the initial rate of recombination on HU varies with respect to the location of the recombinational enhancer. The role of HU, Factor II, and the enhancer in facilitating site-specific recombination is discussed.

Phase variation and the Hin protein: in vivo activity measurements, protein overproduction, and purification.

The alternate expression of the Salmonella flagellin genes H1 and H2 is controlled by the orientation of a 995-base-pair invertible segment of DNA located at the 5' end of the H2 gene. The hin gene, which is encoded within the invertible region, is essential for the inversion of this DNA segment. We cloned the hin gene into Escherichia coli and placed it under the control of the PL promoter of bacteriophage lambda. These cells overproduced the Hin protein. In vivo inversion activity was measured by using a recombinant lambda phage which contains the H2 and lacZ genes under the control of the invertible region. Using this phage, we showed that the amount of inversion activity is proportional to the amount of Hin protein in the cell. An inactive form of the protein was purified by using the unusual solubility properties of the overproduced protein. The amino acid composition of the protein agreed with the DNA sequence of the hin gene. Antibodies were made to the isolated protein. These antibodies cross-reacted with two other unidentified E. coli proteins.

Further characterization of nucleotide binding sites on chloroplast coupling factor one.

The solubilized coupling factor from spinach chloroplasts (CF1) contains one nondissociable ADP/CF1 which exchanges slowly with medium ADP in the presence of Ca2+, Mg2+, or EDTA; medium ATP also exchanges in the presence of Ca2+ or EDTA, but it is hydrolyzed, and only ADP is found bound to CF1. The rate of ATP exchange with heat-activated CF1 is approximately 1000 times slower than the rate of ATP hydrolysis. In the presence of Mg2+, both latent CF1 and heat-activated CF1 bind one ATP/CF1, in addition to the ADP. This MgATP is not removed by dialysis, by gel filtration, or by the substrate CaATP during catalytic turnover; however, it is released when the enzyme is stored several days as an ammonium sulfate precipitate. The photoaffinity label 3'-O-[3-[N-(4-azido-2-nitrophenyl)amino]-propionyl]-ATP binds to the MgATP site, and photolysis results in labeling of the beta subunit of CF1. Equilibrium binding measurements indicate that CF1 has two identical binding sites for ADP with a dissociation constant of 3.9 microM (in addition to the nondissociable ADP site). When MgATP is bound to CF1, one ADP binding site with a dissociation constant of 2.9 microM is found. One ATP binding site is found in addition to the MgATP site with a dissociation constant of 2.9 microM. Reaction of CF1 with the photoaffinity label 3'-O-[3-[N-(4-azido-2-nitrophenyl)amino]propionyl]-ADP indicates that the ADP binding site which is not blocked by MgATP is located near the interface of alpha and beta subunits. No additional binding sites with dissociation constants less than 200 micro M are observed for MgATP with latent CF1 and for CaADP with heat-activated CF1. Thus, three distinct nucleotide binding sites can be identified on CF1, and the tightly bound ADP and MgATP are not at the catalytic site. The active site is either the third ADP and ATP binding site or a site not yet detected.