Solution structure of the Tn3 resolvase-crossover site synaptic complex

Tn3 resolvase is a site-specific DNA recombinase, which catalyzes strand exchange in a synaptic complex containing twelve resolvase subunits and two res sites. Hyperactive mutants of resolvase can form a simpler complex (X synapse) containing a resolvase tetramer and two shorter DNA segments at which strand exchange takes place (site I). We have solved the low-resolution solution structure of the purified, catalytically competent X synapse from small-angle neutron and X-ray scattering data, using methods in which the data are fitted with models constructed by rigid body transformations of a published crystallographic structure of a resolvase dimer bound to site I. Our analysis reveals that the two site I fragments are on the outside of a resolvase tetramer core and provides some information on the quaternary structure of the tetramer. We discuss implications of our structure for the architecture of the natural synaptic complex and the mechanism of strand exchange.     

Specificity of DNA recognition in the nucleoprotein complex for site-specific recombination by Tn21 resolvase.

Resolvases from Tn3-like transposons catalyse site-specific recombination at res sites. Each res site has 3 binding sites for resolvase, I, II, and III. The res sites in Tn3 and Tn21 have similar structures at I and II but they differ at III. Mutagenesis of the Tn21 res site showed that sub-site III is essential for recombination though the sequences in III that are recognized by Tn21 resolvase are positioned differently from the equivalent sequences in the Tn3 site. The deletion of III caused a 1,000-fold drop in the rate of recombination. But other mutations at III, changing 3 or 4 consecutive base pairs, caused only 1.5- to 4-fold decreases in rate, even when the mutations were in target sequences for this helix-turn-helix protein. The reason why Tn21 resolvase has similar activities at a number of different DNA sequences may be due to the multiplicity of protein-protein and protein-DNA interactions in its recombinogenic complex. This lack of precision may be a general feature of nucleoprotein complexes.     

Definition of three resolvase binding sites at the res loci of Tn21 and Tn1721.

The dual functions of resolvase, site-specific recombination and the regulation of its own expression from tnpR, both require the interaction of this protein with the DNA sequence at res, but the specificity of this interaction differs between groups of Tn3-like elements. In this study, DNA fragments that contained res from Tn21 or Tn1721 were subjected to either cleavage by DNase I or methylation by dimethyl sulphate in the presence of the purified resolvase from Tn21 or Tn1721. These experiments showed that each resolvase bound to the same three sites (I, II and III) within res from Tn1721 and to an equivalent series of three sites on Tn21: the differences in the amino acid sequences of the two proteins did not affect their interaction with either DNA. The DNA sequences at each site had some similarities and, in conjunction with data from the related transposon Tn501, a consensus was established. However, the three sites are functionally distinct: site I (tnpR-distal) spans the recombination cross-over point and sites II and III (tnpR-proximal) overlap the promoter of tnpR. The binding sites on these transposons were compared with those in the gamma delta/Tn3 system: the similarities between the two groups of transposons revealed some general features of resolvase-DNA interactions while the differences in fine structure elucidated the specificity of each resolvase.     

Mutants of Tn3 resolvase which do not require accessory binding sites for recombination activity

Tn3 resolvase promotes site-specific recombination between two res sites, each of which has three resolvase dimer-binding sites. Catalysis of DNA-strand cleavage and rejoining occurs at binding site I, but binding sites II and III are required for recombination. We used an in vivo screen to detect resolvase mutants that were active on res sites with binding sites II and III deleted (that is, only site I remaining). Mutations of amino acids Asp102 (D102) or Met103 (M103) were sufficient to permit catalysis of recombination between site I and a full res, but not between two copies of site I. A double mutant resolvase, with a D102Y mutation and an additional activating mutation at Glu124 (E124Q), recombined substrates containing only two copies of site I, in vivo and in vitro. In these novel site Ixsite I reactions, product topology is no longer restricted to the normal simple catenane, indicating synapsis by random collision. Furthermore, the mutants have lost the normal specificity for directly repeated sites and supercoiled substrates; that is, they promote recombination between pairs of res sites in linear molecules, or in inverted repeat in a supercoiled molecule, or in separate molecules.     

Activating mutations of Tn3 resolvase marking interfaces important in recombination catalysis and its regulation

Catalysis of DNA recombination by Tn3 resolvase is conditional on prior formation of a synapse, comprising 12 resolvase subunits and two recombination sites (res). Each res binds a resolvase dimer at site I, where strand exchange takes place, and additional dimers at two adjacent 'accessory' binding sites II and III. 'Hyperactive' resolvase mutants, that catalyse strand exchange at site I without accessory sites, were selected in E. coli. Some single mutants can resolve a res x site I plasmid (that is, with one res and one site I), but two or more activating mutations are necessary for efficient resolution of a site I x site I plasmid. Site I x site I resolution by hyperactive mutants can be further stimulated by mutations at the crystallographic 2-3' interface that abolish activity of wild-type resolvase. Activating mutations may allow regulatory mechanisms of the wild-type system to be bypassed, by stabilizing or destabilizing interfaces within and between subunits in the synapse. The positions and characteristics of the mutations support a mechanism for strand exchange by serine recombinases in which the DNA is on the outside of a recombinase tetramer, and the tertiary/quaternary structure of the tetramer is reconfigured.     

Topological selectivity of a hybrid site-specific recombination system with elements from Tn3 res/resolvase and bacteriophage P1 loxP/Cre.

In order to investigate the functions of the parts of the Tn 3 recombination site res, we created hybrid recombination sites by placing the loxP site for Cre recombinase adjacent to the "accessory" resolvase-binding sites II and III of res. The efficiency and product topology of in vitro recombination by Cre between two of these hybrid sites were affected by the addition of Tn 3 resolvase. The effects of resolvase addition were dependent on the relative orientation and spacing of the elements of the hybrid sites. Substrates with sites II and III of res close to loxP gave specific catenated or knotted products (four-noded catenane, three-noded knot) when resolvase and Cre were added together. The product topological complexity increased when the length of the spacer DNA segment between loxP and res site II was increased. Similar resolvase-induced effects on Cre recombination product topology were observed in reactions of substrates with loxP sites adjacent to full res sites. The results demonstrate that the res accessory sites are sufficient to impose topological selectivity on recombination, and imply that intertwining of two sets of accessory sites defines the simple catenane product topology in normal resolvase-mediated recombination. They are also consistent with current models for the mechanism of catalysis by Cre.     

Inhibitor analysis of synapsis by resolvase

Previously, we isolated several inhibitors that block the site-specific recombination reaction mediated by the Tn3-encoded resolvase protein. One class of inhibitors blocks resolvase binding to the recombination (res) sitc, and a second class inhibits synapse formation between resolvase and two directly repeated res sites. In this report, we identify an inhibitor, A20832, that does not inhibit resolvase binding to res, as measured by filter binding, or synapse formation. Inhibition of resolvase-promoted site-specific recombination by A20832 occurs postsynaptically at strand cleavage. DNase I analysis in the presence of A20832 indicates that only site I of res is bound by resolvase.     

Analysis of inhibitors of the site-specific recombination reaction mediated by Tn3 resolvase

The Tn3-encoded resolvase protein promotes a site-specific recombination reaction between two directly repeated copies of the recombination site res. Several inhibitors that block this event in vitro have been isolated. In this study four of these inhibitors were tested on various steps in the recombination reaction. Two inhibitors. A9387 and A1062, inhibit resolvase binding to the res site. Further, DNase I footprinting revealed that at certain concentrations of A9387 and A1062, resolvase was preferentially bound to site I of res, the site containing the recombinational crossover point. The two other inhibitors, A20812 and A21960, do not affect resolvase binding and bending of the DNA but inhibit synapse formation between resolvase and two directly repeated res sites.     

Accounting for thermodynamic non-ideality in the Guinier region of small-angle scattering data of proteins

Hydrodynamic studies of the solution properties of proteins and other biological macromolecules are often hard to interpret when the sample is present at a reasonably concentrated solution. The reason for this is that solutions exhibit deviations from ideal behaviour which is manifested as thermodynamic non-ideality. The range of concentrations at which this behaviour typically is exhibited is as low as 1–2 mg/ml, well within the range of concentrations used for their analysis by techniques such as small-angle scattering. Here we discuss thermodynamic non-ideality used previously used in the context of light scattering and sedimentation equilibrium analytical ultracentrifugation and apply it to the Guinier region of small-angle scattering data. The results show that there is a complementarity between the radially averaged structure factor derived from small-angle X-ray scattering/small-angle neutron scattering studies and the second virial coefficient derived from sedimentation equilibrium analytical ultracentrifugation experiments.     

Site-specific recombination by mutants of Tn21 resolvase with DNA recognition functions from Tn3 resolvase

The resolvases from the transposons Tn3 and Tn21 are homologous proteins but they possess distinct specificities for the DNA sequence at their respective res sites. The DNA binding domain of resolvase contains an amino acid sequence that can be aligned with the helix-turn-helix motif of other DNA binding proteins. Mutations in the gene for Tn21 resolvase were made by replacing the section of DNA that codes for the helix-turn-helix with synthetic oligonucleotides. Each mutation substituted one amino acid in Tn21 resolvase with either the corresponding residue from Tn3 resolvase or a residue that lacks hydrogen bonding functions. The ability of these proteins to mediate recombination between res sites from either Tn21 or Tn3 was measured in vivo and in vitro. With one exception, where a glutamate residue had been replaced by leucine, the activity of these mutants was similar to that of wild-type Tn21 resolvase. A further mutation was made in which the complete recognition helix of Tn21 resolvase was replaced with that from Tn3 resolvase. This protein retained activity in recombining Tn21 res sites, though at a reduced level relative to wild-type; the reduction can be assigned entirely to weakened binding to this DNA. Neither this mutant nor any other derivative of Tn21 resolvase had any detectable activity for recombination between res sites from Tn3. The exchange of this section of amino acid sequence between the two resolvases is therefore insufficient to alter the DNA sequence specificity for recombination.     

The calcium and magnesium binding sites on cardiac troponin and their role in the regulation of myofibrillar adenosine triphosphatase

The cardiac troponin (Tn) complex, consisting of a Ca2+-binding subunit (TnC), an inhibitory subunit (TnI), and a tropomyosin-binding subunit (TnT), has been reconstituted from purified troponin subunits isolated from bovine heart muscle. The Ca2+-binding properties of cardiac Tn were determined by equilibrium dialysis using either EGTA or EDTA to regulate the free Ca2+ concentration. Cardiac Tn binds 3 mol Ca2+/mol and contains two Ca2+-binding sites with a binding constant of 3 X 10(8) M-1 and one binding site with a binding constant of 2 X 10(6) M-1. In the presence of 4 mM MgC12, the binding constant of the sites of higher affinity is reduced to 3 X 10(7) M-1, while Ca2+ binding to the site at the lower affinity is unaffected. The two high affinity Ca2+-binding sites of cardiac Tn are analogous to the two Ca2+-Mg2+ sites of skeletal Tn, while the single low affinity site is similar to the two Ca2+-specific sites of skeletal Tn (Potter, J. D., and Gergely, J. (1975) J. Biol. Chem. 250, 4625-5633). The Ca2+-binding properties of the complex of TnC and TnI (1:1 molar ratio) were similar to those of Tn. Cardiac TnC also binds 3 mol of Ca2+/mol and contains two sites with a binding constant of 1 X 10(7) M-1 and a single site with a binding constant of 2 X 10(5) M-1. Assuming competition between Mg2+ and Ca2+ for the high affinity sites of TnC and Tn, the binding constants for Mg2+ were 0.7 and 3.0 X 10(3) M-1, respectively. The Ca2+ dependence of cardiac myofibrillar ATPase activity was similar to that of an actomyosin preparation regulated by the reconstituted troponin complex. Comparison by the Ca2+-binding properties of cardiac Tn and the cardiac myofibrillar ATPase activity as a function of [Ca2+] and at millimolar [Mg2+] suggests that activation of the ATPase occurs over the same range of [Ca2+] where the Ca2+-specific site of cardiac Tn binds Ca2+.     

Function of the N-terminal calcium-binding sites in cardiac/slow troponin C assessed in fast skeletal muscle fibers

Fast skeletal troponin C (sTnC) has two low affinity Ca(2+)-binding sites (sites I and II), whereas in cardiac troponin C (cTnC) site I is inactive. By modifying the Ca2+ binding properties of sites I and II in cTnC it was demonstrated that binding of Ca2+ to an activated site I alone is not sufficient for triggering contraction in slow skeletal muscle fibers (Sweeney, H.L., Brito, R. M.M., Rosevear, P.R., and Putkey, J.A. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 9538-9542). However, a similar study using sTnC showed that Ca2+ binding to site I alone could partially activate force production in fast skeletal muscle fibers (Sheng, Z., Strauss, W.L., Francois, J.M., and Potter, J.D. (1990) J. Biol. Chem. 265, 21554-21560). The purpose of the current study was to examine the functional characteristics of modified cTnC derivatives in fast skeletal muscle fibers to assess whether or not either low affinity site can mediate force production when coupled to fast skeletal isoforms of troponin (Tn) I and TnT. Normal cTnC and sTnC were compared with engineered derivatives of cTnC having either both sites I and II active, or only site I active. In contrast to what is seen in slow muscle, binding of Ca2+ to site I alone recovered about 15-20% of the normal calcium-activated force and ATPase activity in skinned fast skeletal muscle fibers and myofibrils, respectively. This is most likely due to structural differences between TnI and/or TnT isoforms that allow for partial recognition and translation of the signal represented by binding Ca2+ to site I of TnC when associated with fast skeletal but not slow skeletal muscle.     

The gamma delta resolvase bends the res site into a recombinogenic complex.

We have characterized complexes between the gamma delta resolvase and its recombination site, res, using both a gel retardation assay and DNase I cleavage. The mobility of resolvase-res complexes in polyacrylamide gels is sensitive to the location of res within the DNA fragment and is at a minimum when res is at its center. This behavior is characteristic of a protein-dependent bend. By the same assay we have found that bends are induced upon the binding of resolvase to each of the three individual binding sites that constitute res. In the wild-type res, the centers of binding sites I and II are 53 bp apart and the central section of the intersite DNA is sensitive to DNase I cleavage. We find that insertions of 10 or 21 bp (one or two turns of the DNA helix) have no discernible effect on the ability of res to recombine or to form complexes with resolvase. However, insertions of short segment (e.g. 6 or 17 bp) equivalent to nonintegral numbers of helical turns, inhibit recombination and prevent the formation of the normally compact resolvase-res complex. Complexes of resolvase with res containing 10 or 21 bp insertions exhibit a pattern of enhanced and suppressed DNase I cleavages that suggest that the intersite segment is curved. This curvature requires both that site I and II are appropriately spaced, and that site III is also present and occupied.     

Synapsis and catalysis by activated Tn3 resolvase mutants

The serine recombinase Tn3 resolvase catalyses recombination between two 114 bp res sites, each of which contains binding sites for three resolvase dimers. We have analysed the in vitro properties of resolvase variants with ‘activating’ mutations, which can catalyse recombination at binding site I of res when the rest of res is absent. Site I × site I recombination promoted by these variants can be as fast as res × res recombination promoted by wild-type resolvase. Activated variants have reduced topological selectivity and no longer require the 2–3′ interface between subunits that is essential for wild-type resolvase-mediated recombination. They also promote formation of a stable synapse comprising a resolvase tetramer and two copies of site I. Cleavage of the DNA strands by the activated mutants is slow relative to the rate of synapsis. Stable resolvase tetramers were not detected in the absence of DNA or bound to a single site I. Our results lead us to conclude that the synapse is assembled by sequential binding of resolvase monomers to site I followed by interaction of two site I-dimer complexes. We discuss the implications of our results for the mechanisms of synapsis and regulation in recombination by wild-type resolvase.     

The identification of three biologically relevant globotriaosyl ceramide receptor binding sites on the Verotoxin 1 B subunit.

The Verotoxin 1 (VT1) B subunit binds to the glycosphingolipid receptor globotriaosylceramide (Gb3). Receptor-binding specificity is associated with the terminally linked Galalpha(1-4) Galbeta disaccharide sequence of the receptor. Recently, three globotriose (Galalpha[1-4] Galbeta [1-4] Glcbeta) binding sites per B-subunit monomer were identified by crystallography. Two of these sites (sites I and II) are located adjacent to phenylalanine-30. Site I was originally predicted as a potential Gb3 binding site on the basis of sequence conservation, and site II was additionally predicted based on computer modelling and receptor docking. The third (site III) was also identified by crystallography and is located at the N-terminal end of the alpha-helix. To determine the biological significance of sites II and III, and to support our previous findings of the significance of site I, we examined the binding properties and cytotoxicity of VT1 mutants designed to block Gb3 binding at each site selectively. The Scatchard analysis of saturation-binding data for each mutant revealed that only the amino acid substitutions predicted to affect site I (D-17E) or site II (G-62T) caused reductions in the binding affinity and capacity of VT1 for Gb3. Similarly, those mutations at sites I and II also caused significant reductions in both Vero and MRC-5 cell cytotoxicity (by seven and five logs, respectively, for G-62T and by four and two logs, respectively, for D-17E). In contrast, the substitution of alanine for W-34 at site III did not reduce the high-affinity binding of the B subunit, despite causing a fourfold reduction in the receptor-binding capacity. The corresponding mutant W-34A holotoxin had a two-log reduction in cytotoxicity on Vero cells and no statistically significant reduction on MRC-5 cells. We conclude that the high-affinity receptor binding most relevant for cell cytotoxicity occurs at sites I and II. In contrast, site III appears to mediate the recognition of additional Gb3 receptor epitopes but with lower affinity. Our results support the significance of the indole ring of W-34 for binding at this site.     

Steady-state kinetic properties of FoF1-ATPase: the pH effect.

1. The kinetic properties of FoF1-ATPase from submitochondrial particles isolated from rat heart were studied, with emphasis to the pH effect. The velocity data were treated according to the Hill equation, and the results were discussed on the basis of the knowledge on the soluble F1-ATPase properties. 2. Three kinetic phases were observed in the range of pH 6.0-8.5, with apparent dissociation constant values (K0.5) of 0.001, 0.04 and 1.5 mM (respectively sites I, II and III) at pH 7.0. Their contribution to the total activity of the enzyme were pH-dependent on the range of 6.0-7.0, but not from 7.0 to 8.5, where the maximal velocity (V) for site III was some 4-fold larger than for site II, and the total V of sites II and III was some 40-fold larger than V assumed for site I. Therefore, two catalytic sites seem to participate significantly in the catalysis at steady-state condition. 3. Azide increased the sites II and III K0.5 values as well as decreased the site III V. In the presence of bicarbonate these two sites were not distinguishable, and the kinetic parameters at pH 7.0 were similar to those for sites II and III combined. Both azide and bicarbonate did not have a significant effect on site I, and this behavior was not pH-dependent. 4. The studies on the effect of pH on the kinetic parameters showed the following results: (1) the optimum pH for V was around 8.5; (2) decrease in the K0.5 values at pH below 7.0 for site II, and increase at pH over 7.0 for sites II and III; (3) in the pH range of 6.0-8.5 the Hill coefficient increased for site II, decreased for site III, and an intermediary effect was observed for the sites II and III combined, with a Michaelis-Menten behavior in the highest affinity pH, which was found in the physiological range.     

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.     

Characterization of a class II defective transposon carrying two haloacetate dehalogenase genes from Delftia acidovorans plasmid pUO1

The two haloacetate dehalogenase genes, dehH1 and dehH2, on the 65-kb plasmid pUO1 from Delftia acidovorans strain B were found to be located on transposable elements. The dehH2 gene was carried on an 8.9-kb class I composite transposon (TnHad1) that was flanked by two directly repeated copies of IS1071, IS1071L and IS1071R. The dehH1 gene was also flanked by IS1071L and a truncated version of IS1071 (IS1071N). TnHad1, dehH1, and IS1071N were located on a 15.6-kb class II transposon (TnHad2) whose terminal inverted repeats and res site showed high homology with those of the Tn21-related transposons. TnHad2 was defective in transposition because of its lacking the transposase and resolvase genes. TnHad2 could transpose when the Tn21-encoded transposase and resolvase were supplied in trans. These results demonstrated that Tn Had2 is a defective Tn21-related transposon carrying another class I catabolic transposon.     

Calcium binding to calmodulin mutants monitored by domain-specific intrinsic phenylalanine and tyrosine fluorescence

Cooperative calcium binding to the two homologous domains of calmodulin (CaM) induces conformational changes that regulate its association with and activation of numerous cellular target proteins. Calcium binding to the pair of high-affinity sites (III and IV in the C-domain) can be monitored by observing calcium-dependent changes in intrinsic tyrosine fluorescence intensity (lambda(ex)/lambda(em) of 277/320 nm). However, calcium binding to the low-affinity sites (I and II in the N-domain) is more difficult to measure with optical spectroscopy because that domain of CaM does not contain tryptophan or tyrosine. We recently demonstrated that calcium-dependent changes in intrinsic phenylalanine fluorescence (lambda(ex)/lambda(em) of 250/280 nm) of an N-domain fragment of CaM reflect occupancy of sites I and II (VanScyoc, W. S., and M. A. Shea, 2001, Protein Sci. 10:1758-1768). Using steady-state and time-resolved fluorescence methods, we now show that these excitation and emission wavelength pairs for phenylalanine and tyrosine fluorescence can be used to monitor equilibrium calcium titrations of the individual domains in full-length CaM. Calcium-dependent changes in phenylalanine fluorescence specifically indicate ion occupancy of sites I and II in the N-domain because phenylalanine residues in the C-domain are nonemissive. Tyrosine emission from the C-domain does not interfere with phenylalanine fluorescence signals from the N-domain. This is the first demonstration that intrinsic fluorescence may be used to monitor calcium binding to each domain of CaM. In this way, we also evaluated how mutations of two residues (Arg74 and Arg90) located between sites II and III can alter the calcium-binding properties of each of the domains. The mutation R74A caused an increase in the calcium affinity of sites I and II in the N-domain. The mutation R90A caused an increase in calcium affinity of sites III and IV in the C-domain whereas R90G caused an increase in calcium affinity of sites in both domains. This approach holds promise for exploring the linked energetics of calcium binding and target recognition.