Functional interaction of reverse gyrase with single-strand binding protein of the archaeon Sulfolobus

Reverse gyrase is a unique hyperthermophile-specific DNA topoisomerase that induces positive supercoiling. It is a modular enzyme composed of a topoisomerase IA and a helicase domain, which cooperate in the ATP-dependent positive supercoiling reaction. Although its physiological function has not been determined, it can be hypothesized that, like the topoisomerase–helicase complexes found in every organism, reverse gyrase might participate in different DNA transactions mediated by multiprotein complexes. Here, we show that reverse gyrase activity is stimulated by the single-strand binding protein (SSB) from the archaeon Sulfolobus solfataricus. Using a combination of in vitro assays we analysed each step of the complex reverse gyrase reaction. SSB stimulates all the steps of the reaction: binding to DNA, DNA cleavage, strand passage and ligation. By co-immunoprecipitation of cell extracts we show that reverse gyrase and SSB assemble a complex in the presence of DNA, but do not make stable protein–protein interactions. In addition, SSB stimulates reverse gyrase positive supercoiling activity on DNA templates associated with the chromatin protein Sul7d. Furthermore, SSB enhances binding and cleavage of UV-irradiated substrates by reverse gyrase. The results shown here suggest that these functional interactions may have biological relevance and that the interplay of different DNA binding proteins might modulate reverse gyrase activity in DNA metabolic pathways.     

In the presence of subunit A inhibitors DNA gyrase cleaves DNA fragments as short as 20 bp at specific sites.

A key step in the supercoiling reaction is the DNA gyrase-mediated cleavage and religation step of double-stranded DNA. Footprinting studies suggest that the DNA gyrase binding site is 100-150 bp long and that the DNA is wrapped around the enzyme with the cleavage site located near the center of the fragment. Subunit A inhibitors interrupt this cleavage and resealing cycle and result in cleavage occurring at preferred sites. We have been able to show that even a 30 bp DNA fragment containing a 20 bp preferred cleavage sequence from the pBR322 plasmid was a substrate for the DNA gyrase-mediated cleavage reaction in the presence of inhibitors. This DNA fragment was cleaved, although with reduced efficiency, at the same sites as a 122 bp DNA fragment. A 20 bp DNA fragment was cleaved with low efficiency at one of these sites and a 10 bp DNA fragment was no longer a substrate. We therefore propose that subunit A inhibitors interact with DNA at inhibitor-specific positions, thus determining cleavage sites by forming ternary complexes between DNA, inhibitors and DNA gyrase.     

DNA gyrase complex with DNA: determinants for site-specific DNA breakage.

DNA gyrase catalyses DNA supercoiling by making a transient double-stranded DNA break within its 120-150 bp binding site on DNA. Addition of the inhibitor oxolinic acid to the reaction followed by detergent traps a covalent enzyme-DNA intermediate inducing sequence-specific DNA cleavage and revealing potential sites of gyrase action on DNA. We have used site-directed mutagenesis to examine the interaction of Escherichia coli gyrase with its major cleavage site in plasmid pBR322. Point mutations have been identified within a short region encompassing the site of DNA scission that reduce or abolish gyrase cleavage in vitro. Mapping of gyrase cleavage sites in vivo reveals that the pBR322 site has the same structure as seen in vitro and is similarly sensitive to specific point changes. The mutagenesis results demonstrate conclusively that a major determinant for gyrase cleavage resides at the break site itself and agree broadly with consensus sequence studies. The gyrase cleavage sequence alone is not a good substrate, however, and requires one or other arm of flanking DNA for efficient DNA breakage. These results are discussed in relation to the mechanism and structure of the gyrase complex.     

A biochemical analysis of the interaction of DNA gyrase with the bacteriophage Mu, pSC101 and pBR322 strong gyrase sites: the role of DNA sequence in modulating gyrase supercoiling and biological activity

Replication of bacteriophage Mu DNA, a process requiring efficient synapsis of the prophage ends, takes place within the confines of the Escherichia coli nucleoid. Critical to ensuring rapid synapsis is the function of the SGS, a strong gyrase site, located at the centre of the Mu genome. Replacement of the SGS by the strong gyrase sites from pSC101 or pBR322 fails to support efficient prophage replication. To probe the unique SGS properties we undertook a biochemical analysis of the interaction of DNA gyrase with the Mu SGS, pSC101 and pBR322 sites. In binding and cleavage assays the order of efficacy was pSC101 > Mu SGS > pBR322. However, in supercoiling assays the Mu SGS (cloned into pUC19) exhibited a strong enhancement of gyrase-catalysed supercoiling over pUC19 alone; the pSC101 site showed none and the pBR322 site gave a moderate improvement. Most striking was the Mu SGS-dependent increase in processivity of the gyrase reaction. This highly processive supercoiling coupled with efficient binding may account for the unique biological properties of the SGS. The results emphasize the importance of the DNA substrate as an active component in modulating the gyrase supercoiling reaction, and in determining the biological roles of specialized gyrase sites.     

Evidence for the role of DNA strand passage in the mechanism of action of microcin B17 on DNA gyrase

Microcin B17 (MccB17) is a DNA gyrase poison; in previous work, this bacterial toxin was found to slowly and incompletely inhibit the reactions of supercoiling and relaxation of DNA by gyrase and to stabilize the cleavage complex, depending on the presence of ATP and the DNA topology. We now show that the action of MccB17 on the gyrase ATPase reaction and cleavage complex formation requires a linear DNA fragment of more than 150 base pairs. MccB17 is unable to stimulate the ATPase reaction by stabilizing the weak interactions between short linear DNA fragments (70 base pairs or less) and gyrase, in contrast with the quinolone ciprofloxacin. However, MccB17 can affect the ATP-dependent relaxation of DNA by gyrase lacking its DNA-wrapping or ATPase domains. From these findings, we propose a mode of action of MccB17 requiring a DNA molecule long enough to allow the transport of a segment through the DNA gate of the enzyme. Furthermore, we suggest that MccB17 may trap a transient intermediate state of the gyrase reaction present only during DNA strand passage and enzyme turnover. The proteolytic signature of MccB17 from trypsin treatment of the full enzyme requires DNA and ATP and shows a protection of the C-terminal 47-kDa domain of gyrase, indicating the involvement of this domain in the toxin mode of action and consistent with its proposed role in the mechanism of DNA strand passage. We suggest that the binding site of MccB17 is in the C-terminal domain of GyrB.     

The interaction between coumarin drugs and DNA gyrase

The coumarin group of antibiotics have as their target the bacterial enzyme DNA gyrase. The drugs bind to the B subunit of gyrase and inhibit DNA supercoiling by blocking the ATPase activity. Recent data show that the binding site for the drugs lies within the N-terminal part of the B protein, and individual amino acids involved in coumarin interaction are being identified. The mode of inhibition of the gyrase ATPase reaction by coumarins is unlikely to be simple competitive inhibition, and the drugs may act by stabilizing a conformation of the enzyme with low affinity for ATP.     

Locking the ATP-operated clamp of DNA gyrase: probing the mechanism of strand passage

DNA gyrase catalyses DNA supercoiling by passing one segment of DNA (the T segment) through another (the G segment) in a reaction coupled to the binding and hydrolysis of ATP. The N-terminal domains of the gyrase B dimer constitute an ATP-operated clamp that is proposed to capture the T segment during the DNA supercoiling reaction. We have locked this clamp in the closed conformation using the non-hydrolysable ATP analogue ADPNP (5'-adenylyl beta,gamma-imidodiphosphate). The clamp-locked enzyme is able to bind and cleave DNA, albeit at a reduced level. Although the locked enzyme is not capable of carrying out DNA supercoiling, it can catalyse limited DNA relaxation, consistent with the ability to complete one strand passage event per enzyme molecule via entry of the T segment through the exit gate of the enzyme. The DNA-protein complex of the clamp-locked enzyme has a conformation that differs from the normal positively wrapped conformation of the gyrase-DNA complex. These experiments confirm the role of the ATP-operated clamp in the strand-passage reactions of gyrase and suggest a model for the interaction of DNA with gyrase in which a conformation with the T segment in equilibrium across the DNA gate can be achieved via T-segment entry through the ATP-operated clamp or through the exit gate.     

Evidence for a conformational change in the DNA gyrase-DNA complex from hydroxyl radical footprinting.

We have used the technique of hydroxyl radical footprinting to probe the complex between DNA gyrase and a 198 bp DNA fragment containing the preferred gyrase cleavage site from plasmid pBR322. We find that gyrase protects 128 bp from the hydroxyl radical with the central 13 bp (adjacent to the gyrase cleavage site) being most strongly protected. Flanking the central region are arms showing periodic protection from the reagent suggesting a helical repeat of 10.6 bp, consistent with the DNA being wrapped upon the enzyme surface. The presence of 5'-adenylyl-beta,gamma-imidodiphosphate or a quinolone drug causes alteration of the protection pattern consistent with a conformational change in the complex involving one arm of the wrapped DNA. The significance of these results for the mechanism of DNA supercoiling by gyrase is discussed.     

Dissection of the bacteriophage Mu strong gyrase site (SGS): significance of the SGS right arm in Mu biology and DNA gyrase mechanism

The bacteriophage Mu strong gyrase site (SGS), required for efficient phage DNA replication, differs from other gyrase sites in the efficiency of gyrase binding coupled with a highly processive supercoiling activity. Genetic studies have implicated the right arm of the SGS as a key structural feature for promoting rapid Mu replication. Here, we show that deletion of the distal portion of the right arm abolishes efficient binding, cleavage, and supercoiling by DNA gyrase in vitro. DNase I footprinting analysis of the intact SGS revealed an adenylyl imidodiphosphate-dependent change in protection in the right arm, indicating that this arm likely forms the T segment that is passed through the cleaved G segment during the supercoiling reaction. Furthermore, in an SGS derivative with an altered right-arm sequence, the left arm showed these changes, suggesting that the selection of a T segment by gyrase is determined primarily by the sequences of the arms. Analysis of the sequences of the SGS and other gyrase sites suggests that the choice of T segment correlates with which arm possesses the more extensive set of phased anisotropic bending signals, with the Mu right arm possessing an unusually extended set of such signals. The implications of these observations for the structure of the gyrase-DNA complex and for the biological function of the Mu SGS are discussed.     

Identification of four GyrA residues involved in the DNA breakage-reunion reaction of DNA gyrase

DNA supercoiling by DNA gyrase involves the cleavage of a DNA helix, the passage of another helix through the break, and the religation of the first helix. The cleavage-religation reaction involves the formation of a 5'-phosphotyrosine intermediate with the GyrA subunit of the gyrase (A(2)B(2)) complex. We report the characterization of mutations near the active-site tyrosine residue in GyrA predicted to affect the cleavage-religation reaction of gyrase. We find that mutations at Arg32, Arg47, His78 and His80 inhibit DNA supercoiling and other reactions of gyrase. These effects are caused by the involvement of these residues in the DNA cleavage reaction; religation is largely unaffected by these mutations. We show that these residues cooperate with the active-site tyrosine residue on the opposite subunit of the GyrA dimer during the cleavage-religation reaction.     

Characterization of quercetin binding site on DNA gyrase

Gyrases are DNA topology modifying enzymes present only in prokaryotes which makes them an attractive target for antibacterial drugs. Quercetin, one of the most abundant natural flavonoids, inhibits supercoiling activity of bacterial gyrase and induces DNA cleavage. It has been generally assumed that the mechanism of flavonoid inhibition is based on interaction with DNA. We show that quercetin binds to the 24 kDa fragment of gyrase B of Escherichia coli with a K(D) value of 15 microM and inhibits ATPase activity of gyrase B. Its binding site overlaps with ATP binding pocket and could be competitively replaced by either ATP or novobiocin. The structural model of quercetin-gyrase complex was prepared, based on the close similarity with ATP and quercetin binding sites of the src family tyrosine kinase Hck. We propose that quercetin inhibits gyrases through two different mechanisms based either on interaction with DNA or with ATP binding site of gyrase.     

Nucleotide- and stoichiometry-dependent DNA supercoiling by reverse gyrase

Reverse gyrase is a unique type IA topoisomerase that can introduce positive supercoils into DNA. We have investigated some of the biochemical properties of Archaeoglobus fulgidus reverse gyrase. It can mediate three distinct supercoiling reactions depending on the adenine nucleotide cofactor that is present in the reaction. Besides the ATP-driven positive supercoiling reaction, the enzyme can introduce negative supercoils with a nonhydrolyzable analog, adenylyl imidodiphosphate. In the presence of ADP the plasmid DNA is relaxed almost completely, leaving a very low level of positive supercoiling. Surprisingly, the final supercoiling extent for all three distinct reactions depends on the stoichiometry of enzyme to DNA. This dependence is not due to the difference of reaction rate, suggesting that the amount of enzyme bound to DNA is an important determinant for the final supercoiling state of the reaction product. Reverse gyrase also displays exquisite sensitivity toward temperature. Raising the reaction temperatures from 80 to 85 degrees C, both of which are within the optimal growth temperature of A. fulgidus, greatly increases enzyme activity for all the supercoiling reactions. For the reaction with AMPPNP, the product is a hypernegatively supercoiled DNA. This dramatic enhancement of the reverse gyrase activity is also correlated with the appearance of DNA in a pre-melting state at 85 degrees C, likely due to the presence of extensively unwound regions in the plasmid. The possible mechanistic insights from these findings will be presented here.     

Isoleucine 10 is essential for DNA gyrase B function in Escherichia coli

DNA gyrase is an essential enzyme that regulates the DNA topology in bacteria. It belongs to the type II DNA topoisomerase family and is responsible for the introduction of negative supercoils into DNA at the expense of hydrolysis of ATP molecules. The aim of the present work was to study the contribution of I10, one of the most important residues responsible for the stabilization of GyrB dimer and involved in the ATP-binding step, in the ATP-hydrolysis reaction and in the DNA supercoiling mechanism. We constructed MBP-tagged GyrB mutants I10G and Delta4-14. Our results demonstrate that both mutations severely affect the DNA-dependent ATPase activity and DNA supercoiling. Mutation of Y5 residue involved in the formation of ATPase catalytic site (Y5G mutant) had only little effect on the DNA-dependent ATPase activity and DNA supercoiling. Interestingly, the DNA-relaxation activity of MBP-GyrB mutants and wild type was completely inhibited by ATP. Binding of ADPNP to MBP-tagged mutants was significantly decreased. ADPNP had no effect on DNA-relaxation activity of MBP-tagged mutants but was able to inhibit MBP-tagged wild type enzyme. Our results demonstrate that GyrB N-terminal arm, and specially I10 residue is essential for ATP binding/hydrolysis efficiency and DNA transfer through DNA gyrase.     

An Escherichia coli DNA topoisomerase I mutant has a compensatory mutation that alters two residues between functional domains of the DNA gyrase A protein.

Nucleotide sequence analysis revealed that the compensatory gyrA mutation in Escherichia coli DM750 affects DNA supercoiling by interchanging the identities of Ala-569 and Thr-586 in the DNA gyrase A subunit. These residues flank Arg-571, a site for trypsin cleavage that splits gyrase A protein between DNA breakage-reunion and DNA-binding domains. The putative interdomain locations of the DM750 mutation and that of E. coli DM800 (in gyrase B protein) suggests that these compensatory mutations may reduce DNA supercoiling activity by altering allosteric interactions in the gyrase complex.     

DNA gyrase on the bacterial chromosome. Oxolinic acid-induced DNA cleavage in the dnaA-gyrB region

Oxolinic acid forms complexes with gyrase and DNA in such a way that subsequent denaturation of gyrase reveals DNA cleavage. Cleavage sites were mapped in a 10,000 base-pair region of the Escherichia coli chromosome containing the dnaA, dnaN, recF, and gyrB genes. Twenty-four cleavage sites were identified. The sites were cleaved at different frequencies, with the most frequent cleavage occurring within gyrB. Not all sites were equally sensitive to oxolinic acid concentration, some sites exhibited an altered cleavage frequency when the gyrB225 delta topA mutant strain DM800 was compared with wild-type cells, and coumermycin selectively changed the cleavage frequency at a few sites in the mutant strain DM800. These perturbations appear to alter the frequency of cleavage at a site but not the location of the site. The availability of many sites of differing strengths may be an important factor in the ability of gyrase to fine-tune the level of supercoiling or provide local swivels in bacterial DNA.     

The "GyrA-box" is required for the ability of DNA gyrase to wrap DNA and catalyze the supercoiling reaction

DNA gyrase is the only topoisomerase that can introduce negative supercoils into DNA. It is thought that the binding of conventional type II topoisomerases, including topoisomerase IV, to DNA takes place at the catalytic domain across the DNA gate, whereas DNA gyrase binds to DNA not only at the amino-terminal catalytic domain but also at the carboxyl-terminal domain (CTD) of the GyrA subunit. The binding of the GyrA CTD to DNA allows gyrase to wrap DNA around itself and catalyze the supercoiling reaction. Recent structural studies, however, have revealed striking similarities between the GyrA CTD and the ParC CTD, as well as the ability of the ParC CTD to bind and bend DNA. Thus, the molecular basis of gyrase-mediated wrapping of DNA needs to be reexamined. Here, we have conducted a mutational analysis to determine the role of the "GyrA-box," a 7-amino acid-long motif unique to the GyrA CTD, in determining the DNA binding mode of gyrase. Either a deletion of the entire GyrA-box or substitution of the GyrA-box with 7 Ala residues abolishes the ability of gyrase to wrap DNA around itself and catalyze the supercoiling reaction. However, these mutations do not affect the relaxation and decatenation activities of gyrase. Thus, the presence of a GyrA-box allows gyrase to wrap DNA and catalyze the supercoiling reaction. The consequence of the loss of the GyrA-box during evolution of bacterial type II topoisomerases is discussed.     

DNA gyrase on the bacterial chromosome: DNA cleavage induced by oxolinic acid.

Treatments in vivo of Escherichia coli with oxolinic acid, a potent inhibitor of DNA gyrase and DNA synthesis, lead to DNA cleavage when extracted chromosomes are incubated with sodium dodecyl sulfate. This DNA breakage has properties similar to those obtained in vitro with DNA gyrase reaction mixtures designed to assay production of supertwists: it is oxolinic acid-dependent, sodium dodecyl sulfate-activated, and at saturating drug concentrations produces double-strand DNA cleavage with a concommitant tight association of protein and DNA. In addition, identical treatments performed on a nalA mutant strain exhibit no DNA cleavage. Thus the DNA cleavage sites probably correspond to chromosomal DNA gyrase sites. Sedimentation measurements of the DNA cleavage products indicate that there are approximately 45 DNA breaks per chromosome. This value is similar to the number of domains of supercoiling found in isolated Escherichia coli chromosomes, suggesting one gyrase site per domain. At low oxolinic acid concentrations single-strand cleavages predominate after sodium dodecyl sulfate treatment, and the inhibition of DNA synthesis parallels the number of sites that obtain a single-strand scission. Double-strand breaks arise from the accumulation of single-strand cleavages in accordance with a model where each cleavage site contains two independent drug targets, one on each DNA strand. Since the nicking-closing subunit of gyrase is the target of oxolinic acid in vitro, we suggest that each gyrase site contains two nicking-closing subunits, one on each DNA strand, and that DNA synthesis requires both to be functional.     

Binding of two DNA molecules by type II topoisomerases for decatenation

Topoisomerases (topos) maintain DNA topology and influence DNA transaction processes by catalysing relaxation, supercoiling and decatenation reactions. In the cellular milieu, division of labour between different topos ensures topological homeostasis and control of central processes. In Escherichia coli, DNA gyrase is the principal enzyme that carries out negative supercoiling, while topo IV catalyses decatenation, relaxation and unknotting. DNA gyrase apparently has the daunting task of undertaking both the enzyme functions in mycobacteria, where topo IV is absent. We have shown previously that mycobacterial DNA gyrase is an efficient decatenase. Here, we demonstrate that the strong decatenation property of the enzyme is due to its ability to capture two DNA segments in trans. Topo IV, a strong dedicated decatenase of E. coli, also captures two distinct DNA molecules in a similar manner. In contrast, E. coli DNA gyrase, which is a poor decatenase, does not appear to be able to hold two different DNA molecules in a stable complex. The binding of a second DNA molecule to GyrB/ParE is inhibited by ATP and the non-hydrolysable analogue, AMPPNP, and by the substitution of a prominent positively charged residue in the GyrB N-terminal cavity, suggesting that this binding represents a potential T-segment positioned in the cavity. Thus, after the GyrA/ParC mediated initial DNA capture, GyrB/ParE would bind efficiently to a second DNA in trans to form a T-segment prior to nucleotide binding and closure of the gate during decatenation.     

Dissection of the nucleotide cycle of B. subtilis DNA gyrase and its modulation by DNA

DNA topoisomerases catalyze the inter-conversion of different topological forms of DNA. While all type II DNA topoisomerases relax supercoiled DNA, DNA gyrase is the only enyzme that introduces negative supercoils into DNA at the expense of ATP hydrolysis. We present here a biophysical characterization of the nucleotide cycle of DNA gyrase from Bacillus subtilis, both in the absence and presence of DNA. B. subtilis DNA gyrase is highly homologous to its well-studied Escherichia coli counterpart, but exhibits unique mechanistic features. The active heterotetramer of B. subtilis DNA gyrase is formed by mixing the GyrA and GyrB subunits. GyrB undergoes nucleotide-induced dimerization and is an ATP-operated clamp. The intrinsic ATPase activity of gyrase is stimulated tenfold in the presence of plasmid DNA. However, in contrast to the E. coli homolog, the rate-limiting step in the nucleotide cycle of B. subtilis GyrB is ATP hydrolysis, not product dissociation or an associated conformational change. Furthermore, there is no cooperativity between the two DNA and ATP binding sites in B. subtilis DNA gyrase. Nevertheless, the enzyme is as efficient in negative supercoiling as the E. coli DNA gyrase. Our results provide evidence that the evolutionary goal of efficient DNA supercoiling can be realized by similar architecture, but differences in the underlying mechanism. The basic mechanistic features are conserved among DNA gyrases, but the kinetics of individual steps can vary significantly even between closely related enzymes. This suggests that each topoisomerase represents a different solution to the complex reaction sequence in DNA supercoiling.