Interactions of CcdB with DNA gyrase. Inactivation of Gyra, poisoning of the gyrase-DNA complex, and the antidote action of CcdA.

The F plasmid-carried bacterial toxin, the CcdB protein, is known to act on DNA gyrase in two different ways. CcdB poisons the gyrase-DNA complex, blocking the passage of polymerases and leading to double-strand breakage of the DNA. Alternatively, in cells that overexpress CcdB, the A subunit of DNA gyrase (GyrA) has been found as an inactive complex with CcdB. We have reconstituted the inactive GyrA-CcdB complex by denaturation and renaturation of the purified GyrA dimer in the presence of CcdB. This inactivating interaction involves the N-terminal domain of GyrA, because similar inactive complexes were formed by denaturing and renaturing N-terminal fragments of the GyrA protein in the presence of CcdB. Single amino acid mutations, both in GyrA and in CcdB, that prevent CcdB-induced DNA cleavage also prevent formation of the inactive complexes, indicating that some essential interaction sites of GyrA and of CcdB are common to both the poisoning and the inactivation processes. Whereas the lethal effect of CcdB is most probably due to poisoning of the gyrase-DNA complex, the inactivation pathway may prevent cell death through formation of a toxin-antitoxin-like complex between CcdB and newly translated GyrA subunits. Both poisoning and inactivation can be prevented and reversed in the presence of the F plasmid-encoded antidote, the CcdA protein. The products of treating the inactive GyrA-CcdB complex with CcdA are free GyrA and a CcdB-CcdA complex of approximately 44 kDa, which may correspond to a (CcdB)2(CcdA)2 heterotetramer.

Reverse gyrase from Methanopyrus kandleri. Reconstitution of an active extremozyme from its two recombinant subunits.

Reverse gyrases are ATP-dependent type I 5'-topoisomerases that positively supercoil DNA. Reverse gyrase from Methanopyrus kandleri is unique as the first heterodimeric type I 5'-topoisomerase described, consisting of a 138-kDa subunit involved in the hydrolysis of ATP (RgyB) and a 43-kDa subunit that forms the covalent complex with DNA during the topoisomerase reaction (RgyA). Here we report the reconstitution of active reverse gyrase from the two recombinant proteins overexpressed in Escherichia coli. Both proteins have been purified by column chromatography to >90% homogeneity. RgyB has a DNA-dependent ATPase activity at high temperature (80 degrees C) and is independent of the presence of RgyA. RgyA alone has no detectable activity. The addition of RgyA to RgyB reconstitutes positive supercoiling activity, but the RgyB and RgyA subunits form a stable heterodimer only after being heated together. This is the first case in which it has been possible to reconstitute an active heterodimeric enzyme of a hyperthermophilic prokaryote from recombinant proteins.

The interaction of the F plasmid killer protein, CcdB, with DNA gyrase: induction of DNA cleavage and blocking of transcription.

We have studied the interaction of the F plasmid killer protein CcdB with its intracellular target DNA gyrase. We confirm that CcdB can induce DNA cleavage by gyrase and show that this cleavage reaction requires ATP hydrolysis when the substrate is linear DNA, but is independent of hydrolysis when negatively supercoiled DNA is used. The 64 kDa domain of the gyrase A protein, which can catalyse DNA cleavage in the presence of the B protein and quinolone drugs, is unable to cleave DNA in the presence of CcdB unless the C-terminal 33 kDa domain of the gyrase A protein is also present. CcdB-induced DNA cleavage by gyrase requires a minimum length of DNA (> approximately 160 bp), whereas in the presence of quinolone drugs gyrase can cleave much shorter DNA molecules. We show that CcdB, like quinolones, can form a complex with gyrase which can block transcription by RNA polymerase. A model for the interaction of CcdB with gyrase involving the trapping of a post-strand-passage intermediate is suggested. We conclude that CcdB can stabilise a cleavage complex between DNA gyrase and DNA in a manner distinct from quinolones but, like the quinolone-induced cleavage complex, the CcdB-stabilised complex can also form a barrier to the passage of polymerases.

Mutations in the B subunit of Escherichia coli DNA gyrase that affect ATP-dependent reactions.

We have previously reported specific labeling of Escherichia coli DNA gyrase by the ATP affinity analog pyridoxal 5'-diphospho-5'adenosine (PLP-AMP), which resulted in inhibition of ATP-dependent reactions. The analog was found to be covalently bound at Lys103 and Lys110 on the gyrase B subunit (Tamura, J. K., and Gellert, M. (1990) J. Biol. Chem. 265, 21342-21349). In this study, the importance of these two lysine residues is examined by site-directed mutagenesis. Substitutions of Lys 103 result in the loss of ATP-dependent functions. These mutants are unable to supercoil DNA, to hydrolyze ATP, or to bind a nonhydrolysable ATP analog, 5'-adenylyl-beta,gamma-imidodiphosphate (ADPNP). The ATP-independent functions of gyrase, such as relaxation of negatively supercoiled DNA and oxolinic acid-induced cleavage of double-stranded DNA, are unaffected by these mutations, suggesting that the mutant B subunits are assembling correctly with the A subunits. Gyrase with substitutions of Lys110 retains all activities. However, the affinity of ATP is decreased. The DNA supercoiling activity of gyrase A2B2, tetramers reconstituted with varying ratios of inactive mutant and wild-type gyrase B subunits is consistent with a mechanism of DNA supercoiling that requires the interdependent activity of both B subunits in ATP binding and hydrolysis.

Energy coupling in Escherichia coli DNA gyrase: the relationship between nucleotide binding, strand passage, and DNA supercoiling.

Binding of the nonhydrolyzable ATP analogue 5'-adenylyl-beta, gamma-imidodiphosphate (ADPNP) to Escherichia coli DNA gyrase can lead to a limited noncatalytic supercoiling of DNA. Here we examine the efficiency of coupling between ADPNP binding and the change in linking number either of positively or negatively supercoiled plasmid DNA or of small DNA circles. The coupling efficiency varies from 100% (delta Lk = -2 per gyrase tetramer, a stoichiometry of 1) with positively supercoiled substrates under certain reaction conditions to an undetectably low value with moderately negatively supercoiled substrates (sigma = -0.046) or small circular substrates. Furthermore, the rate of ADPNP binding to the gyrase-DNA complex is also dependent on the topological state of the DNA; the previously observed slow binding of ADPNP to the complex of gyrase with linear DNA is accelerated 16-fold when the substrate DNA is negatively supercoiled, suggesting a functional interaction between the nucleotide-binding and DNA-binding domains which is independent of the strand-passage process. The implications for the normal ATP-dependent supercoiling reaction of the enzyme are considered and the results discussed in terms of current mechanistic models for DNA gyrase action and the possible in vivo roles of the enzyme.

DNA supercoiling by DNA gyrase. A static head analysis.

Using purified DNA gyrase to supercoil circular plasmid pBR322 DNA, we examined how the linking number attained at the steady state ('static head') varies with the concentrations of ATP and ADP, both in the absence and presence of spermidine. In the absence of spermidine at total adenine nucleotide concentrations between 0.35 and 1.4 mM, the static-head linking number was independent of the sum concentration of ATP and ADP, but depended strongly on the ratio of their concentrations. We established that the same linking number was attained independent of the direction from which the steady state was approached. The decrease in linking number at static head is more extensive when spermidine is present in the incubation, but remains a function of the [ATP]-to-[ADP] ratio. These results are discussed in terms of various kinetic schemes for DNA gyrase. We present one kinetic scheme that accounts for the experimental observations. According to this scheme our experimental results imply that there is significant slip in DNA gyrase when spermidine is absent. It is possible that spermidine acts through adjustment of the degree coupling of DNA gyrase.

Effects of DNA supercoiling on the topological properties of nucleosomes.

In the nucleosome core particle, at least 145 base pairs of DNA are bound to the histone octamer in a superhelical conformation. We have asked what effect the presence of these particles has on the ability of DNA gyrase to supercoil DNA. Synthetic minichromosomes, constructed by reconstituting complexes of core histones with the closed circular plasmid pBR322, were treated with various amounts of DNA gyrase. We have found that the maximum level of supercoiling that is attainable is nearly identical for protein-free plasmids and for plasmids half-saturated with core histones, even though supercoiling does not result in a loss of histones from the complex. It appears that, at sufficiently high levels of supercoiling, the core particle is disrupted in such a way that the DNA bound to histones is no longer constrained.

DNA sequence of the E. coli gyrB gene: application of a new sequencing strategy.

We have determined the sequence of the E. coli gyrB gene, using a new sequencing approach in which transposition from a mini-Mu plasmid into the DNA provides random start points for dideoxynucleotide sequence analysis. The gyrB sequence corresponds to a protein 804 amino acids long; a previously isolated protein fragment with partial enzymatic activity has been identified as the C-terminal half-molecule. A plausible terminator of gyrB transcription is located just beyond the structural gene.

Cloning and simplified purification of Escherichia coli DNA gyrase A and B proteins.

We have transferred the Escherichia coli gyrA and gyrB genes onto plasmids that allow the overproduction of the DNA gyrase A and B proteins and have designed relatively simple purification procedures for both proteins. The pure proteins are obtained in good yield; from 2 liters of culture (12 g of cells), one can recover 25 mg of GyrA or 3 mg of GyrB protein.

Mutations in the DNA gyrB gene that are temperature sensitive for lambda site-specific recombination, Mu growth, and plasmid maintenance.

We report the isolation of two mutations in the gyrB gene of Escherichia coli K12 obtained from an initial selection for resistance to coumermycin A1 and a subsequent screening for bacteria that fail to support site-specific recombination of phage lambda, i.e., Him-. These two mutations have a temperature-sensitive Him- phenotype, supporting site-specific recombination efficiently at low temperature, but inefficiently at high temperatures. Like other Him mutants, the gyrB-him mutants fail to plate phage Mu; again this defect is observed only at high temperatures. Additional thermally sensitive characteristics have also been observed; growth of lambda as well as maintenance of the plasmids pBR322 and F' gal are reduced at high temperature. Restriction of foreign DNA imposed by a P1 prophage is also reduced in these mutants. The temperature-sensitive phenotypic characteristics imposed by both the gyrB-him-230(Ts) and gyrB-him-231(Ts) mutations correlate with in vitro studies that show decreased gyrase activity, especially at higher temperatures, and in vivo studies showing reduced supercoiling of lambda DNA in the mutants at high temperature.

Slow cruciform transitions in palindromic DNA.

Extrusion of cruciform structures in self-complementary regions of DNA is known to be favored by negative supercoiling of DNA. We show here that, in moderately supercoiled DNA, cruciform extrusion is a very slow process. In plasmid pUC7 DNA, with a 48-base-pair palindrome, the half-time of extrusion at 50 degrees C is typically several hours; rates are even slower at lower temperature. The rates increase significantly with increasing DNA supercoiling but are only slightly faster in DNA species with much longer palindromes. The reabsorption of cruciform arms is also very slow. The equilibrium between cruciform and regular DNA structures is sensitive to changes in the linking number. Measurement of this equilibrium leads to an estimate of 18 kcal/mol (75.3 kJ/mol) for the free energy required to generate a cruciform structure. In bacterial cells, cruciform DNA may be rare, even when it is thermodynamically favored, because of its slow formation.

Site-specific interaction of DNA gyrase with DNA.

DNA gyrase, in the presence of the inhibitor oxolinic acid, can induce double-strand DNA breakage at specific sites. The sequences at several sites have been determined. In addition, the structure of complexes formed between DNA gyrase and restriction fragments containing an oxolinic acid-promoted cleavage site has been examined by DNase protection methods. DNA gyrase protects more than 120 base pairs of DNA against pancreatic DNase in a region surrounding the cleavage site. Protection is observed both in the presence and absence of oxolinic acid. Protected DNA flanking the cleavage site contains DNase I-sensitive sites spaced on the average 10 or 11 base pairs apart. This result supports the view that, in the DNA gyrase--DNA complex, the DNA is largely wrapped on the outside of the enzyme.

DNA gyrase action involves the introduction of transient double-strand breaks into DNA.

DNA gyrase from Escherichia coli, in the presence of ATP, can both separate catenated DNA circles and unknot knotted DNA. Both these reactions require passage of a DNA segment through a transient double-strand break in DNA. Evidence that transient double-strand breaks are also involved in the supercoiling and relaxing activities of DNA gyrase is derived from experiments showing that the linking number of circular DNA is changed in steps of two. A mechanism is proposed for the action of the enzyme.

DNA gyrase: purification and catalytic properties of a fragment of gyrase B protein.

A protein isolated from Escherichia coli complements the DNA gyrase A (NalA) protein to generate an activity that relaxes supercoiled DNA. Oxolinic acid, a known inhibitor of DNA gyrase, blocks this activity and causes double-strand cleavage of DNA at the same sites as are attacked by DNA gyrase. The protein, of molecular weight 50,000, appears to be fragment of the DNA gyrase B (Cou) protein (molecular weight, 90,000) as judged by the identical sizes of numerous peptides produced by partial proteolytic digestion. The complex of this fragment and the gyrase A protein lacks both the DNA-supercoiling and DNA-dependent ATPase activities of DNA gyrase.

DNA gyrase: subunit structure and ATPase activity of the purified enzyme.

DNA gyrase has been purified to near homogeneity from Escherichia coli. The enzyme consists of two subunits of molecular weights 90,000 and 100,000 present in roughly equimolar amounts. The subunits can be identified as the products of two genes, determining resistance to coumermycin A1 and novobiocin (cou) and to nalidixic acid and oxolinic acid (nalA), respectively. These antibiotics were previously shown to be specific inhibitors of DNA gyrase. The ATPase activity of DNA gyrase is stimulated by double-stranded DNA and strongly inhibited by novobiocin but is relatively insensitive to oxolinic acid. Covalent attachment of an ATP derivative to the smaller (coumermycin-specific) subunit is also inhibited by novobiocin, suggesting that this drug interferes with the energy-coupling aspect of the DNA supercoiling reaction by blocking the access of ATP to the enzyme.

Nalidixic acid resistance: a second genetic character involved in DNA gyrase activity.

ATP-dependent DNA supercoiling catalyzed by Escherichia coli DNA gyrase was inhibited by oxolinic acid, a compound similar to but more potent than nalidixic acid and a known inhibitor of DNA replication in E. coli. The supercoiling activity of DNA gyrase purified from nalidixic acid-resistant mutant (nalA(R)) bacteria was resistant to oxolinic acid. Thus, the nalA locus is responsible for a second component needed for DNA gyrase activity in addition to the component determined by the previously described locus for resistance to novobiocin and coumermycin (cou). Supercoiling of lambda DNA in E. coli cells was likewise inhibited by oxolinic acid, but was resistant in the nalA(R) mutant. The inhibition by oxolinic acid of colicin E1 plasmid DNA synthesis in a cell-free system was largely relieved by adding resistant DNA gyrase. In the absence of ATP, DNA gyrase preparations relaxed supercoiled DNA; this activity was also inhibited by oxolinic acid, but not by novobiocin. It appears that the oxolinic acid-sensitive component of DNA gyrase is involved in the nicking-closing activity required in the supercoiling reaction. In the presence of oxolinic acid, DNA gyrase forms a complex with DNA, which can be activated by later treatment with sodium dodecyl sulfate and a protease to produce double-strand breaks in the DNA. This process has some similarities to the known properties of relaxation complexes.

Novobiocin and coumermycin inhibit DNA supercoiling catalyzed by DNA gyrase.

Novobiocin and coumermycin are known to inhibit the replication of DNA iing of DNA catalyzed by E. coli DNA gyrase, a recently discovered enzyme that introduces negative superhelical turns into covalently circular DNA. The activity of DNA gyrase purified from a coumermycin-resistant mutant strain is resistant to both drugs. The inhibition by novobiocin of colicin E1 plasmid DNA replication in a cell-free system is partially relieved by adding resistant DNA gyrase. Both in the case of coliclls. DNA molecules which are converted to the covalently circular form in thepresence of coumermycin remain relaxed, instead of achieving their normal supercoiled conformation. We conclude that DNA gyrase controls the supercoiling of DNA in E. coli.