DNA topology: topoisomerases keep it simple.

The ability of type II DNA topoisomerases to perturb the equilibrium distributions of DNA topoisomers is a consequence of their ability to hydrolyse ATP. A sliding mechanism of topoisomerase action has been proposed to account for this phenomenon.

The twist, writhe and overall shape of supercoiled DNA change during counterion-induced transition from a loosely to a tightly interwound superhelix. Possible implications for DNA structure in vivo.

A cryo-electron microscopy study of supercoiled DNA molecules freely suspended in cryo-vitrified buffer was combined with Monte Carlo simulations and gel electrophoretic analysis to investigate the role of intersegmental electrostatic repulsion in determining the shape of supercoiled DNA molecules. It is demonstrated here that a decrease of DNA-DNA repulsion by increasing concentrations of counterions causes a higher fraction of the linking number deficit to be partitioned into writhe. When counterions reach concentrations likely to be present under in vivo conditions, naturally supercoiled plasmids adopt a tightly interwound conformation. In these tightly supercoiled DNA molecules the opposing segments of interwound superhelix seem to directly contact each other. This form of supercoiling, where two DNA helices interact laterally, may represent an important functional state of DNA. In the particular case of supercoiled minicircles (178 bp) the delta Lk = -2 topoisomers undergo a sharp structural transition from almost planar circles in low salt buffers to strongly writhed "figure-eight" conformations in buffers containing neutralizing concentrations of counterions. Possible implications of this observed structural transition in DNA are discussed.

Coupling ATP hydrolysis to DNA strand passage in type IIA DNA topoisomerases.

Type IIA topos (topoisomerases) catalyse topological conversions of DNA through the passage of one double strand through a transient break in another. In the case of the archetypal enzyme, DNA gyrase, it has always been apparent that the enzyme couples the free energy of ATP hydrolysis to the introduction of negative supercoiling, and the structural details of this process are now becoming clearer. The homologous type IIA enzymes such as topo IV and eukaryotic topo II also require ATP and it has more recently been shown that the energy of hydrolysis is coupled to a reduction of supercoiling or catenation (linking) beyond equilibrium. The mechanism behind this effect is less clear. We review the energy coupling process in both classes of enzyme and describe recent mechanistic and structural work on gyrase that addresses the mechanism of energy coupling.

DNA gyrase can supercoil DNA circles as small as 174 base pairs.

DNA gyrase introduces negative supercoils into closed-circular DNA using the free energy of ATP hydrolysis. Consideration of steric and thermodynamic aspects of the supercoiling reaction indicates that there should be a lower limit to the size of DNA circle which can be supercoiled by gyrase. We have investigated the supercoiling reaction of circles from 116-427 base pairs (bp) in size and have determined that gyrase can supercoil certain relaxed isomers of circles as small as 174 bp, dependent on the final superhelix density of the supercoiled product. Furthermore, this limiting superhelical density (-0.11) is the same as that determined for the supercoiling of plasmid pBR322. We also find that although circles in the range 116-152 bp cannot be supercoiled, they can nevertheless be relaxed by gyrase when positively supercoiled. These data suggest that the conformational changes associated with the supercoiling reaction can be carried out by gyrase in a circle as small as 116 bp. We discuss these results with respect to the thermodynamics of DNA supercoiling and steric aspects of the gyrase mechanism.

Slow interaction of 5'-adenylyl-beta,gamma-imidodiphosphate with Escherichia coli DNA gyrase. Evidence for cooperativity in nucleotide binding.

We have examined the kinetics of interaction between Escherichia coli DNA gyrase and the nonhydrolyzable ATP analog 5'-adenylyl-beta,gamma-imidodiphosphate (ADPNP) in the presence and absence of ATP. In the absence of ATP, [alpha-32P]ADPNP binds extremely slowly to gyrase, with an apparent second-order rate constant (k1) of 120 M-1 min-1. Similarly, the limited negative supercoiling of closed-circular DNA caused by ADPNP binding is slow, requiring at least 2 h to reach completion in the presence of 100 microM ADPNP. A very slow but detectable rate of dissociation of ADPNP from gyrase was measured, with a rate constant of 3.5 x 10(-4) min-1. The calculated dissociation constant for ADPNP is thus 2.9 microM. ADPNP is a potent competitive inhibitor of ATP-dependent DNA supercoiling. Inhibition is established much more rapidly than can be accounted for by the slow rate of ADPNP binding in the absence of ATP. We have found that ATP can accelerate the rate of [32P]ADPNP binding by more than 15-fold (k1 = 1,850 M-1 min-1). The ATP-promoted rate enhancement requires the presence of DNA; in the absence of DNA, ATP has no effect on the rate of binding. Relaxed closed-circular, nicked-circular, and linear pBR322 DNA are all equally effective cofactors for ATP-stimulated binding of ADPNP. After a short lag, the presence of ATP also greatly speeds up ADPNP dissociation from gyrase bound initially to closed-circular DNA, with the restoration of DNA supercoiling activity. This effect is not observed in the presence of nicked-circular or linear DNA, suggesting that ADPNP dissociates more rapidly from gyrase bound to supercoiled DNA. The results of ADPNP binding provide evidence for cooperative interactions between the nucleotide binding sites. To account for these data, a model is proposed for the interaction of nucleotides at the two ATP binding sites on DNA gyrase.

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.

A model for the mechanism of strand passage by DNA gyrase.

The mechanism of type II DNA topoisomerases involves the formation of an enzyme-operated gate in one double-stranded DNA segment and the passage of another segment through this gate. DNA gyrase is the only type II topoisomerase able to introduce negative supercoils into DNA, a feature that requires the enzyme to dictate the directionality of strand passage. Although it is known that this is a consequence of the characteristic wrapping of DNA by gyrase, the detailed mechanism by which the transported DNA segment is captured and directed through the DNA gate is largely unknown. We have addressed this mechanism by probing the topology of the bound DNA segment at distinct steps of the catalytic cycle. We propose a model in which gyrase captures a contiguous DNA segment with high probability, irrespective of the superhelical density of the DNA substrate, setting up an equilibrium of the transported segment across the DNA gate. The overall efficiency of strand passage is determined by the position of this equilibrium, which depends on the superhelical density of the DNA substrate. This mechanism is concerted, in that capture of the transported segment by the ATP-operated clamp induces opening of the DNA gate, which in turn stimulates ATP hydrolysis.