Nicholas R. Cozzarelli

Structural transitions and elasticity from torque measurements on DNA

Knowledge of the elastic properties of DNA is required to understand the structural dynamics of cellular processes such as replication and transcription. Measurements of force and extension on single molecules of DNA have allowed direct determination of the molecules mechanical properties, provided rigorous tests of theories of polymer elasticity, revealed unforeseen structural transitions induced by mechanical stresses, and established an experimental and conceptual framework for mechanical assays of enzymes that act on DNA. However, a complete description of DNA mechanics must also consider the effects of torque, a quantity that has hitherto not been directly measured in micromanipulation experiments. We have measured torque as a function of twist for stretched DNA—torsional strain in over- or underwound molecules was used to power the rotation of submicrometre beads serving as calibrated loads. Here we report tests of the linearity of DNAs twist elasticity, direct measurements of the torsional modulus (finding a value ∼40% higher than generally accepted), characterization of torque-induced structural transitions, and the establishment of a framework for future assays of torque and twist generation by DNA-dependent enzymes. We also show that cooperative structural transitions in DNA can be exploited to construct constant-torque wind-up motors and force–torque converters.

Structure of plectonemically supercoiled DNA

Using electron microscopy and topological methods, we have deduced an average structure for negatively supercoiled circular DNA in solution. Our data suggest that DNA has a branched plectonemic (interwound) form over the range of supercoiling tested. The length of the superhelix axis is constant at 41% of the DNA length, whereas the superhelix radius decreases essentially hyperbolically as supercoiling increases. The number of supercoils is 89% of the linking deficit. Both writhe and twist change with supercoiling, but the ratio of the change in writhe to the change in twist is fixed at 2.6:1. The extent of branching of the superhelix axis is proportional to the length of the plasmid, but is insensitive to superhelix density. The relationship between DNA flexibility constants for twisting and bending calculated using our structural data is similar to that deduced from previous studies. The extended thin form of plectonemically supercoiled DNA offers little compaction for cellular packaging, but promotes interaction between cis-acting sequence elements that may be distant in primary structure. We discuss additional biological implications of our structural data.

13S Condensin Actively Reconfigures DNA by Introducing Global Positive Writhe: Implications for Chromosome Condensation

Xenopus 13S condensin converts interphase chromatin into mitotic-like chromosomes, and, in the presence of ATP and a type I topoisomerase, introduces (+) supercoils into DNA. The specific production of (+) trefoil knots in the presence of condensin and a type II topoisomerase shows that condensin reconfigures DNA by introducing an ordered, global, (+) writhe. Knotting required ATP hydrolysis and cell cycle-specific phosphorylation of condensin. Condensin bound preferentially to (+) supercoiled DNA in the presence of ATP but not in its absence. Our results suggest a mechanism for the compaction of chromatin by condensin during mitosis.

The role of topoisomerase IV in partitioning bacterial replicons and the structure of catenated intermediates in DNA replication

Mutants in bacterial topoisomerase (topo) IV are deficient in chromosomal partitioning. To investigate the basis of this phenotype, we examined plasmid DNA topology in conditionally lethal topo IV mutants. We found that dimeric catenated plasmids accumulated in vivo after topo IV inhibition. The catenanes were supercoiled, contained from 2 to > 32 nodes, and were the products of DNA synthesis. Electron microscopy and recombination tests proved that the catenanes have the unique structure predicted for replication intermediates. These data provide strong evidence for a model in which unlinking of the double helix can occur in two stages during DNA replication and for the critical role of topo IV in the second stage. The interlocks in the catenanes appear to be sequestered from DNA gyrase, perhaps by compartmentalization in an enzyme complex dedicated to partitioning.

Conformational and Thermodynamic Properties of Supercoiled DNA

We used Monte Carlo simulations to investigate the conformational and thermodynamic properties of DNA molecules with physiological levels of supercoiling. Three parameters determine the properties of DNA in this model: Kuhn statistical length, torsional rigidity and effective double-helix diameter. The chains in the simulation resemble strongly those observed by electron microscopy and have the conformation of an interwound superhelix whose axis is often branched. We compared the geometry of simulated chains with that determined experimentally by electron microscopy and by topological methods. We found a very close agreement between the Monte Carlo and experimental values for writhe, superhelix axis length and the number of superhelical turns. The computed number of superhelix branches was found to be dependent on superhelix density, DNA chain length and double-helix diameter. We investigated the thermodynamics of supercoiling and found that at low superhelix density the entropic contribution to superhelix free energy is negligible, whereas at high superhelix density, the entropic and enthalpic contributions are nearly equal. We calculated the effect of supercoiling on the spatial distribution of DNA segments. The probability that a pair of DNA sites separated along the chain contour by at least 50 nm are juxtaposed is about two orders of magnitude greater in supercoiled DNA than in relaxed DNA. This increase in the effective local concentration of DNA is not strongly dependent on the contour separation between the sites. We discuss the implications of this enhancement of site juxtaposition by supercoiling in the context of protein-DNA interactions involving multiple DNA-binding sites.

DNA overwinds when stretched.

DNA is often modelled as an isotropic rod, but its chiral structure suggests the possible importance of anisotropic mechanical properties, including coupling between twisting and stretching degrees of freedom. Simple physical intuition predicts that DNA should unwind under tension, as it is pulled towards a denatured structure. We used rotor bead tracking to directly measure twist–stretch coupling in single DNA molecules. Here we show that for small distortions, contrary to intuition, DNA overwinds under tension, reaching a maximum twist at a tension of ∼30 pN. As tension is increased above this critical value, the DNA begins to unwind. The observed twist–stretch coupling predicts that DNA should also lengthen when overwound under constant tension, an effect that we quantitatively confirm. We present a simple model that explains these unusual mechanical properties, and also suggests a possible origin for the anomalously large torsional rigidity of DNA. Our results have implications for the action of DNA-binding proteins that must stretch and twist DNA to compensate for variability in the lengths of their binding sites. The requisite coupled DNA distortions are favoured by the intrinsic mechanical properties of the double helix reported here.

Use of site-specific recombination as a probe of DNA structure and metabolism in vivo

We used site-specific recombination catalyzed by the bacteriophage lambda Int system to probe DNA structure and metabolism in vivo. In vitro, the complexity of catenated products was linearly proportional to substrate supercoil density. A system was developed that gave efficient, controlled Int recombination in Escherichia coli cells. From a comparison of the data obtained in vitro and in vivo, we conclude that Int recombination does have the same mechanism in vivo as it has in vitro, but that only 40% of the plasmid DNA linking deficit in E. coli cells may be in the interwound supercoil form demonstrated in vitro. We suggest that this is the effective level of supercoiling in vivo, because the remaining DNA is constrained in alternative forms by protein binding. The study of Int recombination in vivo also provides an assay for enzymes that decatenate circular molecules, such as those formed during DNA replication. We find that DNA gyrase is the principal decatenase in E. coli and that it acts spontaneously and rapidly.

Genomic transcriptional response to loss of chromosomal supercoiling in Escherichia coli.

BackgroundThe chromosome of Escherichia coli is maintained in a negatively supercoiled state, and supercoiling levels are affected by growth phase and a variety of environmental stimuli. In turn, supercoiling influences local DNA structure and can affect gene expression. We used microarrays representing nearly the entire genome of Escherichia coli MG1655 to examine the dynamics of chromosome structure.ResultsWe measured the transcriptional response to a loss of supercoiling caused either by genetic impairment of a topoisomerase or addition of specific topoisomerase inhibitors during log-phase growth and identified genes whose changes are statistically significant. Transcription of 7% of the genome (306 genes) was rapidly and reproducibly affected by changes in the level of supercoiling; the expression of 106 genes increased upon chromosome relaxation and the expression of 200 decreased. These changes are most likely to be direct effects, as the kinetics of their induction or repression closely follow the kinetics of DNA relaxation in the cells. Unexpectedly, the genes induced by relaxation have a significantly enriched AT content in both upstream and coding regions.ConclusionsThe 306 supercoiling-sensitive genes are functionally diverse and widely dispersed throughout the chromosome. We propose that supercoiling acts as a second messenger that transmits information about the environment to many regulatory networks in the cell.

Topological challenges to DNA replication: Conformations at the fork

The unwinding of the parental DNA duplex during replication causes a positive linking number difference, or superhelical strain, to build up around the elongating replication fork. The branching at the fork and this strain bring about different conformations from that of (−) supercoiled DNA that is not being replicated. The replicating DNA can form (+) precatenanes, in which the daughter DNAs are intertwined, and (+) supercoils. Topoisomerases have the essential role of relieving the superhelical strain by removing these structures. Stalled replication forks of molecules with a (+) superhelical strain have the additional option of regressing, forming a four-way junction at the replication fork. This four-way junction can be acted on by recombination enzymes to restart replication. Replication and chromosome folding are made easier by topological domain barriers, which sequester the substrates for topoisomerases into defined and concentrated regions. Domain barriers also allow replicated DNA to be (−) supercoiled. We discuss the importance of replicating DNA conformations and the roles of topoisomerases, focusing on recent work from our laboratory.

The mechanism of inhibition of topoisomerase IV by quinolone antibacterials

Topoisomerase IV (Topo IV) is a mediator of quinolone toxicity in bacteria. In this work, we demonstrate that norfloxacin, a model quinolone, converts Escherichia coliTopo IV into a poisonous adduct on DNA as opposed to inhibiting topoisomerase activity. Norfloxacin inhibition of Topo IV induces a slow decline in DNA synthesis that parallels cell death. Treatment of cells with a lethal concentration of the antibacterial did not block chromosome segregation, the phenotype of catalytic inhibition of Topo IV. Instead, norfloxacin causes DNA damage, as evidenced by the induction of the SOS pathway for DNA repair; the increase in susceptibility to the drug by mutations in genes for DNA repair pathways including recA, recB, anduvrD; and the efficient detergent-induced linearization of plasmid DNA in drug-treated cells. Wild-type and drug-resistant alleles of Topo IV are co-dominant, but we find that mutations inrecA, seqA, or gyrB result in unconditional dominance of the sensitive allele, the characteristic of a poisoning mode of inhibition. These mutations either compromise chromosome integrity or force Topo IV to play a more active role in DNA unlinking in front of the replication fork. We interpret our results in terms of distinct but complementary roles of Topo IV and gyrase in DNA replication.