Control of bacterial DNA supercoiling

Two DNA topoisomerases control the level of negative supercoiling in bacterial cells. DNA gyrase introduces supercoils, and DNA topoisomerase I prevents supercoiling from reaching unacceptably high levels. Perturbations of supercoiling are corrected by the substrate preferences of these topoisomerases with respect to DNA topology and by changes in expression of the genes encoding the enzymes. However, supercoiling changes when the growth environment is altered in ways that also affect cellular energetics. The ratio of [ATP] to [ADP], to which gyrase is sensitive, may be involved in the response of supercoiling to growth conditions. Inside cells, supercoiling is partitioned into two components, superhelical tension and restrained supercoils. Shifts in superhelical tension elicited by nicking or by salt shock do not rapidly change the level of restrained supercoiling. However, a steady-state change in supercoiling caused by mutation of topA does alter both tension and restrained supercoils. This communication between the two compartments may play a role in the control of supercoiling.     

Negative DNA supercoiling makes protein-mediated looping deterministic and ergodic within the bacterial doubling time

Protein-mediated DNA looping is fundamental to gene regulation and such loops occur stochastically in purified systems. Additional proteins increase the probability of looping, but these probabilities maintain a broad distribution. For example, the probability of lac repressor-mediated looping in individual molecules ranged 0–100%, and individual molecules exhibited representative behavior only in observations lasting an hour or more. Titrating with HU protein progressively compacted the DNA without narrowing the 0–100% distribution. Increased negative supercoiling produced an ensemble of molecules in which all individual molecules more closely resembled the average. Furthermore, in only 12 min of observation, well within the doubling time of the bacterium, most molecules exhibited the looping probability of the ensemble. DNA supercoiling, an inherent feature of all genomes, appears to impose time-constrained, emergent behavior on otherwise random molecular activity.     

DNA supercoiling and suppression of the leu-500 promoter mutation.

top mutations (formerly supX) eliminate DNA topoisomerase I activity and suppress the leu-500 promoter mutation in Salmonella typhimurium (K. M. Overbye, S. K. Basu, and P. Margolin, Cold Spring Harbor Symp. Quant. Biol. 47:785-791, 1983). Sublethal doses of coumermycin which reduce intracellular levels of supercoiling activity in a top mutant eliminated suppression of the leu-500 mutation. This result provides evidence that increased DNA supercoiling suppresses the leu-500 promoter mutation in top mutants.     

Negative supercoiling of DNA by eukaryotic DNA topoisomerase II and dextran sulfate.

In the presence of a molar excess of eukaryotic DNA topoisomerase II and an appropriate concentration of dextran sulfate, relaxed closed circular DNA is converted to a negatively supercoiled form. The reaction is dependent on ATP. Neither adenosine 5'-[beta,gamma-imido]-triphosphate nor adenosine 5'-[gamma-thio]triphosphate can substitute for ATP. The negative supercoils formed are relaxed by subsequent addition of DNA topoisomerase I to the supercoiling reaction mixture. Covalent closure of a nicked circular DNA in the presence of DNA topoisomerase II and dextran sulfate but in the absence of ATP causes a small decrease in the linking number. These results suggest that when an appropriate concentration of dextran sulfate is present, the binding of a molar excess of eukaryotic DNA topoisomerase II constrains a small number of negative supercoils in DNA, which in turn generate unconstrained negative supercoils at the expense of ATP.     

Novobiocin induces positive supercoiling of small plasmids from halophilic archaebacteria in vivo.

The halophilic archaebacterium Halobacterium strain GRB harbours a multicopy plasmid of 1.7 kb which is negatively supercoiled. After addition of novobiocin to culture medium all 1.7 kb plasmid molecules become positively supercoiled. Positive supercoiling occurs at the same dose of novobiocin inhibiting the eubacterial DNA gyrase in vitro. Novobiocin also induces positive supercoiling of pHV2, a 6.3 kb plasmid from Halobacterium volcanii. These results indicate the existence of a mechanism producing positive superturns in halobacteria. The 1.7 kb plasmid from Halobacterium GRB could be used to produce high amounts of pure positively supercoiled DNA for biophysical and biochemical studies.     

Inhibition of DNA synthesis by aphidicolin induces supercoiling in simian virus 40 replicative intermediates.

Highly torsionally stressed replicative intermediate SV40 DNA molecules are produced when ongoing replicative DNA synthesis is inhibited by aphidicolin, a specific inhibitor of DNA polymerase alpha. The high negative superhelical density of these molecules can be partially released by intercalating drugs such as chloroquine or ethidium bromide. The torsionally stressed replicative intermediates bind to monoclonal anti-Z-DNA antibodies. Electron microscopy of anti-Z-DNA cross-linked to torsionally stressed replicative intermediates shows that the antibody specifically binds close to the replication forks. The superhelical structures are not formed when SV40 DNA replication is inhibited by both aphidicolin and novobiocin, suggesting that a topoisomerase type II-like enzyme is somehow involved in the introduction of torsional strain in replicative intermediate DNA. One interpretation of our data is that fork movement continues to some rather limited extent when SV40 DNA synthesis in replicative chromatin is blocked by aphidicolin. After deproteinization, the exposed single-stranded DNA branches reassociate to form paranemic DNA structures with left-handed helical stretches, while the reduced linking number of the parental strands induces a high negative superhelical density.