Bacterial DNA supercoiling and [ATP]/[ADP]. Changes associated with a transition to anaerobic growth.

Shifting Escherichia coli from aerobic to anaerobic growth caused changes in the ratio of [ATP]/[ADP] and in negative supercoiling of chromosomal and plasmid DNA. Shortly after lowering oxygen tension, both [ATP]/[ADP] and supercoiling transiently decreased. Under conditions of exponential anaerobic growth, both were higher than under aerobic conditions. These correlations may reflect an effect of [ATP]/[ADP] on DNA gyrase, since in vitro [ATP]/[ADP] influences the level of plasmid supercoiling attained when gyrase is either introducing or removing supercoils. When the supercoiling activity of gyrase was perturbed by a mutation in gyrB, a shift to anaerobic conditions resulted in plasmid supercoil relaxation similar to that seen with wild-type. However, the low level of supercoiling in the mutant persisted during a time when supercoiling in wild-type recovered and then exceeded aerobic levels. Thus, changes in oxygen tension can alter DNA supercoiling through an effect on gyrase, and correlations exist between changes in supercoiling and changes in the intracellular ratio of [ATP]/[ADP].     

The expression of the Escherichia coli fis gene is strongly dependent on the superhelical density of DNA

The Escherichia coli DNA architectural protein FIS is a pleiotropic regulator, which couples the cellular physiology with transitions in the superhelical density of bacterial DNA. Recently, we have shown that this effect is in part mediated via DNA gyrase, the major cellular topoisomerase responsible for the elevation of negative supercoiling. Here, we demonstrate that, in turn, the expression of the fis gene strongly responds to alterations in the topology of DNA in vivo, being maximal at high levels of negative supercoiling. Any deviations from these optimal levels decrease fis promoter activity. This strict dependence of fis expression on the superhelical density suggests that fis may be involved in 'fine-tuning' the homeostatic control mechanism of DNA supercoiling in E. coli.     

Interplay of novobiocin-resistant and -sensitive DNA gyrase activities in self-protection of the novobiocin producer, Streptomyces sphaeroides

The novobiocin (Nb)-producing organism, Streptomyces sphaeroides, possesses two gyrB genes: gyrBS and gyrBR (encoding the DNA gyrase B subunit-the normal target for Nb) whose products differ in their response to the drug. Novobiocin-sensitive gyrase is the predominant form of the enzyme in this strain and is produced constitutively but at variable levels, whereas Nb-resistant gyrase appears when growth takes place in the presence of the drug. The promoter isolated from the Nb-resistance determinant responds sharply to changes in DNA topology, being activated when the (negative) superhelical density is reduced and vice versa when the supercoiling of DNA is increased. Thus, resistance to Nb in S. sphaeroides is induced by a reduction in DNA supercoiling due to the action of autogenous drug on the sensitive gyrase.     

Mechanism of inhibition of DNA gyrase by ES-1273, a novel DNA gyrase inhibitor

We investigated the mode of action of ES-1273, a novel DNA gyrase inhibitor obtained by optimization of ES-0615, which was found by screening our chemical library using anucleate cell blue assay. ES-1273 exhibited the same antibacterial activity against S. aureus strains with amino acid change(s) conferring quinolone- and coumarin-resistance as that against a susceptible strain. In addition, ES-1273 inhibited DNA gyrase supercoiling activity, but not ATPase activity of the GyrB subunit of DNA gyrase. Moreover, ES-1273 did not induce cleavable complex. These findings demonstrate that the mechanism by which ES-1273 inhibits DNA gyrase is different from that of the quinolones or the coumarins. Preincubation of DNA gyrase and substrate DNA prevented inhibition of DNA gyrase supercoiling activity by ES-1273. ES-1273 antagonized quinolone-induced cleavage. In electrophoretic mobility shift assay, no band representing DNA gyrase-DNA complex was observed in the presence of ES-1273. Taken together, these results indicate that ES-1273 prevents DNA from binding to DNA gyrase. Furthermore, our results from surface plasmon resonance experiments strongly suggest that ES-1273 interacts with DNA. Therefore, the interaction between ES-1273 and DNA prevents DNA from binding to DNA gyrase, resulting in inhibition of DNA gyrase supercoiling. Interestingly, we also found that ES-1273 inhibits topoisomerase IV and human topoisomerase IIalpha, but not human topoisomerase I. These findings indicate that ES-1273 is a type II topoisomerase specific inhibitor.     

The DNA supercoiling-sensitive expression of the Salmonella typhimurium his operon requires the his attenuator and is modulated by anaerobiosis and by osmolarity

Bacterial cells possess a subset of genes whose expression correlates with changes in DNA supercoiling brought about by anaerobic growth and by growth at high osmolarity. It has been shown previously that expression of the histidine biosynthetic operon of Salmonella typhimurium is derepressed by relaxation of supercoiled DNA. Here, we confirm that a his::MudJ operon fusion in S. typhimurium can be induced by treatment with the DNA gyrase inhibitor novobiocin in a dose-dependent manner, and show that the level of derepression is higher in stationary phase than in mid-exponential phase cultures. Furthermore, expression of his is repressed by anaerobiosis and by osmolarity, two environmental parameters which increase the negative supercoiling of bacterial DNA. Novobiocin induction of his is also repressed by growing the cells either at high osmolarity or anaerobically. Both environmental repression and novobiocin induction of his require the his attenuator. In addition, derepression of his expression by novobiocin and its repression by anaerobiosis or osmolarity are independent of the stringent response gene, relA.     

DNA supercoiling and the anaerobic and growth phase regulation of tonB gene expression.

We show that several interacting environmental factors influence the topology of intracellular DNA. Negative supercoiling of DNA in vivo is increased by anaerobic growth and is also influenced by growth phase. The tonB promoter of Escherichia coli and Salmonella typhimurium was found to be highly sensitive to changes in DNA supercoiling. Expression was increased by novobiocin, an inhibitor of DNA gyrase, and was decreased by factors which increase DNA superhelicity. Expression of the plasmid-encoded tonB gene was enhanced by gamma delta insertions in cis in a distance- and orientation-independent fashion. Both the res site and the TnpR protein of gamma delta, which is known to function as a type I topoisomerase, were required for this activation. tonB expression increased during the growth cycle and was reduced by anaerobiosis. There was excellent correlation between tonB expression from a plasmid and the level of supercoiling of that plasmid under a wide range of conditions. The chromosomal tonB gene was regulated in a manner identical to that of the plasmid-encoded gene. Thus, the physiological regulation of tonB expression in response to anaerobiosis and growth phase appears to be mediated by environmentally induced changes in DNA superhelicity.     

Modulation of gene expression by drugs affecting deoxyribonucleic acid gyrase.

Nalidixic acid (Nal), a drug which affects deoxyribonucleic acid gyrase activity, inhibits the expression of catabolite-sensitive genes: the three maltose operons, the lactose and galactose operons, and the tryptophanase gene. A correlation between the degree of sensitivity to Nal and that to catabolite repression has been observed. The expression of the threonine and tryptophan operons, insensitive to catabolite repression, is insensitive to Nal. The expression of the lacZ gene under the control of the IQ promoter is activated by Nal. Strains carrying a mutation in the nalA locus are resistant to these effects. Novobiocin, which inhibits the negative supercoiling activity of deoxyribonucleic acid gyrase, affects expression of the operons similarly to Nal. The involvement of promoters in Nal and novobiocin action, as well as a possible role of in vivo negative supercoiling in the selectivity of gene expression, are discussed.