Characterization of quercetin binding site on DNA gyrase

Gyrases are DNA topology modifying enzymes present only in prokaryotes which makes them an attractive target for antibacterial drugs. Quercetin, one of the most abundant natural flavonoids, inhibits supercoiling activity of bacterial gyrase and induces DNA cleavage. It has been generally assumed that the mechanism of flavonoid inhibition is based on interaction with DNA. We show that quercetin binds to the 24 kDa fragment of gyrase B of Escherichia coli with a K(D) value of 15 microM and inhibits ATPase activity of gyrase B. Its binding site overlaps with ATP binding pocket and could be competitively replaced by either ATP or novobiocin. The structural model of quercetin-gyrase complex was prepared, based on the close similarity with ATP and quercetin binding sites of the src family tyrosine kinase Hck. We propose that quercetin inhibits gyrases through two different mechanisms based either on interaction with DNA or with ATP binding site of gyrase.     

A 4.2 kDa synthetic peptide as a potential probe to evaluate the antibacterial activity of coumarin drugs.

The coumarin antibiotics are potent inhibitors of DNA replication whose target is the enzyme DNA gyrase, an ATP-dependent bacterial type II topoisomerase. The coumarin drugs inhibit gyrase action by competitive binding to the ATP-binding site of DNA gyrase B protein. The production of new biologically active products has stimulated additional studies on coumarin-gyrase interactions. In this regard, a 4.2 kDa peptide mimic of DNA gyrase B protein from Escherichia coli has been designed and synthesized. The peptide sequence includes the natural fragment 131-146 (coumarin resistance-determining region) and a segment containing the gyrase-DNA interaction region (positions 753-770). The peptide mimic binds to novobiocin (Ka = 1.4+/-0.3 x 10(5) M(-1)), plasmid (Ka = 1.6+/-0.5 x 10(6) M(-1)) and ATP (Ka = 1.9+/-50.4 x 10(3) M(-1)), results previously found with the intact B protein. On the other hand, the binding to novobiocin was reduced when a mutation of Arg-136 to Leu-136 was introduced, a change previously found in the DNA gyrase B protein from several coumarin-resistant clinical isolates of Escherichia coli In contrast, the binding to plasmid and to ATP was not altered. These results suggest that synthetic peptides designed in a similar way to that described here could be used as mimics of DNA gyrase in studies which seek a better understanding of the ATP, as well as coumarin, binding to the gyrase and also the mechanism of action of this class of antibacterial drugs.     

The nature of inhibition of DNA gyrase by the coumarins and the cyclothialidines revealed by X-ray crystallography.

This study describes the first crystal structures of a complex between a DNA topoisomerase and a drug. We present the structures of a 24 kDa N-terminal fragment of the Escherichia coli DNA gyrase B protein in complexes with two different inhibitors of the ATPase activity of DNA gyrase, namely the coumarin antibiotic, novobiocin, and GR122222X, a member of the cyclothialidine family. These structures are compared with the crystal structure of the complex with an ATP analogue, adenylyl-beta-gamma-imidodiphosphate (ADPNP). The likely mechanism, by which mutant gyrase B proteins become resistant to inhibition by novobiocin are discussed in light of these comparisons. The three ligands are quite dissimilar in chemical structure and bind to the protein in very different ways, but their binding is competitive because of a small degree of overlap of their binding sites. These crystal structures consequently describe a chemically well characterized ligand binding surface and provide useful information to assist in the design of novel ligands.     

gyrB mutations which confer coumarin resistance also affect DNA supercoiling and ATP hydrolysis by Escherichia coli DNA gyrase

Coumarins are inhibitors of the ATP hydrolysis and DNA supercoiling reactions catalysed by DNA gyrase. Their target is the B subunit of gyrase (GyrB), encoded by the gyrB gene. The exact mode and site of action of the drugs is unknown. We have identified four mutations conferring coumarin resistance to Escherichia coli: Arg-136 to Cys, His or Ser and Gly-164 to Val. In vitro, the ATPase and supercoiling activities of the mutant GyrB proteins are reduced relative to the wild-type enzyme and show resistance to the coumarin antibiotics. Significant differences in the susceptibility of mutant GyrB proteins to inhibition by either chlorobiocin and novobiocin or coumermycin have been found, suggesting wider contacts between coumermycin and GyrB. We discuss the significance of Arg-136 and Gly-164 in relation to the notion that coumarin drugs act as competitive inhibitors of the ATPase reaction.     

The interaction between coumarin drugs and DNA gyrase

The coumarin group of antibiotics have as their target the bacterial enzyme DNA gyrase. The drugs bind to the B subunit of gyrase and inhibit DNA supercoiling by blocking the ATPase activity. Recent data show that the binding site for the drugs lies within the N-terminal part of the B protein, and individual amino acids involved in coumarin interaction are being identified. The mode of inhibition of the gyrase ATPase reaction by coumarins is unlikely to be simple competitive inhibition, and the drugs may act by stabilizing a conformation of the enzyme with low affinity for ATP.     

Contribution of the ATP binding site of ParE to susceptibility to novobiocin and quinolones in Streptococcus pneumoniae

In Streptococcus pneumoniae, an H103Y substitution in the ATP binding site of the ParE subunit of topoisomerase IV was shown to confer quinolone resistance and hypersensitivity to novobiocin when associated with an S84F change in the A subunit of DNA gyrase. We reconstituted in vitro the wild-type topoisomerase IV and its ParE mutant. The ParE mutant enzyme showed a decreased activity for decatenation at subsaturating ATP levels and was more sensitive to inhibition by novobiocin but was as sensitive to quinolones. These results show that the ParE alteration H103Y alone is not responsible for quinolone resistance and agree with the assumption that it facilitates the open conformation of the ATP binding site that would lead to novobiocin hypersensitivity and to a higher requirement of ATP.     

DNA gyrase: affinity chromatography on novobiocin-Sepharose and catalytic properties.

Novobiocin-Sepharose was prepared by coupling of novobiocin to Epoxy-activated Sepharose 6B and used as an affinity adsorbent. Four novobiocin-binding proteins were isolated from crude extracts of Escherichia coli with molecular weights of 105, 92, 85 and 40 kdal. The two larger proteins were identified as the A subunit (gyrA protein) and the B subunit (gyrB protein) of DNA gyrase topoisomerase II). By this method the two gyrase components can be easily separated and purified in high yield. Although both proteins are involved in the ATP-dependent supercoiling of relaxed plasmid DNA, only the gyrB protein is required for catalyzing the cleavage of ATP. The gyrB protein ATPase activity is competitively inhibited by novobiocin and related coumarin antibiotics. ATP hydrolysis is unaffected by the addition of either gyrA protein or DNA but stimulated in the presence of both.     

Flavone-based analogues inspired by the natural product simocyclinone D8 as DNA gyrase inhibitors

The increasing occurrence of drug-resistant bacterial infections in the clinic has created a need for new antibacterial agents. Natural products have historically been a rich source of both antibiotics and lead compounds for new antibacterial agents. The natural product simocyclinone D8 (SD8) has been reported to inhibit DNA gyrase, a validated antibacterial drug target, by a unique catalytic inhibition mechanism of action. In this work, we have prepared simplified flavone-based analogues inspired by the complex natural product and evaluated their inhibitory activity and mechanism of action. While two of these compounds do inhibit DNA gyrase, they do so by a different mechanism of action than SD8, namely DNA intercalation.     

The Naphthoquinone Diospyrin Is an Inhibitor of DNA Gyrase with a Novel Mechanism of Action

Tuberculosis and other bacterial diseases represent a significant threat to human health. The DNA topoisomerases are excellent targets for chemotherapy, and DNA gyrase in particular is a well-validated target for antibacterial agents. Naphthoquinones (e.g. diospyrin and 7-methyljuglone) have been shown to have therapeutic potential, particularly against Mycobacterium tuberculosis. We have found that these compounds are inhibitors of the supercoiling reaction catalyzed by M. tuberculosis gyrase and other gyrases. Our evidence strongly suggests that the compounds bind to the N-terminal domain of GyrB, which contains the ATPase active site, but are not competitive inhibitors of the ATPase reaction. We propose that naphthoquinones bind to GyrB at a novel site close to the ATPase site. This novel mode of action could be exploited to develop new antibacterial agents.     

A DNA-dependent ATPase of calf-thymus.

A DNA-dependent ATPase has been purified from calf thymus. The enzyme hydrolyses ATP and dATP in the presence of heat-denatured DNA. It does not hydrolyse the corresponding nucleoside triphosphates of guanine, uridine and cytosine. The Km values for ATP and dATP are both 0.62 mM. The enzyme requires magnesium or manganese ions. Its sedimentation coefficient is about 4.4 S. The catalytic activity is inhibited by N-ethylmaleimide but is not sensitive to novobiocin and nalidixic acid which are potent inhibitors of bacterial DNA gyrase. In some cases, during purification, chromatographically distinct additional DNA-dependent ATPase activities were detected. Limited proteolysis or covalent modification of the enzyme in the tissues, or during the first steps of its extraction, are probably responsible for the appearance of these chromatographically distinct forms.     

DNA gyrase activities from Rhodobacter capsulatus: analysis of target(s) of coumarins and cloning of the gyrB locus

Bacterial DNA gyrase is composed of two subunits, gyrase A and B, and is responsible for negatively supercoiling DNA in an ATP-dependent manner. The coumarin antibiotics novobiocin and coumermycin are known inhibitors of bacterial DNA gyrase in vivo and in vitro. We have cloned, mapped, and partially sequenced Rhodobacter capsulatus gyrB which encodes the gyrase B subunit that is presumably involved in binding to coumarins. DNA gyrase activities from crude extracts of R. capsulatus were detected and it was shown that the R. capsulatus activity is (1) inhibited by novobiocin and coumermycin, (2) ATP-dependent and, (3) present in highly aerated and anaerobically grown cells. We previously observed that when R. capsulatus coumermycin-resistant strains are continuously recultured on media containing coumermycin they sometimes acquired mutations in hel genes (i.e., cytochromes c biogenesis mutations). We discuss the possibility that coumarins may inhibit cytochromes c biogenesis as a second target in R. capsulatus via hel (i.e., a putative ATP-dependent heme exporter).     

Characterization of the aminocoumarin ligase SimL from the simocyclinone pathway and tandem incubation with NovM,P,N from the novobiocin pathway

Simocyclinone D(8) consists of an anguicycline C-glycoside tethered by a tetraene diester linker to an aminocoumarin. Unlike the antibiotics novobiocin, clorobiocin, and coumermycin A(1), the phenolic hydroxyl group of the aminocoumarin in simocyclinone is not glycosylated with a decorated noviosyl moiety that is the pharmacophore for targeting bacterial DNA gyrase. We have expressed the Streptomyces antibioticus simocyclinone ligase SimL, purified it from Escherichia coli, and established its ATP-dependent amide bond forming activity with a variety of polyenoic acids including retinoic acid and fumagillin. We have then used the last three enzymes from the novobiocin pathway, NovM, NovP, and NovN, to convert a SimL product to a novel novobiocin analogue, in which the 3-prenyl-4-hydroxybenzoate of novobiocin is replaced with a tetraenoate moiety, to evaluate antibacterial activity.     

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.     

Negative supercoiling of DNA by gyrase is inhibited in Salmonella enterica serovar Typhimurium during adaptation to acid stress

DNA in intracellular Salmonella enterica serovar Typhimurium relaxes during growth in the acidified (pH 4–5) macrophage vacuole and DNA relaxation correlates with the upregulation of Salmonella genes involved in adaptation to the macrophage environment. Bacterial ATP levels did not increase during adaptation to acid pH unless the bacterium was deficient in MgtC, a cytoplasmic‐membrane‐located inhibitor of proton‐driven F₁F₀ ATP synthase activity. Inhibiting ATP binding by DNA gyrase and topo IV with novobiocin enhanced the effect of low pH on DNA relaxation. Bacteria expressing novobiocin‐resistant (Nov^R) derivatives of gyrase or topo IV also exhibited DNA relaxation at acid pH, although further relaxation with novobiocin was not seen in the strain with Nov^R gyrase. Thus, inhibition of the negative supercoiling activity of gyrase was the primary cause of enhanced DNA relaxation in drug‐treated bacteria. The Salmonella cytosol reaches pH 5–6 in response to an external pH of 4–5: the ATP‐dependent DNA supercoiling activity of purified gyrase was progressively inhibited by lowering the pH in this range, as was the ATP‐dependent DNA relaxation activity of topo IV. We propose that DNA relaxation in Salmonella within macrophage is due to acid‐mediated impairment of the negative supercoiling activity of gyrase.     

The effect of bacterial DNA gyrase inhibitors on DNA synthesis in mammalian mitochondria

Using isolated rat liver mitochondria, which have previously been shown to carry out true replicative DNA synthesis, we have obtained results which are in accord with the presence and functioning of a DNA gyrase in this organelle. The effects of the Escherichia coli DNA gyrase inhibitors, novobiocin, coumermycin, nalidixic acid and oxolinic acid, upon mtDNA replication suggest the involvement of the putative mitochondrial enzyme in various aspects of this process. First, the preferential inhibition of [3H]dATP incorporation into highly supercoiled DNA together with the appearance of labeled, relaxed DNA are consistent with the involvement of a gyrase in the process of generating negative supercoils in mature mtDNA. Second, the overall depression of incorporation of labeled dATP into mtDNA, including the reduction of radioactivity incorporated into replicative intermediates, suggests a 'swivelase' role for the putative gyrase, and this hypothesis is further supported by results obtained on sucrose gradient centrifugation of heat-denatured, D-loop mtDNA. Here, the synthesis of the completed clean circles is inhibited while 9 S initiator strand synthesis is not, suggesting that chain elongation is blocked by the gyrase inhibitors.     

Biophysical characterization of an indolinone inhibitor in the ATP-binding site of DNA gyrase

Fighting bacterial resistance is a challenging task in the field of medicinal chemistry. DNA gyrase represents a validated antibacterial target and has drawn much interest in recent years. By a structure-based approach we have previously discovered compound 1, an indolinone derivative, possessing inhibitory activity against DNA gyrase. In the present paper, a detailed biophysical characterization of this inhibitor is described. Using mass spectrometry, NMR spectroscopy, and fluorescence experiments we have demonstrated that compound 1 binds reversibly to the ATP-binding site of the 24 kDa N-terminal fragment of DNA gyrase B from Escherichia coli (GyrB24) with low micromolar affinity. Based on these data, a plausible molecular model of compound 1 in the active site of GyrB24 was constructed. The predicted binding mode explains the competitive inhibitory mechanism with respect to ATP and forms a useful basis for further development of potent DNA gyrase inhibitors.     

Ficellomycin and feldamycin; inhibitors of bacterial semiconservative DNA replication.

The two peptide-like antibiotics ficellomycin and feldamycin impair semiconservative DNA replication but not DNA repair synthesis in bacteria. Specifically both antibiotics cause the accumulation of a 34S DNA species in toluenized Escherichia coli cells which lacks the capability of being integrated into larger DNA pieces and eventually the complete bacterial chromosome. Novobiocin, a known inhibitor of replicative DNA synthesis, was investigated for comparative purposes. The action of this latter antibiotic differs from the ones exerted by ficellomycin and feldamycin in the novobiocin appears to block an event associated with the initiation of Okazaki fragments. The fact that novobiocin impairs DNA gyrase suggests that this enzyme plays an essential role during the initiation of Okazaki pieces.     

A monoclonal antibody that inhibits mycobacterial DNA gyrase by a novel mechanism

DNA gyrase is a DNA topoisomerase indispensable for cellular functions in bacteria. We describe a novel, hitherto unknown, mechanism of specific inhibition of Mycobacterium smegmatis and Mycobacterium tuberculosis DNA gyrase by a monoclonal antibody (mAb). Binding of the mAb did not affect either GyrA-GyrB or gyrase-DNA interactions. More importantly, the ternary complex of gyrase-DNA-mAb retained the ATPase activity of the enzyme and was competent to catalyse DNA cleavage-religation reactions, implying a new mode of action different from other classes of gyrase inhibitors. DNA gyrase purified from fluoroquinolone-resistant strains of M.tuberculosis and M.smegmatis were inhibited by the mAb. The absence of cross-resistance of the drug-resistant enzymes from two different sources to the antibody-mediated inhibition corroborates the new mechanism of inhibition. We suggest that binding of the mAb in the proximity of the primary dimer interface region of GyrA in the heterotetrameric enzyme appears to block the release of the transported segment after strand passage, leading to enzyme inhibition. The specific inhibition of mycobacterial DNA gyrase with the mAb opens up new avenues for designing novel lead molecules for drug discovery and for probing gyrase mechanism.     

Bacterial type II topoisomerases as targets for antibacterial drugs

Bacterial type II DNA topoisomerases are essential enzymes for correct genome functioning and cell growth. Gyrase is responsible for maintaining negative supercoiling of bacterial chromosome, whereas topoisomerase IV acts in disentangling daughter chromosomes following replication. Type II DNA topoisomerases possess an ATP binding site, which can be treated as a target for antibacterial drugs. Resolving crystal structures of protein fragments consisting of an ATP binding site complexed with ADPNP/antibiotics have proven to be valuable for the understanding of the mode of action of existing antibacterial agents and presented new possibilities for novel drug design. Coumarins, quinolones and cyclothialidines are diverse group of antibiotics that interfere with type II DNA topoisomerases, however their mode of action is different. Recently a new class of antibiotics, simociclinones, was characterized. Their mechanism of action towards gyrase is entirely distinct from already known modes of action, therefore demonstrating the potential for development of novel anti-bacterial agents.