Tryptic fragments of the Escherichia coli DNA gyrase A protein

Treatment of the Escherichia coli DNA gyrase A protein with trypsin generates two large fragments which are stable to further digestion. The molecular masses of these fragments are 64 and 33 kDa, and they are shown to be derived from the N terminus and the C terminus of the A protein, respectively. These fragments could represent structural and/or functional domains within the A subunit of DNA gyrase. The trypsin-cleaved A protein (A'), in combination with the B subunit of gyrase, can support ATP-dependent supercoiling of relaxed DNA and other reactions of DNA gyrase. The isolated 64-kDa fragment will also catalyse DNA supercoiling in the presence of the B protein, but the 33-kDa fragment shows no enzymic activities. We conclude that the N-terminal 64-kDa fragment represents the DNA breakage/reunion domain of the A protein, while the 33-kDa fragment may contribute to the stability of the gyrase-DNA complex.     

Expression inEscherichia coliof Y5-Mutant and N-terminal Domain-Deleted DNA Gyrase B Proteins Affects Strongly Plasmid Maintenance

Escherichia coliDNA gyrase B subunit (GyrB) is composed of a 43-kDa N-terminal domain containing an ATP-binding site and a 47-kDa C-terminal domain involved in the interaction with the gyrase A subunit (GyrA). Site-directed mutagenesis was used to substitute, in both the entire GyrB subunit and its 43-kDa N-terminal fragment, the amino acid Y5 by either a serine (Y5S) or a phenylalanine residue (Y5F). Under standard conditions, cells bearing Y5S or Y5F mutant GyrB expression plasmids produced significantly less recombinant proteins than cells transformed with the wild-type plasmid. This dramatic decrease in expression of mutant GyrB proteins was not observed when the corresponding N-terminal 43-kDa mutant plasmids were used. Examination of the plasmid content of the transformed cells after induction showed that the Y5F and Y5S GyrB protein level was correlated with the plasmid copy number. By repressing tightly the promoter activity encoded by these expression vectors during cell growth, it was possible to restore the normal level of the mutant GyrB encoding plasmids in the transformed bacteria. Treatment with chloramphenicol before protein induction enabled large overexpression of the GyrB mutant Y5F and Y5S proteins. In addition, the decrease in plasmid copy number was also observed when the 47-kDa C-terminal fragment of the GyrB subunit was expressed in bacteria grown under standard culture conditions. Analysis of DNA supercoiling and relaxation activities in the presence of GyrA demonstrated that purified Y5-mutant GyrB proteins were deficient for ATP-dependent gyrase activities. Taken together, these results show that Y5F and Y5S mutant GyrB proteins, but not the corresponding 43-kDa N-terminal fragments, competein vivowith the bacterial endogenous GyrB subunit of DNA gyrase, thereby reducing the plasmid copy number in the transformed bacteria by probably acting on the level of negative DNA supercoilingin vivo.This competition could be mediated by the presence of the intact 47-kDa C-terminal domain in the Y5F and Y5S mutant GyrB subunits. This study demonstrates also that the amino acid Y5 is a crucial residue for the expression of the gyrase B activityin vivo.Thus, ourin vivoapproach may also be useful for detecting other important amino acids for DNA gyrase activity, as mutations affecting the ATPase activity or the GyrB/GyrB or GyrB/GyrA protein interactions.     

Mechanism of DNA gyrase-mediated illegitimate recombination: characterization of Escherichia coli gyrA mutations that confer hyper-recombination phenotype.

To study the mechanism of DNA gyrase-mediated illegitimate recombination in Escherichia coli, we isolated temperature-sensitive gyrA mutants that confer spontaneous illegitimate recombination and spontaneous induction of lambda prophage at higher frequencies than that in the wild-type. After reconstruction of single mutations by targeted mutagenesis, we confirmed that two single mutations, gyrAL492P and gyrAL488P, and a double mutation, gyrAI203V+gyrAI205V, show the same properties as those described above. With respect to the phenotypes of hyper-recombination and higher induction of lambda prophage, these mutations were dominant over the wild-type. Analysis of recombination junctions of lambdabio transducing phages formed spontaneously in these mutants showed that the parental E. coli bio and lambda recombination sites have a homologous sequence of only 0. 7 base-pair on average, indicating that homology is not required for this illegitimate recombination. Analysis of nucleotide sequences of mutant gyrA genes revealed that the gyrAL492P and gyrAL488P mutations contain amino acid substitutions of Leu492-->Pro and Leu488-->Pro, respectively, which correspond to the alpha18 helix in the breakage-reunion domain of DNA gyrase A subunit. The gyrAI203V and gyrAI205V mutations contain Ile203-->Val and Ile205-->Val, respectively, which correspond to the alpha10' helix, also in the breakage-reunion domain of DNA gyrase A subunit. Biochemical analysis indicated that the GyrA63 protein that contains the L492P mutation has an apparently normal supercoiling activity, but it also produces a small amount of linear DNA in the absence of DNA gyrase inhibitor during the supercoiling reaction, suggesting that the mutant DNA gyrase may have a defect at the step of religation or a defect in the subunit interaction. These results suggest that the recombination is induced by defects of religation and/or dimer formation in the mutant DNA gyrases, implying that two alpha helices, alpha10' and alpha18, of DNA gyrase A subunit have crucial roles in subunit interaction and/or resealing of DNA.     

The C-terminal domain of the Escherichia coli DNA gyrase A subunit is a DNA-binding protein.

We have constructed a clone which over-produces a 33 kDa protein representing the C-terminal portion of the Escherichia coli DNA gyrase A subunit. This protein has no enzymic activity of its own, but will form a complex with a 64 kDa protein (representing the N-terminal part of the A subunit) and the gyrase B subunit, that will efficiently catalyse DNA supercoiling. We show that the 33 kDa protein can bind to DNA on its own in a manner which induces positive supercoiling of the DNA. We propose that the 33 kDa protein represents a domain of the gyrase A subunit which is involved in the wrapping of DNA around DNA gyrase.     

An Escherichia coli DNA topoisomerase I mutant has a compensatory mutation that alters two residues between functional domains of the DNA gyrase A protein.

Nucleotide sequence analysis revealed that the compensatory gyrA mutation in Escherichia coli DM750 affects DNA supercoiling by interchanging the identities of Ala-569 and Thr-586 in the DNA gyrase A subunit. These residues flank Arg-571, a site for trypsin cleavage that splits gyrase A protein between DNA breakage-reunion and DNA-binding domains. The putative interdomain locations of the DM750 mutation and that of E. coli DM800 (in gyrase B protein) suggests that these compensatory mutations may reduce DNA supercoiling activity by altering allosteric interactions in the gyrase complex.     

Characterization of molecular markers for specific and sensitive detection of Botrytis cinerea Pers.: Fr. in strawberry (Fragariaxananassa Duch.) using PCR

Part of the gyrase A gene (gyrA) of Acholeplasma laidlawii was cloned and incorporated directly downstream from a 6 x His tag segment of the pQE expression vector. The 23-kDa fusion protein was expressed as a 6 x His-tagged protein in Escherichia coli. The fusion protein was purified and used as an antigen for rabbit immunization. Western immunoblot analysis revealed that the antiserum raised against the gyrase A fragment had a specific affinity for a 108-kDa protein of A. laidlawii and cross-reacted with a 107.5-kDa protein of Acholeplasma axanthum, a 107-kDa protein of Acholeplasma granularum, and 95-97-kDa proteins of several phytoplasma-infected plants. The antiserum could also detect phytoplasmas in infected plant sap. These results demonstrate that the gyrase A protein (GyrA) of A. laidlawii shares antigenicity with the GyrA of other Acholeplasma species and also with those of phytoplasmas including some from a few groups with unrelated 16S rRNAs.     

The structural basis for substrate specificity in DNA topoisomerase IV

Most bacteria possess two type IIA topoisomerases, DNA gyrase and topo IV, that together help manage chromosome integrity and topology. Gyrase primarily introduces negative supercoils into DNA, an activity mediated by the C-terminal domain of its DNA binding subunit (GyrA). Although closely related to gyrase, topo IV preferentially decatenates DNA and relaxes positive supercoils. Here we report the structure of the full-length Escherichia coli ParC dimer at 3.0 A resolution. The N-terminal DNA binding region of ParC is highly similar to that of GyrA, but the ParC dimer adopts a markedly different conformation. The C-terminal domain (CTD) of ParC is revealed to be a degenerate form of the homologous GyrA CTD, and is anchored to the top of the N-terminal domains in a configuration different from that thought to occur in gyrase. Biochemical assays show that the ParC CTD controls the substrate specificity of topo IV, likely by capturing DNA segments of certain crossover geometries. This work delineates strong mechanistic parallels between topo IV and gyrase, while explaining how structural differences between the two enzyme families have led to distinct activity profiles. These findings in turn explain how the structures and functions of bacterial type IIA topoisomerases have evolved to meet specific needs of different bacterial families for the control of chromosome superstructure.     

Evidence for the role of DNA strand passage in the mechanism of action of microcin B17 on DNA gyrase

Microcin B17 (MccB17) is a DNA gyrase poison; in previous work, this bacterial toxin was found to slowly and incompletely inhibit the reactions of supercoiling and relaxation of DNA by gyrase and to stabilize the cleavage complex, depending on the presence of ATP and the DNA topology. We now show that the action of MccB17 on the gyrase ATPase reaction and cleavage complex formation requires a linear DNA fragment of more than 150 base pairs. MccB17 is unable to stimulate the ATPase reaction by stabilizing the weak interactions between short linear DNA fragments (70 base pairs or less) and gyrase, in contrast with the quinolone ciprofloxacin. However, MccB17 can affect the ATP-dependent relaxation of DNA by gyrase lacking its DNA-wrapping or ATPase domains. From these findings, we propose a mode of action of MccB17 requiring a DNA molecule long enough to allow the transport of a segment through the DNA gate of the enzyme. Furthermore, we suggest that MccB17 may trap a transient intermediate state of the gyrase reaction present only during DNA strand passage and enzyme turnover. The proteolytic signature of MccB17 from trypsin treatment of the full enzyme requires DNA and ATP and shows a protection of the C-terminal 47-kDa domain of gyrase, indicating the involvement of this domain in the toxin mode of action and consistent with its proposed role in the mechanism of DNA strand passage. We suggest that the binding site of MccB17 is in the C-terminal domain of GyrB.     

A New Crystal Structure of the Bifunctional Antibiotic Simocyclinone D8 Bound to DNA Gyrase Gives Fresh Insight into the Mechanism of Inhibition

Simocyclinone D8 (SD8) is an antibiotic produced by Streptomyces antibioticus that targets DNA gyrase. A previous structure of SD8 complexed with the N-terminal domain of the DNA gyrase A protein (GyrA) suggested that four SD8 molecules stabilized a tetramer of the protein; subsequent mass spectrometry experiments suggested that a protein dimer with two symmetry-related SD8s was more likely. This work describes the structures of a further truncated form of the GyrA N-terminal domain fragment with and without SD8 bound. The structure with SD8 has the two SD8 molecules bound within the same GyrA dimer. This new structure is entirely consistent with the mutations in GyrA that confer SD8 resistance and, by comparison with a new apo structure of the GyrA N-terminal domain, reveals the likely conformation changes that occur upon SD8 binding and the detailed mechanism of SD8 inhibition of gyrase. Isothermal titration calorimetry experiments are consistent with the crystallography results and further suggest that a previously observed complex between SD8 and GyrB is ~ 1000-fold weaker than the interaction with GyrA.     

gyrB-225, a mutation of DNA gyrase that compensates for topoisomerase I deficiency: investigation of its low activity and quinolone hypersensitivity

The B subunit of DNA gyrase (GyrB) consists of a 43 kDa N-terminal domain, containing the site of ATP binding and hydrolysis, and a 47 kDa C-terminal domain that is thought to play a role in interactions with GyrA and DNA. In cells containing a deletion of topA (the gene encoding DNA topoisomerase I) a compensatory mutation is found in gyrB. This mutation (gyrB-225) results in a two amino acid insertion in the N-terminal domain of GyrB. We found that cells containing this mutation are more sensitive than wild-type cells to quinolone drugs with respect to bacteriostatic and lethal action. We have characterised the mutant GyrB protein in vitro and found it to have reduced DNA supercoiling, relaxation, ATPase, and cleavage activities. The mutant enzyme is up to threefold more sensitive to quinolones than wild-type. The mutation also increases the affinity of GyrB for GyrA and DNA, while the affinity of quinolone for the enzyme-DNA complex is unaffected. We propose that the loss in activity is due to misfolding of the GyrB-225 protein, providing an example in which misfolding of one protein, DNA gyrase, suppresses a deficiency of another, topoisomerase I. The increased quinolone sensitivity is proposed to be a consequence of an altered conformation of the protein that renders quinolones better able to disrupt, rather than generate, gyrase-drug-DNA complexes.     

Interactions of CcdB with DNA gyrase. Inactivation of Gyra, poisoning of the gyrase-DNA complex, and the antidote action of CcdA

The F plasmid-carried bacterial toxin, the CcdB protein, is known to act on DNA gyrase in two different ways. CcdB poisons the gyrase-DNA complex, blocking the passage of polymerases and leading to double-strand breakage of the DNA. Alternatively, in cells that overexpress CcdB, the A subunit of DNA gyrase (GyrA) has been found as an inactive complex with CcdB. We have reconstituted the inactive GyrA-CcdB complex by denaturation and renaturation of the purified GyrA dimer in the presence of CcdB. This inactivating interaction involves the N-terminal domain of GyrA, because similar inactive complexes were formed by denaturing and renaturing N-terminal fragments of the GyrA protein in the presence of CcdB. Single amino acid mutations, both in GyrA and in CcdB, that prevent CcdB-induced DNA cleavage also prevent formation of the inactive complexes, indicating that some essential interaction sites of GyrA and of CcdB are common to both the poisoning and the inactivation processes. Whereas the lethal effect of CcdB is most probably due to poisoning of the gyrase-DNA complex, the inactivation pathway may prevent cell death through formation of a toxin-antitoxin-like complex between CcdB and newly translated GyrA subunits. Both poisoning and inactivation can be prevented and reversed in the presence of the F plasmid-encoded antidote, the CcdA protein. The products of treating the inactive GyrA-CcdB complex with CcdA are free GyrA and a CcdB-CcdA complex of approximately 44 kDa, which may correspond to a (CcdB)2(CcdA)2 heterotetramer.     

Breakage-reunion domain of Streptococcus pneumoniae topoisomerase IV: crystal structure of a gram-positive quinolone target

The 2.7 A crystal structure of the 55-kDa N-terminal breakage-reunion domain of topoisomerase (topo) IV subunit A (ParC) from Streptococcus pneumoniae, the first for the quinolone targets from a gram-positive bacterium, has been solved and reveals a 'closed' dimer similar in fold to Escherichia coli DNA gyrase subunit A (GyrA), but distinct from the 'open' gate structure of Escherichia coli ParC. Unlike GyrA whose DNA binding groove is largely positively charged, the DNA binding site of ParC exhibits a distinct pattern of alternating positively and negatively charged regions coincident with the predicted positions of the grooves and phosphate backbone of DNA. Based on the ParC structure, a new induced-fit model for sequence-specific recognition of the gate (G) segment by ParC has been proposed. These features may account for the unique DNA recognition and quinolone targeting properties of pneumococcal type II topoisomerases compared to their gram-negative counterparts.     

Lethal fragmentation of bacterial chromosomes mediated by DNA gyrase and quinolones

When DNA gyrase is trapped on bacterial chromosomes by quinolone antibacterials, reversible complexes form that contain DNA ends constrained by protein. Two subsequent processes lead to rapid cell death. One requires ongoing protein synthesis; the other does not. The prototype quinolone, nalidixic acid, kills wild-type Escherichia coli only by the first pathway; fluoroquinolones kill by both. Both lethal processes correlated with irreversible chromosome fragmentation, detected by sedimentation and viscosity of DNA from quinolone-treated cells. However, only fluoroquinolones fragmented purified nucleoids when incubated with gyrase purified from wild-type cells. A GyrA amino acid substitution (A67S) expected to perturb a GyrA-GyrA dimer interface allowed nalidixic acid to fragment chromosomes and kill cells in the absence of protein synthesis; moreover, it made a non-inducible lexA mutant hypersusceptible to nalidixic acid, a property restricted to fluoroquinolones with wild-type cells. The GyrA variation also facilitated immunoprecipitation of DNA fragments by GyrA antiserum following nalidixic acid treatment of cells. The ability of changes in both gyrase and quinolone structure to enhance protein synthesis-independent lethality and chromosome fragmentation is explained by drug-mediated destabilization of gyrase-DNA complexes. Instability of type II topoisomerase-DNA complexes may be a general phenomenon that can be exploited to kill cells.     

Molecular cloning of the DNA gyrase genes from Methylovorus sp. strain SS1 and the mechanism of intrinsic quinolone resistance in methylotrophic bacteria

The genes encoding the DNA gyrase A (GyrA) and B subunits (GyrB) of Methylovorus sp. strain SS1 were cloned and sequenced. gyrA and gyrB coded for proteins of 846 and 799 amino acids with calculated molecular weights of 94,328 and 88,714, respectively, and complemented Escherichia coli gyrA and gyrB temperature sensitive (ts) mutants. To analyze the role of type II topoisomerases in the intrinsic quinolone resistance of methylotrophic bacteria, the sequences of the quinolone resistance-determining regions (QRDRs) in the A subunit of DNA gyrase and the C subunit (ParC) of topoisomerase IV (Topo IV) of Methylovorus sp. strain SS1, Methylobacterium extorquens AM1 NCIB 9133, Methylobacillus sp, strain SK1 DSM 8269, and Methylophilus methylotrophus NCIB 10515 were determined. The deduced amino acid sequences of the QRDRs of the ParCs in the four methylotrophic bacteria were identical to that of E. coli ParC. The sequences of the QRDR in GyrA were also identical to those in E. coli GyrA except for the amino acids at positions 83, 87, or 95. The Ser83 to Thr substitution in Methylovorus sp. strain SS1, and the Ser83 to Leu and Asp87 to Asn substitutions in the three other methylotrophs, agreed well with the minimal inhibitory concentrations of quinolones in the four bacteria, suggesting that these residues play a role in the intrinsic susceptibility of methylotrophic bacteria to quinolones.     

Preliminary crystallographic analysis of the breakage-reunion domain of the Escherichia coli DNA gyrase A protein

The 64 x 10(3) Mr N-terminal breakage-reunion domain of the Escherichia coli DNA gyrase A protein was purified from an over-expressing strain. When complexed with the gyrase B protein, this truncated A protein has all of the enzymic properties of the full-length counterpart, although with reduced efficiency in some cases. The 64 x 10(3) Mr protein has been crystallized in several forms, a number of which were too small for crystallographic analysis. However, two forms grew to sufficient size for preliminary X-ray analysis. Both forms were tetragonal with a primitive lattice. One form (type I) had cell dimensions of a = b = 170 A, c = 145 A a space group of either P41212 (P43212) or P42212, and diffracted to 6 A resolution. The type II crystals had cell dimensions of a = b = 177 A, c = 175 A, a space group of P41212 (P43212) or P42212, and diffracted to at least 4.5 A resolution. Both crystal forms apparently contained four subunits (possibly a tetramer) in the asymmetric unit. We are attempting to increase the size and quality of these crystals.     

Identification and properties of the catalytic domain of mammalian DNA polymerase beta

Rat DNA polymerase beta (beta-pol) is a 39-kDa protein organized in two tightly folded domains, 8-kDa N-terminal and 31-kDa C-terminal domains, connected by a short protease-sensitive region. The 8-kDa domain contributes template binding to the intact protein, and we now report that the 31-kDa C-terminal domain contributes catalytic activity. Our results show that this domain as a purified proteolytic fragment conducts DNA synthesis under appropriate conditions but the kcat is lower and primer extension properties are different from those of the intact enzyme. A proteolytic truncation of the 31-kDa catalytic domain fragment, to remove a 60-residue segment from the NH2-terminal end, results in nearly complete loss of activity, suggesting the importance of this segment. Overall, these results indicate that the domains of beta-pol have distinct functional roles, template binding and nucleotidyltransferase, respectively; yet, the intact protein is more active for each function than the isolated individual domain fragment.     

Escherichia coli DNA gyrase: genetic analysis of gyrA and gyrB mutations responsible for thermosensitive enzyme activity.

Escherichia coli gyrA43 and gyrB203 alleles conferring temperature-sensitive (ts) growth encoded Gly751-->Asp and Pro171-->Ser substitutions in the DNA gyrase A and B subunits, respectively. A plasmid-borne gyrA43 allele was genetically dominant over a chromosomal quinolone-resistant gyrA gene at 30 degrees C but not at 42 degrees C. These results and others confirm the ts phenotype of the mutation, the first to be identified in the C-terminal DNA binding/complex stabilizing domain of gyrase A protein. By contrast, the Pro171-->Ser mutation is located near the ATP-binding site of gyrase B protein and could interfere with energy coupling during DNA supercoiling. These data are discussed in regard to recently described gyrA(ts) mutations that affect the control of chromosome segregation.     

The nucleotide sequence of the fission yeast DNA topoisomerase II gene: structural and functional relationships to other DNA topoisomerases.

We have determined the complete nucleotide sequence of a 5.3-kb long genomic DNA fragment of the fission yeast Schizosaccharomyces pombe that encodes DNA topoisomerase II. It contains a 4293 bp long single open reading frame. The predicted polypeptide has 1431 residues (mol. wt 162,000) and shows three characteristic domains; the large C-terminal region, which consists of alternating acidic-basic stretches and might be a chromatin-binding domain, the NH2 half domain homologous to the ATP-binding gyrB subunit of bacterial gyrase and the central-to-latter part which is homologous to the NH2 domain of the catalytic gyrA subunit, suggesting a possible evolutionary consequence of the gene fusion of the bacterial gyrase subunits into the eucaryotic DNA topoisomerase II gene. We have found that the cloned fission yeast TOP2 gene can complement the budding yeast top2 mutation, although the fission yeast TOP2 protein sequence is only 50% homologous to the recently determined sequence of budding yeast (J.C. Wang, personal communication). Conversely, the budding yeast TOP2 gene can complement the fission yeast top2 mutations, indicating that their DNA topoisomerase II genes are functionally exchangeable.     

The additional 165 amino acids in the B protein of Escherichia coli DNA gyrase have an important role in DNA binding

DNA gyrase is the only enzyme known to negatively supercoil DNA. The enzyme is a heterotetramer of A(2)B(2) subunit composition. Alignment of the primary sequence of gyrase B (GyrB) from various species shows that they can be grouped into two classes. The GyrB of Gram-negative eubacteria has a stretch of about 165 amino acids in the C-terminal half, which is lacking in other GyrB subunits and type II topoisomerases. In Escherichia coli, no function has so far been attributed to this stretch. In this study, we have tried to assess the function of this region both in vivo and in vitro. A deletant (GyrBDelta160) lacking this region is non-functional in vivo. The holoenzyme reconstituted from gyrase A (GyrA) and GyrBDelta160 shows reduced but detectable supercoiling and quinolone-induced cleavage activity in vitro. GyrBDelta160 retains its ability to bind to GyrA and novobiocin. However, when reconstituted with GyrA, the deletant shows greatly impaired DNA binding. The intrinsic ATPase activity of the GyrBDelta160 is comparable to that of wild type GyrB, but this activity is not stimulated by DNA. These studies indicate that the additional stretch present in GyrB is essential for the DNA binding ability of E. coli gyrase.     

Control of segregation of chromosomal DNA by sex factor F in Escherichia coli. Mutants of DNA gyrase subunit A suppress letD (ccdB) product growth inhibition.

The letA (ccdA) and letD (ccdB) genes, located just outside the sequence essential for replication of the F plasmid, apparently contribute to stable maintenance of the plasmid. The letD gene product acts to inhibit partitioning of chromosomal DNA and cell division of the host bacteria, whereas the letA gene product acts to suppress the activity of the letD gene product. To identify the target of the letD gene product, temperature-sensitive growth-defective mutants were screened from bacterial mutants that had escaped the letD product growth inhibition that occurs in hosts carrying an FletA mutant. Of nine mutants analysed, three mutants were shown, by phage P1-mediated transduction and complementation analysis, to have mutations in the gyrA gene and the other six in the groE genes. The nucleotide sequence revealed that one of the gyrA mutants has a base change from G to A at position 641 (resulting in an amino acid change from Gly to Glu at position 214) of the gyrA gene. The mutant GyrA proteins produced by these gyrA(ts) mutants were trans-dominant over wild-type GyrA protein for letD tolerance. The wild-type GyrA protein, produced in excess amounts by means of a multicopy plasmid, overcame growth inhibition of the letD gene product. These observations strongly suggest that the A subunit of DNA gyrase is the target of the LetD protein.