Ciprofloxacin affects conformational equilibria of DNA gyrase A in the presence of magnesium ions.

The conformational equilibria of the A subunit of DNA gyrase (GyrA), of its 59 kDa N-terminal fragment (GyrA59) and of the quinolone-resistant Ser-Trp83 mutant (GyrATrp83), were investigated in the presence of mono- and divalent metal ions and ciprofloxacin, a clinically useful antibacterial quinolone. The stability of the proteins was estimated from temperature denaturation, monitoring unfolding with circular dichroism spectroscopy. Two transitions were observed in GyrA and GyrATrp83, which likely reflect unfolding of the N and C-terminal protein domains. Accordingly, one thermal transition is observed for GyrA59. The melting profile of the GyrA subunit is dramatically affected by monovalent and divalent metal ions, both transitions being shifted to lower temperature upon increasing salt concentration. This effect is much more pronounced with divalent ions (Mg(2+)) and cannot be accounted for by changes in ionic strength only. The presence of ciprofloxacin shifts the melting transitions of the wild-type subunit to higher temperatures when physiological concentrations of Mg(2+) are present. In contrast, both the mutant protein and the 59 kDa fragment do not show evidence for quinolone-driven changes. These data suggest that ciprofloxacin binds to the wild-type subunit in an interaction that involves Ser83 of GyrA and that both C and N-terminal domains may be required for effective drug-protein interactions. The bell-shaped dependence of the binding process upon Mg(2+) concentration, with a maximum centred at 3-4 mM [Mg(2+)], is consistent with a metal-ion mediated GyrA-quinolone-interaction. Affinity chromatography data fully support these findings and additionally confirm the requirement for a free carboxylate to elicit binding of the quinolone to GyrA. We infer that the Mg(2+)-GyrA interaction at physiological metal ion concentration could bear biological relevance, conferring more conformational flexibility to the active enzyme. The results obtained in the presence of ciprofloxacin additionally suggest that the Mg(2+)-mediated quinolone binding to the enzyme might be involved in the mechanism of action of this family of drugs.

Locking the ATP-operated clamp of DNA gyrase: probing the mechanism of strand passage.

DNA gyrase catalyses DNA supercoiling by passing one segment of DNA (the T segment) through another (the G segment) in a reaction coupled to the binding and hydrolysis of ATP. The N-terminal domains of the gyrase B dimer constitute an ATP-operated clamp that is proposed to capture the T segment during the DNA supercoiling reaction. We have locked this clamp in the closed conformation using the non-hydrolysable ATP analogue ADPNP (5'-adenylyl beta,gamma-imidodiphosphate). The clamp-locked enzyme is able to bind and cleave DNA, albeit at a reduced level. Although the locked enzyme is not capable of carrying out DNA supercoiling, it can catalyse limited DNA relaxation, consistent with the ability to complete one strand passage event per enzyme molecule via entry of the T segment through the exit gate of the enzyme. The DNA-protein complex of the clamp-locked enzyme has a conformation that differs from the normal positively wrapped conformation of the gyrase-DNA complex. These experiments confirm the role of the ATP-operated clamp in the strand-passage reactions of gyrase and suggest a model for the interaction of DNA with gyrase in which a conformation with the T segment in equilibrium across the DNA gate can be achieved via T-segment entry through the ATP-operated clamp or through the exit gate.

Sub-cellular localisation of the white/scarlet ABC transporter to pigment granule membranes within the compound eye of Drosophila melanogaster.

The white, scarlet, and brown genes of Drosophila melanogaster encode ABC transporters involved with the uptake and storage of metabolic precursors to the red and brown eye colour pigments. It has generally been assumed that these proteins are localised in the plasma membrane and transport precursor molecules from the heamolymph into the eye pigment cells. However, the immuno-electron microscopy experiments in this study reveal that the White and Scarlet proteins are located in the membranes of pigment granules within pigment cells and retinula cells of the compound eye. No evidence of their presence in the plasma membrane was observed. This result suggests that, rather than tranporting tryptophan into the cell across the plasma membrane, the White/Scarlet complex transports a metabolic intermediate (such as 3-hydroxy kynurenine) from the cytoplasm into the pigment granules. Other functional implications of this new finding are discussed.

The interaction of DNA gyrase with the bacterial toxin CcdB: evidence for the existence of two gyrase-CcdB complexes.

CcdB is a bacterial toxin that targets DNA gyrase. Analysis of the interaction of CcdB with gyrase reveals two distinct complexes. An initial complex (alpha) is formed by direct interaction between GyrA and CcdB; this complex can be detected by affinity column and gel-shift analysis, and has a proteolytic signature which is characterised by a 49 kDa fragment of GyrA. Surface plasmon resonance shows that CcdB binds to the N-terminal domain of GyrA with high affinity. In this mode of binding, CcdB does not affect the ability of gyrase to hydrolyse ATP or promote supercoiling. Incubation of this initial complex with ATP in the presence of GyrB and DNA slowly converts it to a second complex (beta), which has a lower rate of ATP hydrolysis and is unable to catalyse supercoiling. The efficiency of formation of this inactive complex is dependent on the concentrations of ATP and CcdB. We suggest that the conversion between the two complexes proceeds via an intermediate, whose formation is dependent on the rate of ATP hydrolysis.

Mutations in the white gene of Drosophila melanogaster affecting ABC transporters that determine eye colouration.

The white, brown and scarlet genes of Drosophila melanogaster encode proteins which transport guanine or tryptophan (precursors of the red and brown eye colour pigments) and belong to the ABC transporter superfamily. Current models envisage that the white and brown gene products interact to form a guanine specific transporter, while white and scarlet gene products interact to form a tryptophan transporter. In this study, we report the nucleotide sequence of the coding regions of five white alleles isolated from flies with partially pigmented eyes. In all cases, single amino acid changes were identified, highlighting residues with roles in structure and/or function of the transporters. Mutations in w(cf) (G589E) and w(sat) (F590G) occur at the extracellular end of predicted transmembrane helix 5 and correlate with a major decrease in red pigments in the eyes, while brown pigments are near wild-type levels. Therefore, those residues have a more significant role in the guanine transporter than the tryptophan transporter. Mutations identified in w(crr) (H298N) and w(101) (G243S) affect amino acids which are highly conserved among the ABC transporter superfamily within the nucleotide binding domain. Both cause substantial and similar decreases of red and brown pigments indicating that both tryptophan and guanine transport are impaired. The mutation identified in w(Et87) alters an amino acid within an intracellular loop between transmembrane helices 2 and 3 of the predicted structure. Red and brown pigments are reduced to very low levels by this mutation indicating this loop region is important for the function of both guanine and tryptophan transporters.

The interaction of the F plasmid killer protein, CcdB, with DNA gyrase: induction of DNA cleavage and blocking of transcription.

We have studied the interaction of the F plasmid killer protein CcdB with its intracellular target DNA gyrase. We confirm that CcdB can induce DNA cleavage by gyrase and show that this cleavage reaction requires ATP hydrolysis when the substrate is linear DNA, but is independent of hydrolysis when negatively supercoiled DNA is used. The 64 kDa domain of the gyrase A protein, which can catalyse DNA cleavage in the presence of the B protein and quinolone drugs, is unable to cleave DNA in the presence of CcdB unless the C-terminal 33 kDa domain of the gyrase A protein is also present. CcdB-induced DNA cleavage by gyrase requires a minimum length of DNA (> approximately 160 bp), whereas in the presence of quinolone drugs gyrase can cleave much shorter DNA molecules. We show that CcdB, like quinolones, can form a complex with gyrase which can block transcription by RNA polymerase. A model for the interaction of CcdB with gyrase involving the trapping of a post-strand-passage intermediate is suggested. We conclude that CcdB can stabilise a cleavage complex between DNA gyrase and DNA in a manner distinct from quinolones but, like the quinolone-induced cleavage complex, the CcdB-stabilised complex can also form a barrier to the passage of polymerases.

Transient expression of the Drosophila melanogaster cinnabar gene rescues eye color in the white eye (WE) strain of Aedes aegypti.

The lack of eye pigment in the Aedes aegypti WE (white eye) colony was confirmed to be due to a mutation in the kynurenine hydroxylase gene, which catalyzes one of the steps in the metabolic synthesis of ommochrome eye pigments. Partial restoration of eye color (orange to red phenotype) in pupae and adults occurred in both sexes when first or second instar larvae were reared in water containing 3-hydroxykynurenine, the metabolic product of the enzyme kynurenine hydroxylase. No eye color restoration was observed when larvae were reared in water containing kynurenine sulfate, the precursor of 3-hydroxykynurenine in the ommochrome synthesis pathway. In addition, a plasmid clone containing the wild type Drosophila melanogaster gene encoding kynurenine hydroxylase, cinnabar (cn), was also able to complement the kynurenine hydroxylase mutation when it was injected into embryos of the A. aegypti WE strain. The ability to complement this A. aegypti mutant with the transiently expressed D. melanogaster cinnabar gene supports the value of this gene as a transformation reporter for use with A. aegypti WE and possibly other Diptera with null mutations in the kynurenine hydroxylase gene.

The structure, sequence and developmental pattern of expression of the white gene in the blowfly Lucilia cuprina.

We have sequenced the complete coding region of the white gene of Lucilia cuprina. Strong sequence identity exists between this gene and its homologue from Drosophila melanogaster at both nucleotide and derived amino acid levels (68% and 78% respectively). The exon/intron structure of the two genes is also largely conserved, although the Lucilia gene contains one extra intron. Expression of the gene peaks during mid-pupal stage, with secondary peaks in late larval and early adult stages. Comparisons between this and other white genes will contribute to a better understanding of ATP-binding transmembrane transport proteins. The white gene should also serve as a useful marker gene in the development of a gene transformation system for the sheep blowfly.

The 5' regulatory region from the Drosophila pseudoobscura hsp82 gene results in a high level of reporter gene expression in Lucilia cuprina embryos.

We have previously examined the efficiency of two Drosophila melanogaster promoters to enable reporter gene expression in embryos of the Australian sheep blowfly, Lucilia cuprina. Both the hsp70 heat-shock promoter and the actin5C promoter resulted in low levels of expression of a reporter gene in these embryos. In this study, the D. pseudoobscura hsp82 promoter (phsp82) was tested for its ability to direct the expression of the Escherichia coli chloramphenicol acetyltransferase-encoding gene (cat). We report that the level of CAT activity in L. cuprina embryos was comparable to that obtained with the same construct in D. melanogaster, indicating that phsp82 functions efficiently in this non-drosophilid insect. The results suggest that phsp82 may be utilised in other non-drosophilid insects in which poor expression levels are obtained from constructs containing the hsp70 or actin5C promoters.

Drosophila melanogaster contains both X-linked and autosomal homologues of the gene encoding calcineurin B.

A transcription unit was identified in the 43E polytene band region of the second chromosome of Drosophila melanogaster (Dm) whose putative translation product has 85% amino acid (aa) identity with the B subunit of the calcineurin protein (CnB) from humans. Unlike the previously described intronless Dm CnB gene homologue, which is located within the 4F band region of the X chromosome, the coding region of this second CnB is found to be interrupted by three introns. Conceptual translation of both Dm CnB genes predict proteins of identical size that are 98% identical in aa sequence. Northern blot analyses indicate that Dm pupae and adults express two different CnB-encoding transcripts that are differentially regulated.

The hermit transposable element of the Australian sheep blowfly, Lucilia cuprina, belongs to the hAT family of transposable elements.

We report the cloning of hermit, a member of the hAT family of transposable elements from the genome of the Australian sheep blowfly, Lucilia cuprina. Hermit is 2716 bp long and is 49% homologous to the autonomous hobo element, HFL1, at the nucleic acid level. Hermit has 15 bp terminal inverted repeats that share 10 bp with the terminal inverted repeats of HFL1. Conceptual translation reveals a 583 residue open reading frame (ORF) that is 64% similar and 42% identical to the HFL1 ORF. However, the sequence of the hermit element contains two frameshifts within the putative ORF, indication that hermit is an inactive element. Analysis of L. cuprina strains from within and outside Australia suggested that hermit is present as a single copy in all the genomes analysed.

Molecular characterization of the cinnabar region of Drosophila melanogaster: identification of the cinnabar transcription unit.

Early studies of eye pigmentation in Drosophila melanogaster provided compelling evidence that the cinnabar (cn) gene encodes the enzyme kynurenine 3-monooxygenase (EC 1.14.13.9). Here we report the cloning of approximately 60 kb of DNA encompassing the cn gene by chromosome walking in the 43E6-F1 region of chromosome 2. An indication of the position of cn within the cloned region was obtained by molecular analysis of mutants: 9 spontaneous cn mutants were found to have either DNA insertions or deletions within a 5 kb region. In addition, a 7.8 kb restriction fragment encompassing the region altered in the mutants was observed to induce transient cn function when microinjected into cn- embryos. The cn transcription unit was identified by Northern blotting and sequence analysis of cDNA and genomic clones from this region. The predicted cn protein contains several sequence motifs common to aromatic monooxygenases and is consistent with the assignment of cn as encoding the structural gene for kynurenine 3-monooxygenase.

Molecular characterization of spontaneous mutations at the scarlet locus of Drosophila melanogaster.

Six spontaneous mutations of the scarlet (st) locus of Drosophila melanogaster have been studied at the molecular level. Two of the mutants (st1 and stsp) arose in laboratory populations, while the other four (stcob, stct89, stdct and stdv) were isolated from natural populations. In five of these there is a DNA insertion within the st region and in four cases the insertion has been identified as being a transposable element; these include the retrotransposons 412 and B104/roo, and also jockey a member of the LINE family. In the other case (stdct), the insertion appears to consist of partially duplicated st sequences. In two of the mutants (st1 and stdv) the same transposable element (412) has inserted in the same orientation at exactly the same site within the st gene. The transposable element insertions are found in intron and exon regions of the st gene and also in the putative upstream regulatory region; insertions located in introns or exons result in the production of truncated st transcripts. The results show that the same types of transposable elements that cause spontaneous mutation in laboratory stocks of D. melanogaster also cause mutation in the wild.

Immunogold localization of GyrA and GyrB proteins in Escherichia coli.

Immunogold preparations of Escherichia coli, using anti-GyrA and anti-GyrB antibodies to the subunits of DNA gyrase, showed clear labelling with both secondary antibody and protein A-gold conjugates. Both proteins were located mainly in the cytoplasm, with typically less than 10% in the nucleoid. This partitioning of gyrase proteins between nucleoid and cytoplasm was nonrandom and was consistently observed for a range of different cell preparations. Total gold particle counts were highly variable but suggested levels of at least 1000-3000 molecules per cell for both GyrA and GyrB. Sequential treatment with both anti-GyrA and anti-GyrB monoclonal antibodies resulted in simultaneous labelling of both proteins and revealed no clear association between the two groups of molecules. Treatment of cells with chloramphenicol caused marked changes in nucleoid conformation, but no reduction in cytoplasmic labelling of gyrase proteins. On the assumption that gyrase complexes within the nucleoid are not differentially masked from the monoclonal antibodies, the results obtained in this study suggest that most of the gyrase proteins are not associated with either central nucleoid DNA or cytoplasmic loops of peripheral single-stranded DNA, but are distributed randomly throughout the cytoplasm.

Mutational analysis of the traffic ATPase (ABC) transporters involved in uptake of eye pigment precursors in Drosophila melanogaster. Implications for structure-function relationships.

The white, brown, and scarlet genes of Drosophila melanogaster encode three proteins that belong to the Traffic ATPase superfamily of transmembrane permeases and are involved in the transport of guanine and tryptophan (precursors of the red and brown eye pigments). We have determined the nucleotide sequences of two mutant white alleles (wco2 and wBwx) that cause reduced red pigmentation but have no effect on brown pigmentation. In wco2 the effect is only observed when interacting with the bw6 allele or a newly isolated allele (bwT50). These alleles of the brown gene were cloned and sequenced. In wco2 the codon for glycine 588 is changed to encode serine; in wBwx the triplet ATC encoding isoleucine 581 is deleted; asparagine 638 is changed to threonine in bw6, and glycine 578 is changed to aspartate in bwT50. No other relevant changes to the gene structures were detected. P-element-mediated germline transduction was used to construct a fly strain containing a white gene with a mutation of the nucleotide binding domain. Such flies had white eyes, indicating that the mutated white gene was unable to support either guanine or tryptophan transport. The implications of these mutations are discussed in terms of a model of the Drosophila pigment precursor transport system.

The 43-kilodalton N-terminal fragment of the DNA gyrase B protein hydrolyzes ATP and binds coumarin drugs.

We have cloned and overexpressed a gene encoding a 43-kDa protein corresponding to the N-terminal fragment of the DNA gyrase B subunit. We show that this protein hydrolyzes ATP and binds coumarin drugs. The hydrolysis of ATP shows distinctly non-Michaelis-Menten kinetics and is consistent with a scheme in which the active form of the protein is a dimer, a conclusion supported by molecular weight studies. The coumarin drugs bind very tightly to the 43-kDa fragment, with novobiocin binding to the protein monomer and coumermycin A1 apparently inducing the formation of a dimer. The implications of these results with respect to the mechanism of supercoiling by DNA gyrase and the inhibition of gyrase by coumarin drugs are discussed.

Genomic sequences with homology to the P element of Drosophila melanogaster occur in the blowfly Lucilia cuprina.

We have cloned two DNA elements (Lu-P1 and Lu-P2) from the Australian sheep blowfly Lucilia cuprina that are similar to the transposable P element of Drosophila melanogaster in both structure and sequence but have diverged from it and from each other considerably. Hybridization studies indicate that a third related element probably exists in another, as yet unsequenced, clone. Neither Lu-P1 nor Lu-P2 appears to be active in terms of mobility, and it is not known whether any transposition-competent copies of other related elements occur in the genome of the blowfly. However, the isolation of any P-like sequences from a species outside of the family Drosophilidae allows comparisons to be made of more widely divergent P-related elements than has been possible previously. We are unaware of any report of the presence of multiple P-like family members within a single species. The discovery of Lu-P1 and Lu-P2 in the blowfly fuels the possibility that similar elements may be widespread in insects, and perhaps in other orders of animals.