Effects of microcin B17 on microcin B17-immune cells

When microcin B17-immune cells are treated with microcin B17 they show many of the physiological effects displayed by microcin B17-sensitive cells treated in the same way. DNA replication stops immediately and several SOS functions are subsequently induced. In sensitive cells these effects are irreversible and lead to cell death, whereas in immune cells they are reversible and there is no loss of viability. This is an unusual mechanism of immunity because it does not prevent the primary action of the microcin. The implications of this mechanism concerning the mode of action of microcin B17 and the induction of the SOS system are discussed.     

Cloning and mapping of the genetic determinants for microcin B17 production and immunity.

Plasmid pMccB17 (70 kilobases [kb]) codes for the production of microcin B17, a peptide that inhibits DNA synthesis, and for microcin B17 immunity. A BamHI-EcoRI fragment of 5.1 kb from pMccB17 was cloned into pBR322 in two steps. The resulting plasmid (pMM102) overproduced microcin B17 and expressed immunity against microcin. Mcc- and Mcc- Imm- mutants were isolated on plasmids pMccB17 and pMM102 by deleting various DNA fragments and by inserting different translocatable elements. Physical and phenotypic characterization of these mutants showed that a DNA region of 3.0 to 3.5 kb is required to produce microcin B17, whereas an adjacent region of about 1.0 kb is required to express microcin B17 immunity.     

Evidence that colicin X is microcin B17.

The DNA replication inhibitor microcin B17 is a peptide antibiotic produced by Escherichia coli strains carrying plasmid pMccB17. Here we present evidence that antibiotic activities previously named colicin X are probably identical to microcin B17. Our results include comparison of the conditions of production of the antibiotics, their mode of action, cross-immunity of producer strains, and cross-resistance of resistant mutants. Plasmids encoding colicin X have been identified and shown to have a region of significant homology with the microcin B17-producing region of pMccB17 DNA.     

Wild-type Escherichia coli producing microcins B17, D93, J25, and L; cloning of genes for microcin L production and immunity

For the first time, an Escherichia coli strain producing four microcins (Mcc), B17, D93, J25, and L, and showing immunity to Mcc V was isolated and characterized. Each of the gene clusters encoding the production of Mcc B17, D93, and L was cloned separately. The gene cluster for Mcc L was cloned within a 13.5-kb HindIII-SalI fragment, which includes the Mcc V immunity gene, cvi.     

Influence of aeration and carbon source on production of microcin B17 by Escherichia coli ZK650

Previous studies [Connell et al. (1987) Mol Microbiol 1: 195–201] have shown that expression of the microcin B17 (MccB17) promoter is inversely related to the growth rate of the culture, when slower growth was brought about by limitation of sources of carbon, nitrogen or phosphorus. When we used oxygen limitation to decrease growth in a glucose-based chemically defined medium, we found specific MccB17 production to be positively related to growth rate and extent. On the other hand, when we examined various nutritional variations of media, specific production of MccB17 showed a negative relationship to growth rate and extent, as would be predicted by the findings of Connell et al. (1987). Glucose, glycerol and acetate were found to repress MccB17 production; succinate was not repressive. Succinate is an excellent carbon source for production of MccB17 since high levels can be used with no or little interference in product synthesis. Received: 26 November 1996 / Accepted: 7 December 1996     

Cofactor requirements and reconstitution of microcin B17 synthetase: a multienzyme complex that catalyzes the formation of oxazoles and thiazoles in the antibiotic microcin B17

In the maturation of the Escherichia coli antibiotic Microcin B17 (MccB17), the McbA prepro-antibiotic is modified post-translationally by the multimeric microcin synthetase complex (composed of the McbB, -C, and -D proteins), which cyclizes four cysteines and four serines to thiazoles and oxazoles, respectively. Herein, we report the purification of individual subunits of MccB17 synthetase as fusions to maltose binding protein (MBP), and the in vitro reconstitution of heterocyclization activity. Preliminary characterization of each subunit reveals McbB to be a zinc-containing protein that may catalyze the initial cyclodehydration step, and McbC to contain flavin, consistent with an anticipated role for a dehydrogenase. We have previously demonstrated that McbD is a regulated ATPase/GTPase that may function as a conformational switch. Photolabeling experiments with the McbA propeptide now identify McbD as the initial site of substrate recognition. Heterocyclization activity was reconstituted only by combining all three subunits, demonstrating that each protein is required for heterocycle formation. Titration assays indicate that the subunits bind to each other with at least micromolar affinities, although McbD affords activity only after the MBP tag is proteolytically removed. Subunit competition assays with an McbDD147A mutant, which yields a catalytically deficient synthetase in vivo, show it to be defective in complex formation, whereas the McbBC181A/C184A double mutant, which is also inactive, competitively inhibits reconstitution by native McbB. Addition of the HtpG chaperone (originally shown to copurify with MccB17 synthetase), does not stimulate synthetase reconstitution or heterocyclization activity in vitro. A model for synthetase activity is proposed.     

Shear stress enhances microcin B17 production in a rotating wall bioreactor, but ethanol stress does not

Stress, including that caused by ethanol, has been shown to induce or promote secondary metabolism in a number of microbial systems. Rotating-wall bioreactors provide a low stress and simulated microgravity environment which, however, supports only poor production of microcin B17 by Escherichia coli ZK650, as compared to production in agitated flasks. We wondered whether the poor production is due to the low level of stress and whether increasing stress in the bioreactors would raise the amount of microcin B17 formed. We found that applying shear stress by addition of a single Teflon bead to a rotating wall bioreactor improved microcin B17 production. By contrast, addition of various concentrations of ethanol to such bioreactors (or to shaken flasks) failed to increase microcin B17 production. Ethanol stress merely decreased production and, at higher concentrations, inhibited growth. Interestingly, cells growing in the bioreactor were much more resistant to the growth-inhibitory and production-inhibitory effects of ethanol than cells growing in shaken flasks.     

Structure and organization of plasmid genes required to produce the translation inhibitor microcin C7.

The translation inhibitor microcin C7 (MccC7) is a linear heptapeptide whose N terminus has been replaced by an N-formyl group and whose C terminus has been replaced by the phosphodiester of 5'-adenylic acid and n-aminopropanol (J. I. Guijarro, J. E. González-Pastor, F. Baleux, J. L. San Millán, M. A. Castilla, M. Rico, F. Moreno, and M. Delepierre, J. Biol. Chem. 270:23520-23532, 1995). MccC7 production and immunity determinants lie on a 6.2-kb region of the Escherichia coli plasmid pMccC7. This region was entirely sequenced. It contains six open reading frames, which were shown to be true genes by different complementary approaches. Five genes, mccABCDE, which are transcribed in the same direction, are required to produce mature extracellular microcin. The sixth gene, mccF, adjacent to mccE, is transcribed in the opposite direction and encodes specific self-immunity. Genes mccA to -E constitute an operon transcribed from a promoter (mccp) located upstream of mccA. mccA is 21 nucleotides long and encodes the unmodified heptapeptide (J. E. González-Pastor, J. L. San Millán, and F. Moreno, Nature [London] 369:281, 1994). A comparison of predicted gene polypeptide products with those included in databases shows that an 81-amino-acid stretch of MccB is strikingly homologous to fragments of the same length of proteins ThiF and ChlN from E. coli, HesA from Anabaena sp. strain PCC7120, and UBA1, the ubiquitin-activating enzyme from different eukaryotic species. MccC displays several hydrophobic domains, suggesting a transmembrane location. The carboxyl end of MccE displays 41.2% identity with RimL, a protein required to acetylate the ribosome protein L12 from E. coli. In the absence of the other mcc genes, mccA impairs the growth of host cells, suggesting that unmodified MccA has antibiotic activity. A model for MccC7 biosynthesis, export, and immunity is proposed.     

Plasmid required for virulence of Agrobacterium tumefaciens.

The irreversible loss of crown gall-inducing ability of Agrobacterium tumefaciens strain C-58 during growth at 37 C is shown to be due to loss of a large plasmid (1.2 X 10-8 daltons). The gene responsible for this high rate of plasmid loss at elevated temperatures seems to be located on the plasmid. In addition, another spontaneous avirulent variant, A. tumefaciens strain IIBNV6 is shown to lack the virulence plasmid which its virulent sibling strain, IIBV7, possesses. Deoxyribonucleic acid reassociation measurements prove that the plasmid is eliminated, not integrated into the chromosome, in both of the avirulent derivatives. Transfer of virulence from donor strain C-58 to avirulent recipient strain A136 results from the transfer of a plasmid, which appears identical to the donor plasmid by deoxyribonucleic acid reassociation measurements. The transfer of virulence in another cross, K27 X A136, was also shown to result from the transfer of a large plasmid. These findings establish unequivocally that the large plasmid determines virulence. Two additional genetic determinants have been located on the virulence plasmid of A. tumefaciens strain C-58: the ability to utilize nopaline and sensitivity to a bacteriocin produced by strain 84. The latter trait can be exploited for selection of avirulent plasmid-free derivatives of strain C-58. The trait of nopaline utilization appears to be on the virulence plasmid also in strains IIBV7 and K27.     

The McbB component of microcin B17 synthetase is a zinc metalloprotein

The microcin B17 synthetase converts glycine, serine, and cysteine residues in a polypeptide precursor into oxazoles and thiazoles during the maturation of the Escherichia coli antibiotic Microcin B17. This multimeric enzyme is composed of three subunits (McbB, McbC, and McbD), and it employs both ATP and FMN as cofactors. The McbB subunit was purified as a fusion with the maltose-binding protein (MBP), and metal analysis revealed that this protein binds 0.91+/-0.17 zinc atoms. Upon incubation of MBP-McbB with excess zinc, the stoichiometry increased to two atoms of zinc bound, but metal binding to the second site resulted in a decrease in the heterocyclization activity when MBP-McbB was reconstituted with the other components of the synthetase. Apo-protein was prepared by using p-hydroxymercuriphenylsulfonic acid (PMPS), and loss of the metal caused a severe reduction in enzymatic activity. However, if dithiothreitol was added to the PMPS reactions within a few minutes, enzymatic activity was retained and MBP-McbB could be reconstituted with zinc. Spectroscopic analysis of the cobalt-containing protein and extended X-ray absorption fine structure analysis of the zinc-containing protein both provide evidence for a tetrathiolate coordination sphere. Site-directed mutants of MBP-McbB as well as the synthetase tagged with the calmodulin-binding peptide were constructed. Activity assays and metal analysis were used to determine which of the six cysteines in McbB are metal ligands. These results suggest that the zinc cofactor in McbB plays a structural role.     

Effect of simulated microgravity and shear stress on microcin B17 production by Escherichia coli and on its excretion into the medium.

Production of the antibacterial polypeptide microcin B17 (MccB17) by Escherichia coli ZK650 was inhibited by simulated microgravity. The site of MccB17 accumulation was found to be different, depending on whether the organism was grown in shaking flasks or in rotating bioreactors designed to establish a simulated microgravity environment. In flasks, the accumulation was cellular, but in the reactors, virtually all the microcin was found in the medium. The change from a cellular site to an extracellular one was apparently not a function of gravity, since extracellular production occurred in these bioreactors, irrespective of whether they were operated in the simulated microgravity or normal gravity mode. More probably, excretion is due to the much lower degree of shear stress in the bioreactors. Addition of even a single glass bead to the 50-ml medium volume in the bioreactor created enough shear to change the site of MccB17 accumulation from the medium to the cells.     

Computational analysis of the first biheterocyclization site of the antibiotic microcin B17

Microcin B 17 (MccB17) undergoes an enzyme catalyzed posttranslational modification to form four oxazole and four thiazole rings. Four of these rings form 4,2 - connected biheterocyclic functionalities. In this study, the hexapeptide sequence surrounding the first biheterocyclization site of microcin B17 was examined using computational calculations and database analysis to see if it was preorganized for cyclization in a manner similar to that found in the autocatalytic posttranslational cyclization of Green Fluorescent Protein (GFP). Attention was focused on the intermolecular distances between the sulfur and oxygen atoms of the cysteine and serine residues and the carbonyl carbons which they attack in the ring formation. Conformational searches located some low energy conformations that contained relatively short oxygen to carbonyl carbon distances, which indicated that the oxazole forming fragment in microcin B17 is preorganized for cyclization. However, the lack of any clear patterns for the sulfur to carbon distances show that the side-chain of cysteine does not adopt any low energy conformations that are geometrically preorganized for cyclization. The MccB17 synthetase enzyme complex which catalyzes the cyclization process therefore has both steric and electronic functions. The data obtained in this investigation is in agreement with empirical data which shows that biheterocyclization will only occur if the thiazole forms before the oxazole.     

The leader peptide is essential for the post-translational modification of the DNA-gyrase inhibitor microcin B17

Microcin B17 (MccB17) is a ribosomally encoded DNA-gyrase inhibitor. Ribosomally encoded antibiotics are derived from precursors containing an N-terminal leader, which is removed during maturation, and a C-terminal structural peptide. PreMccB17, the translational product of mcbA , is modified into proMccB17 by the action of three enzymes, McbB, McbC, and McbD. A chromosomally encoded peptidase then converts proMccB17 into MccB17. The role of McbB, McbC, and McbD is to convert glycine, cysteine, and serine residues present in preMccB17 into four thiazole and four oxazole rings. Using a modification-specific antibody rather than antimicrobial activity, we show that the 26-amino-acid N-terminal leader of preMccB17 is essential for the conversion of preMccB17 into proMccB17. Neither a preMccB17 peptide lacking the leader nor a preMccB17–β-galactosidase fusion lacking the leader are post-translationally modified.     

The peptide antibiotic microcin B17 induces double-strand cleavage of DNA mediated by E. coli DNA gyrase.

Microcin B17 (MccB17) is a bactericidal peptide antibiotic which inhibits DNA replication. Two Escherichia coli MccB17 resistant mutants were isolated and the mutations were shown to map to 83 min of the genetic map. Cloning of the mutations and Tn5 insertional analysis demonstrated that they were located inside gyrB. The approximate location of the mutations within gyrB was determined by constructing hybrid genes, as a previous step to sequencing. Both mutations were shown to consist of a single AT----GC transition at position 2251 of the gene, which produces a Trp751----Arg substitution in the amino acid sequence of the GyrB polypeptide. The inhibitory effect of MccB17 on replicative cell-free extracts was assayed. In this in vitro system, interaction of MccB17 with a component of the extracts induced double-strand cleavage of plasmid DNA. In vivo treatment with MccB17 also induced a well-defined cleavage pattern on chromosomal DNA. These effects were not observed with a MccB17-resistant, gyrB mutant. Altogether, our results indicate that MccB17 blocks DNA gyrase by trapping an enzyme-DNA cleavable complex. Thus, the mode of action of this peptide antibiotic resembles that of quinolones and a variety of antitumour drugs currently used in cancer chemotherapy. MccB17 is the first peptide shown to inhibit a type II DNA topoisomerase.     

The action of the bacterial toxin, microcin B17, on DNA gyrase

Microcin B17 (MccB17) is a peptide-based bacterial toxin that targets DNA gyrase, the bacterial enzyme that introduces supercoils into DNA. The site and mode of action of MccB17 on gyrase are unclear. We review what is currently known about MccB17-gyrase interactions and summarise approaches to understanding its mode of action that involve modification of the toxin. We describe experiments in which treatment of the toxin at high pH leads to the deamidation of two asparagine residues to aspartates. The modified toxin was found to be inactive in vivo and in vitro, suggesting that the Asn residues are essential for activity. Following on from these studies we have used molecular modelling to suggest a 3D structure for microcin B17. We discuss the implications of this model for MccB17 action and investigate the possibility that it binds metal ions.     

The maturation pathway of microcin B17, a peptide inhibitor of DNA gyrase

The maturation pathway of microcin B17 (MccB17), a ribosomally synthesized peptide antibiotic which inhibits DNA gyrase, has been characterized. Synthesis of MccB17 involves several steps beginning with the translation of the MccB17 structural gene, mcbA, to yield a 69 amino acid precursor, preMccB17. PreMccB17 is then modified and folded by the action of three gene products, McbBCD, to yield proMccB17. Mutations in mcbA were isolated that permit modifications of the resulting mutant peptides, but prevent folding, suggesting that modification and folding are sequential steps. ProMccB17 is subsequently converted to MccB17 by removal of the W-terminal 26-amino-acid leader by a chromosomally encoded protease. Removal of the leader resulted in aggregation of the peptide, suggesting that the leader may function to maintain peptide solubility during synthesis in the cell. Finally, polyclonal antibodies raised against MccB17 recognize both MccB17 and proMccB17, but do not recognize preMccB17. This demonstrates the dramatic structural changes that result from the modifications and has been used to distinguish intermediates in the steps of maturation.