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.     

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 antibiotic microcin B17 is a DNA gyrase poison: characterisation of the mode of inhibition

Microcin B17 is a 3.1-kDa bactericidal peptide; the putative target of this antibiotic is DNA gyrase. Microcin B17 has no detectable effect on gyrase-catalysed DNA supercoiling or relaxation activities in vitro and is unable to stabilise DNA cleavage in the absence of nucleotides. However, in the presence of ATP, or the non-hydrolysable analogue 5'-adenylyl beta,gamma-imidodiphosphate, microcin B17 stabilises a gyrase-dependent DNA cleavage complex in a manner reminiscent of quinolones, Ca(2+), or the bacterial toxin CcdB. The pattern of DNA cleavage produced by gyrase in the presence of microcin B17 is different from that produced by quinolones and more closely resembles Ca(2+)-mediated cleavage. Several gyrase mutants, including well-known quinolone-resistant mutants, are cross resistant to microcin-induced DNA cleavage. We suggest that microcin exerts its effects through a mechanism that has similarities to those of both the bacterial toxin CcdB and the quinolone antibacterial agents.     

Posttranslational heterocyclization of cysteine and serine residues in the antibiotic microcin B17: distributivity and directionality

To produce the antibiotic Microcin B17, four Cys and four Ser residues are converted into four thiazoles and four oxazoles by the three subunit Microcin B17 synthetase. High-resolution mass spectrometry (MS) was used to monitor the kinetics of posttranslational heterocyclic ring formation (-20 Da per ring) and demonstrated the accumulation of all intermediates, from one to seven rings, indicating distributive processing. All of the intermediates could be converted by the enzyme to the eight ring product. Enzymatic chemoselectivity (Cys vs Ser cyclization rates) was assessed using iodoacetamido-salicylate to alkylate unreacted cysteines (+193 Da) in the 8 kDa biosynthetic intermediates; three of the first four rings formed were thiazoles, and by the five ring stage, all four of the cysteines had been heterocyclized while three of the original four serines remained uncyclized. Finally, tandem MS using a 9.4 T Fourier transform instrument with electrospray ionization was used to elaborate the major processing pathway: the first two rings formed are at the most amino proximal sites (Cys(41) then Ser(40)) followed by the remaining three cysteines at positions 48, 51, and 55. The cyclization of serines at positions 56, 62, and 65 then follows, with Ser(62) and Ser(65) the last to heterocyclize and the first of these at a slower rate. Thus, despite free dissociation of intermediates after each of seven ring-forming catalytic cycles, there is an overall directionality of ring formation from N-terminal to C-terminal sites. This remarkable regioselectivity is determined more by the substrate than the enzyme, due to a combination of (1) initial high-affinity binding of the posttranslational catalyst to the N-terminal propeptide of substrate 88mer, and (2) a chemoselectivity for thiazole over oxazole formation. This mechanism is consistent with antibiotic biosynthesis in vivo, yielding microcin with six, seven, and eight rings, all with bioactivity.     

Purification of ferrichrome synthetase from Aspergillus quadricinctus and characterisation as a phosphopantetheine containing multienzyme complex

Aspergillus quadricinctus was grown under iron limitation to induce the enzymes for ferrichrome biosynthesis. The mycelium was disintegrated by ultraturrax homogenization, and ferrichrome synthetase was purified by column chromatography on DEAE cellulose, hydroxyapatite and Bio-Gel A-5m. The enzyme was almost homogeneous in single fractions as shown in gel electrophoresis under non-denaturating conditions. By fast-protein liquid chromatography on Superose 6, the purified ferrichrome synthetase (molecular weight 9.6.10(5) dissociated partly into an enzyme complex with reduced ferrichrome synthetase activity of 8 x 10(5) Da, one acetylhydroxyornithine (AHO) activating protein of 5.5 x 10(5) Da and one glycine activating protein of 4 x 10(5) Da. After SDS treatment the AHO activating protein dissociated into subunits of 9 x 10(4) Da, while the glycine activating protein dissociated into subunits of 5 x 10(4) Da and 4 x 10(4) Da in a molar ratio of 6:1. No subunits were found after SDS treatment of the larger of the two ferrichrome synthetizing enzyme complexes. Pantetheine was detected in protein bands of defined molecular weights (4 x 10(4), 9 x 10(4) and greater than 3.4 x 10(5) after SDS polyacrylamide gel electrophoresis. Gel slices were cut out, and the growth factor activity for Lactobacillus plantarum ATCC 8014 was analyzed. The calculated content was 2 mol of pantetheine per mol of ferrichrome synthetase of 9.6 x 10(5) Da.     

T-protein of the glycine decarboxylase multienzyme complex: evidence for partial similarity to formyltetrahydrofolate synthetase

We have isolated and sequenced cDNA clones encoding T-protein of the glycine decarboxylase complex from three plant species, Flaveria pringlei, Solanum tuberosum and Pisum sativum. The predicted amino acid sequences of these clones are at least 87% identical and all are similar to the predicted sequences of the bovine, human, chicken and Escherichia coli T-proteins. Alignment of all these sequences revealed conserved domains, one of which showed a significant similarity to a part of the formyltetrahydrofolate synthetases from procaryotes and eucaryotes. This suggests that the T-protein sequence is not as unique as previously thought.     

An important role for the multienzyme aminoacyl-tRNA synthetase complex in mammalian translation and cell growth

In mammalian cells, aminoacyl-tRNA synthetases (aaRSs) are organized into a high-molecular-weight multisynthetase complex whose cellular function has remained a mystery. In this study, we have taken advantage of the fact that mammalian cells contain two forms of ArgRS, both products of the same gene, to investigate the complex's physiological role. The data indicate that the high-molecular-weight form of ArgRS, which is present exclusively as an integral component of the multisynthetase complex, is essential for normal protein synthesis and growth of CHO cells even when low-molecular-weight, free ArgRS is present and Arg-tRNA continues to be synthesized at close to wild-type levels. Based on these observations, we conclude that Arg-tRNA generated by the synthetase complex is a more efficient precursor for protein synthesis than Arg-tRNA generated by free ArgRS, exactly as would be predicted by the channeling model for mammalian translation.     

Structural analysis of the multienzyme aminoacyl-tRNA synthetase complex: a three-domain model based on reversible chemical crosslinking.

A subset of eukaryotic aminoacyl-tRNA synthetases (a-RS) are contained in a multienzyme complex for which little structural detail is known. Three reversible chemical crosslinking reagents have been used to investigate the arrangement of polypeptides within this particle as isolated from rabbit reticulocytes. Identification of the crosslinked protein pairs was accomplished by two-dimensional SDS diagonal gel electrophoresis. Seventeen neighboring protein pairs have been identified. Eight are seen with at least two reagents: K-RS:p38, D-RS:K-RS, R-RS dimer, K-RS dimer, K-RS:Q-RS, E/P-RS:K-RS, E/P-RS:I-RS, and Q-RS with one of the nonsynthetase proteins. Nine more are observed with one reagent: D-RS dimer, R-RS:p43, D-RS:Q-RS, D-RS:M-RS, K-RS:L-RS, I-RS:R-RS, D-RS:E/P-RS, I-RS:Q-RS, I-RS:L-RS. One trimeric association is seen: E/P-RS:I-RS:L-RS. The observed neighboring protein pairs suggest that the polypeptides within the aminoacyl-tRNA synthetase complex are distributed in three structural domains of similar mass. These can be arranged in a U-shaped particle in which each "arm" is considered a domain and the third forms the "base" of the structure. The arms have been termed domain I (D-RS, M-RS, Q-RS) and domain II (K-RS, R-RS), with domain III (E/P-RS, I-RS, L-RS) assigned to the base. The smaller proteins (p38, p43) may bridge the domains. This proposed spatial relationship of these domains, as well as their compositions, are consistent with earlier studies. Thus, this study provides an initial three-dimensional working model of the arrangement of polypeptides within the multienzyme aminoacyl-tRNA synthetase complex.     

Mapping of a complex gene locus coding for part of the Saccharomyces cerevisiae fatty acid synthetase multienzyme complex

Summary Using two different experimental approaches—UV induced mitotic recombination and meiotic segregation—a fatty acid synthetase gene locus has been mapped on chromosome Fragment V of the Saccharomyces cerevisiae genetic map. This locus has been tentatively designated as fas1AB since it is a complex locus coding for at least two different fatty acid synthetase component enzymes, namely the -hydroxyacid dehydratase and the enoyl reductase. According to the meiotic segregation patterns obtained, fas1AB is 41.6 centimorgans from ura1 and 35.7 centimorgans from trp3. Furthermore, the same criteria of mitotic sectoring and meiotic segregation indicate that the second known fatty acid synthetase gene cluster in yeast is genetically unlinked to fas1AB or to any other of the known genetic loci on Fragment V.     

Probing protein structural requirements for formation of the core light-harvesting complex of photosynthetic bacteria using hybrid reconstitution methodology

The - and -polypeptides of LH1 isolated from four different photosynthetic bacteria (Rhodospirillum rubrum, Rhodobacter sphaeroides, Rhodobacter capsulatus and Rhodopseudomonas viridis) were used for homologous and hybrid reconstitution experiments with bacteriochlorophyll a. Formation of B820-type subunit complexes and LH1-type complexes were evaluated. The -polypeptides of R. rubrum, Rb. sphaeroides and Rb. capsulatus behaved similarly and formed B820-type subunit complexes in the absence of an -polypeptide. The - and -polypeptides were both required to form a LH1-type complex with each of these three homologous systems. In hybrid experiments where the -polypeptides were tested for reconstitution with -polypeptides other than their homologous partners, half of the twelve possible combinations resulted in formation of both B820- and LH1-type complexes. Three of the combinations that did not result in formation of a LH1-type complex involved the -polypeptide of R. rubrum. It is suggested that these latter results can be explained by charge repulsion between the Lys at position-17 (assigning the conserved His located nearest to the C-terminus as position 0) in the -polypeptide of R. rubrum and each of the heterologous -polypeptides tested, all of which have an Arg at this location. Conclusions that can be derived from these experimental results include: (1) the experimental data support the idea that a central core region of approximately 40 amino acids exists in each of the polypeptides, which contains sufficient information to allow formation of both the B820- and LH1-type complexes and (2) a specific portion of the N-terminal hydrophilic region of each polypeptide was found in which ion pairs between oppositely charged groups on the - and -polypeptides seem to stabilize complex formation.Abbreviations BChl a bacteriochlorophyll a - BChl BChl a is implied - BChl a _P BChl a containing phytol as the esterifying alcohol - BChl a _gg BChl a containing geranylgeraniol as the esterifying alcohol - LH1 the core light-harvesting complex - B873 the core light-harvesting complex of the G-9 mutant (carotenoidless) of R. rubrum or of the wild-type light-harvesting complex after benzene extraction (both with absorption maxima at 873 nm) - B820 the subunit form of B873 consisting of native - and -polypeptides with the same stoichiometry of ₁₁·2BChl as LH1 - B820-type complex a complex exhibiting absorption and CD spectra indistinguishable from B820 but composed of either the -polypeptide only, or of a heterologous mixture of - and -polypeptides - RC reaction center - PRC photoreceptor complex consisting of the RC and LH1 - CD circular dichroism - OG n-octyl -d-glucopyranoside - HFA hexafluoroacetone trihydrate     

Influence of subunit transcript and protein levels on formation of a mitochondrial multienzyme complex

Constitutive expression of nuclear genes encoding mitochondrial proteins raises the question of whether these proteins are present in similar amounts in mitochondria of different tissues. We report that amounts of a single multienzyme complex can vary on a per mitochondrion basis depending on the number of mitochondria per cell. Human branched-chain α-keto acid dehydrogenase (BCKD) expression is used as a paradigm in these studies. Expression is compared and contrasted in HepG2 and DG75 cells in which mitochondrial content is twofold higher in the hepatocarcinoma line than in the lymphoblastoid line. Per cell, BCKD activity is equal in the two cell types, but BCKD protein concentration per mitochondrion is twofold higher in DG75 cells. Steady-state mRNA levels do not appear to be directly related to amounts of protein in the two cell lines. To test whether one subunit is limiting in formation of complex, overexpression of each BCKD subunit was elicited by plasmid transfection of the DG75 cells. Only overexpression of the β-subunit of the decarboxylase component induced more BCKD activity without apparent increase in mRNA for the other endogenously expressed subunits. This implies that free BCKD subunits exist in a cell and can be recruited into an active complex when the limiting subunit becomes available. © 1996 Wiley-Liss, Inc.     

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.     

Growth inhibition of Escherichia coli during heterologous expression of Bacillus subtilis glutamyl-tRNA synthetase that catalyzes the formation of mischarged glutamyl-tRNA1 Gln

It is known that Bacillus subtilis glutamyl-tRNA synthetase (GluRS) mischarges E. coli tRNA1 Gln with glutamate in vitro. It has also been established that the expression of B. subtilis GluRS in Escherichia coli results in the death of the host cell. To ascertain whether E. coli growth inhibition caused by B. subtilis GluRS synthesis is a consequence of Glu-tRNA1 Ghn formation, we constructed an in vivo test system, in which B. subtilis GluRS gene expression is controlled by IPTG. Such a system permits the investigation of factors affecting E. coli growth. Expression of E. coli glutaminyl-tRNA synthetase (GlnRS) also ameliorated growth inhibition, presumably by competitively preventing tRNA1 Gln misacylation. However, when amounts of up to 10 mM L-glutamine, the cognate amino acid for acylation of tRNA1 Gln, were added to the growth medium, cell growth was unaffected. Overexpression of the B. subtilis gatCAB gene encoding Glu-tRNAGln amidotransferase (Glu-AdT) rescued cells from toxic effects caused by the formation of the mischarging GluRS. This result indicates that B. subtilis Glu-AdT recognizes the mischarged E. coli GlutRNA1 Gln, and converts it to the cognate Gln-tRNA1 Gln species. B. subtilis GluRS-dependent Glu-tRNA1 Gln formation may cause growth inhibition in the transformed E. coli strain, possibly due to abnormal protein synthesis.     

Hierarchical network between the components of the multi-tRNA synthetase complex: implications for complex formation

The macromolecular tRNA synthetase complex consists of nine different enzymes and three non-enzymatic factors. This complex was recently shown to be a novel signalosome, since many of its components are involved in signaling pathways in addition to their catalytic roles in protein synthesis. The structural organization and dynamic relationships of the components of the complex are not well understood. Here we performed a systematic depletion analysis to determine the effects of structural intimacy and the turnover of the components. The results showed that the stability of some components depended on their neighbors. Lysyl-tRNA synthetase was most independent of other components for its stability whereas it was most required for the stability of other components. Arginyl- and methionyl-tRNA synthetases had the opposite characteristics. Thus, the systematic depletion of the components revealed the functional reason for the complex formation and the assembly pattern of these multi-functional enzymes and their associated factors.     

Purification of the multienzyme complex for fatty acid oxidation from Pseudomonas fragi and reconstitution of the fatty acid oxidation system

The multienzyme complex for fatty acid oxidation was purified from Pseudomonas fragi, which was grown on oleic acid as the sole carbon source. This complex exhibited enoyl-CoA hydratase [EC 4.2.1.17], 3-hydroxyacyl-CoA dehydrogenase [EC 1.1.1.35], 3-oxoacyl-CoA thiolase [EC 2.3.1.16], cis-3,trans-2-enoyl-CoA isomerase [EC 5.3.3.3], and 3-hydroxyacyl-CoA epimerase [EC 5.1.2.3] activities. The molecular weight of the native complex was estimated to be 240,000. Two types of subunits, with molecular weights of 73,000 and 42,000, were identified. The complex was composed of two copies each of the 73,000- and 42,000-Da subunits. The beta-oxidation system was reconstituted in vitro using the multienzyme complex, acyl-CoA synthetase and acyl-CoA oxidase. This reconstituted system completely oxidized saturated fatty acids with acyl chains of from 4 to 18 carbon atoms as well as unsaturated fatty acids having cis double bonds extending from odd-numbered carbon atoms. However, unsaturated fatty acids having cis double bonds extending from even-numbered carbon atoms were not completely oxidized to acetyl-CoA: about 5 mol of acetyl-CoA was produced from 1 mol of linoleic or alpha-linolenic acid, and about 2 mol of acetyl-CoA from 1 mol of gamma-linolenic acid. These results suggested that the 3-hydroxyacyl-CoA epimerase in the complex was not operative. When the epimerase was by-passed by the addition of 2,4-dienoyl-CoA reductase to the reconstituted system, unsaturated fatty acids with cis double bonds extending from even-numbered carbon atoms were also completely degraded to acetyl-CoA.     

Induction of microcin B17 formation in Escherichia coli ZK650 by limitation of oxygen and glucose is independent of glucose consumption rate

We examined the consumption of glucose from the media in which Escherichia coli ZK650 was grown. This organism, which produces the polypeptide antibiotic microcin B17 best under conditions of limiting supplies of glucose and air, was grown with a low level of glucose (0.5 mg/ml) as well as a high level (5.0 mg/ml) under both high and low aeration. Glucose consumption rates were virtually identical under both high and low aeration. Thus, glucose consumption rate is not a regulating factor in microcin B17 formation. Journal of Industrial Microbiology & Biotechnology (2001) 26, 341–344. Received 25 September 2000/ Accepted in revised form 16 April 2001