Production of enterochelin by Escherichia coli 0111.

The major neutral iron-transporting compound produced by Escherichia coli 0111/K58/H2 has been isolated from iron-deficient cultures of the organism and compared with the corresponding compound, enterochelin, produced by E. coli K12. The product contained serine and 2,3-dihydroxybenzoic acid and formed a complex with Fe3+. Since the PMR spectra of the products from the two strains were identical, it was concluded that E. coli 0111 also secreted enterochelin under iron-deficient conditions. Although it was not possible to establish the optical configuration of the serine residues in the molecule, the CD spectra of the metal free and Fe3+, complexes were found to be of the same sign and magnitude. The spectra show that metal binding results in considerable conformational changes in the enterochelin molecule. The biological properties of the two compounds appear to be identical as judged by their ability to abolish the bacteriostatic effect of serum on E. coli 0111.     

Regulation of enterochelin synthetase in Escherichia coli K-12

Enterochelin synthetase activity is controlled by both repression and feed-back inhibition mechanisms. Inclusion of iron in growth media results in synthesis of all four (D, E, F and G) components of enterochelin synthetase being repressed. The specific inhibition of L-serine activation (partial reaction catalyzed by the F component) by the end products, ferric-enterochelin and 2,3-dihydroxybenzoylserine, is shown to inhibit overall enterochelin synthetase activity.     

Iron supply to Escherichia coli by synthetic analogs of enterochelin.

Synthetic analogs of enterochelin (enterobactin) were tested for their ability to support the growth of Escherichia coli K-12 under iron-limiting conditions. The cyclic compound MECAM [1,3,5-N.N'; N"-tris-(2,3-dihydroxybenzoyl)-triamino-methylbenzene] and its N-methyl derivative Me3MECAM promoted growth, whereas the 2,3-dihydroxy-5-sulfonyl derivatives MECAMS and Me3MECAMS were inactive. The same results were obtained with TRIMCAM [1,3,5-tris(2,3-dihydroxybenzoylcarbamido)-benzene] and TRIMCAMS (the 2,3-dihydroxy-5-sulfonyl derivative of TRIMCAM). However, the sulfonic acid-containing linear compound LICAMS [1,5,10-N,N', N"-tris(5-sulfo-2,3-dihydroxybenzoyl)-triaza-decane] supported growth. In contrast, LIMCAMC, in which the sulfonyl groups at the five position of LICAMS are replaced by carboxyl groups at the four position, was inactive. The uptake of the active analogs required the functions specified by the fepB, fesB, and tonB genes. Surprisingly, growth promotion of mutants lacking the enterochelin receptor protein in the outer membrane was observed. Only MECAM protected cells against colicin B (which kills cells after entering at the enterochelin uptake sites) and transported Fe3+ at about half the enterochelin rate.     

Antibacterial effect of the scandium and indium complexes of enterochelin on Escherichia coli

Enterochelin, the iron chelator produced by a number of pathogenic enterobacteria, appears to be an essential metabolite for multiplication within the host, where it transports iron from the host iron-binding proteins to the bacteria. Previous work showed that complexes of enterochelin containing either scandium (Sc3+) or indium (In3+) exerted a bacteriostatic effect on Klebsiella pneumoniae in serum, whilst the Sc3+ complex exerted a significant therapeutic effect on mice infected with K. pneumoniae. These observations have now been extended to a number of pathogenic serotypes of Escherichia coli including those carrying either the K1 antigen or the ColV plasmid. The Sc3+ and In3+ complexes each exert a bacteriostatic effect on these organisms growing in either whole serum or media containing an iron-binding protein. Evidence is presented that the Sc3+ complex may act as a competitive inhibitor of the Fe3+ complex. In contrast to their effects on K. pneumoniae, sideramines other than enterochelin fail to reverse the bacteriostatic effect of the Sc3+ complex of enterochelin in E. coli, suggesting that the complex produces a more profound derangement of metabolism in this organism. The Sc3+ complex exerts a significant therapeutic effect on E. coli infections in mice although the In3+ complex is less active.     

Studies on the enzymatic synthesis of enterochelin in Escherichia coli K-12. Four polypeptides involved in the conversion of 2,3-dihydroxybenzoate to enterochelin.

Four gene products involved in the enzymatic synthesis of enterochelin from 2,3-dihydroxybenzoate, L-serine and ATP (Luke, R.K.L. and Gibson, F. (1971) J. Bacteriol. 107,557-562; Woodrow, G.C., Young, I.G. and Gibson, F. (1975) J. Bacteriol. 124, 1-6) have been partially purified using a previously reported fractionation procedure (Bryce, G.F. and Brot, N. (1972) Biochemistry 11, 1708-1715). The products of genes E, F and G have been separated from each other and correspond to the E1, E2 and E3 activities described by Bryce and Brot. These three gene products were not completely separated from the product of gene D. We refer to these gene products as components E, F, G and D of the enzymic apparatus for biosynthesis of enterochelin. Certain properties and functions of the four semi-purified components have been investigated. The E component is involved in the activation of 2,3-dihydroxybenzoate and the F component in the activation of L-serine. The D component physically associates with the F and G components during gel filtration and chromatography on DEAE Sephadex. It is proposed that the synthesis of enterochelin from L-serine and 2,3-dihydroxybenzoic acid is catalysed in vivo by a multienzyme complex, enterochelin synthetase.     

Enzymatic hydrolysis of enterochelin and its iron complex in Escherichia Coli K-12. Properties of enterochelin esterase.

Properties of the enzyme which hydrolyses enterochelin (a cyclic trimer of 2,3-dihydroxy-N-benzoyl-L-serine) to 2,3-dihydroxybenzoylserine have been investigated with a view to resolving discrepancies between earlier reports. Enterochelin esterase, previously reported to consists of two components (O'Brien, I.G., Cox, G.B. and Gibson, F. (1971) Biochim. Biophys. Acta 237, 537-549), has been shown to be fully active in the absence of the so-called A component. The hydrolase described previously (Bryce, G.F. and Brot, N. (1972) Biochemistry 11, 1708-1715) as being able to break down enterochelin but not its iron complex, ferric-enterochelin, appears to be identical with the B component of enterochelin esterase. The single component enterochelin esterase corresponding to what was previously described as component B, hydrolyses both enterochelin and ferric-enterochelin. Under the assay conditions used, enterochelin is hydrolysed 2.5 times faster than the complex. Enzymatic activity is inhibited by N-ethylmaleimide and is lost rapidly at 37 degrees C. Activity is stabilized in the presence of ferric-enterochelin, enterochelin, dithiothreitol or certain protein fractions.     

Studies on the enzymatic synthesis of enterochelin in Escherichia coli K-12, Salmonella typhimurium and Klebsiella pneumoniae. Physical association of enterochelin synthetase components in vitro

Further evidence is presented in support of the proposal made previously (Greenwood, K.T. and Luke, R.K.J. (1976) Biochim. Biophys. Acta 454, 285-297) that components of the Escherichia coli enterochelin synthetase system physicaloly associate to form enzyme complexes. Evidence for the existence of three enzyme complexes, designated in order of increasing stability G-D < F-D < F-D-G, has been obtained following gel filtration and chromatography on DEAE-Sephadex. Persistence of the F-D and G-D complexes during chromatography appears to depend on the flow rate of the column. On the basis of complementation with appropriate ent mutants of E. coli, activities corresponding to those of the D, E, F and G components of enterochelin synthetase in E. coli have been detected in cell-extracts of both Salmonella typhimurium and Klebsiella pneumoniae (formerly Aerobacter aerogenes) strains. These are designated D', E', F' and G' activities. Components E' and G' are eluted from Sephadex G-100 in similar fashion to their E. coli counterparts. Peaks of F' and D' activities however, are eluted together at a position corresponding to that of the E. coli F component. We suggest that in S. typhimurium and K. pneumoniae, either a single polypeptide combines the functions of the E. coli F and D components, or that separate F' and D' components form a stable complex and that activity of uncomplexed D' and component was not detected under the conditions used during chromatography and assay.     

Effect of osmotic shock and shearing forces on ferric enterochelin transport in Escherichia coli K12

The fes mutation in Escherichia coli K12, which inactivates enterochelin esterase, allows the cell to accumulate ferric enterochelin. The ferric complex of enterochelin was released in significant quantities from a fes mutant after osmotic shock. Analysis of the effects of the individual stages of the shock procedure in wild-type cells showed that prior exposure of cells to sucrose and EDTA was not required, careful dilution of cells into a hypo-osmolar medium being sufficient to induce efflux of Fe3+. Prior treatment with EDTA or exposure to shearing forces served either to enhance efflux or to induce efflux in isotonic media. Neither vitamin B12 nor 5'-nucleotidase was released from the periplasm by these procedures. The release observed under mild conditions was stimulated specifically by Co2+, did not occur at 0 degree C, and was inhibited by 2,4-dinitrophenol at 37 degrees C. From these observations, it was concluded that the efflux of Fe3+ represents a physiological response of the cell to exposure to a hypo-osmolar medium. Such changes may enhance survival following physicochemical stressing of the bacterial outer membrane.     

Preparation of tritiated lipopolysaccharides from Escherichia coli K12

Tritiated lipopolysaccharide (LPS) from E. coli K12 was prepared by coupling [3H]ethanolamine to the LPS core residue ketodeoxyoctonate (KDO) via activation of its carboxylic function with N-hydroxysuccinimide or N-hydroxy-sulfosuccinimide. Specific activities of 1.5 microCi/mg and 9 microCi/mg were obtained, respectively. Experiments comparing the activity of native and derivatized LPS suggested that the preparation of the radiolabelled LPS did not alter the structural properties of E. coli K12 LPS. This probe will be useful for studying the interactions between LPS and proteins.     

Characterization of group B colicin-resistant mutants of Escherichia coli K-12: colicin resistance and the role of enterochelin.

Nine classes of group B colicin-resistant mutants were examined to study the role of enterochelin in colicin resistance. Four of the mutants studied (cbt, exbC, exbB, and tonB) hypersecreted enterochelin. Enterochelin hypersecretion was apparently responsible for resistance of the exbC mutant to colicins G and H and for resistance of the exbB mutant to colicins G, H, Ia, Ib, S1, and V. All four mutants scored as colicin B tolerant, even in the absence of enterochelin synthesis. The mutants produced substantially increased amounts of two high-molecular-weight outer membrane polypeptides when grown under limiting iron conditions. The presence of these polypeptides was correlated with increased colicin B-neutralizing activity in the outer membrane preparations.     

Preparation and stability of mureinoplasts of Escherichia coli.

A peptidoglycan bounded form termed a mureinoplast was prepared from cells of Escherichia coli and the stability of this was examined in various suspending media. True protoplasts were subsequently formed from mureinoplasts.     

Iron uptake in pseudorevertants of Escherichia coli K-12 mutants with multiple defects in the enterochelin system

Iron uptake in pseudorevertants of Escherichia coli K-12 strains which lack the ability to synthesize enterochelin, 2,3-dihydroxybenzoate, and the ferrienterochelin receptor protein was characterized. In four independent pseudorevertants, the suppressor mutations which permitted growth in iron-poor environments appeared to be located in ompB, the regulatory locus for the porin proteins. Unlike wild-type cells, the pseudorevertants were unable to utilize ferrienterochelin and could acquire iron from citrate without induction by prior growth in citrate. The energy requirements of the pseudorevertant system appeared to be identical to those of the enterochelin system. Evidence that loss of the porin proteins results in the secretion by the pseudorevertants of a molecule with siderophore activity is presented; this siderophore is able to remove iron from the non-biological iron chelators nitrilotriacetic acid and , -dipyridyl but not from the siderophores ferrichrome and enterochelin.     

Crystallization of beta-galactosidase from Escherichia coli.

Two crystal forms of beta-galactosidase have been obtained from Escherichia coli. One crystal form is hexagonal space group P6222 or enantiomorph, with cell dimensions a = b = 154 A, c = 750 A. The second form is monoclinic, space group P21, with cell dimensions a = 107.9 A, b = 207.5 A, c = 509.9 A, beta = 94.7 degrees. The monoclinic form seems better suited to detailed structural analysis. The crystals are radiation-sensitive, but by using synchrotron radiation in conjunction with a long (400 mm) crystal-to-film distance it was possible to resolve the individual reflections. On the basis of crystal density measurements, there are four tetramers each of molecular weight 465,000 per asymmetric unit. The Patterson function strongly suggests that two of the tetramers are related to the other two by translation. The data are consistent with the tetramers having 222 point symmetry, but this is not proven.     

Location of three genes concerned with the conversion of 2,3-dihydroxybenzoate into enterochelin in Escherichia coli K-12

Mutants of Escherichia coli K-12 unable to synthesize the iron-sequestering compound, enterochelin, from 2,3-dihydroxybenzoate have been isolated and divided into three classes on the basis of tests for enzymatic complementation. The genes affected (designated entD, entE, and entF) have been mapped by cotransduction and are located at about minute 14 on the E. coli genome. They were found to be closely linked to other genes (entA, entB, and entC) concerned with enterochelin biosynthesis and a gene (fep) concerned with the uptake of the iron-enterochelin complex. No detectable diffusible intermediate in the formation of enterochelin from 2,3-dihydroxybenzoate was formed by cell extracts of mutants carrying mutations in the entD, entE, or entF genes.     

大肠杆菌最佳感受态细胞制备的探讨

本文对４种大肠杆菌菌株在不同生长时期的转化效率分别进行了测定．结果表明,在细菌的生长繁殖过程中,其转化效率是有很大变化的．对于不同的菌株,它们获得高转化率时的活菌数不同．同时,得到了这４种大肠杆菌菌株制备最佳感受态细胞的条件．