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.     

Iron uptake in colicin B-resistant mutants of Escherichia coli K-12.

Four classes of colicin B-resistant mutants of Escherichia coli K-12 were examined for defects in iron uptake. All four mutant classes (cbt, exbC, exbB, and tonB) were defective in the uptake of ferri-ennterochelin. The tonB mutant was also defective in citrate-, ferrichrome-, and rhodoturulic acid-mediated iron uptake. The defects in iron transport were reflected in increased sensitivity to iron chelators and to chromium and aluminium salts, and in hypersecretion of enterochelin. One of the mutants (cbt) was apparently defective in outer membrane ferri-enterochelin receptor activity. aroE derivatives (unable to synthesize enterochelin) of the four mutant classes and the parent strain produced increased amounts of two outer membranes polypeptides when grown under iron stress. These polypeptides are implicated in ferri-enterochelin receptor activity.     

Relationship between the tonB locus and iron transport in Escherichia coli.

When a strain (arcB-) of Escherichia coli, unable to synthesize the iron transport compound enterochelin, was transduced to tonB-, it became resistant to phage phi80 and simultaneously lost the growth response to enterochelin and the ability to transport its iron complex. However, enterochelin precursors (shikimate and 2,3-dihydroxybenzoate) still supported growth, via the synthesis of enterochelin. Dihydroxybenzoate was a better growth factor at a low concentration than it was at higher levels. The evidence suggests that tonB- strains lack an outer membrane component necessary both for the uptake of ferric-enterochelin and for the adsorption of phage phi80. Thus, although ferric-enterochelin cannot penetrate the cell surface from outside, the complex that is formed within the envelope is transported normally into the cell. The aroB-, tonB- mutant also lacked growth reponses to citrate and various hydroxamate siderochromes, which supported growth in the tonB+ parent strain via inducible transport systems for their ferric complexes. The aroB-, tonB- mutant was unable to transport iron in the presence of citrate, but the low-affinity uptake of uncomplexed iron and the transport of amino acids and phosphate were unimpaired. The tonB locus, thus, affects all the known active transport systems for iron, possibly indicating that they share some common outer membrane component.     

Constitutive expression of the iron-enterochelin and ferrichrome uptake systems in a mutant strain of Salmonella typhimurium.

Two high-affinity iron uptake systems are known in Salmonella typhimurium, one utilizing iron-enterochelin and the other utilizing ferrichrome. It has been shown previously that expression of several elements of the iron-enterochelin uptake system are regulated by the iron content of the medium, with growth in high-iron medium resulting in repression of enzymes of enterochelin synthesis and degradation and of the ability of whole cells to take up iron-enterochelin. In this study we describe a mutant strain in which growth in high-iron medium was associated with constitutive expression of: (i) iron-enterochelin uptake by whole cells; (ii) ferrichrome uptake by whole cells; (iii) synthesis of enterochelin; (iv) intracellular degradation of iron-enterochelin; and (v) synthesis of three major outer membrane proteins (OM1, OM2, and OM3). In contrast, in the wild-type strain these properties were expressed only after growth in iron-deficient medium. It is proposed that the mutation affects a gene responsible for regulating expression of the structural genes for the components of the high-affinity iron uptake systems. The term fur, for iron (Fe) uptake regulation, is suggested for this new class of mutant.     

Involvement of inner and outer membrane components in the transport of iron and in colicin B action in Escherichia coli.

Spheroplasts of Escherichia coli mutants were used to investigate the roles of the inner and outer membranes in the transport of iron. tonA mutants, known to be defective in an outer membrane component of the ferrichrome transport system, regained the ability to transport ferrichrome when converted to spheroplasts. On the other hand, the tonB mutant was unable to transport ferric enterochelin in either whole cells or spheroplasts. This implies that an element of the inner membrane is affected. fep mutants were also unable to transport ferric enterochelin, and fell into two classes, fepA and fepB. Spheroplasts of the former class transported ferric enterochelin, and those of the latter did not. This implies that the fepA mutants are defective in ferric enterochelin transport across the outer membrane, and that fepB mutants probably lack the facility to transport ferric enterochelin across the inner membrane. Colicin B action on fepA mutants was found to differ from that on fepB mutants.     

Iron transport in Escherichia coli K-12

The study of iron uptake promoted by 2,3-dihydroxybenzoate (DHB) into Escherichia coli K-12 aroB mutants allowed some dissection of outer and cytoplasmic membrane functions. These strains are unable to produce the iron-transporting chelate enterochelin, unless fed with a precursor such as DHB. When added to the medium, enterochelin and its natural breakdown products, the linear dimer and trimer of 2,3-dihydroxybenzoylserine (DBS), efficiently transported iron via the feuB, tonB and fep gene products. Thus mutants in these genes were defective in transport of the above chelates. However, feuB and tonB mutants were able to take up iron when DHB was added to the medium. Thus DHB-promoted iron uptake bypassed two functions required for the transport of ferric-enterochelin from the medium. One of these functions, feuB, has been shown to be an outer membrane protein. In contrast to three other iron transport systems including ferric-enterochelin uptake, DHB-promoted iron uptake was little affected by the uncoupler 2,4-dinitrophenol. Dissipation of the energized state of the cytoplasmic membrane apparently only affects those iron transport systems which require an outer membrane protein. Since DHB-promoted iron uptake bypasses the feuB outer membrane protein and the tonB function, it is concluded that, in ferricenterochelin transport, the tonB gene may function in coupling the energized state of the cytoplasmic membrane to the protein-dependent outer membrane permeability. DHB-promoted iron uptake required the synthesis and enzymatic breakdown of enterochelin as judged by the effects of the entF and fesB mutations. A fep mutant was not only deficient in the transport of the ferric chelates of enterochelin and its breakdown products, but was also deficient in DHB-promoted iron uptake. A scheme is presented in which iron diffuses as DHB-complex through the outer membrane, and is subsequently captured by enterochelin or DBS dimer or trimer and translocated across the cytoplasmic membrane.List of Abbreviations DHB 2,3-dihydroxybenzoate - DBS 2,3-dihydroxybenzoylserine - NTA nitrilotriacetate - DNP 2,4-dinitrophenol     

Iron transport systems of Serratia marcescens.

Serratia marcescens W225 expresses an unconventional iron(III) transport system. Uptake of Fe3+ occurs in the absence of an iron(III)-solubilizing siderophore, of an outer membrane receptor protein, and of the TonB and ExbBD proteins involved in outer membrane transport. The three SfuABC proteins found to catalyze iron(III) transport exhibit the typical features of periplasmic binding-protein-dependent systems for transport across the cytoplasmic membrane. In support of these conclusions, the periplasmic SfuA protein bound iron chloride and iron citrate but not ferrichrome, as shown by protection experiments against degradation by added V8 protease. The cloned sfuABC genes conferred upon an Escherichia coli aroB mutant unable to synthesize its own enterochelin siderophore the ability to grow under iron-limiting conditions (in the presence of 0.2 mM 2.2'-dipyridyl). Under extreme iron deficiency (0.4 mM 2.2'-dipyridyl), however, the entry rate of iron across the outer membrane was no longer sufficient for growth. Citrate had to be added in order for iron(III) to be translocated as an iron citrate complex in a FecA- and TonB-dependent manner through the outer membrane and via SfuABC across the cytoplasmic membrane. FecA- and TonB-dependent iron transport across the outer membrane could be clearly correlated with a very low concentration of iron in the medium. Expression of the sfuABC genes in E. coli was controlled by the Fur iron repressor gene. S. marcescens W225 was able to synthesize enterochelin and take up iron(III) enterochelin. It contained an iron(III) aerobactin transport system but lacked aerobactin synthesis. This strain was able to utilize the hydroxamate siderophores ferrichrome, coprogen, ferrioxamine B, rhodotorulic acid, and schizokinen as sole iron sources and grew on iron citrate as well. In contrast to E. coli K-12, S. marcescens could utilize heme. DNA fragments of the E. coli fhuA, iut, exbB, and fur genes hybridized with chromosomal S. marcescens DNA fragments, whereas no hybridization was obtained between S. marcescens chromosomal DNA and E. coli fecA, fhuE, and tonB gene fragments. The presence of multiple iron transport systems was also indicated by the increased synthesis of at least five outer membrane proteins (in the molecular weight range of 72,000 to 87,000) after growth in low-iron media. Serratia liquefaciens and Serratia ficaria produced aerobactin, showing that this siderophore also occurs in the genus Serratia.     

Genetic and physiological regulation of intrinsic proteins of the outer membrane of Salmonella typhimurium.

Four major outer membrane polypeptides, accounting for approximately 20% of the total protein of the outer membrane of Salmonella typhimurium, were induced by growth in minimal medium. The polypeptides were tightly bound membrane components. Physiological and genetic evidence indicates that the four polypeptides fall in two separate regulation groups. Synthesis of one of these groups was coordinately regulated by the concentration of iron in the medium, and a mutant strain has been identified in which there is constitutive synthesis of this group of major outer membrane proteins.     

Identification of an outer membrane protein responsible for the binding of the Fe-enterochelin complex to Escherichia coli cells.

Escherichia coli incorporates iron as a complex with enterochelin. By using mutants which lack one or the other, or both, of the outer membrane proteins, O-2b and O-3, we have shown that protein O-2b (feuB protein) is responsible for the primary binding of the iron-enterochelin complex to the outer membrane in the process of iron transport.     

Effect of iron on the relative abundance of two large polypeptides of the Escherichiacoli outer membrane

The relative abundance of two polypeptides of the $\text{Escherichia}\text{coli}$ outer membrane is affected by the growth medium. The polypeptides have molecular weights of 85,000 and 95,000 and, in cells grown in medium containing low concentrations of iron, are dominant outer membrane proteins.     

Involvement of outer membrane proteins in enterochelin-mediated iron uptake in Escherichia coli.

Escherichia coli K-12 grown in iron-deficient media contained a large amount of outer membrane proteins O-2a, O-2b, and O-3, while cells grown in iron-supplemented media contained far smaller amounts of these proteins. The iron uptake by the iron-deficient cells was significantly stimulated in the presence of enterochelin, while that by the iron-rich cells was not. The outer membrane isolated from cells grown in the iron-deficient media showed enterochelin-stimulated binding of iron, while the outer membrane from iron-rich cells and cytoplasmic membranes from both types of cells did not show such binding activity. The amount of iron bound by the outer membrane was almost equivalent to the amount of O-2a, O2b, or O-3, irrespective of the amount of these proteins in the outer membrane, which is controlled by the amount of iron in the medium. Small particles rich in these proteins were prepared from cells by EDTA extraction. The particles were active in enterochelin-mediated iron binding and the amount of iron bound was equivalent to the amount of each of these proteins in the particles. Although the outer membrane of E. coli B was as active in iron binding as that of E. coli K-12, it did not possess an appreciable amount of O-2a. Gel electrophoretic analysis revealed that 9-2b and 9-3 were identical with the proteins missing mutants feuB and feuA, respectively.     

Siderophore production by Enterobacter cloacae and a common receptor protein for the uptake of aerobactin and cloacin DF13.

Iron-starved cultures of Enterobacter cloacae produced two siderophores, identified as enterochelin and aerobactin. The aerobactin was excreted in larger amounts than was enterochelin, and it was synthesized preferentially in the late logarithmic and stationary growth phases under iron-deficient conditions. Enterochelin was synthesized by cultures in the logarithmic phase of growth and preferentially in medium with 1 microM ferric chloride. Both siderophores appeared to be excreted immediately after their synthesis, since no intracellular aerobactin or enterochelin could be detected. The killing activity of the bacteriocin cloacin DF13 was inhibited by aerobactin. It was shown that aerobactin and cloacin DF13 bound to the same receptor sites located in the outer membrane. The synthesis of these receptor sites was induced by iron limitation. We conclude that the receptor for the uptake of aerobactin also functions as receptor for cloacin DF13.     

Increased production of the outer membrane receptors for colicins B, D and M by Escherichia coli under iron starvation.

Growth of $\text{E. coli}$ K-12 under severe iron stress results in increased production of the outer membrane receptors for colicins B, D, Ib and M. The increase in colicin receptor activity coincides with the appearance of large amounts of two high molecular weight proteins in the outer membrane of the cells. These proteins are identified as the outer membrane receptors for colicins B and D and for colicin M. Mutants lacking a functional outer membrane receptor for colicins B and D are defective in the uptake of iron complexed with the siderochrome enterochelin, and are thus comparable with $\text{tonA}$ mutants which lack a functional receptor for colicin M and are defective in the uptake of iron complexed with ferrichrome (6). The colicin B and D receptor may therefore function in the uptake of ferri-enterochelin.     

Dihydroxybenzolyserine—a siderophore for E. coli

Dihydroxybenzoylserine, the breakdown product of enterochelin, was able to stimulate growth of Escherichia coli under iron limiting conditions by acting as a siderophore. The dihydroxybenzoylserine-iron complex was taken up via the outer membrane receptor proteins Fiu, FepA and to a minor extent via Cir. Transport of Fe3(+)-dihydroxybenzoylserine across the cytoplasmic membrane was only dependent on genes from the fep region. In addition, it was shown that dihydroxybenzoate was taken up via Fiu and Cir and less efficiently by FepA.     

Characterization of a plasmid carrying the Escherichia coli K-12 entD, fepA, fes, and entF genes

Abstract The plasmid pMS101 carries Escherichia coli K-12 genes ( entD, fes, entF ) essential for enterochelin-mediated iron transport [Laird, A.J. and Young, I.G., Gene 11 (1980) 359–366]. We have further characterized pMS101 and shown that it also contains the gene ( fepA ) for the 81 000 Da outer membrane ferrienterochelin receptor. Subcloning experiments in conjunction with complementation and maxicell studies demonstrated the gene order to be entD fepA fes entF . The entF - and fes -encoded polypeptides were found to be 115 000 and 42 000-Da soluble proteins, respectively. Plasmid-borne enterochelin cluster genes were overexpressed in iron-deficient conditions and their products were undetectable under iron-replete conditions.     

Effect of iron and other nutrient limitations on the pattern of outer membrane proteins in the cyanobacterium Synechococcus PCC7942

When cells of Synechococcus PCC7942 were subjected to either iron or magnesium limitation, there was an appearance of specific proteins in the outer membrane (isolated as the cell wall fraction). Under iron limitation outer membrane polypeptides of M _r 92000, 48000–50000 and 35000 appeared. Specific iron-limited outer membrane proteins (IRMPs) of M _r 52000 and 36000 were also induced in iron-limited cultures of Synechocystis PCC6308. Under magnesium limitation polypeptides of M _r 80000, 67000, 62000, 50000, 28000 and 25000 appeared in the outer membrane. phosphate limitation caused minor changes in the outer membrane protein pattern, with polypeptides of M _r 32000 and one of over 100000 being induced, whereas calcium limitation had no apparent affect.Abbreviations EDDA ethylenediaminedihydroxyphenyl acetic acid - IRMP iron-regulated outer membrane protein - HEPES N-2-hydroxyethyl-piperazine-N-2-ethane sulphonic acid - SDS-PAGE sodium dodecyl sulphate polyacrylamide gel electrophoresis - PMSF phenylmethylsulphonyl fluoride     

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.     

In vitro growth of urinaryEscherichia coli related to siderophore production

Thirty seven strains ofEscherichia coli isolated from the urine of patients with acute symptomatic urinary tract infection were examined for siderophore production: hydroxamate (aerobactin) and phenolate (enterochelin). All the strains were found to produce varying amounts of enterochelin. With the chemical assay, 24.3% strains were aerobactin producers, while 43.2% were positive in the bio-assay. All the aerobactin producers carried the aerobactin receptor on their surface. Attempts to correlate siderophore production with growth in minimal and iron-depleted medium showed that there was a positive quantitative correlation between enterochelin production and growth of organisms under iron depletion. Aerobactin production failed to give an additional advantage of growth to strains producing enterochelin.     

Iron transport of Escherichia coli K-12: involvement of the colicin B receptor and of a citrate-inducible protein.

It was shown that feuB mutants (defective in ferric enterochelin uptake) were unable to adsorb colicin B. In addition, they were missing one of the three outer-membrane proteins which are over produced in strains grown in iron-deficient, extracted medium. Thus this protein (the feuB protein) is probably the receptor for colicin B and functions in enterochelin-mediated iron transport. The feuB gene was located by P1 transduction at approximately 72.5 min on the Escherichia coli K-12 genetic map and thus maps separately from the other genes concerned with the enterochelin system. The outer membranes of various strains grown in the presence of 1 mM citrate contained a high level of a protein which was present in very small amounts when citrate was absent from the growth medium. This protein was most easily observed in feuB mutants grown in the presence of citrate, since on polyacrylamide gels it ran in a similar position to the feuB protein, which is missing in these mutants. The relationship of this citrate-inducible protein to the inducible citrate-dependent iron uptake system is discussed.