Genetic and biochemical characterization of the Escherichia coli K-12 fhuB mutation

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

TonB-independent ferrioxamine B-mediated iron transport in Escherichia coli K12

The TonB protein of Escherichia coli K12 couples the energized state of the cytoplasmic membrane with energy-dependent receptors in the outer membrane. High affinity iron transport mediated by ferric dicitrate, ferrienterobactin, ferriaerobactin, ferrichrome, and coprogen all require a functional tonB protein. However, we have found no difference between the growth rates of tonB+ strains and tonB strains using ferrioxamine B as the sole iron source. This TonB-independence of FOB transport and earlier results with a photoactive FOB analog indicate a separate mechanism for iron acquisition from FOB in E. coli.

Identification of the ferrioxamine B receptor, FoxB, in Escherichia coli K12

The photoreactive p-azidobenzoyl analog of ferrioxamine B was used to show that ferrioxamine-B-mediated iron transport is separate and distinct from coprogen-mediated iron transport in Escherichia coli. Photolysis of this analog inhibited uptake of [59Fe]ferrioxamine B but not [59Fe]ferrichrome. Conversely, photolysis of the p-azidobenzoyl analog of coprogen B inhibited uptake of [59Fe]coprogen but not [59Fe]ferrioxamine B or [59Fe]ferrichrome. Photolabeling of outer membranes with p-azidobenzoyl-[59Fe]ferrioxamine B resulted in the labeling of two iron-regulated peptides with molecular masses of about 66 and 26 kDa. Expression of these peptides was increased when ferrioxamine B was the sole iron source. Both peptides were present in outer membrane preparations of the fhuF mutant H1717, but the 66 kDa peptide was not inducible. These results are evidence for an outer membrane receptor in E. coli unique for linear ferrioxamines.

Iron(III) hydroxamate transport of Escherichia coli: restoration of iron supply by coexpression of the N- and C-terminal halves of the cytoplasmic membrane protein FhuB cloned on separate plasmids

Transport of iron(III) hydroxamates across the inner membrane into the cytoplasm of Escherichia coli cells is mediated by the FhuC, FhuD and FhuB proteins. We studied the extremely hydrophobic FhuB protein (70 kDa) which is located in the cytoplasmic membrane. The N- and C-terminal halves of the protein [FhuB(N) and FhuB(C)] show homology to each other and to the equivalent polypeptides involved in uptake of ferric dicitrate and of vitamin B12. Various plasmids carrying only one-half of the fhuB gene were expressed in fhuB- mutants. Only combinations of FhuB(N) and FhuB(C) polypeptides restored sensitivity to albomycin and growth on iron hydroxamates as sole iron source; no activity was obtained with either half of FhuB alone. These results indicate that both halves of FhuB are essential for substrate translocation and that they combine to form an active permease when expressed separately. In addition, a FhuB derivative with a large internal duplication of 271 amino acids was found to be partially active in transport, indicating that the extra portion did not perurb proper insertion of the active FhuB segments into the cytoplasmic membrane.

Iron-hydroxamate transport into Escherichia coli K12: localization of FhuD in the periplasm and of FhuB in the cytoplasmic membrane

The fhuB, fhuC and fhuD genes encode proteins which catalyze transport of iron(III)-hydroxamate compounds from the periplasm into the cytoplasm of Escherichia coli. The fhuB, C, D genes were cloned downstream of a strong phage T7 promoter and transcribed by T7 RNA polymerase. The overexpressed FhuD protein appeared in two forms of 31 and 28 kDa and was released upon conversion of vegetative cells into spheroplasts, suggesting synthesis of FhuD as a precursor and export into the periplasm. The very hydrophobic FhuB protein was found in the cytoplasmic membrane. These properties, together with the previously found homologies in the FhuC protein to ATP-binding proteins, display the characteristics of a periplasmic binding protein dependent transport system across the cytoplasmic membrane. The molecular weight of FhuB and the sequence of fhuC, as previously published by us, was confirmed. FhuB exhibited double the size of most hydrophobic proteins of such systems and showed homology between the amino- and carboxy-terminal halves of the protein, indicating duplication of an original gene and subsequent fusion of the two DNA fragments.

Regulation of the iron uptake system in Vibrio anguillarum: evidence for a cooperative effect between two transcriptional activators

We have identified a 110-kDa polypeptide that has a trans-acting regulatory activity on the expression of the pJM1 plasmid iron-uptake genes in Vibrio anguillarum. This protein is encoded by the angR gene and maps in a 3.6-kilobase-pair pJM1 DNA region located downstream of the iron transport genes. Full expression of this gene occurs under iron-limiting conditions and requires a 2.9-kilobase-pair upstream region in cis that maps within the coding region of the OM2 outer membrane protein, essential for the transport of iron into the cell cytosol. Determination of the siderophore anguibactin levels as well as analysis of specific transcripts for anguibactin biosynthetic genes demonstrated that AngR and another transcriptional activator, Taf, regulate in a synergistic fashion the level of anguibactin production by activation of transcription of the anguibactin biosynthetic genes under iron-limiting conditions.

Nucleotide sequence analysis and expression of the minimum REPI replication region and incompatibility determinants of pColV-K30

We sequenced the minimum REPI replication region and the incompatibility determinants of pColV-K30. The minimum replication region contains an open reading frame which corresponds to a 35-kilodalton (kDa) protein. Sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis with maxicells transformed with a number of deletion derivatives demonstrated that this replication region encodes a 39-kDa protein and also established the direction of transcription of the RepI protein gene. The 39-kDa polypeptide was identified as the trans-acting factor essential for replication of REPI-containing plasmids. A translated region of the nucleotide sequence of the RepI protein gene showed homology with the helix-turn-helix binding domains of a number of DNA-binding proteins and also with other plasmid replication proteins. Further nucleotide analysis of the REPI region revealed the presence of direct and inverted repeat sequences in the incE, incF, and ori regions. The REPI ori also contained a perfect DnaA-binding site in addition to a high frequency of occurrence of the DNA adenine methylation (dam) site 5'GATC3'.

Aerobactin utilization by Neisseria gonorrhoeae and cloning of a genomic DNA fragment that complements Escherichia coli fhuB mutations

Aerobactin, a dihydroxamate siderophore produced by many strains of enteric bacteria, stimulated the growth of Neisseria gonorrhoeae FA19 and F62 in iron-limiting medium. However, gonococci did not produce detectable amounts of aerobactin in the Escherichia coli LG1522 aerobactin bioassay. We probed gonococcal genomic DNA with the cloned E. coli aerobactin biosynthesis (iucABCD), aerobactin receptor (iutA), and hydroxamate utilization (fhuCDB) genes. Hybridization was detected with fhuB sequences but not with the other genes under conditions which will detect 70% or greater homology. Similar results were obtained with 21 additional strains of gonococci by colony filter hybridization. A library of DNA from N. gonorrhoeae FA19 was constructed in the phasmid vector lambda SE4, and a clone was isolated that complemented the fhuB mutation in derivatives of E. coli BU736 and BN3307. These results suggest that fhuB is a conserved gene and may play a fundamental role in iron acquisition by N. gonorrhoeae.

Iron hydroxamate transport of Escherichia coli: nucleotide sequence of the fhuB gene and identification of the protein

The genes fhuA, fhuC and fhuD encode products involved in the transport of ferrichrome into cells of Escherichia coli. The nucleotide sequence of an additional locus contiguous to fhuD and formerly designated fhuB was determined. It contains an open reading frame for a polypeptide that consists of 659 amino acids. Expression of plasmids containing the fhuB region in an in vitro transcription/translation system and in E. coli minicells revealed a polypeptide with an electrophoretic mobility on SDS-polyacrylamide gels extremely dependent on the experimental conditions employed. This property could be explained by the very hydrophobic nature of the protein and it was concluded that the fhuB locus consists of a structural gene that encodes a membrane protein with a molecular weight of 82,181. The fhuB gene is required for all iron transport systems which operate via hydroxamate compounds. The order of the genes in the fhu operon is fhuA fhuC fhuD fhuB, and transcription proceeds from fhuA to fhuB.

Escherichia coli K-12 envelope proteins specifically required for ferrienterobactin uptake

Escherichia coli genes specifically required for transport of iron by the siderophore enterobactin are designated fep. The studies reported here were initiated to identify and localize the fepB product. The plasmid pCP111, which consisted of an 11-kilobase E. coli DNA fragment containing fepB ligated to pACYC184, was constructed. The fepB gene was subcloned; in the process, complementation tests and Tn5 mutagenesis results provided evidence for the existence of a new fep gene, fepC. The order of the transport genes in the ent gene cluster is as follows: fepA fes entF fepC fepB entE. Minicell, maxicell, and in vitro DNA-directed protein synthesizing systems were used to identify the fepB and fepC products. The fepC polypeptide was 30,500 daltons in standard sodium dodecyl sulfate-polyacrylamide gels. The fepB gene was responsible for the appearance of three or four bands (their apparent molecular weights ranged from 31,500 to 36,500) in sodium dodecyl sulfate-polyacrylamide gels, depending on the gel system employed. The largest of these was tentatively designated proFepB, since it apparently had a leader sequence. Localization experiments showed that FepC was a membrane constituent and that mature FepB was present in the periplasm. An additional polypeptide (X) was also encoded by the bacterial DNA of pCP111, but its relationship to iron transport is unknown. The results indicated that ferrienterobactin uptake is mediated by a periplasmic transport system and that genes coding for outer membrane (fepA), periplasmic (fepB), and cytoplasmic membrane (fepC) components have now been identified.

Evidence for a common siderophore transport system but different siderophore receptors in Neurospora crassa

Uptake and competition experiments were performed with Neurospora crassa and Penicillium parvum by using 14C-labeled coprogen and 55Fe-labeled ferrichrome-type siderophores. Several siderophores of the ferrichrome family, such as ferrichrome, ferricrocin, ferrichrysin, and tetraglycyl-ferrichrome as well as the semisynthetic ferricrocin derivatives O-(phenyl-carbamoyl)-ferricrocin and O-(sulfanilyl-carbamoyl)-ferricrocin were taken up by N. crassa. The ferrichrome-type siderophores used vary in the structure of the peptide backbone but possess a common lambda-cis configuration about the iron center and three identical ornithyl-delta-N-acetyl groups as surrounding residues. This suggests that these ferrichrome-type siderophores are recognized by a common ferrichrome receptor. We also concluded that the ferrichrome receptor is lambda-cis specific from the inability to take up the synthetic enantiomers, enantio-ferrichrome and enantio-ferricrocin, possessing a delta-cis configuration about the iron center. On the other hand, we found that coprogen, possessing a delta-absolute configuration and two trans-anhydromevalonic acid residues around the metal center, was also taken up by N. crassa and was competitively inhibited by the ferrichrome-type siderophores. We therefore propose the existence of a common siderophore transport system but the presence of different siderophore receptors in N. crassa. In addition, ferrirubin, which is very slowly transported by N. crassa, inhibited both coprogen and ferrichrome-type siderophore transport. Contrary to the findings with N. crassa, transport experiments with P. parvum revealed the presence of a ferrichrome receptor but the absence of a coprogen receptor; coprogen was neither transported nor did it inhibit the ferrichrome transport.

Mechanisms of iron regulation of luminescence in Vibrio fischeri

Synthesis of luciferase (an autoinducible enzyme) is repressed by iron in the symbiotic bioluminescent bacterium Vibrio fischeri. Possible mechanisms of iron regulation of luciferase synthesis were tested with V. fischeri and with Escherichia coli clones containing plasmids carrying V. fischeri luminescence genes. Experiments were conducted in complete medium with and without the synthetic iron chelator ethylenediamine-di(o-hydroxyphenyl acetic acid). Comparison of the effect of ethylenediamine-di(o-hydroxyphenyl acetic acid) and another growth inhibitor, (2-n-heptyl-4-hydroxyquinoline-N-oxide), showed that iron repression is not due to inhibition of growth. A quantitative bioassay for autoinducer was developed with E. coli HB101 containing pJE411, a plasmid carrying V. fischeri luminescence genes with a transcriptional fusion between luxI and E. coli lacZ. Bioassay experiments showed no effect of iron on either autoinducer activity or production (before induction) or transcription of the lux operon. Ethylenediamine-di(o-hydroxyphenyl acetic acid) did not affect luciferase induction in E. coli strains with wild-type iron assimilation (ED8654) or impaired iron assimilation (RW193) bearing pJE202 (a plasmid with functional V. fischeri lux genes), suggesting that the genes responsible for the iron effect are missing or substituted in these clones. Two models are consistent with the data: (i) iron represses autoinducer transport, and (ii) iron acts through an autoinduction-independent regulatory system (e.g., an iron repressor).