Bacterioferritin: properties, structural and functional organization of the dps gene regulatary region

The paper considers the properties of bacterioferritin Dps, which is involved in the sequestering of iron ions, forms the ferrihydrite core inside the protein cavity, and functions as a major nucleoid protein. Experimental evidence on the effect of microwave irradiation on the dps gene expression is presented. The structural and functional organization of its regulatory region is analyzed, and the technological prospects of bacterioferritin application for designing new materials with desired properties are discussed.     

Isolation, characterisation and expression of the bacterioferritin gene of Rhodobacter capsulatus

Abstract The nucleotide sequence of the Rhodobacter capsulatus bacterioferritin gene ( bfr ) was determined and found to encode a protein of 161 amino acids with a predicted molecular mass of 18 174 Da. The molecular mass of the purified protein was estimated to be 18 176.06 ± 0.80 Da by electrospray mass spectrometry. The bfr gene was introduced into an expression vector, and bacterioferritin was produced to a high level in Escherichia coli . The amino acids which are involved in haem ligation, and those which provide ligands in the binuclear metal centre in bacterioferritin from E. coli are conserved in the R. capsulatus protein. The sequences of bacterioferritins, ferritin-like proteins, and proteins similar to Dps of E. coli are compared, and membership of the bacterioferritin family re-evaluated.     

Use of the multipurpose transposon Tn<Emphasis Type="Italic">KPK2</Emphasis> for the mutational analysis of chromosomal regions upstream and downstream of the<Emphasis Type="Italic"> sipF</Emphasis> gene in<Emphasis Type="Italic"> Bradyrhizobium japonicum</Emphasis>

The DNA regions upstream and downstream of the Bradyrhizobium japonicum gene sipF were cloned by in vivo techniques and subsequently sequenced. In order to study the function of the predicted genes, a new transposon for in vitro mutagenesis, TnKPK2, was constructed. This mutagenesis system has a number of advantages over other transposons. TnKPK2 itself has no transposase gene, making transposition events stable. Extremely short inverted repeats minimize the length of the transposable element and facilitate the determination of the nucleotide sequence of the flanking regions. Since the transposable element carries a promoterless phoA reporter gene, the appearance of functional PhoA fusion proteins indicates that TnKPK2 has inserted in a gene encoding a periplasmic or secreted protein. Although such events are extremely rare, because the transposon has to insert in-frame, in the correct orientation, and at an appropriate location in the target molecule, a direct screening procedure on agar indicator plates permits the identification of candidate clones from large numbers of colonies. In this study, TnKPK2 was used for the construction of various symbiotic mutants of B. japonicum. One of the mutant strains, A2-10, which is defective in a gene encoding a protein that comigrates with bacterioferritin (bcpB), was found to induce the formation of small and ineffective nodules.Communicated by A. Kondorosi     

Photo-oxidation of tyrosine in a bio-engineered bacterioferritin ‘reaction centre’—A protein model for artificial photosynthesis

The photosynthetic reaction centre (RC) is central to the conversion of solar energy into chemical energy and is a model for bio-mimetic engineering approaches to this end. We describe bio-engineering of a Photosystem II (PSII) RC inspired peptide model, building on our earlier studies. A non-photosynthetic haem containing bacterioferritin (BFR) from Escherichia coli that expresses as a homodimer was used as a protein scaffold, incorporating redox-active cofactors mimicking those of PSII. Desirable properties include: a di-nuclear metal binding site which provides ligands for bivalent metals, a hydrophobic pocket at the dimer interface which can bind a photosensitive porphyrin and presence of tyrosine residues proximal to the bound cofactors, which can be utilised as efficient electron-tunnelling intermediates.     

Amino acid sequence of the bacterioferritin (cytochrome b1) of Escherichia coli-K12

The complete amino acid sequence of bacterioferritin (cytochrome b1) from Escherichia coli-K12 has been derived from the nucleotide sequence of the cloned gene. It comprises 158 amino acid residues giving an Mr of 18,495. The identity of the gene product was confirmed by an 87 residue N-terminal sequence obtained from the purified protein, but it differs significantly from much of the previously published partial amino acid sequence (1). Secondary structure prediction indicates a high alpha-helical content consistent with a 4-helix-bundle conformation. The fully assembled bacterioferritin molecule comprising 24 identical subunits and 12 haem moieties is a tetracosamer with an Mr of approximately 452,000.     

Magnetic resonance imaging of tumors colonized with bacterial ferritin-expressing Escherichia coli

Background

Recent studies have shown that human ferritin can be used as a reporter of gene expression for magnetic resonance imaging (MRI). Bacteria also encode three classes of ferritin-type molecules with iron accumulation properties.

Methods and Findings

Here, we investigated whether these bacterial ferritins can also be used as MRI reporter genes and which of the bacterial ferritins is the most suitable reporter. Bacterial ferritins were overexpressed in probiotic E. coli Nissle 1917. Cultures of these bacteria were analyzed and those generating highest MRI contrast were further investigated in tumor bearing mice. Among members of three classes of bacterial ferritin tested, bacterioferritin showed the most promise as a reporter gene. Although all three proteins accumulated similar amounts of iron when overexpressed individually, bacterioferritin showed the highest contrast change. By site-directed mutagenesis we also show that the heme iron, a unique part of the bacterioferritin molecule, is not critical for MRI contrast change. Tumor-specific induction of bacterioferritin-expression in colonized tumors resulted in contrast changes within the bacteria-colonized tumors.

Conclusions

Our data suggest that colonization and gene expression by live vectors expressing bacterioferritin can be monitored by MRI due to contrast changes.     

The genetic organization of Desulfovibrio desulphuricans ATCC 27774 bacterioferritin and rubredoxin-2 genes: involvement of rubredoxin in iron metabolism

The anaerobic bacterium Desulfovibrio desulphuricans ATCC 27774 contains a unique bacterioferritin, isolated with a stable di-iron centre and having iron-coproporphyrin III as its haem cofactor, as well as a type 2 rubredoxin with an unusual spacing of four amino acid residues between the first two binding cysteines. The genes encoding for these two proteins were cloned and sequenced. The deduced amino acid sequence of the bacterioferritin shows that it is among the most divergent members of this protein family. Most interestingly, the bacterioferritin and rubredoxin-2 genes form a dicistronic operon, which reflects the direct interaction between the two proteins. Indeed, bacterioferritin and rubredoxin-2 form a complex in vitro, as shown by the significant increase in the anisotropy and decay times of the fluorescence of rubredoxin-2 tryptophan(s) when mixed with bacterioferritin. In addition, rubredoxin-2 donates electrons to bacterioferritin. This is the first identification of an electron donor to a bacterioferritin and shows the involvement of rubredoxin-2 in iron metabolism. Furthermore, analysis of the genomic data for anaerobes suggests that rubredoxins play a general role in iron metabolism and oxygen detoxification in these prokaryotes.     

Cloning, sequencing, and mapping of the bacterioferritin gene (bfr) of Escherichia coli K-12.

The bacterioferritin (BFR) of Escherichia coli K-12 is an iron-storage hemoprotein, previously identified as cytochrome b1. The bacterioferritin gene (bfr) has been cloned, sequenced, and located in the E. coli linkage map. Initially a gene fusion encoding a BFR-lambda hybrid protein (Mr 21,000) was detected by immunoscreening a lambda gene bank containing Sau3A restriction fragments of E. coli DNA. The bfr gene was mapped to 73 min (the str-spc region) in the physical map of the E. coli chromosome by probing Southern blots of restriction digests of E. coli DNA with a fragment of the bfr gene. The intact bfr gene was then subcloned from the corresponding lambda phage from the gene library of Kohara et al. (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987). The bfr gene comprises 474 base pairs and 158 amino acid codons (including the start codon), and it encodes a polypeptide having essentially the same size (Mr 18,495) and N-terminal sequence as the purified protein. A potential promoter sequence was detected in the 5' noncoding region, but it was not associated with an "iron box" sequence (i.e., a binding site for the iron-dependent Fur repressor protein). BFR was amplified to 14% of the total protein in a bfr plasmid-containing strain. An additional unidentified gene (gen-64), encoding a relatively basic 64-residue polypeptide and having the same polarity as bfr, was detected upstream of the bfr gene.     

Purification and characterization of ferritin fromCampylobacter jejuni

We purified an iron-containing protein from Campylobacter jejuni using ultracentrifugation and ion-exchange chromatography. Electron microscopy of this protein revealed circular particles with a diameter of 11.5 nm and a central core with a diameter of 5.5 nm. The protein was composed of a single peptide of 21 kDa and did not serologically cross-react with horse spleen ferritin. The UV-visible spectrum of the protein showed no absorption peaks in the visible region, indicating that little or no heme is bound. The ratio of Fe:phosphate of C. jejuni ferritin was 1.5:1. From these morphological and chemical examinations, we concluded that the C. jejuni purified protein is a ferritin of the same class as that of Helicobacter pylori and Bacteroides fragilis and differs from the heme-containing bacterioferritin of Escherichia coli. The 30 N-terminal amino acids were sequenced and were found to resemble the sequences of other ferritins strongly (H. pylori ferritin, 73% identity; B. fragilis ferritin, 50% identity; E. coli gene-165 product, 50% identity), and to a lesser degree, bacterioferritins (E. coli bacterioferritin, 26% identity; Azotobacter vinelandii, 26% identity; horse spleen ferritin 30% identity). Proteins that cross-reacted with antiserum against the ferritin of C. jejuni were found in other Campylobacter species and in H. pylori, but not in Vibrio, E. coli, or Pseudomonas aeruginosa. Received: 6 September 1994 / Accepted: 6 February 1995     

A facile method of isolation for the iron molybdenum cofactor of nitrogenase and bacterial ferritin from extracts of azotobacter vinelandii

An alternative method has been developed for the isolation of both the iron molybdenum cofactor of nitrogenase (FeMoco), a small molecular weight FeMoS cluster which is the putative nitrogen- reducing site of the enzyme, and bacterioferritin, an iron storage protein similar to other ferritins, but containing heme prosthetic groups. Previously the isolation of these two species, the characterization of which is of significant current interest, has been dependent on the purification of the nitrogenase enzyme from Azotobacter vinelandii. Out new procedure eliminates the use of the anaerobic column chromatography necessary to obtain pure nitrogenase components, involving instead the heat and RNAase/ DNAase treatment of crude extracts of ruptured cells followed by sedimentation (150000 × g for 18 h) of both the 'nitrogenase complex' and bacterioferritin. The redissolved pellet from this centrifugation yields the pure crystalline bacterioferritin on addition of Mg²⁺. and cooling, the iron content of the protein being higher by this method than in previous reports. Likewise, denaturation by acid/base treatment of this protein mixture yields a precipitate which can be extracted with either N-methylformamide or N,N-dimethylformamide containing dithionite ion to yield solutions of FeMoco, as evidenced by UW 45 reconstitution and EPR spectral criteria. Unfortunately, preparations of FeMoco obtained by this method have a variable, but consistently low, Fe/Mo ratio and additional visible spectral features, indicating that they are significantly less pure than that those generated from purified nitrogenase. The aqueous supernatant from the denaturation also yields bacterioferritin, but with a lower iron content than that from the direct crystallization method.     

The composition and the structure of bacterioferritin of Escherichia coli.

Bacterioferritin isolated from Escherichia coli is of two kinds: a protein containing a polynuclear iron compound, the bacterioferritin proper and a protein free of the polynuclear iron compound, the apo-bacterioferritin. Bacterioferritin of both kinds is characterized by absorption maxima at 417,530 and 560 nm, contributed by protohaem IX. Single crystals of bacterioferritin of the space group I432 suggest that the molecule is made up of 24 identical subunits related by a cubic point symmetry. The molecular weight of the protein subunit, as determined by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, is 15000. In the electron microscope the bacterioferritin molecule appears to be a sphere of 9.5 nm (95 A) diameter composed of a negatively staining outer shell and an inner electron-dense core of 6 nm (60 A) diameter.     

Fungal ferritins: The ferritin from mycelia of Absidia spinosa is a bacterioferritin

Two distinct ferritin like iron containing proteins have been identified and isolated from the fungus Absidia spinosa; one from the spores and another from the mycelia. The mycelial protein has been purified and consists of two subunits of approx. 20 kDa. The N-terminal sequences of both subunits have been determined. The holoprotein as isolated contains approx. 750 iron atoms/molecule and exhibits a heme-like UV-Vis spectrum. Based on the heme spectrum and the high degree of sequence homology found, it has been established that the mycelial protein is a bacterioferritin. This is the first example demonstrating the presence of a bacterioferritin in a eukaryotic organism.     

Mössbauer spectroscopy and electron paramagnetic resonance studies of iron metabolites inPseudomonas aeruginosa: Fe2+ and Fe3+ ferritin in57ferripyoverdine incubated cells and57ferric citrate fed cells

Pseudomonas aeruginosa samples were studied using Mössbauer spectroscopy and electron paramagnetic resonance (EPR). Samples included whole cells, membranes, and soluble fractions from cells which had been grown with⁵⁷ferric chloride,⁵⁷ferric citrate or incubated with⁵⁷ferripyoverdine. These experiments show for the first time thatP. aeruginosa can accumulate iron in a bacterioferritin when grown under conditions of iron limitation and incubated with its cognate ferrisiderophore, ferripyoverdine. Soluble fraction fromP. aeruginosa cells which were grown iron starved and incubated with⁵⁷ferripyoverdine for 120 min showed the presence of both a ferric and ferrous complex whose Mössbauer spectra matched that of bacterioferritin extracted fromAzotobacter vinelandii and whose EPR spectra showed a characteristic ferritin-like resonance. A second soluble fraction sample from cells which had been grown with⁵⁷ferric citrate also showed the presence of a species with the same EPR and Mössbauer parameters. In addition Western blotting confirmed the presence of bacterioferritin in the soluble fraction of the cells which had been incubated with ferripyoverdine.     

Overexpression of bacterioferritin comigratory protein (Bcp) enhance viability and reduced glutathione level in the fission yeast under stress

The structural gene encoding bacterioferritin comigratory protein (Bcp) was amplified using PCR from the genomic DNA of Schizosaccharomyces pombe, and transferred into the shuttle vector pRS316 to generate the recombinant plasmid pBCPlO. The bcp ⁺ mRNA level in the pBCPlO-containing yeast cells was significantly higher than that in the control yeast cells, indicating that the cloned gene is functioning. The S. pombe cells harboring the plasmid pBCPIO exhibited higher survival on the solid minimal media with hydrogen peroxide, tert-BOOH or cadmium than the control yeast cells. They also exhibited enhanced cellular viability in the liquid media containing the stressful agents. The increased viabilities of the fission yeast cells harboring the plasmid pBCP10 were also obtained with 0.4% glucose or 0.4% sucrose as a sole carbon source, and nitrogen starvation, compared with those of the control yeast cells. The total glutathione (GSH) content and total GSH/GSSG ratio were significantly higher in the yeast cells harboring the plasmid pBCP10 than in the control yeast cells. In brief, the S. pombe Bcp plays a protective role in the defensive response to oxidative stress possibly via up-regulation of total and reduced glutathione levels.     

A bacterioferritin from the strict anaerobe Desulfovibrio desulfuricans ATCC 27774

A bacterioferritin was isolated from the anaerobic bacterium Desulfovibrio desulfuricans ATCC 27774, grown with nitrate as the terminal electron acceptor, which is the first example of a bacterioferritin from a strict anaerobic organism. This new bacterioferritin was isolated mainly as a 24-mer of 20 kDa identical subunits, containing 0.5 noncovalently bound heme and 2 iron atoms per monomer. Although its N-terminal sequence is significantly homologous with ferritins from other microorganisms and the ligands to the di-iron ferroxidase center are conserved, it is one of the most divergent bacterioferritins so far characterized. Also, in contrast to all other known bacterioferritins, its heme is not of the B type; its chromatographic behavior is identical to that of iron uroporphyrin. Thus, D. desulfuricans bacterioferritin appears to be the second example of a protein unexpectedly containing this heme cofactor, or a closely related porphyrin, after its finding in Desulfovibrio gigas rubredoxin:oxygen oxidoreductase ?Timkovich, R., Burkhalter, R. S., Xavier, A. V., Chen, L., and Le Gall, J. (1994) Bioorg. Chem. 22, 284-293. The oxidized form of the protein has a visible spectrum characteristic of low-spin ferric hemes, exhibiting a weak absorption band at 715 nm, indicative of bis-methionine heme axial coordination; upon reduction, the alpha-band appears at 550 nm and a splitting of the Soret band occurs, with two maxima at 410 and 425 nm. The heme center has a reduction potential of 140 +/- 10 mV (pH 7.6), a value unusually high compared to that of other bacterioferritins (ca. -200 mV).     

Siderophore-controlled iron assimilation in the enterobacterium Erwinia chrysanthemi: evidence for the involvement of bacterioferritin and the Suf iron-sulfur cluster assembly machinery

The intracellular fate of iron acquired by bacteria during siderophore-mediated assimilation is poorly understood. We investigated this question in the pathogenic enterobacterium Erwinia chrysanthemi. This bacterium produces two siderophores, chrysobactin and achromobactin, during plant infection. We analyzed the distribution of iron into cytosolic proteins in bacterial cells supplied with 59Fe-chrysobactin using native gel electrophoresis. A parental strain and mutants deficient in bacterioferritin (bfr), miniferritin (dps), ferritin (ftnA), bacterioferredoxin (bfd), or iron-sulfur cluster assembly machinery (sufABCDSE) were studied. In the parental strain, we observed two rapidly 59Fe-labeled protein signals identified as bacterioferritin and an iron pool associated to the protein chain-elongation process. In the presence of increased 59Fe-chrysobactin concentrations, we detected mini-ferritin-bound iron. Iron incorporation into bacterioferritin was severely reduced in nonpolar sufA, sufB, sufD, sufS, and sufE mutants but not in a sufC background. Iron recycling from bacterioferritin did not occur in bfd and sufC mutants. Iron depletion caused a loss of aconitase activity, whereas ferric chrysobactin supplementation stimulated the production of active aconitase in parental cells and in bfr and bfd mutants. Aconitase activity in sufA, sufB, sufD, sufS, and sufE mutant strains was 10 times lower than that in parental cells. In the sufC mutant, it was twice as low as that in the parental strain. Defects observed in the mutants were not caused by altered ferric chrysobactin transport. Our data demonstrate a functional link between bacterioferritin, bacterioferredoxin, and the Suf protein machinery resulting in optimal bacterial growth and a balanced distribution of iron between essential metalloproteins.     

Structure and expression of gene <Emphasis Type="Italic">vfr</Emphasis> in <Emphasis Type="Italic">Pseudomonas chlororaphis</Emphasis> 449

Gene vfr of Pseudomonas chlororaphis 449 previously described only in Pseudomonas aeruginosa was identified, cloned, and sequenced; its localization in the chromosome was determined. Amino acid sequence of the protein encoded by gene vfr in P. chlororaphis 449 was shown to have a 83% identity with the Vfr protein of P. aeruginosa PAO1 and a 63% identity with the CRP protein of Escherichia coli. Amino acid residues that ensure the most important structural properties of the CRP protein, i.e., its binding to cAMP, RNA polymerase, and DNA, were identical or highly conserved in Vfr proteins of P. aeruginosa and P. chlororaphis 449. The cloned vfr gene of P. chlororaphis 449 was complemented partially the mutation at gene crp in cells of E. coli AM306 enhancing ten times synthesis of β-galactosidase dependent on the CRP protein. Unlike P. aeruginosa, the Vfr protein in cells of P. chlororaphis 449 does not participate in the regulation of synthesis of N-acyl-homoserine lactones.