A haloarchaeal ferredoxin electron donor that plays an essential role in nitrate assimilation

In the absence of ammonium, many organisms, including the halophilic archaeon Haloferax volcanii DS2 (DM3757), may assimilate inorganic nitrogen from nitrate or nitrite, using a ferredoxin-dependent assimilatory NO??/NO?? reductase pathway. The small acidic ferredoxin Hv-Fd plays an essential role in the electron transfer cascade required for assimilatory nitrate and nitrite reduction by the cytoplasmic NarB- and NirA-type reductases respectively. UV-visible absorbance and EPR spectroscopic characterization of purified Hv-Fd demonstrate that this protein binds a single [2Fe-2S] cluster, and potentiometric titration reveals that the cluster shares similar redox properties with those present in plant-type ferredoxins.     

Crystal structure determination at 1.4 A resolution of ferredoxin from the green alga Chlorella fusca.

BACKGROUND: [2Fe-2S] ferredoxins, also called plant-type ferredoxins, are low-potential redox proteins that are widely distributed in biological systems. In photosynthesis, the plant-type ferredoxins function as the central molecule for distributing electrons from the photolysis of water to a number of ferredox-independent enzymes, as well as to cyclic photophosphorylation electron transfer. This paper reports only the second structure of a [2Fe-2S] ferredoxin from a eukaryotic organism in its native form. RESULTS: Ferredoxin from the green algae Chlorella fusca has been purified, characterised, crystallised and its structure determined to 1.4 A resolution - the highest resolution structure published to date for a plant-type ferredoxin. The structure has the general features of the plant-type ferredoxins already described, with conformational differences corresponding to regions of higher mobility. Immunological data indicate that a serine residue within the protein is partially phosphorylated. A slightly electropositive shift in the measured redox potential value, -325 mV, is observed in comparison with other ferredoxins. CONCLUSIONS: This high-resolution structure provides a detailed picture of the hydrogen-bonding pattern around the [2Fe-2S] cluster of a plant-type ferredoxin; for the first time, it was possible to obtain reliable error estimates for the geometrical parameters. The presence of phosphoserine in the protein indicates a possible mechanism for the regulation of the distribution of reducing power from the photosynthetic electron-transfer chain.     

An efficient proteomics based strategy for the functional characterization of a novel halophilic enzyme from Halobacterium salinarum

The extremely halophilic archaeon, Halobacterium salinarum grows in environments containing over 25% NaCl. The enzymes of this organism have thus been adapted to be active and stable in hypersaline conditions, which makes them strong candidates as robust industrial enzymes. In this study, the proteomics approach was applied to screen novel halophilic enzymes. We focused initially on proteins that are differentially expressed under different salt concentrations in culture media. After two-dimensional gel electrophoresis over a pH 3.5-4.5 range, 29 differentially expressed protein spots were identified by tandem mass spectrometry and six of these had no similarity to preexisting genes of known function. To predict the function of them, we used various bioinformatic methods. Among other proteins, we selected Vng0487h, which showed a high similarity to acetyltransferases. As a step toward assaying the enzymatic activity of this protein, we cloned the Vng0487h gene of H. salinarum and expressed and purified the recombinant protein with a glutathione-S-transferase (GST) tag in Escherichia coli. Using a GST-pulldown assay, a protein fragment derived from E. coli could interact with recombinant Vng0487h, and was identified to be the ribosomal protein L3. This protein showed high sequence homology with ribosomal protein L7/12 from E. coli and ribosomal protein L13p from H. salinarum. This suggests that Vng0487h acetylates a subunit of ribosomal protein, possibly L13p, in H. salinarum. During the present study, an efficient procedure was established to screen novel halophilic enzymes, and to predict and assess their functions.     

Structural similarities between the N-terminal domain of Clostridium pasteurianum hydrogenase and plant-type ferredoxins

An N-terminal domain of Clostridium pasteurianum hydrogenase I, encompassing 76 residues out of the 574 composing the full-size enzyme, had previously been overproduced in Escherichia coli and shown to form a stable fold around a [2Fe-2S] cluster. This domain displays only marginal sequence similarity with [2Fe-2S] proteins of known structure, and therefore, two-dimensional 1H NMR has been implemented to elucidate features of the polypeptide fold. Despite the perturbing presence of the paramagnetic [2Fe-2S] cluster, 57 spin systems were detected in the TOCSY spectra, 52 of which were sequentially assigned through NOE connectivities. Several secondary structure elements were identified. The N terminus of the protein consists of two antiparallel beta strands followed by an alpha helix contacting both strands. Two additional antiparallel beta strands, one of them at the C terminus of the sequence, form a four-stranded beta sheet together with the two N-terminal strands. The proton resonances that can be attributed to this beta2alphabeta2 structural motif undergo no paramagnetic perturbations, suggesting that it is distant from the [2Fe-2S] cluster. In plant- and mammalian-type ferredoxins, a very similar structural pattern is found in the part of the protein farthest from the [2Fe-2S] cluster. This indicates that the N-terminal domain of C. pasteurianum hydrogenase folds in a manner very similar to those of plant- and mammalian-type ferredoxins over a significant part (ca. 50%) of its structure. Even in the vicinity of the metal site, where 1H NMR data are blurred by paramagnetic interactions, the N-terminal domains of hydrogenase and mammalian- and plant-type ferredoxins most likely display significant structural similarity, as inferred from local sequence alignments and from previously reported circular dichroism and resonance Raman spectra. These data afford structural information on a kind of [2Fe-2S] cluster-containing domain that occurs in a number of redox enzymes and complexes. In addition, together with previously published sequence alignments, they highlight the widespread distribution of the plant-type ferredoxin fold in bioenergetic systems encompassing anaerobic metabolism, photosynthesis, and aerobic respiratory chains.     

Crystal structure determination at 1.4 Å resolution of ferredoxin from the green alga Chlorella fusca

Background: [2Fe–2S] ferredoxins, also called plant-type ferredoxins, are low-potential redox proteins that are widely distributed in biological systems. In photosynthesis, the plant-type ferredoxins function as the central molecule for distributing electrons from the photolysis of water to a number of ferredox-independent enzymes, as well as to cyclic photophosphorylation electron transfer. This paper reports only the second structure of a [2Fe–2S] ferredoxin from a eukaryotic organism in its native form.Results: Ferredoxin from the green algae Chlorella fusca has been purified, characterised, crystallised and its structure determined to 1.4 Å resolution – the highest resolution structure published to date for a plant-type ferredoxin. The structure has the general features of the plant-type ferredoxins already described, with conformational differences corresponding to regions of higher mobility. Immunological data indicate that a serine residue within the protein is partially phosphorylated. A slightly electropositive shift in the measured redox potential value, -325 mV, is observed in comparison with other ferredoxins.Conclusions: This high-resolution structure provides a detailed picture of the hydrogen-bonding pattern around the [2Fe–2S] cluster of a plant-type ferredoxin; for the first time, it was possible to obtain reliable error estimates for the geometrical parameters. The presence of phosphoserine in the protein indicates a possible mechanism for the regulation of the distribution of reducing power from the photosynthetic electron-transfer chain.     

Equisetum (horsetail) ferredoxin: characterization of the active centre and position of the four cysteine residues in this 2Fe-2S protein.

Analysis of the ferredoxin of the primitive vascular plant Equisetum indicates that the cysteine residue normally found at position 18 of plant-type ferredoxins is replaced by a valine, although the spectroscopic properties of the ferredoxins are unaffected. It is concluded that the iron--sulphur cluster in plant-type ferredoxins is attached to cysteine residues 39, 44, 47 and 77.     

Electron-nuclear interactions in two prototypical [2Fe-2S] proteins: selective (chiral) deuteration and analysis of (1)H and (2)H NMR signals from the alpha and beta hydrogens of cysteinyl residues that ligate the iron in the active sites of human ferredoxin and Anabaena 7120 vegetative ferredoxin

A vertebrate ferredoxin (human ferredoxin) and a plant-type ferredoxin (the ferredoxin from the vegetative form of Anabaena 7120) were labeled selectively with deuterium at their active site cysteines. The recombinant proteins were produced in Escherichia coli and labeled by replacing natural abundance cysteine in the defined culture medium with (2)H(alpha)-cysteine, (2)H(beta2), (2)H(beta3)-cysteine, or (2)H(beta2)-cystine. The chiral labeled cystine ((2)H(beta2)-cystine) was prepared by selective hydrogen exchange catalyzed by cystathionine gamma-synthase. NMR spectra of these samples in their oxidized and reduced states support unambiguous identifications by atom type of (1)H and (2)H NMR signals from the cysteine alpha and beta hydrogens. These signals lie outside the normal diamagnetic spectral region as a result of interaction of the hydrogens with unpaired electron density from the iron-sulfur cluster, and their chemical shifts are highly dependent on local conformation at the active site. The very different chemical properties of the iron centers of plant-type and vertebrate ferredoxins reflect relatively small differences in the conformation of the iron-sulfur cluster ligands.     

A hyperthermophilic plant-type [2Fe-2S] ferredoxin from Aquifex aeolicus is stabilized by a disulfide bond

A [2Fe-2S] ferredoxin (Fd1) from the hyperthermophilic bacterium Aquifex aeolicus has been obtained by heterologous expression of the encoding gene in Escherichia coli. Sequence comparisons show that this protein belongs to the extended family of plant- and mammalian-type [2Fe-2S] ferredoxins but also indicate that it is not closely similar to either the plant-type or mammalian-type subfamilies. Instead, it appears to bear some similarity to novel members of this family, in particular the Isc-type ferredoxins involved in the assembly of iron-sulfur clusters in vivo. The two redox levels of the [2Fe-2S](2+/+) metal site of A. aeolicus ferredoxin have been studied by UV-visible, resonance Raman, EPR, variable temperature magnetic circular dichroism, and M?ssbauer spectroscopies. A full-spin Hamiltonian analysis is given for the M?ssbauer spectra. In aggregate, the spectroscopic data reveal differences with both the plant-type and mammalian-type ferredoxins, in keeping with the sequence comparisons. The midpoint potential of the [2Fe-2S](2+/+) couple, at -375 mV versus the normal hydrogen electrode, is more negative than those of mammalian-type ferredoxins and at the upper end of the range covered by plant-type ferredoxins. A. aeolicus ferredoxin contains two cysteines in addition to the four that are committed as ligands of the [2Fe-2S] cluster. These two residues have been shown by chemical modification and site-directed mutagenesis to form a disulfide bridge in the native protein. While that cystine unit plays a significant role in the exceptional thermostability of A. aeolicus ferredoxin (T(m) = 121 degrees C at pH 7 versus T(m) = 113 degrees C in a molecular variant where the disulfide bridge has been removed), it does not bear on the properties of the [2Fe-2S](2+/+) chromophore. This observation is consistent with the large distance (ca. 20 A) that is predicted to separate the iron-sulfur chromophore from the disulfide bridge.     

Halophile aldehyde dehydrogenase from Halobacterium salinarum

Halobacterium salinarum is a member of the halophilic archaea. In the present study, H. salinarum was cultured at various NaCl concentrations (3.5, 4.3, and 6.0 M NaCl), and its proteome was determined and identificated via proteomics technique. We detected 14 proteins which were significantly down-regulated in 3.5 M and/or 6 M NaCl. Among the identified protein spots, aldehyde dehydrogenase (ALDH) was selected for evaluation with regard to its potential applications in industry. The most effective metabolism function exhibited by ALDH is the oxidation of aldehydes to carboxylic acids. The ALDH gene from H. salinarum (1.5 kb fragment) was amplified by PCR and cloned into the E. coli strain, BL21 (DE3), with the pGEX-KG vector. We subsequently analyzed the enzyme activity of the recombinant ALDH (54 kDa) at a variety of salt concentrations. The purified recombinant ALDH from H. salinarum exhibited the most pronounced activity at 1 M NaCl. Therefore, the ALDH from H.salinarum is a halophilic enzyme, and may prove useful for applications in hypersaline environments.     

The loop region covering the iron-sulfur cluster in bovine adrenodoxin comprises a new interaction site for redox partners

The amino acid in position 49 in bovine adrenodoxin is conserved among vertebrate [2Fe-2S] ferredoxins as hydroxyl function. A corresponding residue is missing in the cluster-coordinating loop of plant-type [2Fe-2S] ferredoxins. To probe the function of Thr-49 in a vertebrate ferredoxin, replacement mutants T49A, T49S, T49L, and T49Y, and a deletion mutant, T49Delta, were generated and expressed in Escherichia coli. CD spectra of purified proteins indicate changes of the [2Fe-2S] center geometry only for mutant T49Delta, whereas NMR studies reveal no transduction of structural changes to the interaction domain. The redox potential of T49Delta (-370 mV) is lowered by approximately 100 mV compared with wild type adrenodoxin and reaches the potential range of plant-type ferredoxins (-305 to -455 mV). Substitution mutants show moderate changes in the binding affinity to the redox partners. In contrast, the binding affinity of T49Delta to adrenodoxin reductase and cytochrome P-450 11A1 (CYP11A1) is dramatically reduced. These results led to the conclusion that Thr-49 modulates the redox potential in adrenodoxin and that the cluster-binding loop around Thr-49 represents a new interaction region with the redox partners adrenodoxin reductase and CYP11A1. In addition, variations of the apparent rate constants of all mutants for CYP11A1 reduction indicate the participation of residue 49 in the electron transfer pathway between adrenodoxin and CYP11A1.     

Structural stability of halophilic proteins

An examination of halobacterial amino acids exchanges as they appear in the known Spirulina platensis [2Fe-2S] ferredoxin tertiary structure indicated that most of the additional acidic residues of the halophiles occurred on the external surface of the alga structure; however, further negative changes were not placed in the ferredoxin active site region. A statistical investigation of the amino acid compositions of seven halophile and nonhalophile protein counterparts indicated that the bulkiness of amino acids used by halophiles is considerably reduced and that the overall hydrophobicity of halophilic and non halophilic molecules was essentially the same. It is suggested that the principal mode of structural stabilization for halophilic proteins is effective competition with the cytoplasmic salt for water through utilization of many external carboxyl groups of glutamic and aspartic acids. A reduction is residue bulkiness would prevent inactivation in the presence of the high molarity, antichaotropic KCl. Halophilic functionality is preserved through avoidance of additional negative charge at the active site surface.     

Reduction of salt-requirement of halophilic nucleoside diphosphate kinase by engineering S-S bond

Nucleoside diphosphate kinase (HsNDK) from extremely halophilic haloarchaeon, Halobacterium salinarum, requires salt at high concentrations for folding. A D148C mutant, in which Asp148 was replaced with Cys, was designed to enhance stability and folding in low salt solution by S-S bond. It showed increased thermal stability by about 10 °C in 0.2 M NaCl over the wild type HsNDK. It refolded from heat-denaturation even in 0.1 M NaCl, while the wild type required 2 M NaCl to achieve the same level of activity recovery. This enhanced refolding is due to the three S-S bonds between two basic dimeric units in the hexameric HsNDK structure, indicating that assembly of the dimeric unit may be the rate-limiting step in low salt solution. Circular dichroism and native-PAGE analysis showed that heat-denatured HsNDK formed partially folded dimeric structure, upon refolding, in the absence of salt and the native-like secondary structure in the presence of salt above 0.1 M NaCl. However, it remained dimeric upon prolonged incubation at this salt concentration. In contrary, heat-denatured D148C mutant refolded into tetrameric folding intermediate in the absence of salt and native-like structure above 0.1 M salt. This native-like structure was then converted to the native hexamer with time.     

Isolation and characterization of soluble cytochromes, ferredoxins and other chromophoric proteins from the halophilic phototrophic bacterium Ectothiorhodospira halophila

A cytochrome c-551 and a pair of 'high redox-potential' ferredoxins (iso-high-potential iron-sulfur proteins) were found to be the major soluble electron-transport proteins in Ectothiorhodospira halophila. Smaller amounts of 'bacterial' ferredoxin and cytochrome c' were also observed. With the exception of cytochrome c-551, these proteins are commonly encountered in the purple sulfur bacteria, family Chromatiaceae and less frequently in the purple bacteria, family Rhodospirillaceae. In addition to the cytochromes and ferredoxins, E. halophila synthesizes substantial amounts of a small yellow-colored protein, which has a chromophore spectrally similar to flavins having oxygen, nitrogen or sulfur substituents in place of the 8-methyl group such as roseoflavin and the methanogen cofactor F-420. A purple-colored protein was only partially purified, but it is spectrally similar to iron proteins having a tyrosine ligand, such as transferrin, catechuate dioxygenase, and especially the purple acid phosphatases. Neither the yellow protein nor the purple one has previously been observed in phototrophic bacteria, but may in some way be required for survival in extremely halophilic habitats. The only feature common to halophiles including E. halophila is the very acidic nature of their proteins.     

Plasmid transfer and susceptibility to antibiotics in the halophilic phototrophs Rhodovibrio salinarum and Rhodothalassium salexigens

The present study defines a series of genetic procedures to be used for molecular studies in photosynthetic halophilic species such as Rhodovibrio salinarum and Rhodothalassium salexigens. In both species, the minimal inhibitory concentrations for the antibiotics tetracycline, rifampicin, chloramphenicol, spectinomycin, streptomycin, and kanamycin were determined. In addition, conjugal transfer of IncP and IncQ plasmids from Escherichia coli was demonstrated and the resistance markers expressed in these halophiles were determined. Finally, Rth. salexigens growth dependence on variable salt concentrations was measured: maximal growth rates were seen at 6% and 4% NaCl under phototrophic and chemotrophic conditions, respectively. To the best of our knowledge, this is the first report analyzing the genetic properties of two representative species of halophilic purple non-sulfur phototrophs.     

Reverse micelles in organic solvents: a medium for the biotechnological use of extreme halophilic enzymes at low salt concentration

Alkaline p-nitrophenylphosphate phosphatase (pNPPase) from the halophilic archaeobacterium Halobacterium salinarum (previously halobium) was solubilized at low salt concentration in reverse micelles of hexadecyltrimethyl-ammoniumbromide in cyclohexane with 1-butanol as co-surfactant. The enzyme maintained its catalytic properties under these conditions. The thermodynamic "solvation-stabilization hypothesis" has been used to explain the bell-shaped dependence of pNPPase activity on the water content of reverse micelles, in terms of protein-solvent interactions. According to this model, the stability of the folded protein depends on a network of hydrated ions associated with acidic residues at the protein surface. At low salt concentration and low water content (the ratio of water concentration to surfactant concentration; w0), the network of hydrated ions within the reverse micelles may involve the cationic heads of the surfactant. The bell-shaped profile of the relationship between enzyme activity and w0 varied depending on the concentrations of NaCl and Mn2+.     

Identification and characterization of inosine monophosphate dehydrogenase from Halobacterium salinarum

Extremely halophilic Archaea, Halobacterium salinarum live in hypersaline habitats and maintain an osmotic balance of their cytoplasm by accumulating high concentrations of salt (mainly KCl). Therefore, their enzymes adapted to high NaCl concentrations offer a multitude of acutal or potential applications such as biocatalysts in the presence of high salt concentrations. In this study, the protein expression profile of H. salinarum cultured under different NaCl concentrations (3.5 M, 4.3 M, and 6.0 M) was investigated using two-dimensional gel electrophoresis (2-DE). As a result of 2-DE, the protein spots concentrated in acidic range at pH 3-10 were separated effectively using pH 3.5-4.5 ultrazoom IPG DryStrips. The proteins which proved to be upregulated or downregulated in 2-DE gel were digested with trypsin and identified with matrix-assisted laser desorption/ionization-time of flight (MALDI-TOF) and electrospray ionization quadrupole (ESI-Q) TOF-mass spectrometry. Most proteins were identified as known annotated proteins based on sequence homology and few as unknown hypothetical proteins. Among proteins identified, an enzyme named inosine monophosphate dehydrogenase (IMPDH) was selected based on the possibility of its industrial application. IMPDH gene (1.6 kb fragment) expected to exist in H. salinarum was amplified by polymerase chain reaction (PCR) and expressed in Escherichia coli strain, BL21 (DE3) using a pGEX-KG vector. Recombinant IMPDH purified from H. salinarum has a higher activity in the presence of salt than in the absence of salt.     

Salt dependent stability and unfolding of [Fe2-S2] ferredoxin of Halobacterium salinarum: spectroscopic investigations

Ferredoxin from the haloarchaeon Halobacterium salinarum is a 14. 6-kDa protein with a [Fe2-S2] center and is involved in the oxidative decarboxylation of 2-oxoacids. It possesses a high molar excess of acidic amino acid residues and is stable at high salt concentration. We have purified the protein from this extreme haloarchaeon and investigated its salt-dependent stability by circular dichroism, fluorescence, and absorption techniques. The predominantly beta-sheeted protein is stable in salt concentrations of >/=1.5 M NaCl. At lower concentrations a time-dependent increase in fluorescence intensity ratio (I(360):I(330)), a decrease in the absorption at 420 nm, and a decrease in ellipticity values are observed. The rate of fluorescence intensity change at any low salt concentration is the highest, followed by absorption and ellipticity. This suggests that at low salt the unfolding of ferredoxin starts with the loss of tertiary structure, which leads to the disruption of the [Fe2-S2] center, resulting in the loss of secondary structural elements.     

NMR studies of a ferredoxin from Haloferax mediterranei and its physiological role in nitrate assimilatory pathway

Haloferax mediterranei is a halophilic archaeon that can grow in aerobic conditions with nitrate as sole nitrogen source. The electron donor in the aerobic nitrate reduction to ammonium was a ferredoxin. This ferredoxin has been purified and characterised. Air-oxidized H. mediterranei ferredoxin has a UV-visible absorption spectra typical of 2Fe-type ferredoxins with an A420/A280 of 0.21. The nuclear magnetic resonance (NMR) spectra of the ferredoxin showed similarity to those of ferredoxins from plant and bacteria, containing a [2Fe-2S] cluster. The physiological function of ferredoxin might be to serve as an electron donor for nitrate reduction to ammonium by assimilatory nitrate (EC 1.6.6.2) and nitrite reductases (EC 1.7.7.1). The apparent molecular weight (Mr) of the ferredoxin was estimated to be 21 kDa on SDS-polyacrylamide gel electrophoresis (SDS-PAGE).     

Vertebrate-type and plant-type ferredoxins: crystal structure comparison and electron transfer pathway modelling

Crystallographic analysis of a fully functional, truncated bovine adrenodoxin, Adx(4-108), has revealed the structure of a vertebrate-type [2Fe-2S] ferredoxin at high resolution. Adrenodoxin is involved in steroid hormone biosythesis in adrenal gland mitochondria by transferring electrons from adrenodoxin reductase to different cytochromes P450. Plant-type [2Fe-2S] ferredoxins interact with photosystem I and a diverse set of reductases.A systematic structural comparison of Adx(4-108) with plant-type ferredoxins which share about 20 % sequence identity yields these results. (1) The ferredoxins of both types are partitioned into a large, strictly conserved core domain bearing the [2Fe-2S] cluster and a smaller interaction domain which is structurally different for both subfamilies. (2) In both types, residues involved in interactions with reductase are located at similar positions on the molecular surface and coupled to the [2Fe-2S] cluster via structurally equivalent hydrogen bonds. (3) The accessibility of the [2Fe-2S] cluster differs between Adx(4-108) and the plant-type ferredoxins where a solvent funnel leads from the surface to the cluster. (4) All ferredoxins are negative monopoles with a clear charge separation into two compartments, and all resulting dipoles but one point into a narrow cone located in between the interaction domain and the [2Fe-2S] cluster, possibly controlling predocking movements during interactions with redox partners. (5) Model calculations suggest that FE1 is the origin of electron transfer pathways to the surface in all analyzed [2Fe-2S] ferredoxins and that additional transfer probability for electrons tunneling from the more buried FE2 to the cysteine residue in position 92 of Adx is present in some.