Overexpression of Desulfovibrio vulgaris Hildenborough cytochrome c553 in Desulfovibrio desulfuricans G200. Evidence of conformational heterogeneity in the oxidized protein by NMR

Characterization of pNC1, a small and mobilizable plasmid for use in genetic manipulation of Desulfovibrio africanus

To develop a vector system that facilitates genetic manipulation in Desulfovibrio species, we screened native sulfate-reducing bacteria for small plasmids. A self-replicating plasmid was discovered in Desulfovibrio africanus SR-1. Sequence analysis of this 8568-bp plasmid (pNC1) revealed a G+C content of 47.2% and nine open reading frames. This plasmid has a copy number of six. Compatible hosts include D. africanus and Pseudomonas aeruginosa PA14. Genetic characterization of pNC1 revealed that 53.6% of the plasmid contains genes associated with replication, mobilization, and partitioning. The 1123-bp replicon is composed of a rep gene and four 22-bp iterons. The mobilization operon is composed of three genes with a putative 144-bp oriT. The partitioning operon is composed of parA and parB with a downstream parS. We report the construction of a small pNC1-based cloning vector which transforms D. africanus at high frequencies (approximately 1.5 x 10(3) CFU/microg DNA), is mobilizable at high transfer frequency (4.8 x 10(-4) transconjugants/donor), and is stably maintained under non-selective pressure. This study provides a potential host-vector system for Desulfovibrio gene functional analyses.

Artificial photoactive proteins

Solar power is the most abundant source of renewable energy. In this respect, the goal of making photoactive proteins is to utilize this energy to generate an electron flow. Photosystems have provided the blueprint for making such systems, since they are capable of converting the energy of light into an electron flow using a series of redox cofactors. Protein tunes the redox potential of the cofactors and arranges them such that their distance and orientation are optimal for the creation of a stable charge separation. The aim of this review is to present an overview of the literature with regard to some elegant functional structures that protein designers have created by introducing cofactors and photoactivity into synthetic proteins.

Heme crevice disorder after sixth ligand displacement in the cytochrome c-551 family

1H NMR and visible absorption spectroscopy were used to monitor sixth ligand methionine displacement reactions in four members of the ferricytochrome c-551 family from Pseudomonas aeruginosa, Pseudomonas stutzeri, Pseudomonas stutzeri substrain ZoBell, and Nitrosomonas europae. Potassium cyanide displaces the methionine ligand with very modest changes in the visible spectra, but profound changes in the NMR spectra. The initial product formed kinetically, designated complex I, changes with time and/or heating to a more thermodynamically favored product termed complex II. Spectra indicate that both I and II are actually a family of closely related conformational isomers. Low temperature NMR spectra of complex II indicate that some of the isomers are in chemical exchange on the NMR time scale. High pH also displaces the methionine ligand in a manner similar to the well-known alkaline transition of mitochondrial cytochrome c. However, the reaction occurs at higher pH values and over a narrower pH range for the c-551 family, and the transition pH range is different for the different proteins studied. The final alkaline forms also show peak widths and a number of peaks indicative of multiple conformational isomers.

Heme axial methionine fluxion in Pseudomonas aeruginosa Asn64Gln cytochrome c551

Heme axial methionine ligands in ferricytochromes c552 from Hydrogenobacter thermophilus (HT) and Nitrosomonas europaea, both members of the cyt c8 family, display fluxional behavior. The ligand motion, proposed to be inversion at sulfur, results in an unusually small range of hyperfine shifts for heme substituents in these proteins. Herein, heme axial Met fluxion is induced in a structurally homologous cytochrome c551 from Pseudomonas aeruginosa (PA) by substituting heme pocket residue Asn64 with Gln. The mutant, PA-N64Q, displays a highly compressed range of heme substituent hyperfine shifts, temperature-dependent heme methyl resonance line broadening, low rhombic magnetic anisotropy, and a magnetic axes orientation consistent with Met orientational averaging. Analysis of NMR properties of PA-N64Q demonstrates that the heme pocket of the mutant resembles that of HT. This result confirms the importance of peripheral interactions and, in particular, residue 64 in determining axial Met orientation and heme electronic structure in proteins in the cyt c8 family.

The Genetics of Geochemistry

Bacteria are remarkable in their metabolic diversity due to their ability to harvest energy from myriad oxidation and reduction reactions. In some cases, their metabolisms involve redox transformations of metal(loid)s, which lead to the precipitation, transformation, or dissolution of minerals. Microorganism/mineral interactions not only affect the geochemistry of modern environments, but may also have contributed to shaping the near-surface environment of the early Earth. For example, bacterial anaerobic respiration of ferric iron or the toxic metalloid arsenic is well known to affect water quality in many parts of the world today, whereas the utilization of ferrous iron as an electron donor in anoxygenic photosynthesis may help explain the origin of Banded Iron Formations, a class of ancient sedimentary deposits. Bacterial genetics holds the key to understanding how these metabolisms work. Once the genes and gene products that catalyze geochemically relevant reactions are understood, as well as the conditions that trigger their expression, we may begin to predict when and to what extent these metabolisms influence modern geochemical cycles, as well as develop a basis for deciphering their origins and how organisms that utilized them may have altered the chemical and physical features of our planet.

Tuning the reduction potential of engineered cytochrome c-553

Cytochrome c-553 from Desulfovibrio vulgaris exhibits a highly exposed heme and an unusually low reduction potential with respect to other c-type cytochromes. Solvent heme exposure has been indicated as one of the most important factors in modulating the midpoint potential of the redox center. To test this hypothesis, a unique surface-exposed cysteine has been substituted for either M23 or G51 to produce the corresponding mutants and allow the formation of homodimers through a specific disulfide bridge. The reduction potentials, determined via spectroelectrochemistry, show an increase from +20 +/- 5 mV for the wt to +88 +/- 5 and +105 +/- 5 mV for the M23C-M23C homodimer and G51C-G51C homodimer, respectively. Chemical denaturation of the homodimers leads to parameters related to the hydrophobicity (m) and the number of buried side chains (n(B)), which suggest a decrease of exposure of the heme as a result of dimerization. These results are consistent with the heme-accessible surface area (ASA) calculated from a computer model of the homodimers. The ASA values show a decrease from 73 A(2) for the wt to 66 and 50 A(2) per heme for the M23C-M23C homodimer and G51C-G51C homodimer, respectively. The trend of the m- and n(B)-values, the degree of solvent accessibility, and the midpoint potential observed upon formation of the homodimers indicate a correlation between the reduction potential values and the exclusion of water from the heme surface.

Structural model of the Fe-hydrogenase/cytochrome c553 complex combining transverse relaxation-optimized spectroscopy experiments and soft docking calculations

Fe-hydrogenase is a 54-kDa iron-sulfur enzyme essential for hydrogen cycling in sulfate-reducing bacteria. The x-ray structure of Desulfovibrio desulfuricans Fe-hydrogenase has recently been solved, but structural information on the recognition of its redox partners is essential to understand the structure-function relationships of the enzyme. In the present work, we have obtained a structural model of the complex of Fe-hydrogenase with its redox partner, the cytochrome c(553), combining docking calculations and NMR experiments. The putative models of the complex demonstrate that the small subunit of the hydrogenase has an important role in the complex formation with the redox partner; 50% of the interacting site on the hydrogenase involves the small subunit. The closest contact between the redox centers is observed between Cys-38, a ligand of the distal cluster of the hydrogenase and Cys-10, a ligand of the heme in the cytochrome. The electron pathway from the distal cluster of the Fe-hydrogenase to the heme of cytochrome c(553) was investigated using the software Greenpath and indicates that the observed cysteine/cysteine contact has an essential role. The spatial arrangement of the residues on the interface of the complex is very similar to that already described in the ferredoxin-cytochrome c(553) complex, which therefore, is a very good model for the interacting domain of the Fe-hydrogenase-cytochrome c(553).

Cloning, sequencing and expression of the tetraheme cytochrome c(3) from Desulfovibrio gigas

The gene encoding the tetraheme cytochrome c(3) from Desulfovibrio gigas was cloned and sequenced from a 2.7-kb EcoRI-PstI insert of D. gigas DNA. The derived amino acid sequence showed that the D. gigas cytochrome c(3) is synthesized as a precursor protein with an N-terminal signal peptide sequence of 25 residues and allowed the correction of the previous reported amino acid sequence (Matias et al. Protein Science 5 (1996) 1342-1354). Expression in D. vulgaris (Hildenborough) was possible by conjugal transfer of a recombinant broad-host-range vector pSUP104 containing a SmaI fragment of the D. gigas cytochrome c(3) gene. Biochemical, immunological and spectroscopic analysis of the purified protein showed that the recombinant cytochrome is identical to that isolated from D. gigas.

Heteronuclear NMR and soft docking: an experimental approach for a structural model of the cytochrome c553-ferredoxin complex

The combination of docking algorithms with NMR data has been developed extensively for the studies of protein-ligand interactions. However, to extend this development for the studies of protein-protein interactions, the intermolecular NOE constraints, which are needed, are more difficult to access. In the present work, we describe a new approach that combines an ab initio docking calculation and the mapping of an interaction site using chemical shift variation analysis. The cytochrome c553-ferredoxin complex is used as a model of numerous electron-transfer complexes. The 15N-labeling of both molecules has been obtained, and the mapping of the interacting site on each partner, respectively, has been done using HSQC experiments. 1H and 15N chemical shift analysis defines the area of both molecules involved in the recognition interface. Models of the complex were generated by an ab initio docking software, the BiGGER program (bimolecular complex generation with global evaluation and ranking). This program generates a population of protein-protein docked geometries ranked by a scoring function, combining relevant stabilization parameters such as geometric complementarity surfaces, electrostatic interactions, desolvation energy, and pairwise affinities of amino acid side chains. We have implemented a new module that includes experimental input (here, NMR mapping of the interacting site) as a filter to select the accurate models. Final structures were energy minimized using the X-PLOR software and then analyzed. The best solution has an interface area (1037.4 A2) falling close to the range of generally observed recognition interfaces, with a distance of 10.0 A between the redox centers.

Mapping the cytochrome c553 interacting site using 1H and 15N NMR

Cytochrome c553 is the electron transfer partner of formate dehydrogenase and of [Fel-hydrogenase, two metalloenzymes essential in the metabolism of sulfate reducing bacteria. These two enzymes contain a 'ferredoxin-like' domain which presents 30% identity with Desulfovibrio desulfuricans Norway ferredoxin 1. This was chosen as a model for the 'ferredoxin-like' domain involved in the electron transfer reaction with cytochrome c553. ID NMR titration of complex formation gave us the stoichiometry (1:1) and the dissociation constant of the complex (Kd approximately 3x10(-6) M). 2D heteronuclear NMR experiments were performed to analyze the 1H and 15N chemical shift variations that are induced by the protein-protein recognition. This is the first mapping of the interaction site on a c-type cytochrome, using heteronuclear NMR.

15N-labelling and preliminary heteronuclear NMR study of Desulfovibrio vulgaris Hildenborough cytochrome c553

When using heteronuclear NMR, 15N-labelling is necessary for structural analysis, dynamic studies and determination of complex formation. The problems that arise with isotopic labelling of metalloproteins are due to their complex maturation process, which involves a large number of factors. Cytochromes c are poorly expressed in Escherichia coli and the overexpression that is necessary for 15N-labelling, requires an investigation of the expression host and special attention to growth conditions. We have succeeded in the heterologous expression and the complete and uniform isotopic 15N-labelling of the cytochrome c553 from Desulfovibrio vulgaris Hildenborough, in a sulphate-reducing bacterium, D. desulfuricans G200, by using a growth medium combining 15N-ammonium chloride and 15N-Celtone. These conditions allowed us to obtain approximately 0.8 mg x L-1 of pure labelled cytochrome c553. 1H and 15N-assignments for both the oxidized and the reduced states of cytochrome c553 were obtained from two-dimensional heteronuclear experiments. Pseudocontact effects due to the haem Fe3+ have been analysed for the first time through 15N and 1H chemical shifts in a c-type cytochrome.

Engineering multi-domain redox proteins containing flavodoxin as bio-transformer: preparatory studies by rational design

This work demonstrates that non-physiological electron transfer (ET) can occur in solution between wild type D. vulgaris flavodoxin (Fld) and horse heart cytochrome c (cyt-c), D. vulgaris cytochrome c553 (cyt-c553) and the haem domain of B. megaterium cytochrome P450 (cyt-P450 BMP). Second order rate constants of the ET reaction between [Fld]sq/[cyt-c]ox, [Fld]sq/[cyt-c553]ox and [Fld]sq/[cyt-P450 BMP]ox, were found to be 6.16 x 10(5), 1.80 x 10(4) and in the region of 10(5) respectively. These data are interpreted in terms of complementarity between the surfaces of the two proteins, their surface and redox potentials. Analysis of the ET results obtained from the separate wild type proteins supported the rational design approach in the creation of Fld-based chimeras. The preliminary design of the chimeras reported here is a 3D prototype for an artificial flavo-cytochrome obtained by covalent linkage of a Fld module to cyt-c553 via a disulphide bond. Theoretical ET rates calculated on the modelled flavo-cytochrome are encouraging the construction of these chimeric systems at DNA level. This work is now underway. The relevance of this molecular lego approach is to be seen in the long term goal of producing engineered multi-domain systems to be applied in the field of biosensors and bioelectronics to fulfil specific requirements. Novel catalytic devices can be obtained by using natural redox proteins in different combinations: this process mimics the natural evolution of proteins such as gene shuffling and gene fusion.

Tyrosine 64 of cytochrome c553 is required for electron exchange with formate dehydrogenase in Desulfovibrio vulgaris Hildenborough

Replacement of tyrosine 64 by alanine in cytochrome c553 from Desulfovibrio vulgarisHildenborough prevents electron transfer with the formate dehydrogenase. Biophysical and biochemical studies show that the protein is correctly folded and that the oxidoreduction potential is not modified. The solution structure of the mutant cytochrome determined by two-dimensional (2D) NMR clearly establishes that the overall fold of the molecule is nearly identical to that of the wild-type cytochrome. The electrostatic surface charge distributions for the wild-type and mutant cytochrome are similar, suggesting that the interaction site of the physiological partners is not modified by the mutation. The lack of the aromatic ring induces slight destabilization of the hydrophobic core of the molecule and modifications of the hydrogen bond at position 64, as well as conformational disorder of the side chain of K63. The loss of the hydrogen bond from tyrosine 64 and the increase of the solvent exposure of the heme are probably responsible of the loss of electron transfer between formate dehydrogenase and cytochrome c553.

The Desulfuromonas acetoxidans triheme cytochrome c7 produced in Desulfovibrio desulfuricans retains its metal reductase activity

Multiheme cytochrome c proteins that belong to class III have been recently shown to exhibit a metal reductase activity, which could be of great environmental interest, especially in metal bioremediation. To get a better understanding of these activities, the gene encoding cytochrome c7 from the sulfur-reducing bacterium Desulfuromonas acetoxidans was cloned from genomic DNA by PCR and expressed in Desulfovibrio desulfuricans G201. The expression system was based on the cyc transcription unit from Desulfovibrio vulgaris Hildenborough and led to the synthesis of holocytochrome c7 when transferred by electrotransformation into the sulfate reducer Desulfovibrio desulfuricans G201. The produced cytochrome was indistinguishable from the protein purified from Desulfuromonas acetoxidans cells with respect to several biochemical and biophysical criteria and exhibited the same metal reductase activities as determined from electrochemical experiments. This suggests that the molecule was correctly folded in the host organism. Desulfovibrio desulfuricans produces functional multiheme c-type cytochromes from bacteria belonging to a different genus and may be considered a suitable host for the heterologous biogenesis of multiheme c-type cytochromes for either structural or engineering studies. This report, which presents the first example of the transformation of a Desulfovibrio desulfuricans strain by electrotransformation, describes work that is the first necessary step of a protein engineering program that aims to specify the structural features that are responsible for the metal reductase activities of multiheme cytochrome c7.

New conformational properties induced by the replacement of Tyr-64 in Desulfovibrio vulgaris Hildenborough ferricytochrome c553 using isotopic exchanges monitored by mass spectrometry

In order to study the conformational stability induced by the replacement of Tyr-64 in Desulfovibrio vulgaris Hildenborough (DvH) cytochrome c553, fast peptic digestion of deuterated protein followed by separation and measurement of related peptides using liquid chromatography coupled to electrospray ionization mass spectrometry was performed. We show that the H-bonding and/or solvent accessibility properties were modified by the single-site mutation. The mutant proteins can be classified into two groups: the Y64F and Y64L mutants with nearly unchanged deuterium incorporation compared to the wild-type protein and the Y64S, Y64V and Y64A mutants with increased deuterium incorporation. The 70-74 peptide was the most affected by mutation of Tyr-64, the phenylalanine mutant inducing slight stabilization whereas the serine mutant was significantly destabilized. In addition, from the analysis of the overlapping 37-57 and 38-57 peptides we can conclude that the amide proton of Tyr-38 has been replaced by deuterium in all proteins.

Investigation of oxidation state-dependent conformational changes in Desulfovibrio vulgaris Hildenborough cytochrome c553 by two-dimensional H-NMR spectra

Two-dimensional nuclear magnetic resonance spectroscopy (2D-NMR) was used to assign the proton resonances of ferricytochrome C553 from Desulfovibrio vulgaris Hildenborough. The spin systems of 76 out of 79 amino acids were identified by J-correlation spectroscopy (COSY and HOHAHA) in H20 and D20 and correlated by nuclear Overhauser effect spectroscopy (NOESY). The proton chemical shifts are compared in both oxidized and reduced states of the protein at 23 degrees C and pH 5.9. Chemical shift variations between reduced and oxidized states are due to the paramagnetic contribution. Medium and long-range nOe demonstrate the lack of major changes between the two redox states. NMR data provide evidence that in this low oxidoreduction potential cytochrome, the oxidized state is more rigid than the reduced state.

Comparison of low oxidoreduction potential cytochrome c553 from Desulfovibrio vulgaris with the class I cytochrome c family

The cytochrome c553 from Desulfovibrio vulgaris (DvH c553) is of importance in the understanding of the relationship of structure and function of cytochrome c due to its lack of sequence homology with other cytochromes, and its abnormally low oxido-reduction potential. In evolutionary terms, this protein also represents an important reference point for the understanding of both bacterial and mitochondrial cytochromes c. Using the recently determined nuclear magnetic resonance (NMR) structure of the reduced protein we compare the structural, dynamic, and functional characteristics of DvH c553 with members of both the mitochondrial and bacterial cytochromes c to characterize the protein in the context of the cytochrome c family, and to understand better the control of oxide-reduction potential in electron transfer proteins. Despite the low sequence homology, striking structural similarities between this protein and representatives of both eukaryotic [cytochrome c from tuna (tuna c)] and prokaryotic [Pseudomonas aeruginosa c551 (Psa c551)] cytochromes c have been recognized. The previously observed helical core is also found in the DvH c553. The structural framework and hydrogen bonding network of the DvH c553 is most similar to that of the tuna c, with the exception of an insertion loop of 24 residues closing the heme pocket and protecting the propionates, which is absent in the DvH c553. In contrast, the Psa c551 protects the propionates from the solvent principally by extending the methionine ligand arm. The electrostatic distribution at the recognized encounter surface around the heme in the mitochondrial cytochrome is reproduced in the DvH c553, and corresponding hydrogen bonding networks, particularly in the vicinity of the heme cleft, exist in both molecules. Thus, although the cytochrome DvH c553 exhibits higher primary sequence homology to other bacterial cytochromes c, the structural and physical homology is significantly greater with respect to the mitochondrial cytochrome c. The major structural and functional difference is the absence of solvent protection for the heme, differentiating this cytochrome from both reference cytochromes, which have evolved different mechanisms to cover the propionates. This suggests that the abnormal redox potential of the DvH c553 is linked to the raised accessibility of the heme and supports the theory that redox potential in cytochromes is controlled by heme propionate solvent accessibility.

Effects of the Tyr64 substitution on the stability of cytochrome c553, a low oxidoreduction-potential cytochrome from Desulfovibrio vulgaris Hildenborough

Cytochrome c553 from sulfate-reducing bacteria is a low-oxidoreduction-potential cytochrome. The primary and tertiary structures show notable differences when compared to mitochondrial cytochromes. Tyr64 replacement in cytochrome c553 provides evidence that this residue is not directly involved in the potential modulation but is mostly implicated in the hydrogen-bond network around the heme. While the different variants obtained did not induce drastic structural modifications, they did affect the stability of the protein. This decrease of stability in acidic and alkaline environments was observed by variations in the optical spectra and by mass spectrometry. In addition, the mobility of aromatic side-chain was found to be increased in the mutant proteins as monitored by two-dimensional NMR spectroscopy.

Molecular biology of c-type cytochromes from Desulfovibrio vulgaris Hildenborough

Sulfate reducing bacteria of the genus Desulfovibrio harbor a wide variety of redox proteins. Three different c-type cytochromes, cytochrome c-553, cytochrome c3 and the high molecular mass cytochrome have been isolated from these bacteria. The high molecular mass cytochrome is part of an operon that encodes a transmembrane protein complex that mediates electron transfer across the cytoplasmic membrane. The physiological function of the other two cytochromes is less clear. They are encoded by monocistronic genes and their redox partners can thus not be identified by gene sequencing. Expression of genes for c-type cytochromes in a foreign host are complicated due to the requirement for covalent heme insertion. Cytochrome c-553 is readily expressed in Escherichia coli in functional form, but cytochrome c3 and the high molecular mass cytochrome are for reasons that are presently not clear.