Cytochromes c555 from the hyperthermophilic bacterium Aquifex aeolicus. 2. Heterologous production of soluble cytochrome c555s and investigation of the role of methionine residues.

The cycB2 gene encoding the soluble cytochrome c555s from Aquifex aeolicus, an hyperthermophilic organism, has been cloned and expressed using Escherichia coli as the host organism. The cytochrome was successfully produced in the periplasm of an E. coli strain coexpressing the ccmABCDEFGH genes involved in the cytochrome c maturation process. Comparison of native and recombinant cytochrome c555s shows that both proteins are indistinguishable in terms of spectroscopic and physicochemical properties. Since two different methionine residues are present in the sequence stretch usually providing the sixth ligand to the heme iron, site-directed mutagenesis has been performed in order to identify the methionine serving as the axial ligand. Two single mutations were introduced, leading to the replacement of each methionine by a histidine residue. Characterization of both mutants, M78H and M84H cytochromes c555s, using biochemical and biophysical techniques has been carried out. The M84H mutant exhibits spectral features identical to those of native cytochrome. Its redox midpoint potential is decreased by 40 mV. By contrast, substitution of methionine 78 by a histidine residue strongly alters the structural and physicochemical properties of the molecule which exhibits characteristics of His/His iron coordination type rather than His/Met. These results allow us to identify methionine 78 as the sixth ligand of cytochrome c555s heme iron. Preliminary results on the thermostability of the native and mutant cytochromes c555 are also reported.

A novel approach for assessing macromolecular complexes combining soft-docking calculations with NMR data.

We present a novel and efficient approach for assessing protein-protein complex formation, which combines ab initio docking calculations performed with the protein docking algorithm BiGGER and chemical shift perturbation data collected with heteronuclear single quantum coherence (HSQC) or TROSY nuclear magnetic resonance (NMR) spectroscopy. This method, termed "restrained soft-docking," is validated for several known protein complexes. These data demonstrate that restrained soft-docking extends the size limitations of NMR spectroscopy and provides an alternative method for investigating macromolecular protein complexes that requires less experimental time, effort, and resources. The potential utility of this novel NMR and simulated docking approach in current structural genomic initiatives is discussed.

Interactions of bile salt micelles and colipase studied through intermolecular nOes.

Colipase is a small protein (10 kDa), which acts as a protein cofactor for the pancreatic lipase. Various models of the activated ternary complex (lipase-colipase-bile salt micelles) have been proposed using detergent micelles, but no structural information has been established with bile salt micelles. We have investigated the organization of sodium taurodeoxycholate (NaTDC) micelles and their interactions with pig and horse colipases by homonuclear nuclear magnetic resonance (NMR) spectroscopy. The NMR data supply evidence that the folding of horse colipase is similar to that already described for pig colipase. Intermolecular nuclear Overhauser effects have shown that two conserved aromatic residues interact with NaTDC micelles.

Escherichia coli is able to produce heterologous tetraheme cytochrome c(3) when the ccm genes are co-expressed.

The production of Desulfovibrio vulgaris Hildenborough cytochrome c(3) (M(r) 13000), which is a tetraheme cytochrome, in Escherichia coli was examined. This cytochrome was successfully produced in an E. coli strain co-expressing the ccmABCDEFGH genes involved in the cytochrome c maturation process. The apocytochrome c(3) was matured in either anaerobic or aerobic conditions, but aerobic growth in the presence of delta-aminolevulinic acid was found to be best for cytochrome c(3) production. Site-directed mutagenesis was performed to investigate the effect of the presence of four amino acids in between the two cysteines of the heme binding sites 2 and 4 on the maturation of holocytochrome c(3) in E. coli.

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).

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.

Interaction-induced redox switch in the electron transfer complex rusticyanin-cytochrome c(4).

The blue copper protein rusticyanin isolated from the acidophilic proteobacterium Thiobacillus ferrooxidans displays a pH-dependent redox midpoint potential with a pK value of 7 on the oxidized form of the protein. The nature of the alterations of optical and EPR spectra observed above the pK value indicated that the redox-linked deprotonation occurs on the epsilon-nitrogen of the histidine ligands to the copper ion. Complex formation between rusticyanin and its probable electron transfer partner, cytochrome c(4), induced a decrease of rusticyanin's redox midpoint potential by more than 100 mV together with spectral changes similar to those observed above the pK value of the free form. Complex formation thus substantially modifies the pK value of the surface-exposed histidine ligand to the copper ion and thereby tunes the redox midpoint potential of the copper site. Comparisons with reports on other blue copper proteins suggest that the surface-exposed histidine ligand is employed as a redox tuning device by many members of this group of soluble electron carriers.

Evaluation of slaved pulses to study protein hydration.

The new concept of slaved pulses is evaluated in the context of the study of protein hydration. The inversion properties of these pulses are shown to be superior in quality to the previously published schemes. High-quality water selective homonuclear 2D 1H NOESY-NOESY and NOESY-TOCSY experiments were recorded on horse heart ferrocytochrome c.

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.

The formate dehydrogenase-cytochrome c553 complex from Desulfovibrio vulgaris Hildenborough.

The electron transfer between formate dehydrogenase and cytochrome c553 from the anaerobic bacteria Desulfovibrio vulgaris Hildenborough has been investigated. Parameters of the electron transfer kinetics are reported. The ionic strength dependence of the complex formation has been evidenced. Two mutants of cytochrome c553 have been obtained using site-directed mutagenesis with the substitutions K62E and K62E,K63E. According to one-dimensional and two-dimensional NMR analysis, the two variants were found to have the same folding pattern as that of the wild-type cytochrome. The replacements of the lysine residues by acidic groups have important effects on the affinity between the two oxidoreduction partners. K62 and K63 are essential for recognition between the formate dehydrogenase and the cytochrome c553. Previous structural studies of cytochrome c553 have demonstrated the involvement of the polypeptide chain in the modulation of the particular low oxidoreduction potential of this cytochrome. The present study provides evidence that, during the evolution of cytochromes from the anaerobic metabolism to aerobic respiration and photosynthesis, the electrostatic distribution at the recognised encounter surface around the heme is highly conserved in all cytochromes.

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.

1H-NMR study of the structural influence of Y64 substitution in Desulfovibrio vulgaris Hildenborough cytochrome c553.

Y64 has been replaced in cytochrome c553 from Desulfovibrio vulgaris Hildenborough by phenylalanine, leucine, valine, serine and alanine residues. An NMR study of structural variation induced in both oxidoreduction states of the molecule has been carried out by analysing observed chemical-shift variations. Dynamic changes were evidenced using NH exchange. We have observed that the substitution has a drastic effect on the stability of the molecule in the reduced state, although there is no effect on the reduction potential of the cytochrome. Y64-->F substitution induces particular effects on the NH exchange at the N-terminal, C-terminal and central alpha-helices and increases the stability of the oxidized molecule.

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.

Crystal structure of a dimeric octaheme cytochrome c3 (M(r) 26,000) from Desulfovibrio desulfuricans Norway.

BACKGROUND: The octaheme cytochrome C3 (M(r) 26,000; cc3) from Desulfovibrio desulfuricans Norway is a dimeric cytochrome made up of two identical subunits, each containing four heme groups. It is involved in the redox transfer chain of sulfate-reducing bacteria, which links the periplasmic oxidation of hydrogen to the cytoplasmic reduction of sulfate. The amino-acid sequence of cc3 shows similarities to that of the tetraheme cytochrome c3 (M(r) 13,000; c3) from the same bacteria. Structural analysis of cc3 forms a basis for understanding the precise roles of the multiheme-containing redox proteins and the reason for the presence of several different multiheme cytochromes in one bacterial strain. RESULTS: The crystal structure of cytochrome cc3 has been determined at 2.16 A resolution. The subunits display the c3 structural fold with significant amino-acid substitutions, relative to the tetraheme cytochromes c3, in the regions of the dimer interface. The identical subunits are related by a crystallographic twofold axis, with one heme of each subunit in close contact. The overall structure and the environments of the different heme groups are compared with those of the tetraheme cytochromes c3. CONCLUSIONS: A common scheme for interactions between these types of cytochrome and their redox partners involves the interaction of a heme crevice, surrounded by positively charged lysine residues, with acidic residues surrounding the redox partner's functional group. Despite the relatively acidic character of cytochrome cc3, the crevice of one heme is surrounded by a high number of positively charged residues, in the same manner as has been reported for cytochromes c3. The environment of this heme is formed by four flexible surface loops which are variable in length and orientation in the different c3-type cytochromes although the overall structural folds are very similar. It has been proposed that this region, adapted in topology and charge, is the interaction site for physiological partners and is also most likely to be the interaction site in the dimeric cytochrome cc3.

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.

Purification and characterization of the formate dehydrogenase from Desulfovibrio vulgaris Hildenborough.

Formate dehydrogenase from Desulfovibrio vulgaris Hildenborough, a sulfate-reducing bacterium, has been isolated and characterized. The enzyme is composed of three subunits. A high molecular mass subunit (83,500 Da) is proposed to contain a molybdenum cofactor, a 27,000 Da subunit is found to be similar to the Fe-S subunit of the formate dehydrogenase from Escherichia coli and a low molecular mass subunit (14,000 Da) holds a c-type heme. The presence of heme c in formate dehydrogenase is reported for the first time and is correlated to the peculiar low oxidoreduction potential of the metabolism of these strictly anaerobic bacteria. In vitro measurements have shown that a monoheme cytochrome probably acts as a physiological partner of the enzyme in the periplasm.

Biochemical properties of a beta-xylosidase from Clostridium cellulolyticum.

A 43-kDa beta-xylosidase from Clostridium cellulolyticum was purified to homogeneity. The enzyme releases xylose from p-nitrophenylxylose and xylodextrins with a degree of polymerization ranging between 2 and 5. The N-terminal amino acid sequence of the enzyme showed homologies with three other bacterial beta-xylosidases. By proton nuclear magnetic resonance spectroscopy, the enzyme was found to act by inverting the beta-anomeric configuration.