NADH peroxidase activity of rubrerythrin

P. S. Alban et al. (J. Appl. Microbiol. (1998) 85, 875-882) reported that a mutant H2O2-resistant strain of Spirullum (S.) volutans showed constitutive overexpression of a protein whose amino acid sequence and molecular weight closely resembled that of a subunit of rubrerythrin, a non-heme iron protein with no known function. They also reported that the mutant strain, but not the wild-type, showed NADH peroxidase activity. Here we demonstrate that rubrerythrin and nigerythrin from Desulfovibrio vulgaris and rubrerythrin from Clostridium perfringens show NADH peroxidase activities in an in vitro system containing NADH, hydrogen peroxide, and a bacterial NADH oxidoreductase. The peroxidase specific activities of the rubrerythrins with the "classical" heme peroxidase substrate, o-dianisidine, are many orders of magnitude lower than that of horseradish peroxidase. These results are consistent with the phenotype of the H2O2-resistant strain of S. volutans. The reaction of reduced (i.e., all-ferrous) rubrerythrin with excess O2 takes several minutes, whereas the anaerobic reaction of reduced rubrerythrin with hydrogen peroxide is on the millisecond time scale and results in full oxidation of all iron centers to their ferric states. Rubrerythrins could, thus, function as the terminal components of NADH peroxidases in air-sensitive bacteria and archaea.

Iron storage in bacteria

Iron is an essential nutrient for nearly all organisms but presents problems of toxicity, poor solubility and low availability. These problems are alleviated through the use of iron-storage proteins. Bacteria possess two types of iron-storage protein, the haem-containing bacterioferritins and the haem-free ferritins. These proteins are widespread in bacteria, with at least 39 examples known so far in eubacteria and archaebacteria. The bacterioferritins and ferritins are distantly related but retain similar structural and functional properties. Both are composed of 24 identical or similar subunits (approximately 19 kDa) that form a roughly spherical protein (approximately 450 kDa, approximately 120 A diameter) containing a large hollow centre (approximately 80 A diameter). The hollow centre acts as an iron-storage cavity with the capacity to accommodate at least 2000 iron atoms in the form of a ferric-hydroxyphosphate core. Each subunit contains a four-helix bundle which carries the active site or ferroxidase centre of the protein. The ferroxidase centres endow ferrous-iron-oxidizing activity and are able to form a di-iron species that is an intermediate in the iron uptake, oxidation and core formation process. Bacterioferritins contain up to 12 protoporphyrin IX haem groups located at the two-fold interfaces between pairs of two-fold related subunits. The role of the haem is unknown, although it may be involved in mediating iron-core reduction and iron release. Some bacterioferritins are composed of two subunit types, one conferring haem-binding ability (alpha) and the other (beta) bestowing ferroxidase activity. Bacterioferritin genes are often adjacent to genes encoding a small [2Fe-2S]-ferredoxin (bacterioferritin-associated ferredoxin or Bfd). Bfd may directly interact with bacterioferritin and could be involved in releasing iron from (or delivering iron to) bacterioferritin or other iron complexes. Some bacteria contain two bacterioferritin subunits, or two ferritin subunits, that in most cases co-assemble. Others possess both a bacterioferritin and a ferritin, while some appear to lack any type of iron-storage protein. The reason for these differences is not understood. Studies on ferritin mutants have shown that ferritin enhances growth during iron starvation and is also involved in iron accumulation in the stationary phase of growth. The ferritin of Campylobacter jejuni is involved in redox stress resistance, although this does not appear to be the case for Escherichia coli ferritin (FtnA). No phenotype has been determined for E. coli bacterioferritin mutants and the precise role of bacterioferritin in E. coli remains uncertain.

Identification of a gene for a rubrerythrin/nigerythrin-like protein in Spirillum volutans by using amino acid sequence data from mass spectrometry and NH2-terminal sequencing

A hydrogen peroxide-resistant mutant of the catalase-negative microaerophile, Spirillum volutans, constitutively expresses a 21.5 kDa protein that is undetectable and non-inducible in the wild-type cells. Part of the gene that encodes the protein was cloned using amino acid sequence data obtained by both mass spectrometry and NH2-terminal sequencing. The deduced 158 amino acid polypeptide shows high relatedness to rubrerythrin and nigerythrin previously described in the anaerobes Clostridium perfringens and Desulfovibrio vulgaris. The protein also shows high similarity to putative rubrerythrin proteins found in the anaerobic archeons Archaeoglobus fulgidus, Methanococcus jannaschii and Methanobacterium thermoautotrophicum. This is the first report of this type of protein in an organism that must respire with oxygen. It seems likely that the novel combination of methodologies used in this study could be applied to the rapid cloning of other genes in bacteria for which no genomic library yet exists.

A rubrerythrin operon and nigerythrin gene in Desulfovibrio vulgaris (Hildenborough)

Rubrerythrin is a nonheme iron protein of unknown function isolated from Desulfovibrio vulgaris (Hildenborough). We have sequenced a 3.3-kbp Sal1 fragment of D. vulgaris chromosomal DNA containing the rubrerythrin gene, rbr, identified additional open reading frames (ORFs) adjacent to rbr, and shown that these ORFs are part of a transcriptional unit containing rbr. One ORF, designated fur, lies just upstream of rbr and encodes a 128-amino-acid-residue protein which shows homology to Fur (ferric uptake regulatory) proteins from other purple bacteria. The other ORF, designated rdl, lies just downstream of rbr and encodes a 74-residue protein with significant sequence homology to rubredoxins but with a different number and spacing of cysteine residues. Overexpression of rdl in Escherichia coli yielded a protein, Rdl, which has spectroscopic properties and iron content consistent with one Fe3+(SCys)4 site per polypeptide but is clearly distinct from both rubrerythrin and a related protein, nigerythrin. Northern analysis indicated that fur, rbr, and rdl were each present on a transcript of 1.3 kb; i.e., these three genes are cotranscribed. Because D. vulgaris nigerythrin appears to be closely related to rubrerythrin, and its function is also unknown, we cloned and sequenced the gene encoding nigerythrin, ngr. The amino acid sequence of nigerythrin is 33% identical to that of rubrerythrin, and all residues which furnish iron ligands to both the FeS4 and diiron-oxo sites in rubrerythrin are conserved in nigerythrin. Despite the close resemblance of these two proteins, ngr was found to be no closer than 7 kb to rbr on the D. vulgaris chromosome, and Northern analysis showed that, in contrast to rbr, ngr is not cotranscribed with other genes. Possible redox-linked functions for rubrerythrin and nigerythrin in iron homeostasis are proposed.

Rubrerythrin from Clostridium perfringens: cloning of the gene, purification of the protein, and characterization of its superoxide dismutase function

The food-borne pathogen Clostridium perfringens, which is an obligate anaerobe, showed growth under conditions of oxidative stress. In protein extracts we looked for superoxide dismutase (SOD) activities which might scavenge highly toxic superoxide radicals evolving under such stress conditions. Using the classical assay to detect SOD activity on gels after electrophoresis of C. perfringens proteins, we obtained a pattern of three major bands indicating SOD activity. The protein representing the brightest band was purified by three chromatographic steps. On the basis of 20 amino acids determined from the N terminus of the protein, we designed a degenerate oligonucleotide probe to isolate the corresponding gene. We finally sequenced an open reading frame of 195 amino acids (molecular mass, 21,159 Da) with a strong homology to the Desulfovibrio vulgaris rubrerythrin; therefore, we assumed to have cloned a rubrerythrin gene from C. perfringens, and we named it rbr. The C-terminal region of the newly detected rubrerythrin from C. perfringens contains a characteristic non-heme, non-sulfur iron-binding site -Cys-X-X-Cys-(X)12-Cys-X-X-Cys- similar to that found in rubrerythrin from D. vulgaris. In addition, three -Glu-X-X-His- sequences could represent diiron binding domains. We observed SOD activity in extracts of Escherichia coli strains containing the recombinant rbr gene from C. perfringens. A biological function of rubrerythrin as SOD was confirmed with the functional complementation by the rbr gene of an E. coli mutant strain lacking SOD activity. We therefore suppose that rubrerythrin plays a role as a scavenger of oxygen radicals.

Di-iron-carboxylate proteins

Di-iron centers bridged by carboxylate residues and oxide/hydroxide groups have so far been seen in four classes of proteins involved in dioxygen chemistry or phosphoryl transfer reactions. The dinuclear iron centers in these proteins are coordinated by histidines and additional carboxylate ligands. Recent structural data on some of these enzymes, combined with spectroscopic and kinetic data, can now serve as a base for detailed mechanistic suggestions. The di-iron sites in the major class of hydroxylase-oxidase enzymes, which contains ribonucleotide reductase and methane monooxygenase, show significant flexibility in the geometry of their coordination of three or more carboxylate groups. This flexibility, combined with a relatively low coordination number, and a buried environment suitable for reactive oxygen chemistry, explains their efficient harnessing of the oxidation power of molecular oxygen.

Recombinant Desulfovibrio vulgaris rubrerythrin. Isolation and characterization of the diiron domain

The gene encoding Desulfovibrio (D.) vulgaris rubrerythrin (Prickril, B. C., Kurtz, D. M., Jr., LeGall, J., & Voordouw, G. (1991) Biochemistry 30, 1118), a protein of unknown function containing both FeS4 and (mu-oxo)diiron sites, was cloned and overexpressed in Escherichia coli. Upon cell lysis, the overexpressed protein was found in an insoluble form deficient in iron. Iron was incorporated in vitro by dissolving the protein in 3 M guanidinium chloride, adding Fe(II) anaerobically and diluting the denaturant. This recombinant rubrerythrin was found to have properties very similar to those of rubrerythrin isolated from D. vulgaris, except that the recombinant rubrerythrin contained six rather than four (or five) iron atoms per 44 kDa homodimer. Analyses of UV-vis, Mössbauer, and EPR spectra showed that the six iron atoms in recombinant rubrerythrin are organized as two FeS4 and two (mu-oxo/hydroxo)diiron sites. In order to allow examination of the diiron sites in the absence of the FeS4 sites, a truncated gene encoding the N-terminal 152 residues of D. vulgaris rubrerythrin was also cloned and overexpressed as an insoluble protein in E. coli, and iron was incorporated by a procedure analogous to that for recombinant rubrerythrin. This so-called "chopped" rubrerythrin (CRr) was found to consist of an approximately 35 kDa homodimer containing four iron atoms. Spectroscopic characterization indicated that the four iron atoms in CRr are organized as two diiron sites, the majority of which closely resemble the (mu-oxo)diiron(III) sites in E. coli ribonucleotide reductase R2 protein, and a minor fraction of which resemble the mixed-valent diiron(II,III) site in methane monooxygenase hydroxylase.(ABSTRACT TRUNCATED AT 250 WORDS)

Resonance Raman spectroscopic evidence for the FeS4 and Fe-O-Fe sites in rubrerythrin from Desulfovibrio vulgaris

Resonance Raman (RR) spectra of the non-heme iron protein rubrerythrin from Desulfovibrio vulgaris unequivocally demonstrate the presence of both a rubredoxin-type FeS4 site and a (mu-oxo)diiron(III) cluster. The RR spectra of rubrerythrin excited at 496.5 and 568.2 nm are dominated by bands similar to those of rubredoxin and conform to the vibrational pattern expected for a distorted FeS4 tetrahedron of an Fe(S-Cys)4 site. Numerous overtone and combination bands of the Fe-S stretches are also observed, and a band at 650 cm-1 is assigned to a cysteine C-S stretching mode. The 374-, 355-, and 340-cm-1 bands, assigned to the three components of the v3(T2) asymmetric FeS4 stretching mode, are 2-8 cm-1 lower than the corresponding frequencies for the Desulfovibrio gigas rubredoxin FeS4 site. Similar differences in frequencies of bands assigned to SFeS bending modes between rubredoxin and rubrerythrin are also detected. These frequency differences imply either slightly weaker Fe-S bonds or subtle conformational differences among the cysteinyl ligands in the rubrerythrin versus rubredoxin FeS4 sites. The RR spectrum of rubrerythrin excited at 406.7 nm shows dramatically diminished intensities of the FeS4 bands with concomitant enhancement of a band at 514 cm-1. This band shifts 18 cm-1 to lower frequency when the protein is dissolved in H(2)18O. The frequency of this band and the 18O isotope shift are those expected for the symmetric Fe-O-Fe stretch of a bent oxo-bridged diiron(III) cluster and indicate that this cluster has at least one additional bridging ligand.(ABSTRACT TRUNCATED AT 250 WORDS)

Localization and specificity of cytochromes and other electron transfer proteins from sulfate-reducing bacteria

Recently data have accumulated concerning the electron transfer chains of sulfate-reducing bacteria in general and of the genus Desulfovibrio in particular. Because of the ever growing number of newly discovered individual redox proteins, it has become essential to try to assign them to physiologically relevant chains. This work presents some new data concerning the localization of these proteins within the bacterial cell and the specificity of electron transfer between the three types of hydrogenases which have been found so far in Desulfovibrio, namely the iron-only, the iron-nickel and the iron-nickel-selenium enzymes. The iron-only hydrogenase reduces cytochromes which have bis-histidinyl heme ligation or histidinyl-methionyl heme ligation. In contrast, the iron-nickel and iron-nickel-selenium hydrogenases cannot reduce cytochromes having a His-Met heme ligation, but are very active toward the cytochromes having a bis-histidinyl ligand. This observation has been used to demonstrate that the tetraheme cytochrome c3 can exchange electrons with the monoheme cytochrome c553. No clear specificity has been established for the reaction of hydrogenases toward the hexadecaheme cytochromes from either D vulgaris or D gigas.

Spectroscopic characterization of 57Fe-reconstituted rubrerythrin, a non-heme iron protein with structural analogies to ribonucleotide reductase

Rubrerythrin, a contraction of rubredoxin and hemerythrin, is the trivial name given to a non-heme iron protein isolated from Desulfovibrio vulgaris (Hildenborough). This protein, whose physiological function is unknown, was first characterized by J. LeGall et al. [(1988) Biochemistry 28, 1636] as being a homodimer of subunit M(r) = 21,900 with four Fe per homodimer distributed as two rubredoxin-type FeS4 centers and one hemerythrin-type diiron cluster. Subsequent analysis of the amino acid sequence of the rubrerythrin gene [Kurtz, D. M., Jr., & Prickril, B.C. (1991) Biochem. Biophys. Res. Commun. 181, 137] revealed an internal homology which suggested that each subunit can accommodate one diiron cluster. Here, we report a procedure for reconstitution of the as-isolated D. vulgaris rubrerythrin with 57Fe. The reconstituted protein was characterized by optical, electron paramagnetic resonance, and Mössbauer spectroscopies. The results indicate successful incorporation of 57Fe into the two types of sites and strongly suggest that each subunit of rubrerythrin can indeed accommodate one diiron cluster as well as one rubredoxin-type center. Combined with amino acid sequence analysis, the spectroscopic characterization further suggests that the rubrerythrin subunit contains a diiron site whose structure is more closely related to that in ribonucleotide reductase than to that in hemerythrin.

Nigerythrin and rubrerythrin from Desulfovibrio vulgaris each contain two mononuclear iron centers and two dinuclear iron clusters

The trivial name 'rubr-erythrin' is a contraction of two other trivial names: rubredoxin (ruber, red) and hemerythrin. It names a protein of undetermined biological function which putatively carries rubredoxin-like mononuclear iron and hemerythrin-like dinuclear iron. The name 'nigerythrin' (niger, black) is an analogy of rubrerythrin. It identifies a second protein of undetermined function which has prosthetic groups similar to rubrerythrin. Rubrerythrin was initially described [LeGall, J., Prickril, B. C., Moura, I., Xavier, A. V., Moura, J. J. G. & Huynh, B.-H. (1988) Biochemistry 27, 1636-1642] as a homodimer with four iron ions arranged into two rubredoxin sites and one inter-subunit dinuclear cluster. Nigerythrin is a novel protein. Here, we report that both proteins are homodimers, each dimer carrying not four but six iron ions in two mononuclear centers and two dinuclear clusters. Rubrerythrin and nigerythrin are probably both located in the cytoplasm; they are differentially characterized with respect to molecular mass, pI, N-terminal sequence, antibody cross-reactivity, optical absorption, EPR spectroscopy, and reduction potentials. All three reduction potentials in both proteins are > +200 mV. These appear too high to be of practical relevance in the cytoplasm of the sulfate reducer Desulfovibrio vulgaris (Hildenborough). We suggest the possibility of a non-redox role for both proteins with all six iron ions in the ferrous state.

Intrapeptide sequence homology in rubrerythrin from Desulfovibrio vulgaris: identification of potential ligands to the diiron site

Two regions in the amino acid sequence of the 21.5 kDa subunit of rubrerythrin from Desulfovibrio vulgaris (Hildenborough) are shown to be homologous. Rubrerythrin contains a non-heme, non-sulfur diiron site, and the internally homologous regions share homology with at least one proposed iron binding region of the component A alpha subunit of methane monooxygenase, which also contains a non-heme, non-sulfur diiron site. Comparison of the rubrerythrin sequences with those of the B2 subunit of E. coli ribonucleotide reductase, whose diiron site ligands have been identified, suggests that two glutamate and two histidine residues at positions 53, 56, 129, and 131 within the rubrerythrin sequence furnish ligands to the diiron site. A pair of EXXH sequences appears to represent a diiron binding motif in all three aforementioned proteins. No propene monooxygenase activity was detected with rubrerythrin using the assay designed to test activity of methane monooxygenase component A in the absence of other protein components.

Cloning and sequencing of the gene for rubrerythrin from Desulfovibrio vulgaris (Hildenborough)

The gene coding for rubrerythrin from the sulfate-reducing bacterium Desulfovibrio vulgaris (Hildenborough) has been cloned and sequenced. Rubrerythrin is known to contain two types of iron sites: one rubredoxin-like FeS4 center in each of the two identical subunits and one hemerythrin-like diiron site per dimer [LeGall, J., et al. (1988) Biochemistry 27, 1636-1642]. The gene encodes a polypeptide of 191 amino acids, and a normal ribosome binding site is located 11-6 base pairs upstream from the translational start of the gene. There is no evidence for the presence of a leader sequence, suggesting a cytoplasmic location for the protein. The rubrerythrin gene is not part of any other known transcriptional unit in the D. vulgaris genome. The nucleotide sequence encodes four Cys residues, the minimum required for ligation to iron in rubredoxin. The pairs of Cys residues occur in Cys-X-X-Cys sequences as they do in rubredoxin, but the 12-residue spacing between the Cys pairs in rubrerythrin is less than half that in rubredoxins. A pair of Arg residues flanking one Cys residue may contribute to the much more positive reduction potential of the rubredoxin-like site in rubrerythrin compared to that of rubredoxin. While the amino acid sequence of rubrerythrin shows no significant overall homology with that of any known protein, the C-terminal region does share some homology with rubredoxin sequences. If folding of the rubredoxin-like amino acid sequence domain in rubrerythrin is similar to that in rubredoxins, then three His residues are brought into proximity.(ABSTRACT TRUNCATED AT 250 WORDS)

Purification and characterization of two proteins with inorganic pyrophosphatase activity from Desulfovibrio vulgaris: rubrerythrin and a new, highly active, enzyme

The inorganic pyrophosphatase activity of a soluble extract from the strict anaerobe, sulfate-reducing, Desulfovibrio vulgaris, is readily resolved into two peaks. After purification, two active proteins with very dissimilar properties are obtained. One is the non-heme iron-containing rubrerythrin, with a specific activity of 350 pyrophosphate hydrolyzed, min-1, mg protein-1. The other, a protein of Mr = 39,000, with a specific activity of 12,000.

A ligand field analysis of the spectroscopic differences between rubredoxin and desulforedoxin in the reduced state

We propose a ligand field model to interpret the differences between the spectroscopic properties of reduced rubredoxin and desulforedoxin. The experimental data are well reproduced by using a common set of ligand field parameters and slightly different values of the mixing parameter theta for the two proteins. In this class of iron-sulfur clusters, the rhombic distortion could be modulated by variations of the S-Fe-S angles.

Rubredoxin from Desulfovibrio gigas. A molecular model of the oxidized form at 1.4 A resolution

The crystal structure of rubredoxin from the sulfate-reducing bacterium Desulfovibrio gigas has been determined at 1.4 A resolution (1 A = 0.1 nm) by X-ray diffraction methods; starting with a model of the isostructural rubredoxin from Desulfovibrio vulgaris. Refinement of the molecular model has been carried out by restrained least-squares techniques and Fourier series calculations. The present model includes a formyl at the N-terminal end and 121 possible sites for solvent molecules with full or partial occupancy, which corresponds to the modeling of nearly all the solvent medium. The crystallographic R factor against the data with 10 A greater than d greater than 1.4 A with F greater than 2 sig(F), is 0.136; and R = 0.140 when all the data are considered. The estimated average root-mean-square (r.m.s.) error on the positional parameters is about 0.12 A. The overall structural features of this molecule are close to those of the two highly refined rubredoxins from Clostridium pasteurianum and D. vulgaris. Superposition of these two molecules on the rubredoxin from D. gigas shows in both cases an overall r.m.s. deviation of 0.5 A for the atoms in the main-chain and of 0.4 A for the atoms in the side-chains that make up the hydrophobic core. The iron atom is co-ordinated to four cysteine sulfur atoms forming an almost regular tetrahedron, with Fe-SG distances ranging from 2.27 A to 2.31 A and angles varying from 103 degrees to 115 degrees. The intramolecular hydrogen-bonding pattern is quite comparable to those found in other proteins refined at high resolution. All the polar groups are involved in hydrogen bonds: intramolecular, intermolecular or with solvent molecules. The main structural differences from the other rubredoxins are in the nature and the distribution of some of the charged residues over the molecular surface. The possible influence of several structural factors on the intramolecular and intermolecular electron transfer properties such as the NH...SG bonds, the solvent exposure of the redox center, and the aromatic core is discussed. The conservation, during evolution, of a ring of acidic residues in the proximity of the FeSG4 center suggests that this ring may be implicated in the recognition processes between rubredoxins and their functional partners.

Tertiary templates for proteins. Use of packing criteria in the enumeration of allowed sequences for different structural classes

We assume that each class of protein has a core structure that is defined by internal residues, and that the external, solvent-contacting residues contribute to the stability of the structure, are of primary importance to function, but do not determine the architecture of the core portions of the polypeptide chain. An algorithm has been developed to supply a list of permitted sequences of internal residues compatible with a known core structure. This list is referred to as the tertiary template for that structure. In general the positions in the template are not sequentially adjacent and are distributed throughout the polypeptide chain. The template is derived using the fixed positions for the main-chain and beta-carbon atoms in the test structure and selected stereochemical rules. The focus of this paper is on the use of two packing criteria: avoidance of steric overlap and complete filling of available space. The program also notes potential polar group interactions and disulfide bonds as well as possible burial of formal charges. Central to the algorithm is the side-chain rotamer library. In an update of earlier studies by others, we show that 17 of the 20 amino acids (omitting Met, Lys and Arg) can be represented adequately by 67 side-chain rotamers. A list of chi angles and their standard deviations is given. The newer, high-resolution, refined structures in the Brookhaven Protein Data Bank show similar mean chi values, but have much smaller deviations than those of earlier studies. This suggests that a rotamer library may be a better structural approximation than was previously thought. In using packing constraints, it has been found essential to include all hydrogen atoms specifically. The "unified atom" representation is not adequate. The permitted rotamer sequences are severely restricted by the main-chain plus beta-carbon atoms of the test structure. Further restriction is introduced if the full set of atoms of the external residues are held fixed, the full-chain model. The space-filling requirement has a major role in restricting the template lists. The preliminary tests reported here make it appear likely that templates prepared from the currently known core structures will be able to discriminate between these structures. The templates should thus be useful in deciding whether a sequence of unknown tertiary structure fits any of the known core classes and, if a fit is found, how the sequence should be aligned in three dimensions to fit the core of that class.(ABSTRACT TRUNCATED AT 400 WORDS)

The electronic and magnetic properties of rubredoxin: a low-temperature magnetic circular dichroism study

Oxidized rubredoxin from Clostridium pasteurianum has been investigated by magnetic circular dichroism (MCD) spectroscopy over the temperature range 1.5 to 150 K and at magnetic fields between 0 and 4.5 tesla. The results show that studies of the temperature and field dependence of MCD transitions afford insight into the polarization of electronic transitions for ground states with large g-value anisotropy, in addition to estimates of ground-state g values and zero-field splitting parameters. In agreement with the assignment made by Eaton and Lovenberg (Eaton, W.A. and Lovenberg, W. (1973) in Iron-Sulfur Proteins, Vol. II (Lovenberg, W., ed.), pp. 131-162, Academic Press, New York), the ultraviolet-visible spectrum of oxidized rubredoxin is assigned to two S----Fe(III) charge transfer transitions (both 6A1----6T2 under tetrahedral symmetry), each spanning a range of 650-430 nm and 430-330 nm, respectively. The observed splitting in each of these transitions is attributed to a predominant axial distortion in the excited state resulting in effective D2d symmetry.

Amino acid sequence of rubredoxin from Desulfovibrio desulfuricans strain 27774

The amino acid sequence of a rubredoxin from Desulfovibrio desulfuricans (strain 27774) has been determined. Comparison with rubredoxins from other species reveals pervasive homology, including the regions known to provide the cysteine ligands to the iron atom in several rubredoxins. Neither an extra cysteinyl residue nor a unique histidyl residue in the new sequence is located in the sequence in such a way that, by homology, a functional role in the structure is suggested.

Hydrogen-1 nuclear magnetic resonance investigation of Clostridium pasteurianum rubredoxin: previously unobserved signals

Previously unobserved signals were located in the 470-MHz 1H NMR spectra of oxidized and reduced rubredoxin (Rd) from Clostridium pasteurianum. When the protein was oxidized, some of the resonances broadened beyond detection. Longitudinal relaxation (T1) measurements identified a number of these peaks as arising from residues close to the paramagnetic iron; these resonances exhibited short T1 values attributable to the dominant electron-nuclear dipolar relaxation mechanism. The chemical shifts of these peaks were not strongly dependent on the oxidation state of the protein, although relative ratios of line widths of several peaks in the spectra of oxidized and reduced Rd suggested localized conformational changes of the protein as a result of oxidation. Furthermore, spectra of the oxidized protein collected in the range 8-60 degrees C revealed no appreciable changes in the chemical shifts of these peaks with temperature. These results seem to point out a negligible dipolar contribution, due to either magnetic anisotropy or zero field splitting, to the observed shifts in the spectrum of oxidized Rd. Resonances were assigned to tyrosine-11 or phenylalanine-49 (but not to either specifically) on the basis of their T1 values and the X-ray diffraction data of the protein molecule [Watenpaugh, K. D., Sieker, L. C., Herriott, J. R., & Jensen, L. H. (1973) Acta Crystallogr., Sect. B: Struct. Crystallogr. Cryst. Chem. B29, 943-956; and a further refinement deposited with the Protein Data Bank]. An upfield-shifted peak at about -1.1 ppm in the spectra of both oxidized and reduced Rd was assigned to a methyl group.(ABSTRACT TRUNCATED AT 250 WORDS)