Two hemes in Bacillus subtilis succinate:menaquinone oxidoreductase (complex II).

Succinate:menaquinone-7 oxidoreductase (complex II) of the Gram-positive bacterium Bacillus subtilis consists of equimolar amounts of three polypeptides; a 65-kDa FAD-containing polypeptide, a 28-kDa iron-sulfur cluster containing polypeptide, and a 23-kDa membrane-spanning cytochrome b558 polypeptide. The enzyme complex was overproduced 2-3-fold in membranes of B. subtilis cells containing the sdhCAB operon on a low copy number plasmid and was purified in the presence of detergent. The cytochrome b558 subunit alone was similarly overexpressed in a complex II deficient mutant and partially purified. Isolated complex II catalyzed the reduction of various quinones and also quinol oxidation. Both activities were efficiently albeit not completely blocked by 2-n-heptyl-4-hydroxyquinoline N-oxide. Chemical analysis demonstrated two protoheme IX per complex II. One heme component was found to have an Em,7.4 of +65 mV and an EPR gmax signal at 3.68, to be fully reducible by succinate, and showed a symmetrical alpha-band absorption peak at 555 nm at 77 K. The other heme component was found to have an Em,7.4 of -95 mV and an EPR gmax signal at 3.42, was not reducible by succinate under steady-state conditions, and showed in the reduced state an apparent split alpha-band absorption peak with maxima at 553 and 558 nm at 77 K. Potentiometric titrations of partially purified cytochrome b558 subunit demonstrated that the isolated cytochrome b558 also contains two hemes. Some of the properties, i.e., the alpha-band light absorption peak at 77 K, the line shapes of the EPR gmax signals, and reactivity with carbon monoxide were observed to be different in B. subtilis cytochrome b558 isolated and in complex II. This suggests that the bound flavoprotein and iron-sulfur protein subunits protect or affect the heme environment in the assembled complex.     

Purification of Two Nitrate Reductases from Xanthomonas maltophilia Grown in Aerobic Cultures

Xanthomonas maltophilia ATCC 17666 is an obligate aerobe that accumulates nitrite when grown on nitrate. Spectra of membranes from nitrate-grown cells exhibited b-type cytochrome peaks and A_615-630 indicative of d-type cytochrome but no absorption peaks corresponding to c-type cytochromes. The nitrate reductase (NR) activity was located in the membrane fraction. Triton X-100-extracted reduced methyl viologen-NRs were purified on DE-52, hydroxylapatite, and Sephacryl S-300 columns to specific activities of 52 to 67 μmol of nitrite formed per min per mg of protein. The cytochrome-containing NR_I separated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis into a 135-kDa α-subunit, a 64-kDa β-subunit, and a 23-kDa γ-subunit with relative band intensities indicative of a 1:1:1 α/β/γ subunit ratio and a M_r of 222,000. The electronic spectrum of dithionite-reduced purified NR displayed peaks at 425, 528, and 558 nm, indicative of the presence of a cytochrome b, an interpretation consistent with the pyridine hemochrome spectrum formed. The cytochrome b of the NR was reduced under anaerobic conditions by menadiol and oxidized by nitrate with the production of nitrite. This NR contained 0.96 Mo, 12.5 nonheme iron, and 1 heme per 222 kDa: molybdopterin was detected with the Neurospora crassa nit-1 assay. A smaller reduced methyl viologen-NR (169 kDa), present in various concentrations in the Triton X-100 preparations, lacked a cytochrome spectrum and did not oxidize menadiol. The characteristics of the NRs and the absence of c-type cytochromes provide insights into why X. maltophilia accumulates nitrite.     

Low temperature electron paramagnetic resonance studies on iron-sulfur centers in cardiac NADH dehydrogenase

EPR signals arising from at least seven iron-sulfur centers were resolved in both reconstitutively active and inactive NADH dehydrogenases, as well as in particulate NADH-UQ reductase (Complex I). EPR lineshapes of individual iron-sulfur centers in the active dehydrogenase are almost unchanged from that in Complex I. Iron-sulfur centers in the inactive dehydrogenase give broadened EPR spectra, suggesting that modification of iron-sulfur active centers is associated with loss of the reconstitutive activity of the dehydrogenase. With the reconstitutively active dehydrogenase, the E_m8.0 value of Center N-2 (iron-sulfur centers associated with NADH dehydrogenase are designated with prefix N) was shifted to a more negative value than in Complex I and restored to the original value on reconstitution of the enzyme with purified phospholipids.     

Chromatographic and protein chemical analysis of the ubiquinol-cytochrome c2 oxidoreductase isolated from Rhodobacter sphaeroides

The ubiquinol-cytochrome c2 oxidoreductase (cytochrome bc1 complex) purified from chromatophores of Rhodobacter sphaeroides consists of four polypeptide subunits corresponding to cytochrome b, c1, and the Rieske iron-sulfur protein, as well as a 14-kDa polypeptide of unknown function, respectively. In contrast, the complex isolated from Rhodospirillum rubrum by the same procedure lacked a polypeptide corresponding to the 14-kDa subunit. Gel-permeation chromatography of the R. sphaeroides cytochrome bc1 complex in the presence of 200 mM NaCl removed the iron-sulfur protein, while the 14-kDa polypeptide remained tightly bound to the cytochromes; this is consistent with the possibility that the latter protein is an authentic component of the complex rather than an artifact of the isolation procedure. The individual polypeptides of the R. sphaeroides complex were purified to homogeneity by gel-permeation chromatography in the presence of 50% aqueous formic acid and their amino acid compositions determined. The 14-kDa polypeptide was found to be rich in charged and polar residues. Edman degradation analysis indicated that its N terminus is blocked and not rendered accessible by de-blocking procedures. Cyanogen bromide cleavage gave rise to a blocked N-terminal fragment as well as a C-terminal peptide comprising more than one-third of the protein. Gas-phase sequence analysis of this peptide established a sequence of 48 residues and identified a putative trans-membrane segment near the C terminus. The blocked N-terminal fragment was cleaved at tryptophan with BNPS-skatole. The resulting peptides, together with tryptic fragments derived from the intact protein, yielded additional sequence information; however, none of the sequences exhibited significant homologies to any known proteins. Tryptic fragments were also used to generate sequence information for cytochrome c1.     

Electron paramagnetic resonance spectroscopic characterization of dimethyl sulfoxide reductase of Escherichia coli

The electron transfer centers in dimethyl sulfoxide reductase were examined by EPR spectroscopy in membranes of the overproducing Escherichia coli strain HB101/pDMS159, and in purified enzyme. Iron-sulfur clusters of the [4Fe-4S] type and a molybdenum center were detected in the protein, which comprises three different subunits: DmsA, -B, and -C. The intensity of the reduced iron-sulfur clusters corresponded to 3.82 +/- 0.5 spins per molecule. The dithionite-reduced clusters were reoxidized by DMSO or TMAO. The enzyme, as prepared, showed a spectrum of Mo(V), which resembles the high-pH form of E. coli nitrate reductase. The Mo(V) detected by EPR was absent from a mutant which does not assemble the molybdenum cofactor. In these cases, the levels of EPR-detectable iron-sulfur clusters in the cells were increased. Extracts from HB101/pDMS159 enriched in DmsA showed more Mo(V) signals and considerably less iron-sulfur. These results are in agreement with predictions from amino acid sequence comparisons, that the molybdenum center is located in DmsA, while four iron-sulfur clusters are in DmsB. The midpoint potentials of the molybdenum and iron-sulfur clusters in the various preparations were determined by mediator titrations. The iron-sulfur signals could be best fitted by four clusters, with midpoint potentials spread between -50 and -330 mV. The midpoint potentials of the iron-sulfur clusters and Mo(V) species were pH dependent. In addition, all potentials became less negative in the presence of the detergent Triton X-100. Observation of relaxation enhancement of the Mo(V) species by the reduced [4Fe-4S] clusters indicated that the centers are in proximity within the protein.     

Bacterial expression of the molybdenum domain of assimilatory nitrate reductase: production of both the functional molybdenum-containing domain and the nonfunctional tungsten analog

Assimilatory NADH:nitrate reductase (EC 1.6.6.1), a complex molybdenum-, cytochrome b(557)- and FAD-containing protein, catalyzes the regulated and rate-limiting step in the utilization of inorganic nitrogen by higher plants. To facilitate structure/function studies of the individual molybdenum center, we have developed bacterial expression systems for the heterologous production of the 541 residue amino-terminal, molybdenum center-containing domain of spinach nitrate reductase either as a six-histidine-tagged variant or as a glutathione-S-transferase-tagged fusion protein. Expression of the his-tagged molybdenum domain in Escherichia coli BL21(DE3) cells under anaerobic conditions yielded a 55-kDa domain with a specific activity of 1.5 micromol NO(3)(-) consumed/min/nmol enzyme and with a K(mapp)(NO(3)(-)) of 8 mciroM. In contrast, expression of the molybdenum domain as a GST-tagged fusion protein in E. coli TP1000(MobA(-) strain) cells under aerobic conditions yielded an 85-kDa fusion protein with a specific activity of 10.8 micromol NO(3)(-) consumed/min/nmol enzyme and with a K(mapp)(NO(3)(-)) of 12 microM. Fluorescence analysis indicated that both forms of the molybdenum domain contained the cofactor, MPT, although the MPT content was higher in the GST-fusion domain. Inductively coupled plasma mass spectrometric analysis of both the his-tagged and GST-fusion protein domain samples indicated Mo/protein ratios of 0.44 and 0.93, respectively, confirming a very high level of Mo incorporation in the GST-fusion protein. Expression of the GST-fusion protein in TP1000 cells in the presence of elevated tungsten concentrations resulted in an 85-kDa fusion protein that contained MPT but which was devoid of nitrate-reducing activity. Partial reduction of the molybdenum domain resulted in the generation of an axial Mo(V) EPR species with g values of 1.9952, 1.9693, and 1.9665, respectively, and exhibiting superhyperfine coupling to a single exchangeable proton, analogous to that previously observed for the native enzyme. In contrast, the tungsten-substituted MPT-containing domain yielded a W(V) EPR species with g values of 1.9560, 1.9474, and 1.9271, respectively, with unresolved superhyperfine interaction. NADH:nitrate reductase activity could be reconstituted using the GST-molybdenum domain fusion protein in the presence of the recombinant forms of the spinach nitrate reductase' flavin- and heme-containing domains.     

Quinol-cytochrome c oxidoreductase from the thermophilic bacterium PS3. Purification and properties of a cytochrome bc1(b6f) complex

A quinol-cytochrome c oxidoreductase (cytochrome bc1 complex) has been purified from plasma membranes of a thermophilic Bacillus, PS3, by ion-exchange chromatography in the presence of Triton X-100. The purified enzyme shows absorption bands at 561-562 nm and 553 nm at room temperature, and 560, 551, and 547 nm at 80 K upon reduction, and gives an ESR signal similar to that of a Rieske-type iron sulfur center. Its contents of protohemes, heme c, and non-heme iron are about 23, 10, and 21 nmol/mg of protein, respectively. The enzyme consists of four polypeptides with molecular masses of 29, 23, 21, and 14 kDa judging from their electrophoretic mobilities in the presence of sodium lauryl sulfate. Since the staining intensities of the respective bands are almost proportional to their molecular masses, the monomer complex (87 kDa) of the subunits probably consists of a cytochrome b having two protohemes, a cytochrome c1 and an Fe2-S2-type iron sulfur center. The 29 and 21 kDa subunits were identified as cytochromes c1 and b, respectively, and the 23-kDa subunit is probably an iron-sulfur protein, since the 14-kDa polypeptide can be removed with 3 M urea without reducing the content of non-heme iron. Several characteristics of the subunits and chromophores indicate that the PS3 enzyme is rather similar to cytochrome b6f (a bc1 complex equivalent) of chloroplasts and Cyanobacteria. The PS3 complex catalyzes reduction of cytochrome c with various quinol compounds in the presence of P-lipids and menaquinone. The turnover number at pH 6.8 was about 5 s-1 at 40 degrees C and 50 s-1 at 60 degrees C. The enzyme is heat-stable up to 65 degrees C.     

Xanthine dehydrogenase from Drosophila melanogaster: purification and properties of the wild-type enzyme and of a variant lacking iron-sulfur centers.

Xanthine dehydrogenase has been purified to homogeneity by conventional procedures from the wild-type strain of the fruit fly Drosophila melanogaster, as well as from a rosy mutant strain (E89----K, ry5231) known to carry a point mutation in the iron-sulfur domain of the enzyme. The wild-type enzyme had all the specific properties that are peculiar to the molybdenum-containing hydroxylases. It had normal contents of molybdenum, the pterin molybdenum cofactor, FAD, and iron-sulfur centers. EPR studies showed its molybdenum center to be quite indistinguishable from that of milk xanthine oxidase. As isolated, only about 10% of the enzyme was present in the functional form, with most or all of the remainder as the inactive desulfo form. It is suggested that this may be present in vivo. Extensive proteolysis accompanied by the development of oxidase activity took place during isolation, but dehydrogenase activity was retained. EPR properties of the reduced iron-sulfur centers, Fe-SI and Fe-SII, in the enzyme are very similar to those of the corresponding centers in milk xanthine oxidase. The E89----K mutant enzyme variant was in all respects closely similar to the wild-type enzyme, with the exception that it lacked both of the iron-sulfur centers. This was established both by its having the absorption spectrum of a simple flavoprotein and by the complete absence of EPR signals characteristic of iron-sulfur centers in the reduced enzyme. Despite the lack of iron-sulfur centers, the mutant enzyme had xanthine:NAD+ oxidoreductase activity indistinguishable from that of the wild-type enzyme. Stopped-flow measurements indicated that, as for the wild-type enzyme, reduction of the mutant enzyme was rate-limiting in turnover. Thus, the iron-sulfur centers appear irrelevant to the normal turnover of the wild-type enzyme with these substrates. However, activity to certain oxidizing substrates, particularly phenazine methosulfate, is abolished in the mutant enzyme variant. This is one of the first examples of deletion by genetic means of iron-sulfur centers from an iron-sulfur protein. The relevance of our findings both to the roles of iron-sulfur centers in other systems and to the nature of the oxidizing substrate for the Drosophila enzyme in vivo are briefly discussed.     

Effect of papain digestion on polypeptide subunits and electron-transfer pathways in mitochondrial b-c1 complex

Papain digestion of subunits of mitochondrial b-c1 complex (ubiquinol-cytochrome-c reductase) isolated from bovine heart and its impact on redox and proton-motive activity of the whole complex were investigated. A 5-min incubation of the oxidized enzyme with papain resulted in digestion of core protein II and the 14-kDa subunit, and limited digestion of the iron-sulfur protein. This was accompanied by a small inhibition of the rate of electron flow and a marked inhibition of proton translocation with decrease of the H+/e- ratio for proton pumping. When papain treatment was performed on the b-c1 complex pre-reduced with ascorbate, partial proteolysis of the iron-sulfur protein and the 14-kDa subunit was greatly accelerated and the electron transfer activity was more markedly inhibited. In all the conditions tested, digestion of the Rieske iron-sulfur protein paralleled the inhibition of reductase activity. Under ascorbate-reduced conditions, papain digestion of the complex gave rise to an alteration of the EPR line shape of the iron-sulfur cluster, namely a broadening and shift of the gx negative peak and destabilization of the protein-bound antimycin-sensitive semiquinone. The latter paralleled the decrease in electron transfer activity and inhibition of antimycin-sensitive cytochrome-b reduction. The results obtained indicate the following. 1. Core protein II and the 14-kDa protein may contribute to the proton-conducting pathway(s) from the matrix aqueous phase to the primary protolytic redox center (protein-bound semiquinone/quinone couple). 2. The iron-sulfur protein contributes, together with other protein(s) (the 14-kDa subunit), to the stabilization of the protein-bound antimycin-sensitive semiquinone species in a protein pocket in the complex. 3. Reduction of the high-potential redox centers induces a change in the quaternary structure of the complex which results in an enhanced surface exposure of segments of the 14-kDa protein and the iron-sulfur protein.     

EPR and redox characterization of iron-sulfur centers in nitrate reductases A and Z from Escherichia coli. Evidence for a high-potential and a low-potential class and their relevance in the electron-transfer mechanism.

The redox properties of the iron-sulfur centers of the two nitrate reductases from Escherichia coli have been investigated by EPR spectroscopy. A detailed study of nitrate reductase A performed in the range +200 mV to -500 mV shows that the four iron-sulfur centers of the enzyme belong to two classes with markedly different redox potentials. The high-potential group comprises a [3Fe-4S] and a [4Fe-4S] cluster whose midpoint potentials are +60 mV and +80 mV, respectively. Although these centers are magnetically isolated, they are coupled by a significant anticooperative redox interaction of about 50 mV. The [4Fe-4S]1+ center occurs in two different conformations as shown by its composite EPR spectrum. The low-potential group contains two [4Fe-4S] clusters with more typical redox potentials (-200 mV and -400 mV). In the fully reduced state, the three [4Fe-4S]1+ centers are magnetically coupled, leading to a broad featureless spectrum. The redox behaviour of the high-pH EPR signal given by the molybdenum cofactor was also studied. The iron-sulfur centers of the second nitrate reductase of E. coli, nitrate reductase Z, exhibit essentially the same characteristics than those of nitrate reductase A, except that the midpoint potentials of the high-potential centers appear negatively shifted by about 100 mV. From the comparison between the redox centers of nitrate reductase and of dimethylsulfoxide reductase, a correspondence between the high-potential iron-sulfur clusters of the two enzymes can be proposed.     

Nitrite oxidoreductase from Nitrobacter hamburgensis: redox centers and their catalytic role

Nitrite oxidoreductase was isolated from mixotrophically grown cells of Nitrobacter hamburgensis. The enzyme purified from heat treated membranes was homogeneous by the criteria of polyacrylamide gel electrophoresis and size exclusion chromatography. The monomeric form consisted of two subunits with M_r 115000 and 65000, respectively. The dimeric form of the enzyme contained 0.70 molybdenum, 23.0 iron, 1.76 zinc, and 0.89 copper. The catalytically active enzyme was investigated by visible and electron paramagnetic resonance spectroscopy (EPR) under oxidizing (as isolated), reducing (dithionite), and turnover (nitrite) conditions. As isolated the enzyme exhibited a complex set of EPR signals between 5–75 K, originating from several ironsulfur and molybdenum (V) centers. Addition of the substrate nitrite, or the reducing agent dithionite resulted in a set of new resonances. The molybdenum and the iron-sulfur centers of nitrite oxidoreductase from Nitrobacter hamburgensis were involved in the transformation of nitrite to nitrate.Abbreviations EPR electron paramagnetic resonance - ICP-AES inductively coupled plasma-atomic emission spectrometry - NaP_i sodium phosphate - PAGE polyacrylamide gel electrophoresis - SDS sodium dodecyl sulfate     

Cytochrome b from Escherichia coli nitrate reductase. Its properties and association with the enzyme complex

Membrane-bound nitrate reductase purified from Escherichia coli was resolved into two separate forms. The majority of the enzyme complex had a subunit composition of 2A:2B:4C, exhibited cytochrome b spectra, and was found to be stable after purification. A second form of nitrate reductase activity was a modified complex with a subunit composition of 2A:2B and lacked cytochrome. The subunit B from this complex was altered in its mobility on sodium dodecyl sulfate-polyacrylamide gels. The cytochrome-containing enzyme had 28 +/- 2 atoms of iron and 1.35 atoms of molybdenum whereas iron and molybdenum in cytochromeless enzyme were 24 +/- 2 atoms and 1.18 atoms/molecule, respectively. Besides cytochrome-containing nitrate reductase, two other cytochrome b-containing fractions were also resolved. These were cytochrome b associated with formate dehydrogenase and a novel cytochrome b with reduced absorption maxima at 430, 529.5, and 560 nm. Nitrate reductase cytochrome b (subunit C) was isolated from subunits A and B as a partially denatured form and its renaturation was accomplished by dialyzing against hemin. The renatured cytochrome yielded absorption spectra similar to the holoenzyme. The pure cytochrome aggregated upon heating, even in the presence of sodium dodecyl sulfate. It had a high isoelectric point (pH greater than 9.5) and had 45% hydrophobic amino acids.     

A homologue of a nuclear-coded iron-sulfur protein subunit of bovine mitochondrial complex I is encoded in chloroplast genomes

The chloroplast genomes of Marchantia polymorpha, Nicotiana tabacum, and Oryza sativa contain open reading frames (ORFs or potential genes) encoding homologues of some of the subunits of mitochondrial NADH:ubiquinone oxidoreductase (complex I). Seven of these subunits (ND1-ND4, ND4L, ND5, and ND6) are products of the mitochondrial genome, and two others (the 49- and 30-kDa components of the iron-sulfur protein fraction) are nuclear gene products. These findings have been taken to indicate the presence in chloroplasts of an enzyme related to complex I, possibly an NAD(P)H:plastoquinone oxidoreductase, participating in chlororespiration. This view is reinforced by the present work in which we have shown that chloroplast genomes encode a homologue of the 23-kDa subunit, another nuclear-encoded component of bovine complex I. The 23-kDa subunit is in the hydrophobic protein fraction of the enzyme, the residuum after removal of the flavoprotein and iron-sulfur protein fractions. The sequence motif CysXXCysXXCysXXXCysPro, which provides ligands for tetranuclear iron-sulfur centers in ferredoxins, occurs twice in its polypeptide chain and is evidence of two associated 4Fe-4S clusters. This is the only iron-sulfur protein identified so far in the hydrophobic protein fraction of complex I, and so it is possible that one of these centers is that known as N-2, the donor of electrons to ubiquinone. The sequence of the 23-kDa subunit is closely related to potential proteins, which also contain the cysteine-rich sequence motifs, encoded in the frxB ORFs in chloroplast genomes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification of a three-subunit ubiquinol-cytochrome c oxidoreductase complex from Paracoccus denitrificans

A ubiquinol-cytochrome c oxidoreductase (cytochrome bc1) complex has been purified from the plasma membrane of aerobically grown Paracoccus denitrificans by extraction with dodecyl maltoside and ion exchange chromatography of the extract. The purified complex contains two spectrally and thermodynamically distinct b cytochromes, cytochrome c1, and a Rieske-type iron-sulfur protein. Optical spectra indicate absorption peaks at 553 nm for cytochrome c1 and at 560 and 566 nm for the high and low potential hemes of cytochrome b. The spectrum of cytochrome b560 is shifted to longer wavelength by antimycin. The Paracoccus bc1 complex consists of only three polypeptide subunits. On the basis of their relative electrophoretic mobilities, these have apparent molecular masses of 62, 39, and 20 kDa. The 62- and 39-kDa subunits have been identified as cytochromes c1 and b, respectively. The 20-kDa subunit is assumed to be the Rieske-type iron-sulfur protein on the basis of its molecular weight and the presence of an EPR-detectable signal typical of this iron-sulfur protein in the three-subunit complex. The Paracoccus bc1 complex catalyzes reduction of cytochrome c by ubiquinol with a turnover of 470 s-1. This activity is inhibited by antimycin, myxothiazol, stigmatellin, and hydroxyquinone analogues of ubiquinone, all of which inhibit electron transfer in the cytochrome bc1 complex of the mitochondrial respiratory chain. The electron transfer functions of the Paracoccus complex thus appear to be similar, and possibly identical, to those of the bc1 complex of eukaryotic mitochondria. The Paracoccus bc1 complex has the simplest subunit composition and one of the highest turnover numbers of any bc1 complex isolated from any species to date. These properties suggest that the structural requirements for electron transfer from ubiquinol to cytochrome c are met by a small number of peptides and that the "extra" peptides occurring in the mitochondrial bc1 complexes serve some other function(s), possibly in biogenesis or insertion of the complex into that organelle.     

The formate complex of the cytochrome bo quinol oxidase of Escherichia coli exhibits a 'g = 12' EPR feature analogous to that of 'slow' cytochrome oxidase.

The cytochrome bo quinol oxidase of Escherichia coli is homologous in sequence and in structure to cytochrome aa3 type cytochrome oxidase in subunit I, which contains the catalytic core. The cytochrome bo enzyme forms a formate complex which exhibits 'g = 12' and 'g = 2.9' EPR signals at X band; similar signals have previously been observed only in association with the 'slow' and formate-ligand states of cytochrome oxidase. These signals arise from transitions within integral spin multiples identified with the homologous heme-copper binuclear catalytic centers in both enzymes.     

Photosynthetic electron-transfer reactions in the green sulfur bacterium Chlorobium vibrioforme: evidence for the functional involvement of iron-sulfur redox centers on the acceptor side of the reaction center.

The green sulfur bacterium Chlorobium vibrioforme was cultured in the presence of ethylene to selectively inhibit the synthesis of the chlorosome antenna BChl d. Use of these cells as starting material simplified the isolation of a photoactive antenna-depleted membrane fraction without the use of high concentrations of detergents. The preparation had a BChl alpha/P840 of 50, and the spectral properties were similar to those of preparations isolated from cells grown with a normal complement of chlorosomes. The membrane preparation was active in NADP+ photoreduction. This indicated that the fraction contained reaction centers with complete electron-transfer sequences which were then characterized further by flash kinetic spectrophotometry and EPR. We confirmed that cytochrome c553 is the endogenous donor to P840+, and at room temperature we observed a recombination reaction between the reduced terminal acceptor and P840+ with a t1/2 = 7 ms. Oxidative degradation of iron-sulfur centers using low concentrations of chaotropic salts introduced a faster recombination reaction of t1/2 = 50 microseconds which was lost at higher concentrations of chaotrope, indicating the participation of another iron-sulfur redox center earlier than the terminal acceptor. Cluster insertion using ferric chloride and sodium sulfide in the presence of 2-mercaptoethanol restored both the 50-microseconds and 7-ms recombination reactions, allowing definitive assignments of these centers as iron-sulfur centers. Following the suggestion of Nitschke et al. [(1990) Biochemistry 29, 3834-3842], we associate these two kinetic phases to back-reactions between P840+ and iron-sulfur centers FX and FAFB, respectively. The iron-sulfur cluster degradation and reconstitution protocols also led to inhibition and restoration of NADP+ photoreduction by the membrane preparation, providing unequivocal evidence for the function of the centers FX and FAFB in the physiological electron-transfer sequence on the acceptor side of the Chlorobium reaction center. At 77 K we observed a recombination reaction of t1/2 = 20 ms that we suggest occurs between Fx- and P840+. Degradation of the iron-sulfur clusters resulted in replacement of the 20-ms phase with a faster reaction of t1/2 = 80 microseconds that was most likely a recombination between the early acceptor A1- and P840+ or decay of 3P840. Analysis of the iron-sulfur centers in the preparation by EPR at cryogenic temperature supports the optical measurements. EPR signals originating from the terminal acceptor(s) were not observed following treatment of the membrane preparation by chaotropes, and a modified signal was restored following cluster reinsertion.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mitochondrial respiratory chain of Tetrahymena pyriformis: the properties of submitochondrial particles and the soluble b and c type pigments.

Submitochondrial particles isolated from Tetrahymena pyriformis contain essentially the same redox carriers as those present in parental mitochondria: at pH 7.2 and 22 degree C there are two b-type pigments with half-reduction potentials of --0.04 and --0.17 V, a c-type cytochrome with a half reduction potential of 0.215 V, and a two-component cytochrome a2 with Em7.2 of 0.245 and 0.345 V. EPR spectra of the aerobic submitochondrial particles in the absence of substrate show the presence of low spine ferric hemes with g values at 3.4 and 3.0, a high spin ferric heme with g =6, and a g=2.0 signal characteristic of oxidized copper. In the reduced submitochondrial particles signals of various iron-sulfur centers are observed. Cytochrome c553 is lost from mitochondria during preparation of the submitochondrial particles. The partially purified cytochrome c553 is a negatively charged protein at neutral pH with an Em7.2 of 0.25 V which binds to the cytochrome c-depleted Tetrahymena mitochondria in the amount of 0.5 nmol/mg protein with KD of 0.8.10(-6) M. Reduced cytochrome c553 serves as an efficient substrate in the reaction with its own oxidase. The EPR spectrum of the partially purified cytochrome c553 shows the presence of a low spin ferric heme with the dominant resonance signal at g=3.28. A pigment with an alpha absorption maximum at 560 nm can be solubilized from the Tetrahymena cells with butanol. This pigments has a molecular weight of approx. 18 000, and Em7.2 of--0.17 V and exhibits a high spin ferric heme signal at g=6.     

The Tmc complex from Desulfovibrio vulgaris hildenborough is involved in transmembrane electron transfer from periplasmic hydrogen oxidation

Three membrane-bound redox complexes have been reported in Desulfovibrio spp., whose genes are not found in the genomes of other sulfate reducers such as Desulfotalea psycrophila and Archaeoglobus fulgidus. These complexes contain a periplasmic cytochrome c subunit of the cytochrome c(3) family, and their presence in these organisms probably correlates with the presence of a pool of periplasmic cytochromes c(3), also absent in the two other sulfate reducers. In this work we report the isolation and characterization of the first of such complexes, Tmc from D. vulgaris Hildenborough, which is associated with the tetraheme type II cytochrome c(3). The isolated Tmc complex contains four subunits, including the TpIIc(3) (TmcA), an integral membrane cytochrome b (TmcC), and two cytoplasmically predicted proteins, an iron-sulfur protein (TmcB) and a tryptophan-rich protein (TmcD). Spectroscopic studies indicate the presence of eight hemes c and two hemes b in the complex pointing to an alpha(2)betagammadelta composition (TmcA(2)BCD). EPR analysis reveals the presence of a [4Fe4S](3+) center and up to three other iron-sulfur centers in the cytoplasmic subunit. Nearly full reduction of the redox centers in the Tmc complex could be obtained upon incubation with hydrogenase/TpIc(3), supporting the role of this complex in transmembrane transfer of electrons resulting from periplasmic oxidation of hydrogen.     

Isolation and characterization of nitrate reductase from the halophilic sulfur-oxidizing bacterium <Emphasis Type="Italic">Thioalkalivibrio nitratireducens</Emphasis>

A novel nitrate reductase (NR) was isolated from cell extract of the haloalkaliphilic bacterium Thioalkalivibrio nitratireducens strain ALEN 2 and characterized. This enzyme is a classical nitrate reductase containing molybdopterin cofactor in the active site and at least one iron-sulfur cluster per subunit. Mass spectrometric analysis showed high homology of NR with the catalytic subunit NarG of the membrane nitrate reductase from the moderately halophilic bacterium Halomonas halodenitrificans. In solution, NR exists as a monomer with a molecular weight of 130–140 kDa and as a homotetramer of about 600 kDa. The specific nitrate reductase activity of NR is 12 μmol/min per mg protein, the maximal values being observed within the neutral range of pH. Like other membrane nitrate reductases, NR reduces chlorate and is inhibited by azide and cyanide. It exhibits a higher thermal stability than most mesophilic enzymes.