Electron-paramagnetic-resonance spectroscopy of Bacillus subtilis cytochrome b558 in Escherichia coli membranes and in succinate dehydrogenase complex from Bacillus subtilis membranes.

Cytochrome b558 of the Bacillus subtilis succinate dehydrogenase complex was studied by electron-paramagnetic-resonance (EPR) spectroscopy. The cytochrome amplified in Escherichia coli membranes by expression of the cloned cytochrome gene and in the succinate dehydrogenase complex immunoprecipitated from solubilized B. subtilis membranes, respectively, is shown to be low spin with a highly anisotropic (gmax approximately equal to 3.5) EPR signal. The amino acid residues most likely forming fifth and sixth axial ligands to heme in cytochrome b558 are discussed on the basis of the EPR signal and the recently determined gene sequence (K. Magnusson, M. Philips, J.R. Guest, and L. Rutberg, J. Bacteriol. 166:1067-1071, 1986) and in comparison with other b-type cytochromes.     

Orientation of succinate dehydrogenase and cytochrome b558 in the Bacillus subtilis cytoplasmic membrane.

The orientation of the three subunits of the membrane-bound succinate dehydrogenase (SDH)-cytochrome b558 complex in Bacillus subtilis was studied in protoplasts ("right side out") and isolated membranes (random orientation), using immunoadsorption and surface labeling with [35S]diazobenzenesulfonate. Anti-SDH antibodies were adsorbed by isolated membranes but not by protoplasts. The SDH Mr 65,000 flavoprotein subunit was labeled with [35S]diazobenzenesulfonate in isolated membranes but not in protoplasts. The flavoprotein subunit is thus located on the cytoplasmic side of the membrane. The location of the SDH Mr 28,000 iron-protein subunit was not definitely established, but most probably the iron-protein subunit also is located on the cytoplasmic side of the membrane. Antibodies were not obtained to the hydrophobic cytochrome b558. The cytochrome was strongly labeled with [35S]diazobenzenesulfonate in protoplasts, and labeling was also obtained with isolated membranes. Cytochrome b558 is thus exposed on the outside of the membrane. In B. subtilis SDH binds specifically to cytochrome b558, which suggests that the cytochrome is exposed also on the cytoplasmic side of the membrane. The results obtained suggest that the B. subtilis SDH is exclusively located on the cytoplasmic side of the membrane where it is bound to cytochrome b558, which spans the membrane.     

Succinate dehydrogenase mutants of Bacillus subtilis lacking covalently bound flavin in the flavoprotein subunit

Succinate dehydrogenase consists of two unequal subunits; Fp and Ip. An FAD group is covalently linked to a histidyl residue in the Fp subunit. The mechanism by which flavin is attached to protein is not known. Covalently bound flavin was studied in wild-type and succinate-dehydrogenase-negative Bacillus subtilis. The Fp subunit of succinate dehydrogenase was found to be the only (major) flavinylated protein in the cell. Mutants lacking covalently bound flavin and still containing the Fp polypeptide are described. It is shown that the flavin is not essential for assembly and membrane binding of succinate dehydrogenase in B. subtilis.     

Bacillus subtilis mutant succinate dehydrogenase lacking covalently bound flavin: identification of the primary defect and studies on the iron-sulfur clusters in mutated and wild-type enzyme

Succinate dehydrogenase consists of two protein subunits and contains one FAD and three iron-sulfur clusters. The flavin is covalently bound to a histidine in the larger, Fp, subunit. The reduction oxidation midpoint potentials of the clusters designated S-1, S-2, and S-3 in Bacillus subtilis wild-type membrane-bound enzyme were determined as +80, -240, and -25 mV, respectively. Magnetic spin interactions between clusters S-1 and S-2 and between S-1 and S-3 were detected by using EPR spectroscopy. The point mutations of four B. subtilis mutants with defective Fp subunits were mapped. The gene of the mutant specifically lacking covalently bound flavin in the enzyme was cloned. The mutation was determined from the DNA sequence as a glycine to aspartate substitution at a conserved site seven residues downstream from the histidine that binds the flavin in wild-type enzyme. The redox midpoint potential of the iron-sulfur clusters and the magnetic spin interactions in mutated succinate dehydrogenases were indistinguishable from the those of the wild type. This shows that flavin has no role in the measured magnetic spin interactions or in the structure and stability of the iron-sulfur clusters. It is concluded from sequence and mutant studies that conserved amino acid residues around the histidyl-FAD are important for FAD binding; however, amino acids located more than 100 residues downstream from the histidyl in the Fp subunit can also effect flavinylation.     

Nucleotide sequence of the gene for cytochrome b558 of the Bacillus subtilis succinate dehydrogenase complex.

The nucleotide sequence was determined for the first part of the Bacillus subtilis sdh operon. An open reading frame corresponding to the structural gene, sdhA, for cytochrome b558 was identified. The predicted molecular weight of the cytochrome (excluding the N-terminal methionine) is 22,770. It is a very hydrophobic protein with five probable membrane-spanning segments. There is little homology between the B. subtilis cytochrome b558 and cytochrome b of mitochondrial complex III from different organisms or between cytochrome b558 and the hydrophobic sdhC and sdhD peptides of the Escherichia coli sdh operon. About 30 bases downstream of the sdhA stop codon, a new open reading frame starts. The nucleotide sequence predicts the presence of a typical flavin-binding peptide which identifies this reading frame as part of the sdhB gene. Seven bases upstream of the sdhA initiation codon ATG there is a typical B. subtilis ribosome binding site (free energy of interaction, -63 kJ), and further upstream, tentative sigma 55 and sigma 32 promoter sequences were found. The upstream region also contains two 12-base-long direct repeats; their significance is unknown.     

Identification of the covalently bound flavin of thiamin dehydrogenase.

Thiamin dehydrogenase, a flavoprotein isolated from an unidentified soil bacterium, contains 1 mol of covalently bound FAD/mol of enzyme. A flavin peptide, isolated from tryptic-chymotryptic digests of the enzyme and hydrolyzed to the FMN level, shows a pH-dependent fluorescence yield being maximal at pH 3.5 to 4.0 and decreasing over 90% at pH 7.5 with a pKa of 5.8. Acid hydrolysis of the peptide results in an aminoacylflavin which shows a pKa of fluorescence quenching of 5.2. Absorption and electron paramagnetic resonance spectral data show the covalent substituent to be at the 8alpha position of the flavin as is the case with all known enzymes containing covalently bound flavin. The aminoacylflavin gives a negative Pauly reaction but yields 1 mol of histidine on drastic acid hydrolysis thus showing an imidazole ring nitrogen as the 8alpha substituent of the flavin. The aminoacylflavin differs from synthetic 8alpha-[N(3)-histidyl]riboflavin or its acid-modified form in pKa of fluorescence quenching, in electrophoretic mobility, in being reduced by borohydride, and in being labile to storage, yielding 8-formylriboflavin. In all of these properties, however, the 8alpha-histidylriboflavin isolated from thiamin dehydrogenase is indistinguishable from 8alpha-[N(1)-histidyl]riboflavin. It is therefore concluded that the FAD moiety of thiamin dehydrogenase is covalently linked via the 8alpha-methylene group to the N(1) position of the imidazole ring of histidine.     

Fumarate reductase mutants of Escherichia coli that lack covalently bound flavin

Menaquinol-fumarate oxidoreductase of Escherichia coli is a four-subunit membrane-bound complex that catalyzes the final step in anaerobic respiration when fumarate is the terminal electron acceptor. The catalytic domain of fumarate reductase consists of the FrdA subunit, which contains the active site, and a FAD prosthetic group covalently attached to His44, plus the FrdB subunit which contains at least two of the three nonidentical iron-sulfur clusters of the enzyme. To examine the role of covalently bound FAD in enzyme activity and electron transfer during anaerobic cell growth, site-directed mutagenesis was used to alter His44 of the FrdA subunit to a Ser, Cys, or Tyr residue. The resulting mutant enzyme complexes that were synthesized associated normally with the cytoplasmic membrane, but had decreased ability (greater than 70%) to reduce fumarate with reduced benzyl viologen, an artificial electron donor of low redox potential (Em = -359 mV; Clark, W. M. (1972) Oxidation-Reduction Potentials of Organic Systems, Robert E. Kreiger Publishing Co., Melbourne, FL). Even lower activities were measured when the higher potential, natural electron donor menaquinol was used, which, however, correlated with the slower growth rates of the different mutant complexes. In contrast to the normal enzyme, the mutant enzyme complexes were unable to oxidize succinate. Substitution of Arg for His44 produced a totally inactive enzyme complex that permitted no cell growth on nonfermentable substrates with fumarate as electron acceptor. All four mutant complexes contained noncovalently bound FAD in stoichiometric amounts. These data indicate a unique role of the 8 alpha-[N(3)-histidyl] FAD linkage in enzyme activity, by raising the redox potential of free FAD to permit reduction by both menaquinol and succinate.     

Low temperature EPR and MCD studies on cytochrome b-558 of the Bacillus subtilis succinate: quinone oxidoreductase indicate bis-histidine coordination of the heme iron

Bacillus subtilis cytochrome b-558 was expressed in high amounts in Escherichia coli, solubilized from membranes with detergent and purified free from other hemoproteins. The cytochrome possibly contains two heme groups. To determine the axial ligands to the low-spin heme and the heme rhombicity, the cytochrome was analyzed using low-temperature electron paramagnetic resonance (EPR) and magnetic circular dichroism (MCD) spectroscopy. The combined results exclude bis-methionine, bis-lysine and histidine-methionine coordination. Bis-histidine coordination of the heme(s) with a near perpendicular orientation of the imidazole planes is strongly suggested by the highly axial low-spin EPR signals and the intense near infrared MCD spectrum (delta epsilon = 380 M-1.cm-1 at 4.2 K and 5 T) of the charge-transfer band at 1600 nm.     

Glucose dehydrogenase from Bacillus subtilis expressed in Escherichia coli. I: Purification, characterization and comparison with glucose dehydrogenase from Bacillus megaterium

Escherichia coli containing the Bacillus subtilis glucose dehydrogenase gene on a plasmid (prL7) was used to produce the enzyme in high quantities. Gluc-DH-S was purified from the cell extract by (NH4)2SO4-precipitation, ion-exchange chromatography and Triazine-dye chromatography to a specific activity of 375 U/mg. The enzyme was apparently homogenous on SDS-PAGE with a subunit molecular mass of 31.5 kDa. Investigation of Gluc-DH-S was performed for comparison with the corresponding properties of Gluc-DH-M. The limiting Michaelis constant at pH 8.0 for NAD+ is Ka = 0.11 mM and for D-glucose Kb = 8.7 mM. The dissociation constant for NAD+ is Kia = 17.1 mM. Similar to Gluc-DH-M, Gluc-DH-S is inactivated by dissociation under weak alkaline conditions at pH 9.0. Complete reactivation is attained by readjustment to pH 6.5. Ultraviolet absorption, fluorescence and CD-spectra of native Gluc-DH-S, as well as fluorescence- and CD-backbone-spectra of the dissociated enzyme were nearly identical to the corresponding spectra of Gluc-DH-M. The aromatic CD-spectrum of dissociated Gluc-DH-S was different, representing a residual ellipticity of tryptophyl moieties in the 290-310 nm region. Density gradient centrifugation proved that this behaviour is due to the formation of inactive dimers in equilibrium with monomers after dissociation. In comparison to Gluc-DH-M, the kinetics of inactivation as well as the time-dependent change of fluorescence intensity at pH 9.0 of Gluc-DH-S showed a higher velocity and a changed course of the dissociation process.     

Production of completely flavinylated histamine dehydrogenase, unique covalently bound flavin, and iron-sulfur cluster-containing enzyme of nocardioides simplex in Escherichia coli, and its properties

The hmd gene of histamine dehydrogenase from Nocardioides simplex was overexpressed in Escherichia coli, and the resulting enzyme was purified to homogeneity. The purified recombinant enzyme is almost identical with the native enzyme in view of molecular weight and specific activity, and is stoichiometrically assembled with the three cofactors 6-S-cysteinyl FMN, 4Fe-4S cluster, and ADP.     

Reactivity of the Bacillus subtilis succinate dehydrogenase complex with quinones.

The succinate dehydrogenase isolated from Bacillus subtilis was found to catalyze the oxidation of succinate with hydrophilic quinones. Either naphthoquinones or benzoquinones served as acceptors. The enzyme activity increased with the redox potential of the quinone. The highest turnover number was commensurate with that of the bacterial succinate respiration in vivo. The succinate dehydrogenase was similarly active in fumarate reduction with quinols. The highest activity was obtained with the most electronegative quinol. The fumarate reductase isolated from Wolinella succinogenes catalyzed succinate oxidation with quinones and fumarate reduction with the corresponding quinols at activities similar to those of the B. subtilis enzyme. Succinate oxidation by the lipophilic quinones, ubiquinone or vitamin K-1, was monitored as cytochrome c reduction using proteoliposomes containing succinate dehydrogenase together with the cytochrome bc1 complex. The activity with ubiquinone or vitamin K-1 was commensurate with the succinate respiratory activity of bacteria or of the bacterial membrane fraction. The results suggest that menaquinone is involved in the succinate respiration of B. subtilis, although its redox potential is unfavorable.     

Relation of phospholipase D activity to the decay of succinate dehydrogenase and of covalently bound flavin in yeast cells undergoing glucose repression

The disappearance of succinate dehydrogenase activity and of protein-bound histidyl flavin were studied in aerobic yeast cells incubated with high glucose concentrations. The decay of succinate dehydrogenase activity, covalently bound flavin, and of respiration is prevented by cycloheximide but not by chloramphenicol. During this decay there is a large increase in mitochondrial phospholipase D activity; the appearance of this enzyme is also prevented by cycloheximide. It seems possible, therefore, that the formation of phospholipase D may be important in triggering the disappearance of covalently bound flavin, succinate dehydrogenase, and of other mitochondrial enzymes during glucose repression of aerobic yeast cells.