The Carboxin-Binding Site on Paracoccus denitrificans Succinate:Quinone Reductase Identified by Mutations

Succinate:quinone reductase catalyzes electron transfer from succinate to quinone in aerobic respiration. Carboxin is a specific inhibitor of this enzyme from several different organisms. We have isolated mutant strains of the bacterium Paracoccus denitrificans that are resistant to carboxin due to mutations in the succinate:quinone reductase. The mutations identify two amino acid residues, His228 in SdhB and Asp89 in SdhD, that most likely constitute part of a carboxin-binding site. This site is in the same region of the enzyme as the proposed active site for ubiquinone reduction. From the combined mutant data and structural information derived from Escherichia coli and Wolinella succinogenes quinol:fumarate reductase, we suggest that carboxin acts by blocking binding of ubiquinone to the active site. The block would be either by direct exclusion of ubiquinone from the active site or by occlusion of a pore that leads to the active site.     

Extracellular S100A4 stimulates the migration rate of astrocytic tumor cells by modifying the organization of their actin cytoskeleton

An overview of the present knowledge about succinate:quinone oxidoreductase in Paracoccus denitrificans and Bacillus subtilis is presented. P. denitrificans contains a monoheme succinate:ubiquinone oxidoreductase that is similar to that of mammalian mitochondria with respect to composition and sensitivity to carboxin. Results obtained with carboxin-resistant P. denitrificans mutants provide information about quinone-binding sites on the enzyme and the molecular basis for the resistance. B. subtilis contains a diheme succinate:menaquinone oxidoreductase whose activity is dependent on the electrochemical gradient across the cytoplasmic membrane. Data from studies of mutant variants of the B. subtilis enzyme combined with available crystal structures of a similar enzyme, Wolinella succinogenes fumarate reductase, substantiate a proposed explanation for the mechanism of coupling between quinone reductase activity and transmembrane potential.     

Flutolanil and carboxin resistance in<Emphasis Type="Italic"> Coprinus cinereus</Emphasis> conferred by a mutation in the cytochrome<Emphasis Type="Italic"> b</Emphasis><Subscript>560</Subscript> subunit of succinate dehydrogenase complex (Complex II)

A gene that confers resistance to the systemic fungicide flutolanil was isolated from a mutant strain of the basidiomycete Coprinus cinereus. The flutolanil resistance gene was mapped to a chromosome of approximately 3.2 Mb, and a chromosome-specific cosmid library was constructed. Two cosmid clones that were able to transform a wild-type, flutolanil-sensitive, strain of C. cinereus to resistance were isolated from the library. Analysis of a subclone containing the resistance gene revealed the presence of the sdhC gene, which encodes the cytochrome b ₅₆₀ subunit of the succinate dehydrogenase (SDH) complex (Complex II) in the mitochondrial membrane. Comparison between the sdhC gene of a wild-type strain and that of a mutant strain revealed a single point mutation, which results in the replacement of Asn by Lys at position 80. Measurements of succinate-cytochrome c reductase activity in the transformants with mutant sdhC gene(s) suggest that flutolanil resistance of the fungus is caused by a decrease in the affinity of the SDH complex for flutolanil. This sdhC mutation also conferred cross-resistance against another systemic fungicide, carboxin, an anilide that is structurally related to flutolanil. In other organisms carboxin resistance mutations have been found in the genes sdhB and sdhD, but this is the first demonstration that a mutation in sdhC can also confer resistance. The mutant gene cloned in this work can be utilized as a dominant selectable marker in gene manipulation experiments in C. cinereus.Communicated by E. Cerdá-Olmedo     

Studies on the succinate dehydrogenating system. II. Reconstitution of succinate-ubiquinone reductase from the soluble components

1. A protein fraction containing three polypeptides (the major one with M_r < 13 000) was isolated by means of Triton X-100 extraction of submitochondrial particles specifically treated to remove succinate dehydrogenase.2. The mixing of the protein fraction with the soluble reconstitutively active succinate dehydrogenase results in formation of highly active succinate-DCIP reductase which is sensitive to thenoyltrifluoroacetone or carboxin.3. The maximal turnover number of succinate dehydrogenase in the succinate-DCIP reductase reaction revealed in the presence of a saturating amount of the protein fraction is slightly higher than that measured with phenazine methosulfate as artificial electron acceptor.4. The protein fraction greatly increases the stability of soluble succinate dehydrogenase under aerobic conditions.5. The titration of soluble succinate dehydrogenase by the protein fraction shows that smaller amounts of the protein fraction are required to block the reduction of ferrycyanide by Hipip center than that required to reveal the maximal catalytic capacity of the enzyme.6. The apparent K_m of the reconstituted system for DCIP depends on the amount of protein fraction; the more protein fraction added to the enzyme, the lower the K_m value obtained.7. A comparison of different reconstituted succinate-ubiquinone reductases described in the literature is presented and the possible arrangement of the native and reconstituted succinate-ubiquinone region of the respiratory chain is discussed.     

Kinetics of ubiquinone reduction by the resolved succinate: Ubiquinone reductase

A significant lag in the thenoyltrifluoroacetone (TTFA)-sensitive succinate: ubiquinone reductase activity was observed when a ubiquinone-deficient resolved preparation of the enzyme was assayed in the presence of exogenous ubiquinone-2 (Q2) and 2,6-dichlorophenolindophenol. No such lag was seen when the free radical of N,N,N′,N′-tetramethyl-p-phenylenediamine (Wurster's Blue) was used as the terminal electron acceptor, or when the reduction of Q2 was directly measured. The apparent Km value for exogenous Q2 was determined in the Q2-mediated TTFA-sensitive succinate: Wurster's Blue reductase reaction. When the enzyme activity was measured directly by monitoring Q2 reduction without terminal acceptors, the time course of the reaction deviated from zero-order kinetics at Q2 concentrations which were much higher than those expected from the KQ2m value determined in the presence of Wurster's Blue. The time course of Q2 reduction fits a curve describing a competitive interrelationship between oxidized and reduced Q2 at the specific binding site. The data obtained are in agreement with the Q-pool behavior of ubiquinone in mitochondrial membranes and suggest that the rate of ubiquinone reduction by succinate is dependent on the ratio.     

A new point mutation in the iron–sulfur subunit of succinate dehydrogenase confers resistance to boscalid in Sclerotinia sclerotiorum

Research has established that mutations in highly conserved amino acids of the succinate dehydrogenase (SDH) complex in various fungi confer SDH inhibitor (SDHI) resistance. For Sclerotinia sclerotiorum (Lib.) de Bary, a necrotrophic fungus with a broad host range and a worldwide distribution, boscalid resistance has been attributed to the mutation H132R in the highly conserved SdhD subunit protein of the SDH complex. In our previous study, however, only one point mutation, A11V in SdhB (GCA to GTA change in SdhB), was detected in S. sclerotiorum boscalid‐resistant (BR) mutants. In the current study, replacement of the SdhB gene in a boscalid‐sensitive (BS) S. sclerotiorum strain with the mutant SdhB gene conferred resistance. Compared with wild‐type strains, BR and GSM (SdhB gene in the wild‐type strain replaced by the mutant SdhB gene) mutants were more sensitive to osmotic stress, lacked the ability to produce sclerotia and exhibited lower expression of the pac1 gene. Importantly, the point mutation was not located in the highly conserved sequence of the iron–sulfur subunit of SDH. These results suggest that resistance based on non‐conserved vs. conserved protein domains differs in mechanism. In addition to increasing our understanding of boscalid resistance in S. sclerotiorum, the new information will be useful for the development of alternative antifungal drugs.     

Aerobic inactivation of fumarate reductase from Escherichia coli by mutation of the [3Fe-4S]-quinone binding domain.

Fumarate reductase from Escherichia coli functions both as an anaerobic fumarate reductase and as an aerobic succinate dehydrogenase. A site-directed mutation of E. coli fumarate reductase in which FrdB Pro-159 was replaced with a glutamine or histidine residue was constructed and overexpressed in a strain of E. coli lacking a functional copy of the fumarate reductase or succinate dehydrogenase complex. The consequences of these mutations on bacterial growth, assembly of the enzyme complex, and enzymatic activity were investigated. Both mutations were found to have no effect on anaerobic bacterial growth or on the ability of the enzyme to reduce fumarate compared with the wild-type enzyme. The FrdB Pro-159-to-histidine substitution was normal in its ability to oxidize succinate. In contrast, however, the FrdB Pro-159-to-Gln substitution was found to inhibit aerobic growth of E. coli under conditions requiring a functional succinate dehydrogenase, and furthermore, the aerobic activity of the enzyme was severely inhibited upon incubation in the presence of its substrate, succinate. This inactivation could be prevented by incubating the mutant enzyme complex in an anaerobic environment, separating the catalytic subunits of the fumarate reductase complex from their membrane anchors, or blocking the transfer of electrons from the enzyme to quinones. The results of these studies suggest that the succinate-induced inactivation occurs by the production of hydroxyl radicals generated by a Fenton-type reaction following introduction of this mutation into the [3Fe-4S] binding domain. Additional evidence shows that the substrate-induced inactivation requires quinones, which are the membrane-bound electron acceptors and donors for the succinate dehydrogenase and fumarate reductase activities. These data suggest that the [3Fe-4S] cluster is intimately associated with one of the quinone binding sites found n fumarate reductase and succinate dehydrogenase.     

Variation in proton donor/acceptor pathways in succinate:quinone oxidoreductases

The anaerobically expressed fumarate reductase and aerobically expressed succinate dehydrogenase from Escherichia coli comprise two different classes of succinate:quinone oxidoreductases (SQR), often termed respiratory complex II. The X-ray structures of both membrane-bound complexes have revealed that while the catalytic/soluble domains are structurally similar the quinone binding domains of the enzyme complexes are significantly different. These results suggest that the anaerobic and aerobic forms of complex II have evolved different mechanisms for electron and proton transfer in their respective membrane domains.     

Carboxin-Resistant Mutant of Ustilago maydis Is Impaired in Its Pathogenicity for Zea mays

We analyzed the pathogenicity of chitin synthetase (chs) disruptants of Ustilago maydis obtained with the carboxin-resistant or the hygromycin-resistant cassettes. We found that only chitin synthetase (chs) mutants obtained by gene disruption with the carboxin resistance cassette lost their virulence to maize (Zea mays) seedlings. Carboxin is a systemic fungicide that inhibits respiration by preventing the oxidation of succinate. We demonstrated that carboxin-resistant transformants were affected in the levels of succinate dehydrogenase and respiratory activities when compared with hygromycin-resistant disruptants. We propose that loss of virulence in the carboxin-resistant transformants is owing to loss of respiratory fitness, which probably represents an important component of virulence in this fungus. Received: 13 May 1999 / Accepted: 26 June 1999     

Biochemical and biophysical characterization of succinate: quinone reductase from Thermus thermophilus

Enzymes serving as respiratory complex II belong to the succinate:quinone oxidoreductases superfamily that comprises succinate:quinone reductases (SQRs) and quinol:fumarate reductases. The SQR from the extreme thermophile Thermus thermophilus has been isolated, identified and purified to homogeneity. It consists of four polypeptides with apparent molecular masses of 64, 27, 14 and 15kDa, corresponding to SdhA (flavoprotein), SdhB (iron-sulfur protein), SdhC and SdhD (membrane anchor proteins), respectively. The existence of [2Fe-2S], [4Fe-4S] and [3Fe-4S] iron-sulfur clusters within the purified protein was confirmed by electron paramagnetic resonance spectroscopy which also revealed a previously unnoticed influence of the substrate on the signal corresponding to the [2Fe-2S] cluster. The enzyme contains two heme b cofactors of reduction midpoint potentials of -20mV and -160mV for b(H) and b(L), respectively. Circular dichroism and blue-native polyacrylamide gel electrophoresis revealed that the enzyme forms a trimer with a predominantly helical fold. The optimum temperature for succinate dehydrogenase activity is 70°C, which is in agreement with the optimum growth temperature of T. thermophilus. Inhibition studies confirmed sensitivity of the enzyme to the classical inhibitors of the active site, as there are sodium malonate, sodium diethyl oxaloacetate and 3-nitropropionic acid. Activity measurements in the presence of the semiquinone analog, nonyl-4-hydroxyquinoline-N-oxide (NQNO) showed that the membrane part of the enzyme is functionally connected to the active site. Steady-state kinetic measurements showed that the enzyme displays standard Michaelis-Menten kinetics at a low temperature (30°C) with a K(M) for succinate of 0.21mM but exhibits deviation from it at a higher temperature (70°C). This is the first example of complex II with such a kinetic behavior suggesting positive cooperativity with k' of 0.39mM and Hill coefficient of 2.105. While the crystal structures of several SQORs are already available, no crystal structure of type A SQOR has been elucidated to date. Here we present for the first time a detailed biophysical and biochemical study of type A SQOR-a significant step towards understanding its structure-function relationship.     

Retention of heme in axial ligand mutants of succinate-ubiquinone xxidoreductase (complex II) from Escherichia coli

Succinate-ubiquinone oxidoreductase (SdhCDAB, complex II) from Escherichia coli is a four-subunit membrane-bound respiratory complex that catalyzes ubiquinone reduction by succinate. In the E. coli enzyme, heme b(556) is ligated between SdhC His(84) and SdhD His(71). Contrary to a previous report (Vibat, C. R. T., Cecchini, G., Nakamura, K., Kita, K., and Gennis, R. B. (1998) Biochemistry 37, 4148-4159), we demonstrate the presence of heme in both SdhC H84L and SdhD H71Q mutants of SdhCDAB. EPR spectroscopy reveals the presence of low spin heme in the SdhC H84L (g(z) = 2.92) mutant and high spin heme in the SdhD H71Q mutant (g = 6.0). The presence of low spin heme in the SdhC H84L mutant suggests that the heme b(556) is able to pick up another ligand from the protein. CO binds to the reduced form of the mutants, indicating that it is able to displace one of the ligands to the low spin heme of the SdhC H84L mutant. The g = 2.92 signal of the SdhC H84L mutant titrates with a redox potential at pH 7.0 (E(m)(,7)) of approximately +15 mV, whereas the g = 6.0 signal of the SdhD H71Q mutant titrates with an E(m)(,7) of approximately -100 mV. The quinone site inhibitor pentachlorophenol perturbs the heme optical spectrum of the wild-type and SdhD H71Q mutant enzymes but not the SdhC H84L mutant. This finding suggests that the latter residue also plays an important role in defining the quinone binding site of the enzyme. The SdhC H84L mutation also results in a significant increase in the K(m) and a decrease in the k(cat) for ubiquinone-1, whereas the SdhD H71Q mutant has little effect on these parameters. Overall, these data indicate that SdhC His(84) has an important role in defining the interaction of SdhCDAB with both quinones and heme b(556).     

DNA-mediated transformation system in a bipolar basidiomycete, <Emphasis Type="Italic">Pholiota microspora</Emphasis> (<Emphasis Type="Italic">P. nameko</Emphasis>)

We cloned a gene encoding the succinate dehydrogenase iron-sulfur protein subunit (sip) from a bipolar mushroom, Pholiota microspora, and introduced a point mutation that confers carboxin resistance into this gene. Using this homologous selective marker and also a heterologous drug selective marker, the hygromycin B phosphotransferase gene (hph), we successfully constructed a DNA-mediated transformation system in P. microspora. Both these selection markers have high transformation efficiency: the efficiency of carboxin resistance transformation was about 88.8 transformants/μg pMBsip2 DNA using 5 × 10⁶ protoplasts in regeneration plates containing 1.0 μg/ml carboxin, and the efficiency of hygromycin B resistance transformation was about 122.4 transformants/μg pMBhph1 DNA using 5 × 10⁶ protoplasts in regeneration plates containing 150 μg/ml hygromycin B. Southern hybridization analysis showed that the introduced sequence (mutant sip or hph) was integrated into the chromosomal DNA in these transformants with a copy number of one or more.     

Characterization of the quinone reductase activity of the ferric reductase B protein from Paracoccus denitrificans

The ferric reductase B (FerB) protein of Paracoccus denitrificans exhibits activity of an NAD(P)H: Fe(III) chelate, chromate and quinone oxidoreductase. Sequence analysis places FerB in a family of soluble flavin-containing quinone reductases. The enzyme reduces a range of quinone substrates, including derivatives of 1,4-benzoquinone and 1,2- and 1,4-naphthoquinone, via a ping-pong kinetic mechanism. Dicoumarol and Cibacron Blue 3GA are competitive inhibitors of NADH oxidation. In the case of benzoquinones, FerB apparently acts through a two-electron transfer process, whereas in the case of naphthoquinones, one-electron reduction takes place resulting in the formation of semiquinone radicals. A ferB mutant strain exhibited an increased resistance to 1,4-naphthoquinone, attributable to the absence of the FerB-mediated redox cycling. The ferB promoter displayed a high basal activity throughout the growth of P. denitrificans, which could not be further enhanced by addition of different types of naphthoquinones. This indicates that the ferB gene is expressed constitutively.     

Carboxins: Powerful selective inhibitors of succinate oxidation in animal tissues

Carboxin (5,6-dihydro-2-methyl-1,4-oxathiin-3-carboxanilide) is a systemic fungicide, reported to inhibit succinate oxidation in certain fungi, particularly $\text{Ustilago}\text{maydis}$ (corn smut). In the present study the action of carboxin and of other oxathiin derivatives on beef heart succinate dehydrogenase has been investigated. Carboxins inhibited the same activities to the same extent as thenoyltrifluoroacetone (TTF) but at much lower concentrations. For 14 carboxin derivatives the inhibition constants (concentration required to inhibit 50% of the carboxin-sensitive activity) ranged from 2 × 10^?8 to 2 × 10^?6$\text{M}$. Like TTF, carboxin derivatives did not inhibit soluble succinate dehydrogenase but inhibited the reduction of coenzyme Q analogs, of 2,6-dichlorophenolindophenol, and of phenazine methosulfate (PMS) in Complex II preparations. The same reactions and succinoxidase activity were also inhibited in inner membranes (ETP). In ETP only ～ 50% of the succinate-PMS activity was carboxin sensitive, the same fraction as is inhibited by TTF or is lost on extraction of coenzyme Q and on incubation with cyanide. While the inhibition of PMS reduction by carboxin was largely or entirely competitive in Complex II, it was predominantly non-competitive in ETP at low concentrations. Some other carboxin derivatives gave mixed inhibition patterns for PMS reduction in ETP even at low inhibitor concentrations. The complex inhibition pattern in the PMS assay seems more compatible with conformation changes affecting activity than with loss of a reaction site for PMS.     

Mode of action of oxathiin systemic fungicides. V. Effect on electron transport system of Ustilago maydis and Saccharomyces cerevisiae

The systemic fungicide carboxin (5,6-dihydro-2-methyl-1,4-oxathiin-3-carboxanilide) at 100 mum inhibited succinate cytochrome c reductase in mitochondria from Ustilago maydis and Saccharomyces cerevisiae. It did not have any effect on reduced nicotinamide adenine dinucleotide (NADH) cytochrome c reductase. Succinate coenzyme Q reductase was also inhibited, but NADH coenzyme Q reductase was not. When dichlorophenolindophenol (DCIP) was used as the terminal acceptor of electrons from the oxidation of succinate, carboxin was very effective in inhibiting succinate-DCIP reductase. Carboxin was inhibitory to succinic dehydrogenase assayed with phenazine methosulfate plus DCIP when intact mitochondria were used as the enzyme source but not when solubilized enzyme was used. The main site of action of carboxin, therefore, appears to lie between succinate and coenzyme Q. The dioxide analogue of carboxin was also effective in inhibiting succinate-cytochrome c reductase, succinate-coenzyme Q reductase, or succinate-DCIP reductase, whereas the monoxide analogue was less effective in inhibiting these enzymes.     

An Escherichia coli mutant defective in the NAD-dependent succinate semialdehyde dehydrogenase

Escherichia coli mutants, unable to grown on 4-hydroxyphenylacetate, have been isolated and found to be defective in the NAD-dependent succinate semialdehyde dehydrogenase. When the mutants are grown with 4-aminobutyrate as sole nitrogen source an NAD-dependent succinate semialdehyde dehydrogenase seen in the parental strain is absent but, as in the parental strain, an NADP-dependent enzyme is induced. Growth of the mutants is inhibited by 4-hydroxyphenylacetate due to the accumulation of succinate semialdehyde. The mutants are more sensitive to inhibition by exogenous succinate semialdehyde than is the parental strain. Secondary mutants able to grow in the presence of 4-hydroxyphenylacetate but still unable to use it as sole carbon source were defective in early steps of 4-hydroxyphenylacetate catabolism and so did not form succinate semialdehyde from 4-hydroxyphenylacetate. The gene encoding the NAD-dependent succinate semialdehyde dehydrogenase of Escherichia coli K-12 was located at min 34.1 on the genetic map.     

A succinate-oxidising nitrate reductase is located at the plasma membrane of plant roots

Plasma-membrane-bound nitrate reductase (PM-NR) is located in roots and leaves of tobacco (Nicotiana tabacum L. cv. Samsun) and reduces nitrate with NADH as electron donor. When plasma membranes were prepared under specific protecting conditions, a PM-NR of roots was detected that accepts electrons from succinate to reduce nitrate. Comparison between the succinate dehydrogenase of mitochondria and the succinate-oxidising PM-NR of roots indicated that they are two different enzymes. Partial purification of the nitrate reductase forms by anion-exchange chromatography indicated that succinate and NADH supply electrons to the same plasma-membrane-bound protein. Received: 27 March 1997 / Accepted: 9 April 1997     

Isolation and characterization of Paracoccus denitrificans mutants with increased conjugation frequencies and pleiotropic loss of a (nGATCn) DNA-modifying property

A selection scheme was devised to isolate Paracoccus denitrificans mutants with increased recipient qualities in transfer experiments, using broad host range plasmids. In some of the mutants obtained, a DNA modifying activity that prevents the activity of the restriction endonucleases BamHI and BglII on isolated P. denitrificans DNA had simultaneously been lost. From a detailed analysis of the restriction properties of the enzymes SAU3 AI, MboI and DpnI, it was concluded that a subset of GATC sequences in P. denitrificans DNA may be methylated at an unusual position. It was concluded that P. denitrificans possesses at least one potent host-dependent restriction/modification system which affects conjugation. In addition to the class of restriction-defective mutants, at least one other class of enhanced transfer mutants with unknown defect(s) was isolated. Strains, in which the two mutant classes were combined, exhibited transfer frequencies which were significantly higher than strains containing either mutation alone. Such double mutant strains appeared to be well suited for future experiments like complementation analysis, transposon mutagenesis and gene replacement by homologous recombination.     

A durohydroquinone oxidation site in the mitochondrial transport chain

Although duroquinone had little effect upon NADH oxidation in neutral lipid depleted mitochondria, durohydroquinone was oxidized by ETP at a rate sensitive to antimycin A. Fractionation of mitochondria into purified enzyme systems showed durohydroquinone: cytochromec reductase to be concentrated in NADH: cytochromec reductase, absent in succinate:cytochromec reductase, and decreased in reduced coenzyme Q:cytochromec reductase. Durohydroquinone oxidation could be restored by recombining reduced coenzyme Q:cytochromec reductase with NADH:coenzyme Q reductase. Pentane extraction had no effect upon either durohydroquinone or reduced coenzyme Q₁₀ oxidation, indicating lack of a quinone requirement between cytochromesb andc. Both chloroquine diphosphate and acetone (96%) treatment irreversibly inhibited NADH but not succinate oxidation. Neither reagents had any effect upon durohydroquinone oxidation but both inhibited reduced coenzyme Q₁₀ oxidation 50%, indicating a site of action between Q₁₀ and duroquinone sites. Loss of chloroquine sensitive reduced coenzyme Q₁₀ oxidation after acetone extraction suggests two sites for Q₁₀ before cytochromeb.     

Purification and characterization of succinate:menaquinone oxidoreductase from <Emphasis Type="Italic">Corynebacterium glutamicum</Emphasis>

Succinate:menaquinone oxidoreductase from Corynebacterium glutamicum, a high-G+C, Gram-positive bacterium, was purified to homogeneity. The enzyme contained two heme B molecules and three polypeptides with apparent molecular masses of 67, 29 and 23 kDa, which corresponded to SdhA (flavoprotein), SdhB (iron–sulfur protein), and SdhC (membrane anchor protein), respectively. In non-denaturating polyacrylamide gel electrophoresis, the enzyme migrated as a single band with an apparent molecular mass of 410 kDa, suggesting that it existed as a trimer. The succinate dehydrogenase activity assayed using 2,3-dimethoxy-5-methyl-6-decyl-1,4-benzoquinone and 2,6-dichloroindophenol as the electron acceptor was inhibited by 2-n-heptyl-4-hydroxyquinoline N-oxide (HQNO), and the Dixon plots were biphasic. In contrast, the succinate dehydrogenase activity assayed using phenazine methosulfate and 2,6-dichloroindophenol was inhibited by p-benzoquinone and not by HQNO. These findings suggested that the C. glutamicum succinate:menaquinone oxidoreductase had two quinone binding sites. In the phylogenetic tree of SdhA, Corynebacterium species do not belong to the high-G+C group, which includes Mycobacterium tuberculosis and Streptomyces coelicolor, but are rather close to the group of low-G+C, Gram-positive bacteria such as Bacillus subtilis. This situation may have arisen due to the horizontal gene transfer.