Your search keyword '"Electron Transport Complex II chemistry"' showing total 87 results

51. Mutation of the heme axial ligand of Escherichia coli succinate-quinone reductase: implications for heme ligation in mitochondrial complex II from yeast.

Author

Maklashina E, Rajagukguk S, McIntire WS, and Cecchini G

Subjects

Amino Acid Motifs, Amino Acid Sequence, Amino Acid Substitution, Animals, Base Sequence, Cattle, DNA Primers genetics, Electron Transport Complex II metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Heme chemistry, In Vitro Techniques, Kinetics, Ligands, Mitochondria enzymology, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Mutation, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Sequence Homology, Amino Acid, Species Specificity, Spectrophotometry, Electron Transport Complex II chemistry, Electron Transport Complex II genetics, Escherichia coli enzymology, Escherichia coli genetics, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae genetics

Abstract

A b-type heme is conserved in membrane-bound complex II enzymes (SQR, succinate-ubiquinone reductase). The axial ligands for the low spin heme b in Escherichia coli complex II are SdhC His84 and SdhD His71. E. coli SdhD His71 is separated by 10 residues from SdhD Asp82 and Tyr83 which are essential for ubiquinone catalysis. The same His-10x-AspTyr motif dominates in homologous SdhD proteins, except for Saccharomyces cerevisiae where a tyrosine is at the axial position (Tyr-Cys-9x-AspTyr). Nevertheless, the yeast enzyme was suggested to contain a stoichiometric amount of heme, however, with the Cys ligand in the aforementioned motif acting as heme ligand. In this report, the role of Cys residues for heme coordination in the complex II family of enzymes is addressed. Cys was substituted to the SdhD-71 position and the yeast Tyr71Cys72 motif was also recreated. The Cys71 variant retained heme, although it was high spin, while the Tyr71Cys72 mutant lacked heme. Previously the presence of heme in S. cerevisiae was detected by a spectral peak in fumarate-oxidized, dithionite-reduced mitochondria. Here it is shown that this method must be used with caution. Comparison of bovine and yeast mitochondrial membranes shows that fumarate induced reoxidation of cytochromes in both SQR and the bc1 complex (ubiquinol-cytochrome c reductase). Thus, this report raises a concern about the presence of low spin heme b in S. cerevisiae complex II., (Published by Elsevier B.V.)

Published

2010

52. Mitochondrial respiratory chain super-complex I-III in physiology and pathology.

Author

Lenaz G, Baracca A, Barbero G, Bergamini C, Dalmonte ME, Del Sole M, Faccioli M, Falasca A, Fato R, Genova ML, Sgarbi G, and Solaini G

Subjects

Aging pathology, Aging physiology, Animals, Electron Transport, Electron Transport Chain Complex Proteins chemistry, Electron Transport Complex I chemistry, Electron Transport Complex I physiology, Electron Transport Complex II chemistry, Electron Transport Complex II physiology, Electron Transport Complex III chemistry, Electron Transport Complex III physiology, Humans, Kinetics, Mitochondrial Diseases pathology, Mitochondrial Diseases physiopathology, Models, Biological, Protein Multimerization, Protein Stability, Reactive Oxygen Species metabolism, Electron Transport Chain Complex Proteins physiology, Mitochondria pathology, Mitochondria physiology

Abstract

Recent investigations by native gel electrophoresis showed the existence of supramolecular associations of the respiratory complexes, confirmed by electron microscopy analysis and single particle image processing. Flux control analysis demonstrated that Complex I and Complex III in mammalian mitochondria kinetically behave as a single unit with control coefficients approaching unity for each component, suggesting the existence of substrate channeling within the super-complex. The formation of this supramolecular unit largely depends on the lipid content and composition of the inner mitochondrial membrane. The function of the super-complexes appears not to be restricted to kinetic advantages in electron transfer: we discuss evidence on their role in the stability and assembly of the individual complexes, particularly Complex I, and in preventing excess oxygen radical formation. There is increasing evidence that disruption of the super-complex organization leads to functional derangements responsible for pathological changes, as we have found in K-ras-transformed fibroblasts., (Copyright © 2010 Elsevier B.V. All rights reserved.)

Published

2010

53. Peroxynitrite-mediated oxidative modifications of complex II: relevance in myocardial infarction.

Author

Zhang L, Chen CL, Kang PT, Garg V, Hu K, Green-Church KB, and Chen YR

Subjects

Amino Acid Sequence, Animals, Cell Hypoxia, Cyclic N-Oxides metabolism, Cysteine metabolism, Disulfides metabolism, Electron Transport Complex II chemistry, Flavin-Adenine Dinucleotide metabolism, Humans, Molecular Sequence Data, Molecular Weight, Muscle Cells metabolism, Muscle Cells pathology, Myocardial Infarction enzymology, Myocardial Infarction pathology, Oxidation-Reduction, Peroxynitrous Acid biosynthesis, Protein Subunits chemistry, Protein Subunits metabolism, Rats, Rats, Sprague-Dawley, Tyrosine metabolism, Electron Transport Complex II metabolism, Myocardial Infarction metabolism, Peroxynitrous Acid metabolism

Abstract

Increased O(2)(*-) and NO production is a key mechanism of mitochondrial dysfunction in myocardial ischemia/reperfusion injury. In complex II, oxidative impairment and enhanced tyrosine nitration of the 70 kDa FAD-binding protein occur in the post-ischemic myocardium and are thought to be mediated by peroxynitrite (OONO(-)) in vivo [Chen, Y.-R., et al. (2008) J. Biol. Chem. 283, 27991-28003]. To gain deeper insights into the redox protein thiols involved in OONO(-)-mediated oxidative post-translational modifications relevant in myocardial infarction, we subjected isolated myocardial complex II to in vitro protein nitration with OONO(-). This resulted in site-specific nitration at the 70 kDa polypeptide and impairment of complex II-derived electron transfer activity. Under reducing conditions, the gel band of the 70 kDa polypeptide was subjected to in-gel trypsin/chymotrypsin digestion and then LC-MS/MS analysis. Nitration of Y(56) and Y(142) was previously reported. Further analysis revealed that C(267), C(476), and C(537) are involved in OONO(-)-mediated S-sulfonation. To identify the disulfide formation mediated by OONO(-), nitrated complex II was alkylated with iodoacetamide. In-gel proteolytic digestion and LC-MS/MS analysis were conducted under nonreducing conditions. The MS/MS data were examined with MassMatrix, indicating that three cysteine pairs, C(306)-C(312), C(439)-C(444), and C(288)-C(575), were involved in OONO(-)-mediated disulfide formation. Immuno-spin trapping with an anti-DMPO antibody and subsequent MS was used to define oxidative modification with protein radical formation. An OONO(-)-dependent DMPO adduct was detected, and further LC-MS/MS analysis indicated C(288) and C(655) were involved in DMPO binding. These results offered a complete profile of OONO(-)-mediated oxidative modifications that may be relevant in the disease model of myocardial infarction.

Published

2010

54. Functional and composition differences between mitochondrial complex II in Arabidopsis and rice are correlated with the complex genetic history of the enzyme.

Author

Huang S, Taylor NL, Narsai R, Eubel H, Whelan J, and Millar AH

Subjects

Adenosine Triphosphate metabolism, Arabidopsis genetics, Cluster Analysis, Electron Transport Complex II chemistry, Electron Transport Complex II genetics, Enzyme Stability, Gene Expression, Oryza genetics, Oxygen metabolism, Plant Proteins chemistry, Plant Proteins genetics, Protein Subunits chemistry, Protein Subunits genetics, Protein Subunits metabolism, Sequence Analysis, Protein, Species Specificity, Succinic Acid metabolism, Arabidopsis enzymology, Electron Transport Complex II physiology, Mitochondria metabolism, Oryza enzymology, Plant Proteins physiology

Abstract

Complex II plays a central role in mitochondrial metabolism as a component of both the electron transport chain and the tricarboxylic acid cycle. However, the composition and function of the plant enzyme has been elusive and differs from the well-characterised enzymes in mammals and bacteria. Herewith, we demonstrate that mitochondrial Complex II from Arabidopsis and rice differ significantly in several aspects: (1) Stability-Rice complex II in contrast to Arabidopsis is not stable when resolved by native electrophoresis and activity staining. (2) Composition-Arabidopsis complex II contains 8 subunits, only 7 of which have homologs in the rice genome. SDH 1 and 2 subunits display high levels of amino acid identity between two species, while the remainder of the subunits are not well conserved at a sequence level, indicating significant divergence. (3) Gene expression-the pairs of orthologous SDH1 and SDH2 subunits were universally expressed in both Arabidopsis and rice. The very divergent genes for SDH3 and SDH4 were co-expressed in both species, consistent with their functional co-ordination to form the membrane anchor. The plant-specific SDH5, 6 and 7 subunits with unknown functions appeared to be differentially expressed in both species. (4) Biochemical regulation -succinate-dependent O(2) consumption and SDH activity of isolated Arabidopsis mitochondria were substantially stimulated by ATP, but a much more minor effect of ATP was observed for the rice enzyme. The ATP activation of succinate-dependent reduction of DCPIP in frozen-thawed and digitonin-solubilised mitochondrial samples, and with or without the uncoupler CCCP, indicate that the differential ATP effect on SDH is not via the protonmotive force but likely due to an allosteric effect on the plant SDH enzyme itself, in contrast to the enzyme in other organisms.

Published

2010

55. Structure of Escherichia coli succinate:quinone oxidoreductase with an occupied and empty quinone-binding site.

Author

Ruprecht J, Yankovskaya V, Maklashina E, Iwata S, and Cecchini G

Subjects

Animals, Binding Sites physiology, Birds, Carboxin chemistry, Protein Structure, Quaternary physiology, Structural Homology, Protein, Electron Transport Complex II chemistry, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Ubiquinone chemistry

Abstract

Three new structures of Escherichia coli succinate-quinone oxidoreductase (SQR) have been solved. One with the specific quinone-binding site (Q-site) inhibitor carboxin present has been solved at 2.4 A resolution and reveals how carboxin inhibits the Q-site. The other new structures are with the Q-site inhibitor pentachlorophenol and with an empty Q-site. These structures reveal important details unresolved in earlier structures. Comparison of the new SQR structures shows how subtle rearrangements of the quinone-binding site accommodate the different inhibitors. The position of conserved water molecules near the quinone binding pocket leads to a reassessment of possible water-mediated proton uptake networks that complete reduction of ubiquinone. The dicarboxylate-binding site in the soluble domain of SQR is highly similar to that seen in high resolution structures of avian SQR (PDB 2H88) and soluble flavocytochrome c (PDB 1QJD) showing mechanistically significant structural features conserved across prokaryotic and eukaryotic SQRs.

Published

2009

56. Limited reversibility of transmembrane proton transfer assisting transmembrane electron transfer in a dihaem-containing succinate:quinone oxidoreductase.

Author

Madej MG, Müller FG, Ploch J, and Lancaster CR

Subjects

Bacillus enzymology, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Carbonyl Cyanide m-Chlorophenyl Hydrazone, Electrochemistry, Electron Transport, Heme chemistry, Membrane Potentials, Models, Molecular, Oxidoreductases chemistry, Oxidoreductases metabolism, Proteolipids, Protons, Uncoupling Agents, Wolinella enzymology, Electron Transport Complex II chemistry, Electron Transport Complex II metabolism

Abstract

Membrane protein complexes can support both the generation and utilisation of a transmembrane electrochemical proton potential (Deltap), either by supporting transmembrane electron transfer coupled to protolytic reactions on opposite sides of the membrane or by supporting transmembrane proton transfer. The first mechanism has been unequivocally demonstrated to be operational for Deltap-dependent catalysis of succinate oxidation by quinone in the case of the dihaem-containing succinate:menaquinone reductase (SQR) from the Gram-positive bacterium Bacillus licheniformis. This is physiologically relevant in that it allows the transmembrane potential Deltap to drive the endergonic oxidation of succinate by menaquinone by the dihaem-containing SQR of Gram-positive bacteria. In the case of a related but different respiratory membrane protein complex, the dihaem-containing quinol:fumarate reductase (QFR) of the epsilon-proteobacterium Wolinella succinogenes, evidence has been obtained that both mechanisms are combined, so as to facilitate transmembrane electron transfer by proton transfer via a both novel and essential compensatory transmembrane proton transfer pathway ("E-pathway"). Although the reduction of fumarate by menaquinol is exergonic, it is obviously not exergonic enough to support the generation of a Deltap. This compensatory "E-pathway" appears to be required by all dihaem-containing QFR enzymes and results in the overall reaction being electroneutral. However, here we show that the reverse reaction, the oxidation of succinate by quinone, as catalysed by W. succinogenes QFR, is not electroneutral. The implications for transmembrane proton transfer via the E-pathway are discussed.

Published

2009

57. The CCG-domain-containing subunit SdhE of succinate:quinone oxidoreductase from Sulfolobus solfataricus P2 binds a [4Fe-4S] cluster.

Author

Hamann N, Bill E, Shokes JE, Scott RA, Bennati M, and Hedderich R

Subjects

Amino Acid Motifs, Binding Sites, Electron Spin Resonance Spectroscopy, Electron Transport Complex II genetics, Electron Transport Complex II metabolism, Magnetic Resonance Spectroscopy, Molecular Sequence Data, Protein Subunits genetics, Spectrophotometry, Ultraviolet, Spectroscopy, Mossbauer, Zinc chemistry, Electron Transport Complex II chemistry, Iron-Sulfur Proteins chemistry, Protein Subunits chemistry, Sulfolobus solfataricus enzymology

Abstract

In type E succinate:quinone reductase (SQR), subunit SdhE (formerly SdhC) is thought to function as monotopic membrane anchor of the enzyme. SdhE contains two copies of a cysteine-rich sequence motif (CX(n)CCGX(m)CXXC), designated as the CCG domain in the Pfam database and conserved in many proteins. On the basis of the spectroscopic characterization of heterologously produced SdhE from Sulfolobus tokodaii, the protein was proposed in a previous study to contain a labile [2Fe-2S] cluster ligated by cysteine residues of the CCG domains. Using UV/vis, electron paramagnetic resonance (EPR), (57)Fe electron-nuclear double resonance (ENDOR) and Mössbauer spectroscopies, we show that after an in vitro cluster reconstitution, SdhE from S. solfataricus P2 contains a [4Fe-4S] cluster in reduced (2+) and oxidized (3+) states. The reduced form of the [4Fe-4S](2+) cluster is diamagnetic. The individual iron sites of the reduced cluster are noticeably heterogeneous and show partial valence localization, which is particularly strong for one unique ferrous site. In contrast, the paramagnetic form of the cluster exhibits a characteristic rhombic EPR signal with g (zyx) = 2.015, 2.008, and 1.947. This EPR signal is reminiscent of a signal observed previously in intact SQR from S. tokodaii with g (zyx) = 2.016, 2.00, and 1.957. In addition, zinc K-edge X-ray absorption spectroscopy indicated the presence of an isolated zinc site with an S(3)(O/N)(1) coordination in reconstituted SdhE. Since cysteine residues in SdhE are restricted to the two CCG domains, we conclude that these domains provide the ligands to both the iron-sulfur cluster and the zinc site.

Published

2009

58. Mitochondrial dehydrogenases in the aerobic respiratory chain of the rodent malaria parasite Plasmodium yoelii yoelii.

Author

Kawahara K, Mogi T, Tanaka TQ, Hata M, Miyoshi H, and Kita K

Subjects

Animals, Electron Transport, Electron Transport Complex II chemistry, Female, Malaria metabolism, Malaria parasitology, Mice, Mice, Inbred BALB C, Mitochondria metabolism, NADH Dehydrogenase chemistry, Oxidative Phosphorylation, Plasmodium yoelii metabolism, Plasmodium yoelii pathogenicity, Protozoan Proteins chemistry, Rats, Electron Transport Complex II metabolism, Mitochondria enzymology, NADH Dehydrogenase metabolism, Plasmodium yoelii enzymology, Protozoan Proteins metabolism

Abstract

In the intraerythrocytic stages of malaria parasites, mitochondria lack obvious cristae and are assumed to derive energy through glycolysis. For understanding of parasite energy metabolism in mammalian hosts, we isolated rodent malaria mitochondria from Plasmodium yoelii yoelii grown in mice. As potential targets for antiplasmodial agents, we characterized two respiratory dehydrogenases, succinate:ubiquinone reductase (complex II) and alternative NADH dehydrogenase (NDH-II), which is absent in mammalian mitochondria. We found that P. y. yoelii complex II was a four-subunit enzyme and that kinetic properties were similar to those of mammalian enzymes, indicating that the Plasmodium complex II is favourable in catalysing the forward reaction of tricarboxylic acid cycle. Notably, Plasmodium complex II showed IC(50) value for atpenin A5 three-order of magnitudes higher than those of mammalian enzymes. Divergence of protist membrane anchor subunits from eukaryotic orthologs likely affects the inhibitor resistance. Kinetic properties and sensitivity to 2-heptyl-4-hydroxyquinoline-N-oxide and aurachin C of NADH: ubiquinone reductase activity of Plasmodium NDH-II were similar to those of plant and fungus enzymes but it can oxidize NADPH and deamino-NADH. Our findings are consistent with the notion that rodent malaria mitochondria are fully capable of oxidative phosphorylation and that these mitochondrial enzymes are potential targets for new antiplasmodials.

Published

2009

59. Regulation of succinate-ubiquinone reductase and fumarate reductase activities in human complex II by phosphorylation of its flavoprotein subunit.

Author

Tomitsuka E, Kita K, and Esumi H

Subjects

Animals, Cell Culture Techniques, Cell Hypoxia, Cell Line, Tumor, Glucose deficiency, Humans, Mitochondria enzymology, Phosphoric Monoester Hydrolases pharmacology, Phosphorylation drug effects, Protein Kinases pharmacology, Electron Transport Complex II chemistry, Electron Transport Complex II metabolism, Flavoproteins metabolism, Protein Subunits metabolism, Succinate Dehydrogenase chemistry, Succinate Dehydrogenase metabolism

Abstract

Complex II (succinate-ubiquinone reductase; SQR) is a mitochondrial respiratory chain enzyme that is directly involved in the TCA cycle. Complex II exerts a reverse reaction, fumarate reductase (FRD) activity, in various species such as bacteria, parasitic helminths and shellfish, but the existence of FRD activity in humans has not been previously reported. Here, we describe the detection of FRD activity in human cancer cells. The activity level was low, but distinct, and it increased significantly when the cells were cultured under hypoxic and glucose-deprived conditions. Treatment with phosphatase caused the dephosphorylation of flavoprotein subunit (Fp) with a concomitant increase in SQR activity, whereas FRD activity decreased. On the other hand, treatment with protein kinase caused an increase in FRD activity and a decrease in SQR activity. These data suggest that modification of the Fp subunit regulates both the SQR and FRD activities of complex II and that the phosphorylation of Fp might be important for maintaining mitochondrial energy metabolism within the tumor microenvironment.

Published

2009

60. Electroneutral and electrogenic catalysis by dihaem-containing succinate:quinone oxidoreductases.

Author

Lancaster CR, Herzog E, Juhnke HD, Madej MG, Müller FG, Paul R, and Schleidt PG

Subjects

Bacterial Proteins chemistry, Catalysis, Electron Transport, Electron Transport Complex II chemistry, Fumarates chemistry, Fumarates metabolism, Models, Molecular, Molecular Structure, Multienzyme Complexes chemistry, Multienzyme Complexes metabolism, Oxidation-Reduction, Oxidoreductases chemistry, Oxidoreductases metabolism, Protein Conformation, Protons, Quinones chemistry, Quinones metabolism, Wolinella enzymology, Bacillus enzymology, Bacterial Proteins metabolism, Electrochemistry, Electron Transport Complex II metabolism

Abstract

Membrane protein complexes can support both the generation and utilization of a transmembrane electrochemical proton potential (Deltap), either by supporting transmembrane electron transfer coupled to protolytic reactions on opposite sides of the membrane or by supporting transmembrane proton transfer. Regarding the first mechanism, this has been unequivocally demonstrated to be operational for Deltap-dependent catalysis of succinate oxidation by quinone in the case of the dihaem-containing SQR (succinate:menaquinone reductase) from the Gram-positive bacterium Bacillus licheniformis. This is physiologically relevant in that it allows the transmembrane Deltap to drive the endergonic oxidation of succinate by menaquinone by the dihaem-containing SQR of Gram-positive bacteria. In the case of a related but different respiratory membrane protein complex, the dihaem-containing QFR (quinol:fumarate reductase) of the epsilon-proteobacterium Wolinella succinogenes, evidence has been obtained indicating that both mechanisms are combined, so as to facilitate transmembrane electron transfer by proton transfer via a both novel and essential compensatory transmembrane proton transfer pathway ('E-pathway'). This is necessary because, although the reduction of fumarate by menaquinol is exergonic, it is obviously not exergonic enough to support the generation of a Deltap. This compensatory E-pathway appears to be required by all dihaem-containing QFR enzymes and the conservation of the essential acidic residue on transmembrane helix V (Glu-C180 in W. succinogenes QFR) is a useful key for the sequence-based discrimination of these QFR enzymes from the dihaem-containing SQR enzymes.

Published

2008

61. Direct and mediated electron transfer between intact succinate:quinone oxidoreductase from Bacillus subtilis and a surface modified gold electrode reveals redox state-dependent conformational changes.

Author

Christenson A, Gustavsson T, Gorton L, and Hägerhäll C

Subjects

Bacillus subtilis drug effects, Catalysis drug effects, Electrochemistry, Electrodes, Electron Transport drug effects, Heme chemistry, Hydroxyquinolines pharmacology, Models, Biological, Oxidation-Reduction drug effects, Protein Structure, Secondary, Spectrum Analysis, Bacillus subtilis enzymology, Electron Transport Complex II chemistry, Electron Transport Complex II metabolism, Gold metabolism

Abstract

Succinate:quinone oxidoreductase (SQR) from Bacillus subtilis consists of two hydrophilic protein subunits comprising succinate dehydrogenase, and a di-heme membrane anchor protein harboring two putative quinone binding sites, Q(p) and Q(d). In this work we have used spectroelectrochemistry to study the electronic communication between purified SQR and a surface modified gold capillary electrode. In the presence of two soluble quinone mediators the midpoint potentials of both hemes were revealed essentially as previously determined by conventional redox titration (heme b(H), E(m)=+65 mV, heme b(L), E(m)=-95 mV). In the absence of mediators the enzyme still communicated with the electrode, albeit with a reproducible hysteresis, resulting in the reduction of both hemes occurring approximately at the midpoint potential of heme b(L), and with a pronounced delay of reoxidation. When the specific inhibitor 2-n-heptyl-4 hydroxyquinoline N-oxide (HQNO), which binds to Q(d) in B. subtilis SQR, was added together with the two quinone mediators, rapid reductive titration was still possible which can be envisioned as an electron transfer occurring via the HQNO insensitive Q(p) site. In contrast, the subsequent oxidative titration was severely hampered in the presence of HQNO, in fact it completely resembled the unmediated reaction. If mediators communicate with Q(p) or Q(d), either event is followed by very rapid electron redistribution within the enzyme. Taken together, this strongly suggests that the accessibility of Q(p) depended on the redox state of the hemes. When both hemes were reduced, and Q(d) was blocked by HQNO, quinone-mediated communication via the Q(p) site was no longer possible, revealing a redox-dependent conformational change in the membrane anchor domain.

Published

2008

62. Screening of detergents for solubilization, purification and crystallization of membrane proteins: a case study on succinate:ubiquinone oxidoreductase from Escherichia coli.

Author

Shimizu H, Nihei C, Inaoka DK, Mogi T, Kita K, and Harada S

Subjects

Crystallization, Electron Transport Complex II metabolism, Escherichia coli chemistry, Membrane Proteins metabolism, Phospholipids chemistry, Phospholipids metabolism, Solubility, Succinic Acid metabolism, Ubiquinone analogs & derivatives, Ubiquinone metabolism, Detergents, Electron Transport Complex II chemistry, Electron Transport Complex II isolation & purification, Escherichia coli enzymology, Membrane Proteins chemistry, Membrane Proteins isolation & purification

Abstract

Succinate:ubiquinone oxidoreductase (SQR) was solubilized and purified from Escherichia coli inner membranes using several different detergents. The number of phospholipid molecules bound to the SQR molecule varied greatly depending on the detergent combination that was used for the solubilization and purification. Crystallization conditions were screened for SQR that had been solubilized and purified using 2.5%(w/v) sucrose monolaurate and 0.5%(w/v) Lubrol PX, respectively, and two different crystal forms were obtained in the presence of detergent mixtures composed of n-alkyl-oligoethylene glycol monoether and n-alkyl-maltoside. Crystallization took place before detergent phase separation occurred and the type of detergent mixture affected the crystal form.

Published

2008

63. A threonine on the active site loop controls transition state formation in Escherichia coli respiratory complex II.

Author

Tomasiak TM, Maklashina E, Cecchini G, and Iverson TM

Subjects

Aerobiosis physiology, Anaerobiosis physiology, Electron Transport Complex II metabolism, Flavin-Adenine Dinucleotide chemistry, Flavin-Adenine Dinucleotide metabolism, Fumarates chemistry, Fumarates metabolism, Hydrogen Bonding, Oxidoreductases metabolism, Protein Binding physiology, Protein Structure, Secondary physiology, Protein Structure, Tertiary physiology, Protons, Succinic Acid chemistry, Succinic Acid metabolism, Electron Transport Complex II chemistry, Escherichia coli enzymology, Models, Molecular, Oxidoreductases chemistry

Abstract

In Escherichia coli, the complex II superfamily members succinate:ubiquinone oxidoreductase (SQR) and quinol:fumarate reductase (QFR) participate in aerobic and anaerobic respiration, respectively. Complex II enzymes catalyze succinate and fumarate interconversion at the interface of two domains of the soluble flavoprotein subunit, the FAD binding domain and the capping domain. An 11-amino acid loop in the capping domain (Thr-A234 to Thr-A244 in quinol:fumarate reductase) begins at the interdomain hinge and covers the active site. Amino acids of this loop interact with both the substrate and a proton shuttle, potentially coordinating substrate binding and the proton shuttle protonation state. To assess the loop's role in catalysis, two threonine residues were mutated to alanine: QFR Thr-A244 (act-T; Thr-A254 in SQR), which hydrogen-bonds to the substrate at the active site, and QFR Thr-A234 (hinge-T; Thr-A244 in SQR), which is located at the hinge and hydrogen-bonds the proton shuttle. Both mutations impair catalysis and decrease substrate binding. The crystal structure of the hinge-T mutation reveals a reorientation between the FAD-binding and capping domains that accompanies proton shuttle alteration. Taken together, hydrogen bonding from act-T to substrate may coordinate with interdomain motions to twist the double bond of fumarate and introduce the strain important for attaining the transition state.

Published

2008

64. Change of subunit composition of mitochondrial complex II (succinate-ubiquinone reductase/quinol-fumarate reductase) in Ascaris suum during the migration in the experimental host.

Author

Iwata F, Shinjyo N, Amino H, Sakamoto K, Islam MK, Tsuji N, and Kita K

Subjects

Animal Migration physiology, Animals, Antibodies, Helminth analysis, Antibodies, Helminth metabolism, Ascariasis enzymology, Ascaris suum growth & development, Ascaris suum physiology, Blotting, Western, Electron Transport Complex II analysis, Electron Transport Complex II chemistry, Electrophoresis, Polyacrylamide Gel, Larva enzymology, Larva physiology, Oxidoreductases analysis, Oxidoreductases metabolism, Protein Subunits analysis, Protein Subunits metabolism, Quinones analysis, Rabbits, Ascariasis parasitology, Ascaris suum enzymology, Electron Transport Complex II metabolism, Mitochondria, Muscle enzymology

Abstract

The mitochondrial metabolic pathway of the parasitic nematode Ascaris suum changes dramatically during its life cycle, to adapt to changes in the environmental oxygen concentration. We previously showed that A. suum mitochondria express stage-specific isoforms of complex II (succinate-ubiquinone reductase: SQR/quinol-fumarate reductase: QFR). The flavoprotein (Fp) and small subunit of cytochrome b (CybS) in adult complex II differ from those of infective third stage larval (L3) complex II. However, there is no difference in the iron-sulfur cluster (Ip) or the large subunit of cytochrome b (CybL) between adult and L3 isoforms of complex II. In the present study, to clarify the changes that occur in the respiratory chain of A. suum larvae during their migration in the host, we examined enzymatic activity, quinone content and complex II subunit composition in mitochondria of lung stage L3 (LL3) A. suum larvae. LL3 mitochondria showed higher QFR activity ( approximately 160 nmol/min/mg) than mitochondria of A. suum at other stages (L3: approximately 80 nmol/min/mg; adult: approximately 70 nmol/min/mg). Ubiquinone content in LL3 mitochondria was more abundant than rhodoquinone ( approximately 1.8 nmol/mg versus approximately 0.9 nmol/mg). Interestingly, the results of two-dimensional bule-native/sodium dodecyl sulfate polyacrylamide gel electrophoresis analyses showed that LL3 mitochondria contained larval Fp (Fp(L)) and adult Fp (Fp(A)) at a ratio of 1:0.56, and that most LL3 CybS subunits were of the adult form (CybS(A)). This clearly indicates that the rearrangement of complex II begins with a change in the isoform of the anchor CybS subunit, followed by a similar change in the Fp subunit.

Published

2008

65. Ubiquinone-binding site mutations in the Saccharomyces cerevisiae succinate dehydrogenase generate superoxide and lead to the accumulation of succinate.

Author

Szeto SSW, Reinke SN, Sykes BD, and Lemire BD

Subjects

Binding Sites, Electron Transport Complex II chemistry, Oxidative Stress, Saccharomyces cerevisiae growth & development, Electron Transport Complex II genetics, Mutation, Saccharomyces cerevisiae enzymology, Succinic Acid metabolism, Superoxides metabolism, Ubiquinone metabolism

Abstract

The mitochondrial succinate dehydrogenase (SDH) is an essential component of the electron transport chain and of the tricarboxylic acid cycle. Also known as complex II, this tetrameric enzyme catalyzes the oxidation of succinate to fumarate and reduces ubiquinone. Mutations in the human SDHB, SDHC, and SDHD genes are tumorigenic, leading to the development of several types of tumors, including paraganglioma and pheochromocytoma. The mechanisms linking SDH mutations to oncogenesis are still unclear. In this work, we used the yeast SDH to investigate the molecular and catalytic effects of tumorigenic or related mutations. We mutated Arg(47) of the Sdh3p subunit to Cys, Glu, and Lys and Asp(88) of the Sdh4p subunit to Asn, Glu, and Lys. Both Arg(47) and Asp(88) are conserved residues, and Arg(47) is a known site of cancer causing mutations in humans. All of the mutants examined have reduced ubiquinone reductase activities. The SDH3 R47K, SDH4 D88E, and SDH4 D88N mutants are sensitive to hyperoxia and paraquat and have elevated rates of superoxide production in vitro and in vivo. We also observed the accumulation and secretion of succinate. Succinate can inhibit prolyl hydroxylase enzymes, which initiate a proliferative response through the activation of hypoxia-inducible factor 1alpha. We suggest that SDH mutations can promote tumor formation by contributing to both reactive oxygen species production and to a proliferative response normally induced by hypoxia via the accumulation of succinate.

Published

2007

66. Preliminary molecular characterization and crystallization of mitochondrial respiratory complex II from porcine heart.

Author

Huo X, Su D, Wang A, Zhai Y, Xu J, Li X, Bartlam M, Sun F, and Rao Z

Subjects

Amino Acid Sequence, Animals, Base Sequence, Crystallization, DNA Primers, Electron Transport Complex II chemistry, Electron Transport Complex II genetics, Electron Transport Complex II isolation & purification, Electrophoresis, Polyacrylamide Gel, Molecular Sequence Data, Polymerase Chain Reaction, Swine, Transcription, Genetic, Electron Transport Complex II metabolism, Myocardium metabolism

Abstract

The mitochondrial respiratory complex II, or succinate:ubiquinone oxidoreductase, is an integral membrane protein complex in both the tricarboxylic acid cycle (Krebs cycle) and aerobic respiration. The gene sequences of each complex II subunit were measured by RT-PCR. N-terminal sequencing work was performed to identify the mitochondrial targeting signal peptide of each subunit. Complex II was extracted from porcine heart and purified by the ammonium sulfate precipitation method. The sample was solubilized by 0.5% (w/v) sugar detergent n-decyl-beta-D-maltoside, stabilized by 200 mM sucrose, and crystallized with 5% (w/v) poly(ethylene glycol) 4000. Important factors for the extraction, purification and crystallization of mitochondrial respiratory complex II are discussed.

Published

2007

67. The role of Sdh4p Tyr-89 in ubiquinone reduction by the Saccharomyces cerevisiae succinate dehydrogenase.

Author

Silkin Y, Oyedotun KS, and Lemire BD

Subjects

Amino Acid Sequence, Amino Acid Substitution, Electron Transport Complex II chemistry, Electron Transport Complex II genetics, Humans, Hydrogen Bonding, Models, Molecular, Oxidation-Reduction, Paraganglioma genetics, Pheochromocytoma genetics, Reactive Oxygen Species metabolism, Tyrosine genetics, Electron Transport Complex II metabolism, Saccharomyces cerevisiae enzymology, Tyrosine physiology, Ubiquinone metabolism

Abstract

Succinate dehydrogenase (complex II or succinate:ubiquinone oxidoreductase) is a tetrameric, membrane-bound enzyme that catalyzes the oxidation of succinate and the reduction of ubiquinone in the mitochondrial respiratory chain. Two electrons from succinate are transferred one at a time through a flavin cofactor and a chain of iron-sulfur clusters to reduce ubiquinone to an ubisemiquinone intermediate and to ubiquinol. Residues that form the proximal quinone-binding site (Q(P)) must recognize ubiquinone, stabilize the ubisemiquinone intermediate, and protonate the ubiquinone to ubiquinol, while minimizing the production of reactive oxygen species. We have investigated the role of the yeast Sdh4p Tyr-89, which forms a hydrogen bond with ubiquinone in the Q(P) site. This tyrosine residue is conserved in all succinate:ubiquinone oxidoreductases studied to date. In the human SDH, mutation of this tyrosine to cysteine results in paraganglioma, tumors of the parasympathetic ganglia in the head and neck. We demonstrate that Tyr-89 is essential for ubiquinone reductase activity and that mutation of Tyr-89 to other residues does not increase the production of reactive oxygen species. Our results support a role for Tyr-89 in the protonation of ubiquinone and argue that the generation of reactive oxygen species is not causative of tumor formation.

Published

2007

68. Phenotypic variability of mitochondrial disease caused by a nuclear mutation in complex II.

Author

Pagnamenta AT, Hargreaves IP, Duncan AJ, Taanman JW, Heales SJ, Land JM, Bitner-Glindzicz M, Leonard JV, and Rahman S

Subjects

Amino Acid Sequence, Base Sequence, Child, Child, Preschool, DNA Mutational Analysis, DNA, Complementary metabolism, Electron Transport Complex II chemistry, Electron Transport Complex II metabolism, Electrophoresis, Polyacrylamide Gel, Humans, Hypothalamus, Middle diagnostic imaging, Infant, Magnetic Resonance Imaging, Male, Molecular Sequence Data, Protein Structure, Secondary, Protein Subunits chemistry, Protein Subunits genetics, Protein Subunits metabolism, Radiography, Ubiquinone metabolism, Cell Nucleus metabolism, Electron Transport Complex II genetics, Mitochondrial Diseases genetics, Mutation genetics, Phenotype

Abstract

We report a patient with relatively mild Leigh syndrome and mitochondrial respiratory chain complex II deficiency caused by a homozygous G555E mutation in the nuclear encoded flavoprotein subunit of succinate dehydrogenase. This mutation has previously been reported in a lethal-infantile presentation of complex II deficiency. Such marked phenotypic heterogeneity, although typical of heteroplasmic mutations in the mitochondrial genome, is unusual for nuclear mutations. Comparable activities and stability of mitochondrial respiratory chain enzymes were demonstrated in both patients, so other reasons for the phenotypic variability are considered.

Published

2006

69. RNA silencing of mitochondrial m-Nfs1 reduces Fe-S enzyme activity both in mitochondria and cytosol of mammalian cells.

Author

Fosset C, Chauveau MJ, Guillon B, Canal F, Drapier JC, and Bouton C

Subjects

Animals, Carbon-Sulfur Lyases chemistry, Carbon-Sulfur Lyases genetics, Down-Regulation, Electron Transport Complex I chemistry, Electron Transport Complex II chemistry, Ferritins chemistry, Mice, Mitochondria enzymology, NIH 3T3 Cells, Xanthine Oxidase chemistry, Carbon-Sulfur Lyases physiology, Cytosol metabolism, Iron-Sulfur Proteins chemistry, Mitochondria metabolism, RNA Interference

Abstract

In prokaryotes and yeast, the general mechanism of biogenesis of iron-sulfur (Fe-S) clusters involves activities of several proteins among which IscS and Nfs1p provide, through cysteine desulfuration, elemental sulfide for Fe-S core formation. Although these proteins have been well characterized, the role of their mammalian homolog in Fe-S cluster biogenesis has never been evaluated. We report here the first functional study that implicates the putative cysteine desulfurase m-Nfs1 in the biogenesis of both mitochondrial and cytosolic mammalian Fe-S proteins. Depletion of m-Nfs1 in cultured fibroblasts through small interfering RNA-based gene silencing significantly inhibited the activities of mitochondrial NADH-ubiquinone oxidoreductase (complex I) and succinate-ubiquinone oxidoreductase (complex II) of the respiratory chain, as well as aconitase of the Krebs cycle, with no alteration in their protein levels. Activity of cytosolic xanthine oxidase, which holds a [2Fe-2S] cluster, was also specifically reduced, and iron-regulatory protein-1 was converted from its [4Fe-4S] aconitase form to its apo- or RNA-binding form. Reduction of Fe-S enzyme activities occurred earlier and more markedly in the cytosol than in mitochondria, suggesting that there is a mechanism that primarily dedicates m-Nfs1 to the biogenesis of mitochondrial Fe-S clusters in order to maintain cell survival. Finally, depletion of m-Nfs1, which conferred on apo-IRP-1 a high affinity for ferritin mRNA, was associated with the down-regulation of the iron storage protein ferritin.

Published

2006

70. Crystallographic studies of the binding of ligands to the dicarboxylate site of Complex II, and the identity of the ligand in the "oxaloacetate-inhibited" state.

Author

Huang LS, Shen JT, Wang AC, and Berry EA

Subjects

Animals, Binding Sites, Chickens, Crystallography, X-Ray, Electron Transport Complex II antagonists & inhibitors, Fumarates metabolism, Iron-Sulfur Proteins metabolism, Ligands, Malates metabolism, Malonates metabolism, Oxaloacetic Acid metabolism, Protein Structure, Secondary, Spectrophotometry, Ultraviolet, Time Factors, Electron Transport Complex II chemistry, Electron Transport Complex II metabolism, Oxaloacetic Acid pharmacology

Abstract

Mitochondrial Complex II (succinate:ubiquinone oxidoreductase) is purified in a partially inactivated state, which can be activated by removal of tightly bound oxaloacetate (E.B. Kearney, et al., Biochem. Biophys. Res. Commun. 49 1115-1121). We crystallized Complex II in the presence of oxaloacetate or with the endogenous inhibitor bound. The structure showed a ligand essentially identical to the "malate-like intermediate" found in Shewanella Flavocytochrome c crystallized with fumarate (P. Taylor, et al., Nat. Struct. Biol. 6 1108-1112) Crystallization of Complex II in the presence of excess fumarate also gave the malate-like intermediate or a mixture of that and fumarate at the active site. In order to more conveniently monitor the occupation state of the dicarboxylate site, we are developing a library of UV/Vis spectral effects induced by binding different ligands to the site. Treatment with fumarate results in rapid development of the fumarate difference spectrum and then a very slow conversion into a species spectrally similar to the OAA-liganded complex. Complex II is known to be capable of oxidizing malate to the enol form of oxaloacetate (Y.O. Belikova, et al., Biochim. Biophys. Acta 936 1-9). The observations above suggest it may also be capable of interconverting fumarate and malate. It may be useful for understanding the mechanism and regulation of the enzyme to identify the malate-like intermediate and its pathway of formation from oxaloacetate or fumarate.

Published

2006

71. Structural and computational analysis of the quinone-binding site of complex II (succinate-ubiquinone oxidoreductase): a mechanism of electron transfer and proton conduction during ubiquinone reduction.

Author

Horsefield R, Yankovskaya V, Sexton G, Whittingham W, Shiomi K, Omura S, Byrne B, Cecchini G, and Iwata S

Subjects

Amino Acid Sequence, Binding Sites, Catalysis, Computational Biology, Crystallography, X-Ray, Electron Transport, Electrons, Escherichia coli metabolism, Histidine chemistry, Hydrogen Bonding, Ligands, Models, Chemical, Models, Molecular, Molecular Sequence Data, Oxygen metabolism, Phenotype, Protein Binding, Protein Conformation, Protein Structure, Tertiary, Protons, Pyridones chemistry, Quinones chemistry, Sequence Homology, Amino Acid, Serine chemistry, Succinate Dehydrogenase chemistry, Benzoquinones chemistry, Electron Transport Complex II chemistry, Escherichia coli enzymology, Ubiquinone chemistry

Abstract

The transfer of electrons and protons between membrane-bound respiratory complexes is facilitated by lipid-soluble redox-active quinone molecules (Q). This work presents a structural analysis of the quinone-binding site (Q-site) identified in succinate:ubiquinone oxidoreductase (SQR) from Escherichia coli. SQR, often referred to as Complex II or succinate dehydrogenase, is a functional member of the Krebs cycle and the aerobic respiratory chain and couples the oxidation of succinate to fumarate with the reduction of quinone to quinol (QH(2)). The interaction between ubiquinone and the Q-site of the protein appears to be mediated solely by hydrogen bonding between the O1 carbonyl group of the quinone and the side chain of a conserved tyrosine residue. In this work, SQR was co-crystallized with the ubiquinone binding-site inhibitor Atpenin A5 (AA5) to confirm the binding position of the inhibitor and reveal additional structural details of the Q-site. The electron density for AA5 was located within the same hydrophobic pocket as ubiquinone at, however, a different position within the pocket. AA5 was bound deeper into the site prompting further assessment using protein-ligand docking experiments in silico. The initial interpretation of the Q-site was re-evaluated in the light of the new SQR-AA5 structure and protein-ligand docking data. Two binding positions, the Q(1)-site and Q(2)-site, are proposed for the E. coli SQR quinone-binding site to explain these data. At the Q(2)-site, the side chains of a serine and histidine residue are suitably positioned to provide hydrogen bonding partners to the O4 carbonyl and methoxy groups of ubiquinone, respectively. This allows us to propose a mechanism for the reduction of ubiquinone during the catalytic turnover of the enzyme.

Published

2006

72. 3-nitropropionic acid is a suicide inhibitor of mitochondrial respiration that, upon oxidation by complex II, forms a covalent adduct with a catalytic base arginine in the active site of the enzyme.

Author

Huang LS, Sun G, Cobessi D, Wang AC, Shen JT, Tung EY, Anderson VE, and Berry EA

Subjects

Animals, Binding Sites, Carboxin chemistry, Carboxin metabolism, Chickens, Crystallography, X-Ray, Models, Molecular, Molecular Structure, Oxidation-Reduction, Succinate Dehydrogenase antagonists & inhibitors, Succinic Acid metabolism, Swine, Arginine metabolism, Cell Respiration physiology, Convulsants metabolism, Electron Transport Complex II antagonists & inhibitors, Electron Transport Complex II chemistry, Electron Transport Complex II metabolism, Mitochondria metabolism, Nitro Compounds metabolism, Propionates metabolism, Protein Conformation

Abstract

We report three new structures of mitochondrial respiratory Complex II (succinate ubiquinone oxidoreductase, E.C. 1.3.5.1) at up to 2.1 A resolution, with various inhibitors. The structures define the conformation of the bound inhibitors and suggest the residues involved in substrate binding and catalysis at the dicarboxylate site. In particular they support the role of Arg(297) as a general base catalyst accepting a proton in the dehydrogenation of succinate. The dicarboxylate ligand in oxaloacetate-containing crystals appears to be the same as that reported for Shewanella flavocytochrome c treated with fumarate. The plant and fungal toxin 3-nitropropionic acid, an irreversible inactivator of succinate dehydrogenase, forms a covalent adduct with the side chain of Arg(297). The modification eliminates a trypsin cleavage site in the flavoprotein, and tandem mass spectroscopic analysis of the new fragment shows the mass of Arg(297) to be increased by 83 Da and to have the potential of losing 44 Da, consistent with decarboxylation, during fragmentation.

Published

2006

73. Crystal structure of mitochondrial respiratory membrane protein complex II.

Author

Sun F, Huo X, Zhai Y, Wang A, Xu J, Su D, Bartlam M, and Rao Z

Subjects

Animals, Binding Sites physiology, Crystallography, X-Ray, Electron Transport Complex II metabolism, Enzyme Inhibitors pharmacology, Flavoproteins chemistry, Iron-Sulfur Proteins chemistry, Membrane Proteins chemistry, Models, Molecular, Molecular Sequence Data, Oxidation-Reduction, Protein Structure, Tertiary physiology, Protein Subunits chemistry, Sequence Homology, Amino Acid, Succinic Acid metabolism, Sus scrofa, Ubiquinone metabolism, Cell Respiration physiology, Electron Transport physiology, Electron Transport Complex II chemistry, Intracellular Membranes metabolism, Mitochondria metabolism

Abstract

The mitochondrial respiratory Complex II or succinate:ubiquinone oxidoreductase (SQR) is an integral membrane protein complex in both the tricarboxylic acid cycle and aerobic respiration. Here we report the first crystal structure of Complex II from porcine heart at 2.4 A resolution and its complex structure with inhibitors 3-nitropropionate and 2-thenoyltrifluoroacetone (TTFA) at 3.5 A resolution. Complex II is comprised of two hydrophilic proteins, flavoprotein (Fp) and iron-sulfur protein (Ip), and two transmembrane proteins (CybL and CybS), as well as prosthetic groups required for electron transfer from succinate to ubiquinone. The structure correlates the protein environments around prosthetic groups with their unique midpoint redox potentials. Two ubiquinone binding sites are discussed and elucidated by TTFA binding. The Complex II structure provides a bona fide model for study of the mitochondrial respiratory system and human mitochondrial diseases related to mutations in this complex.

Published

2005

74. Activation of isolated NADH:ubiquinone reductase I (complex I) from Escherichia coli by detergent and phospholipids. Recovery of ubiquinone reductase activity and changes in EPR signals of iron-sulfur clusters.

Author

Sinegina L, Wikström M, Verkhovsky MI, and Verkhovskaya ML

Subjects

Detergents, Dose-Response Relationship, Drug, Electron Spin Resonance Spectroscopy, Electron Transport Complex I isolation & purification, Electron Transport Complex II chemistry, Electron Transport Complex II metabolism, Enzyme Activation, Escherichia coli Proteins isolation & purification, NAD chemistry, NAD metabolism, Ruthenium Compounds metabolism, Electron Transport Complex I chemistry, Electron Transport Complex I metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Glucosides chemistry, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism, Phospholipids chemistry

Abstract

NADH:ubiquinone oxidoreductase (NDH-1 or complex I) from Escherichia coli was purified using a combination of anion exchange chromatography and centrifugation in sucrose density gradient. The dependence of enzyme activity on detergent and phospholipids was studied. Artificial hexaammineruthenium reductase activity was not affected by dodecyl maltoside (DDM) and asolectin. Ubiquinone reductase activity had a bell-shape dependence on DDM concentration; 7-10-fold activation could be achieved. Treatment with asolectin subsequently yields additional 2-fold activation with a corresponding increase in the apparent V(max) and without significant changes in apparent K(m). Comparative EPR studies of complex I reduced with NADH, "as prepared" and "activated by asolectin" showed an increase in the signals derived mainly from two [4Fe-4S] clusters in the activated enzyme. One of these signals could be simulated with an axial spectrum with g values of g(xyz)= 1.895, 1.904, 2.05, which corresponds to the parameters reported for the N2 cluster. This data indicates conformational rearrangements of catalytic importance in complex I upon binding of phospholipids.

Published

2005

75. Carbenoxolone induces oxidative stress in liver mitochondria, which is responsible for transition pore opening.

Author

Salvi M, Fiore C, Battaglia V, Palermo M, Armanini D, and Toninello A

Subjects

Animals, Apoptosis drug effects, Ascorbic Acid pharmacology, Biological Transport drug effects, Calcium metabolism, Calcium pharmacology, Cytochromes c metabolism, Electron Transport, Electron Transport Complex I chemistry, Electron Transport Complex II chemistry, Electron Transport Complex III chemistry, Hydrogen Peroxide metabolism, Intracellular Membranes drug effects, Intracellular Membranes physiology, Ion Channels physiology, Membrane Potentials drug effects, Mitochondria, Liver ultrastructure, Mitochondrial Membrane Transport Proteins, Mitochondrial Permeability Transition Pore, Mitochondrial Swelling drug effects, Oxidation-Reduction, Permeability, Rats, Ruthenium Red pharmacology, Sulfhydryl Compounds chemistry, Carbenoxolone pharmacology, Ion Channels drug effects, Mitochondria, Liver drug effects, Mitochondria, Liver physiology, Oxidative Stress drug effects

Abstract

Carbenoxolone (Cbx), a derivative of glycyrrhetinic acid, which has been found to affect mineralocorticoid and glucocorticoid receptors, induces swelling and membrane potential collapse when added to Ca(2+)-loaded liver mitochondria at 10 microM concentrations. These effects are strictly correlated with hydrogen peroxide generation, increase in oxygen uptake, and sulfhydryl and pyridine nucleotide oxidation. Cyclosporin A, bongkrekic acid, and N-ethylmaleimide completely abolish all the above-described effects, suggesting that Cbx can be considered an inducer of mitochondrial permeability transition by means of oxidative stress. Cbx can also trigger the apoptotic pathway because the above events are also correlated with the loss of cytochrome c. These effects are probably related to the conjugated carbonyl oxygen in C-11, which produces reactive oxygen species by interacting with the mitochondrial respiratory chain, mainly at the level of complex I but, most likely, also with complex III. The oxidative stress induced by Cbx, which is responsible for pore opening, excludes that this is related to a genomic effect of the compound.

Published

2005

76. Crystallization of mitochondrial respiratory complex II from chicken heart: a membrane-protein complex diffracting to 2.0 A.

Author

Huang LS, Borders TM, Shen JT, Wang CJ, and Berry EA

Subjects

Animals, Binding Sites, Chickens, Crystallization, Crystallography, X-Ray, Electrophoresis, Polyacrylamide Gel, Spectrophotometry, Electron Transport Complex II chemistry, Mitochondria, Heart enzymology

Abstract

A procedure is presented for preparation of diffraction-quality crystals of a vertebrate mitochondrial respiratory complex II. The crystals have the potential to diffract to at least 2.0 A with optimization of post-crystal-growth treatment and cryoprotection. This should allow determination of the structure of this important and medically relevant membrane-protein complex at near-atomic resolution and provide great detail of the mode of binding of substrates and inhibitors at the two substrate-binding sites.

Published

2005

77. The mitochondrial SDHD gene is required for early embryogenesis, and its partial deficiency results in persistent carotid body glomus cell activation with full responsiveness to hypoxia.

Author

Piruat JI, Pintado CO, Ortega-Sáenz P, Roche M, and López-Barneo J

Subjects

Alleles, Animals, Calcium metabolism, Carotid Body metabolism, Carotid Body Tumor metabolism, DNA Mutational Analysis, Electron Transport Complex II chemistry, Electron Transport Complex II metabolism, Gene Targeting, Heterozygote, Immunohistochemistry, Membrane Proteins chemistry, Membrane Proteins metabolism, Mice, Mice, Knockout, Mitochondria metabolism, Mutation, Patch-Clamp Techniques, Potassium metabolism, RNA, Messenger metabolism, Recombination, Genetic, Succinate Dehydrogenase chemistry, Succinate Dehydrogenase metabolism, Carotid Body Tumor genetics, Cell Hypoxia physiology, Electron Transport Complex II genetics, Embryonic Development, Membrane Proteins genetics, Paraganglioma genetics, Succinate Dehydrogenase genetics

Abstract

The SDHD gene encodes one of the two membrane-anchoring proteins of the succinate dehydrogenase (complex II) of the mitochondrial electron transport chain. This gene has recently been proposed to be involved in oxygen sensing because mutations that cause loss of its function produce hereditary familiar paraganglioma, a tumor of the carotid body (CB), the main arterial chemoreceptor that senses oxygen levels in the blood. Here, we report the generation of a SDHD knockout mouse, which to our knowledge is the first mammalian model lacking a protein of the electron transport chain. Homozygous SDHD(-/-) animals die at early embryonic stages. Heterozygous SDHD(+/-) mice show a general, noncompensated deficiency of succinate dehydrogenase activity without alterations in body weight or major physiological dysfunction. The responsiveness to hypoxia of CBs from SDHD(+/-) mice remains intact, although the loss of an SDHD allele results in abnormal enhancement of resting CB activity due to a decrease of K(+) conductance and persistent Ca(2+) influx into glomus cells. This CB overactivity is linked to a subtle glomus cell hypertrophy and hyperplasia. These observations indicate that constitutive activation of SDHD(+/-) glomus cells precedes CB tumor transformation. They also suggest that, contrary to previous beliefs, mitochondrial complex II is not directly involved in CB oxygen sensing.

Published

2004

78. "Respirasome"-like supercomplexes in green leaf mitochondria of spinach.

Author

Krause F, Reifschneider NH, Vocke D, Seelert H, Rexroth S, and Dencher NA

Subjects

Animals, Buffers, Chloroplasts chemistry, Chloroplasts ultrastructure, Digitonin metabolism, Electron Transport Complex II chemistry, Electron Transport Complex II metabolism, Electron Transport Complex III chemistry, Electron Transport Complex III metabolism, Indicators and Reagents metabolism, Mitochondria chemistry, Mitochondria ultrastructure, Multienzyme Complexes chemistry, Plant Leaves metabolism, Plant Proteins chemistry, Plant Proteins metabolism, Chloroplasts metabolism, Mitochondria metabolism, Multienzyme Complexes metabolism, Oxidative Phosphorylation, Spinacia oleracea cytology, Spinacia oleracea metabolism

Abstract

Higher plant mitochondria have many unique features compared with their animal and fungal counterparts. This is to a large extent related to the close functional interdependence of mitochondria and chloroplasts, in which the two ATP-generating processes of oxidative phosphorylation and photosynthesis, respectively, take place. We show that digitonin treatment of mitochondria contaminated with chloroplasts from spinach (Spinacia oleracea) green leaves at two different buffer conditions, performed to solubilize oxidative phosphorylation supercomplexes, selectively extracts the mitochondrial membrane protein complexes and only low amounts of stroma thylakoid membrane proteins. By analysis of digitonin extracts from partially purified mitochondria of green leaves from spinach using blue and colorless native electrophoresis, we demonstrate for the first time that in green plant tissue a substantial proportion of the respiratory complex IV is assembled with complexes I and III into "respirasome"-like supercomplexes, previously observed in mammalian, fungal, and non-green plant mitochondria only. Thus, fundamental features of the supramolecular organization of the standard respiratory complexes I, III, and IV as a respirasome are conserved in all higher eukaryotes. Because the plant respiratory chain is highly branched possessing additional alternative enzymes, the functional implications of the occurrence of respiratory supercomplexes in plant mitochondria are discussed.

Published

2004

79. Mitochondrial cytochrome c oxidase and succinate dehydrogenase complexes contain plant specific subunits.

Author

Millar AH, Eubel H, Jänsch L, Kruft V, Heazlewood JL, and Braun HP

Subjects

Amino Acid Sequence, Arabidopsis genetics, Arabidopsis metabolism, Electron Transport Complex II chemistry, Electron Transport Complex II genetics, Electron Transport Complex IV chemistry, Electron Transport Complex IV genetics, Electrophoresis, Gel, Two-Dimensional methods, Fabaceae genetics, Fabaceae metabolism, Mass Spectrometry methods, Molecular Sequence Data, Plant Proteins chemistry, Plant Proteins genetics, Sequence Analysis, Protein, Sequence Homology, Amino Acid, Solanum tuberosum genetics, Solanum tuberosum metabolism, Electron Transport Complex II analysis, Electron Transport Complex IV analysis, Plant Proteins analysis

Abstract

Respiratory oxidative phosphorylation represents a central functionality in plant metabolism, but the subunit composition of the respiratory complexes in plants is still being defined. Most notably, complex II (succinate dehydrogenase) and complex IV (cytochrome c oxidase) are the least defined in plant mitochondria. Using Arabidopsis mitochondrial samples and 2D Blue-native/SDS-PAGE, we have separated complex II and IV from each other and displayed their individual subunits for analysis by tandem mass spectrometry and Edman sequencing. Complex II can be discretely separated from other complexes on Blue-native gels and consists of eight protein bands. It contains the four classical SDH subunits as well as four subunits unknown in mitochondria from other eukaryotes. Five of these proteins have previously been identified, while three are newly identified in this study. Complex IV consists of 9-10 protein bands, however, it is more diffuse in Blue-native gels and co-migrates in part with the translocase of the outer membrane (TOM) complex. Differential analysis of TOM and complex IV reveals that complex IV probably contains eight subunits with similarity to known complex IV subunits from other eukaryotes and a further six putative subunits which all represent proteins of unknown function in Arabidopsis . Comparison of the Arabidopsis data with Blue-native/SDS-PAGE separation of potato and bean mitochondria confirmed the protein band complexity of these two respiratory complexes in plants. Two-dimensional Blue-native/Blue-native PAGE, using digitonin followed by dodecylmaltoside in successive dimensions, separated a diffusely staining complex containing both TOM and complex IV. This suggests that the very similar mass of these complexes will likely prevent high purity separations based on size. The documented roles of several of the putative complex IV subunits in hypoxia response and ozone stress, and similarity between new complex II subunits and recently identified plant specific subunits of complex I, suggest novel biological insights can be gained from respiratory complex composition analysis.

Published

2004

80. Complex II from a structural perspective.

Author

Horsefield R, Iwata S, and Byrne B

Subjects

Amino Acid Oxidoreductases chemistry, Amino Acid Oxidoreductases metabolism, Amino Acid Sequence, Animals, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Catalysis, Catalytic Domain, Crystallography, X-Ray, Cytochrome c Group chemistry, Cytochrome c Group metabolism, Electron Transport Complex II genetics, Electron Transport Complex II metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Flavoproteins chemistry, Flavoproteins metabolism, Humans, Membrane Proteins chemistry, Membrane Proteins metabolism, Models, Biological, Models, Molecular, Molecular Sequence Data, Molecular Structure, Oxidoreductases chemistry, Oxidoreductases metabolism, Protein Subunits chemistry, Protein Subunits metabolism, Reactive Oxygen Species chemistry, Reactive Oxygen Species metabolism, Sequence Homology, Amino Acid, Succinate Dehydrogenase chemistry, Succinate Dehydrogenase metabolism, Electron Transport Complex II chemistry, Protein Structure, Quaternary

Abstract

The super-macromolecular complex, succinate:quinone oxidoreductase (SQR, Complex II, succinate dehydrogenase) couples the oxidation of succinate in the matrix / cytoplasm to the reduction of quinone in the membrane. This function directly connects the Krebs cycle and the aerobic respiratory chain. Until the recent first report of the structure of SQR from Escherichia coli (E. coli) the structure-function relationships in SQR have been inferred from the structures of the homologous QFR, which catalyses the same reaction in the opposite direction. The structure of SQR from E. coli, analogous to the mitochondrial respiratory Complex II, has provided new insight into SQR's molecular design and mechanism, revealing the electron transport pathway through the enzyme. Comparison of the structures of SQR, QFR and other related flavoproteins shows how common amino acid residues at the interface of two domains facilitate the inter-conversion of succinate and fumarate. Additionally, the structure has provided a possible explanation as to why certain organisms utilise both SQR and QFR despite the fact that both can catalyse the inter-conversion of succinate and fumarate, in vitro and in vivo. Here we review how this structure has advanced our knowledge of this important enzyme and compare the structural information to other members of the Complex II superfamily and related flavoproteins.

Published

2004

81. X-ray absorption spectroscopic analysis of reductive [2Fe-2S] cluster degradation in hyperthermophilic archaeal succinate:caldariellaquinone oxidoreductase subunits.

Author

Li Z, Shokes JE, Kounosu A, Imai T, Iwasaki T, and Scott RA

Subjects

Archaeal Proteins metabolism, Electron Transport Complex II metabolism, Iron-Sulfur Proteins metabolism, Oxidation-Reduction, Protein Subunits metabolism, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Spectrum Analysis methods, Sulfolobus enzymology, Archaeal Proteins chemistry, Electron Transport Complex II chemistry, Iron-Sulfur Proteins chemistry, Protein Subunits chemistry, Quinones metabolism

Abstract

The biological [2Fe-2S] clusters play important roles in electron transfer and cellular signaling for a variety of organisms from archaea, bacteria to eukarya. The two recombinant hyperthermophilic archaeal [2Fe-2S] cluster-binding proteins, SdhC and the N-terminal domain fragment of SdhB, of Sulfolobus tokodaii respiratory complex II overproduced in Escherichia coli are thermostable as isolated, but moderately sensitive to reduction with excess dithionite. We used iron K-edge X-ray absorption spectroscopy to monitor the structural changes of their Fe sites in the irreversible [2Fe-2S] cluster degradation process. Regardless of the differences in the cluster-ligating cysteine motifs and the XAS-detectable [2Fe-2S](2+) cluster environments, a complete reductive breakdown of the [2Fe-2S] clusters resulted in the appearance of a new Fourier transform (FT) peak at approximately 3.3 A with a concomitant loss of the Fe-Fe interaction at ca. 2.7 A for both proteins. On the basis of the unambiguous assignment of the 3.3 A FT peak, our results suggest that a biological [2Fe-2S] cluster breakdown under reducing conditions generally releases Fe(2+) from the polypeptide chain into the aqueous solution, and the Fe(2+) might then be recruited as a secondary ferrous iron source for de novo biosynthesis and/or regulation of iron-binding enzymes in the cellular system.

Published

2003

82. The ubiquinone-binding site of the Saccharomyces cerevisiae succinate-ubiquinone oxidoreductase is a source of superoxide.

Author

Guo J and Lemire BD

Subjects

Animals, Binding Sites, Caenorhabditis elegans, Catalysis, Coenzymes, Dose-Response Relationship, Drug, Glycerol chemistry, Mitochondria metabolism, Models, Molecular, Mutation, Oxidative Stress, Oxygen metabolism, Phenotype, Plasmids metabolism, Protein Binding, Superoxide Dismutase metabolism, Superoxides metabolism, Electron Transport Complex II chemistry, Saccharomyces cerevisiae enzymology, Succinate Dehydrogenase chemistry, Superoxides chemistry, Ubiquinone analogs & derivatives, Ubiquinone chemistry

Abstract

The mitochondrial succinate dehydrogenase (SDH) is a tetrameric iron-sulfur flavoprotein of the Krebs cycle and of the respiratory chain. A number of mutations in human SDH genes are responsible for the development of paragangliomas, cancers of the head and neck region. The mev-1 mutation in the Caenorhabditis elegans gene encoding the homolog of the SDHC subunit results in premature aging and hypersensitivity to oxidative stress. It also increases the production of superoxide radicals by the enzyme. In this work, we used the yeast succinate dehydrogenase to investigate the molecular and catalytic effects of paraganglioma- and mev-1-like mutations. We mutated Pro-190 of the yeast Sdh2p subunit to Gln (P190Q) and recreated the C. elegans mev-1 mutation by converting Ser-94 in the Sdh3p subunit into a glutamate residue (S94E). The P190Q and S94E mutants have reduced succinate-ubiquinone oxidoreductase activities and are hypersensitive to oxygen and paraquat. Although the mutant enzymes have lower turnover numbers for ubiquinol reduction, larger fractions of the remaining activities are diverted toward superoxide production. The P190Q and S94E mutations are located near the proximal ubiquinone-binding site, suggesting that the superoxide radicals may originate from a ubisemiquinone intermediate formed at this site during the catalytic cycle. We suggest that certain mutations in SDH can make it a significant source of superoxide production in mitochondria, which may contribute directly to disease progression. Our data also challenge the dogma that superoxide production by SDH is a flavin-mediated event rather than a quinone-mediated one.

Published

2003

83. Wolinella succinogenes quinol:fumarate reductase and its comparison to E. coli succinate:quinone reductase.

Author

Lancaster CR

Subjects

Amino Acid Sequence, Binding Sites, Crystallography, X-Ray, Electron Transport, Electron Transport Complex II genetics, Electron Transport Complex II metabolism, Escherichia coli genetics, Evolution, Molecular, Heme chemistry, Models, Molecular, Molecular Sequence Data, Oxidoreductases genetics, Oxidoreductases metabolism, Protein Conformation, Protein Subunits, Proton-Motive Force, Sequence Homology, Amino Acid, Wolinella genetics, Electron Transport Complex II chemistry, Escherichia coli enzymology, Oxidoreductases chemistry, Wolinella enzymology

Abstract

The three-dimensional structure of Wolinella succinogenes quinol:fumarate reductase (QFR), a dihaem-containing member of the superfamily of succinate:quinone oxidoreductases (SQOR), has been determined at 2.2 A resolution by X-ray crystallography [Lancaster et al., Nature 402 (1999) 377-385]. The structure and mechanism of W. succinogenes QFR and their relevance to the SQOR superfamily have recently been reviewed [Lancaster, Adv. Protein Chem. 63 (2003) 131-149]. Here, a comparison is presented of W. succinogenes QFR to the recently determined structure of the mono-haem containing succinate:quinone reductase from Escherichia coli [Yankovskaya et al., Science 299 (2003) 700-704]. In spite of differences in polypeptide and haem composition, the overall topology of the membrane anchors and their relative orientation to the conserved hydrophilic subunits is strikingly similar. A major difference is the lack of any evidence for a 'proximal' quinone site, close to the hydrophilic subunits, in W. succinogenes QFR.

Published

2003

84. Direct evidence for expression of type II flavoprotein subunit in human complex II (succinate-ubiquinone reductase).

Author

Tomitsuka E, Goto Y, Taniwaki M, and Kita K

Subjects

Amino Acid Sequence, Blotting, Southern, Blotting, Western, Cell Line, Cell Line, Tumor, DNA, Complementary metabolism, Dose-Response Relationship, Drug, Electrophoresis, Gel, Two-Dimensional, Electrophoresis, Polyacrylamide Gel, Humans, Inhibitory Concentration 50, Isoelectric Focusing, Liver metabolism, Mitochondria metabolism, Molecular Sequence Data, Protein Binding, Protein Isoforms, Protein Structure, Tertiary, RNA metabolism, Reverse Transcriptase Polymerase Chain Reaction, Sequence Homology, Amino Acid, Tissue Distribution, Electron Transport Complex II chemistry, Flavoproteins chemistry

Abstract

Succinate-ubiquinone reductase (complex II) is an important enzyme complex in aerobic respiration and the tricarboxylic acid cycle. We recently identified two distinct cDNAs for the human flavoprotein subunit (Fp) from a single individual and demonstrated mRNAs of these two isoforms, Type I Fp and Type II Fp, in skeletal muscle, liver, brain, heart, and kidney. Type I Fp was expressed at higher levels than Type II Fp in all cases. In the present study, the biochemical properties of Type II Fp-containing complex II in Raji cells predominantly expressing Type II Fp were investigated. Complex II having Type II Fp was separated from that having Type I Fp by isoelectric focusing in the presence of sucrose monolaurate. Together with the fact that succinate-ubiquinone reductase activity of mitochondria prepared from Raji cell was almost identical to that from human liver, these results clearly indicate the presence of two distinct isoforms of active complex II in human mitochondria.

Published

2003

85. New insights into the respiratory chain of plant mitochondria. Supercomplexes and a unique composition of complex II.

Author

Eubel H, Jänsch L, and Braun HP

Subjects

Arabidopsis metabolism, Digitonin pharmacology, Electron Transport physiology, Electron Transport Complex I chemistry, Electron Transport Complex I drug effects, Electron Transport Complex I metabolism, Electron Transport Complex II chemistry, Electron Transport Complex II drug effects, Electron Transport Complex III chemistry, Electron Transport Complex III drug effects, Electron Transport Complex III metabolism, Electron Transport Complex IV chemistry, Electron Transport Complex IV drug effects, Electron Transport Complex IV metabolism, Electrophoresis, Gel, Two-Dimensional, Fabaceae metabolism, Glucosides pharmacology, Hordeum metabolism, Mass Spectrometry, Mitochondrial Proteins, Octoxynol pharmacology, Oxidoreductases metabolism, Plant Proteins metabolism, Protein Conformation, Solanum tuberosum metabolism, Electron Transport Complex II metabolism, Mitochondria metabolism, Plants metabolism

Abstract

A project to systematically investigate respiratory supercomplexes in plant mitochondria was initiated. Mitochondrial fractions from Arabidopsis, potato (Solanum tuberosum), bean (Phaseolus vulgaris), and barley (Hordeum vulgare) were carefully treated with various concentrations of the nonionic detergents dodecylmaltoside, Triton X-100, or digitonin, and proteins were subsequently separated by (a) Blue-native polyacrylamide gel electrophoresis (PAGE), (b) two-dimensional Blue-native/sodium dodecyl sulfate-PAGE, and (c) two-dimensional Blue-native/Blue-native PAGE. Three high molecular mass complexes of 1,100, 1,500, and 3,000 kD are visible on one-dimensional Blue native gels, which were identified by separations on second gel dimensions and protein analyses by mass spectrometry. The 1,100-kD complex represents dimeric ATP synthase and is only stable under very low concentrations of detergents. In contrast, the 1,500-kD complex is stable at medium and even high concentrations of detergents and includes the complexes I and III(2). Depending on the investigated organism, 50% to 90% of complex I forms part of this supercomplex if solubilized with digitonin. The 3,000-kD complex, which also includes the complexes I and III, is of low abundance and most likely has a III(4)I(2) structure. The complexes IV, II, and the alternative oxidase were not part of supercomplexes under all conditions applied. Digitonin proved to be the ideal detergent for supercomplex stabilization and also allows optimal visualization of the complexes II and IV on Blue-native gels. Complex II unexpectedly was found to be composed of seven subunits, and complex IV is present in two different forms on the Blue-native gels, the larger of which comprises additional subunits including a 32-kD protein resembling COX VIb from other organisms. We speculate that supercomplex formation between the complexes I and III limits access of alternative oxidase to its substrate ubiquinol and possibly regulates alternative respiration. The data of this investigation are available at http://www.gartenbau.uni-hannover.de/genetik/braun/AMPP.

Published

2003

86. Direct evidence for two distinct forms of the flavoprotein subunit of human mitochondrial complex II (succinate-ubiquinone reductase).

Author

Tomitsuka E, Hirawake H, Goto Y, Taniwaki M, Harada S, and Kita K

Subjects

Adolescent, Adult, Aged, Amino Acid Sequence, Animals, Base Sequence, DNA, Complementary genetics, Electron Transport Complex II biosynthesis, Female, Humans, Introns genetics, Isoenzymes, Male, Middle Aged, Models, Molecular, Molecular Sequence Data, Protein Structure, Secondary, Protein Subunits, Recombinant Proteins biosynthesis, Recombinant Proteins chemistry, Recombinant Proteins genetics, Sequence Homology, Amino Acid, Electron Transport Complex II chemistry, Electron Transport Complex II genetics, Flavoproteins chemistry, Mitochondria enzymology

Abstract

Succinate-ubiquinone reductase (complex II) is an important enzyme complex in both the tricarboxylic acid cycle and aerobic respiration. A recent study showed that defects in human complex II are associated with cancers as well as mitochondrial diseases. Mutations in the four subunits of human complex II are associated with a wide spectrum of clinical presentations. Such tissue-specific clinical symptoms suggest the presence of multiple isoforms of the subunits, but subunit isoforms have not been previously reported. In the present study, we identified two distinct cDNAs for the human flavoprotein subunit (Fp) from a single individual, and demonstrated expression of these two isoforms in skeletal muscle, liver, brain, heart and kidney. Interestingly, one of the Fp isoforms was encoded as an intronless gene.

Published

2003

87. Function and structure of complex II of the respiratory chain.

Author

Cecchini G

Subjects

Animals, Catalysis, Electron Transport, Electron Transport Complex II genetics, Flavin-Adenine Dinucleotide chemistry, Heme metabolism, Humans, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism, Models, Molecular, Protein Structure, Tertiary, Protein Subunits, Reactive Oxygen Species chemistry, Reactive Oxygen Species metabolism, Electron Transport Complex II chemistry, Electron Transport Complex II metabolism

Abstract

Complex II is the only membrane-bound component of the Krebs cycle and in addition functions as a member of the electron transport chain in mitochondria and in many bacteria. A recent X-ray structural solution of members of the complex II family of proteins has provided important insights into their function. One feature of the complex II structures is a linear electron transport chain that extends from the flavin and iron-sulfur redox cofactors in the membrane extrinsic domain to the quinone and b heme cofactors in the membrane domain. Exciting recent developments in relation to disease in humans and the formation of reactive oxygen species by complex II point to its overall importance in cellular physiology.

Published

2003