Protein levels of genes encoded on chromosome 21 in fetal Down syndrome brain: challenging the gene dosage effect hypothesis (Part III).

Down syndrome (DS) is the most frequent genetic disorder with mental retardation and caused by trisomy 21. Although the gene dosage effect hypothesis has been proposed to explain the impact of extra chromosome 21 on the pathology of DS, a series of evidence that challenge this hypothesis has been reported. The availability of the complete sequences of genes on chromosome 21 serves now as starting point to find functional information of the gene products, but information on gene products is limited so far. We therefore evaluated expression levels of six proteins whose genes are encoded on chromosome 21 (synaptojanin-1, chromosome 21 open reading frame 2, oligomycin sensitivity confering protein, peptide 19, cystatin B and adenosine deaminase RNA-specific 2) in fetal cerebral cortex from DS and controls at 18-19 weeks of gestational age using Western blot analysis. Synaptojanin-1 and C21orf2 were increased in DS, but others were comparable between DS and controls, suggesting that the DS phenotype cannot be simply explained by gene dosage effects. We are systematically quantifying all proteins whose genes are encoded on chromosome 21 in order to provide a better understanding of the pathobiochemistry of DS at the protein level. These studies are of significance as they show for the first time protein levels that are carrying out specific function in human fetal brain with DS.

Ubiquinol:cytochrome c oxidoreductase (complex III). Effect of inhibitors on cytochrome b reduction in submitochondrial particles and the role of ubiquinone in complex III.

Two sets of studies have been reported on the electron transfer pathway of complex III in bovine heart submitochondrial particles (SMP). 1) In the presence of myxothiazol, MOA-stilbene, stigmatellin, or of antimycin added to SMP pretreated with ascorbate and KCN to reduce the high potential components (iron-sulfur protein (ISP) and cytochrome c(1)) of complex III, addition of succinate reduced heme b(H) followed by a slow and partial reduction of heme b(L). Similar results were obtained when SMP were treated only with KCN or NaN(3), reagents that inhibit cytochrome oxidase, not complex III. The average initial rate of b(H) reduction under these conditions was about 25-30% of the rate of b reduction by succinate in antimycin-treated SMP, where both b(H) and b(L) were concomitantly reduced. These results have been discussed in relation to the Q-cycle hypothesis and the effect of the redox state of ISP/c(1) on cytochrome b reduction by succinate. 2) Reverse electron transfer from ISP reduced with ascorbate plus phenazine methosulfate to cytochrome b was studied in SMP, ubiquinone (Q)-depleted SMP containing

The multiple nicotinamide nucleotide-binding subunits of bovine heart mitochondrial NADH:ubiquinone oxidoreductase (complex I).

Direct photoaffinity labeling of purified bovine heart NADH:ubiquinone oxidoreductase (complex I) with 32P-labeled NAD(H), NADP(H) and ADP has shown that five polypeptides become labeled, with molecular masses of 51, 42, 39, 30, and 18-20 kDa. The 51 and the 30-kDa polypeptides were labeled with either [32P]NAD(H), [32P]NADP(H) or [beta-32P]ADP. The 42-kDa polypeptide was labeled with [32P]NAD(H) and to a small extent with [beta-32P]ADP. It was not labeled with [32P]NADP(H). The 39-kDa polypeptide was labeled with [32P]NADPH and to a small extent with [beta-32P]ADP. Our previous studies had shown that this subunit also binds NADP, but not NAD(H) [Yamaguchi, M., Belogrudov, G.I. & Hatefi, Y. (1998) J. Biol. Chem. 273, 8094-8098]. The 18-20-kDa polypeptide was labeled only with [32P]NADPH. Among these polypeptides, the 51-kDa subunit is known to contain FMN and a [4Fe-4S] cluster, and is the NAD(P)H-binding subunit of the primary dehydrogenase domain of complex I. The possible roles of the other nucleotide-binding subunits of complex I have been discussed.

Phylogenetic analyses of proton-translocating transhydrogenases.

The proton-translocating nicotinamide nucleotide transhydrogenases (TH) provide a simple model for understanding chemically coupled transmembrane proton translocation. To further our understanding of TH structure-function relationships, we have identified all sequenced homologous of these vectorial enzymes and have conducted sequence comparison studies. The NAD-binding domains of TH are homologous to bacterial alanine dehydrogenases (ADH) and eukaryotic saccharopine dehydrogenases (SDH) as well as N5(carboxyethyl)-L-ornithine synthase of Lactococcus lactis and dipicolinate synthase of Bacillus subtilis. A multiple alignment, a phylogenetic tree, and two signature sequences for this family, designated the TH-ADH-SDH or TAS superfamily, have been derived. Additionally, the TH family has been characterized. Phylogenetic analyses suggested that these proteins have evolved without inter-system shuffling. However, interdomain splicing-fusion events have occurred during the evolution of several of these systems. Analyses of the multiple alignment for the TH family revealed that domain conservation occurs in the order: NADP-binding domain (domain III) > NAD-binding domain (domain I) > proton-translocating transmembrane domain (domain II). A topologic model for the proton-translocating transmembrane domain consistent with published data is presented, and a possible involvement of specific transmembrane alpha-helical segments in channel formation is suggested.

Crystal structure of transhydrogenase domain III at 1.2 A resolution.

The nicotinamide nucleotide transhydrogenases (TH) of mitochondria and bacteria are membrane-intercalated proton pumps that transduce substrate binding energy and protonmotive force via protein conformational changes. In mitochondria, TH utilizes protonmotive force to promote direct hydride ion transfer from NADH to NADP, which are bound at the distinct extramembranous domains I and III, respectively. Domain II is the membrane-intercalated domain and contains the enzyme's proton channel. This paper describes the crystal structure of the NADP(H) binding domain III of bovine TH at 1.2 A resolution. The structure reveals that NADP is bound in a manner inverted from that previously observed for nucleotide binding folds. The non-classical binding mode exposes the NADP(H) nicotinamide ring for direct contact with NAD(H) in domain I, in accord with biochemical data. The surface of domain III surrounding the exposed nicotinamide is comprised of conserved residues presumed to form the interface with domain I during hydride ion transfer. Further, an adjacent region contains a number of acidic residues, forming a surface with negative electrostatic potential which may interact with extramembranous loops of domain II. Together, the distinctive surface features allow mechanistic considerations regarding the NADP(H)-promoted conformation changes that are involved in the interactions of domain III with domains I and II for hydride ion transfer and proton translocation.

Ubiquinol:cytochrome c oxidoreductase. Effects of inhibitors on reverse electron transfer from the iron-sulfur protein to cytochrome b.

The effects of inhibitors on the reduction of the bis-heme cytochrome b of ubiquinol: cytochrome c oxidoreductase (complex III, bc1 complex) has been studied in bovine heart submitochondrial particles (SMP) when cytochrome b was reduced by NADH and succinate via the ubiquinone (Q) pool or by ascorbate plus N,N,N', N'-tetramethyl-p-phenylenediamine via cytochrome c1 and the iron-sulfur protein of complex III (ISP). The inhibitors used were antimycin (an N-side inhibitor), beta-methoxyacrylate derivatives, stigmatellin (P-side inhibitors), and ethoxyformic anhydride, which modifies essential histidyl residues in ISP. In agreement with our previous findings, the following results were obtained: (i) When ISP/cytochrome c1 were prereduced or SMP were treated with a P-side inhibitor, the high potential heme bH was fully and rapidly reduced by NADH or succinate, whereas the low potential heme bL was only partially reduced. (ii) Reverse electron transfer from ISP/c1 to cytochrome b was inhibited more by antimycin than by the P-side inhibitors. This reverse electron transfer was unaffected when, instead of normal SMP, Q-extracted SMP containing 200-fold less Q (0. 06 mol Q/mol cytochrome b or c1) were used. (iii) The cytochrome b reduced by reverse electron transfer through the leak of a P-side inhibitor was rapidly oxidized upon subsequent addition of antimycin. This antimycin-induced reoxidation did not happen when Q-extracted SMP were used. The implications of these results on the path of electrons in complex III, on oxidant-induced extra cytochrome b reduction, and on the inhibition of forward electron transfer to cytochrome b by a P-side plus an N-side inhibitor have been discussed.

Mitochondrial NADH-ubiquinone oxidoreductase (Complex I). Effect of substrates on the fragmentation of subunits by trypsin.

It has been shown that treatment of bovine mitochondrial complex I (NADH-ubiquinone oxidoreductase) with NADH or NADPH, but not with NAD or NADP, increases the susceptibility of a number of subunits to tryptic degradation. This increased susceptibility involved subunits that contain electron carriers, such as FMN and iron-sulfur clusters, as well as subunits that lack electron carriers. Results shown elsewhere on changes in the cross-linking pattern of complex I subunits when the enzyme was pretreated with NADH or NADPH (Belogrudov, G., and Hatefi, Y. (1994) Biochemistry 33, 4571-4576) also indicated that complex I undergoes extensive conformation changes when reduced by substrate. Furthermore, we had previously shown that in submitochondrial particles the affinity of complex I for NAD increases by >/=20-fold in electron transfer from succinate to NAD when the particles are energized by ATP hydrolysis. Together, these results suggest that energy coupling in complex I may involve protein conformation changes as a key step. In addition, it has been shown here that treatment of complex I with trypsin in the presence of NADPH, but not NADH or NAD(P), produced from the 39-kDa subunit a 33-kDa degradation product that resisted further hydrolysis. Like the 39-kDa subunit, the 33-kDa product bound to a NADP-agarose affinity column, and could be eluted with a buffer containing NADPH. It is possible that together with the acyl carrier protein of complex I the NADP(H)-binding 39-kDa subunit is involved in intramitochondrial fatty acid synthesis.

Ubiquinol:cytochrome c oxidoreductase. The redox reactions of the bis-heme cytochrome b in unenergized and energized submitochondrial particles.

The redox reactions of the bis-heme cytochrome b of the ubiquinol:cytochrome c oxidoreductase complex (complex III, bc1 complex) were studied in bovine heart submitochondrial particles (SMP). It was shown that (i) when SMP were treated with the complex III inhibitor myxothiazol (or MOA-stilbene or stigmatellin) or with KCN and ascorbate to reduce the high potential centers of complex III (iron-sulfur protein and cytochromes c + c1), NADH or succinate reduced heme bL slowly and incompletely. In contrast, heme bH was reduced by these substrates completely and much more rapidly. Only when the complex III inhibitor was antimycin, and the high potential centers were in the oxidized state, NADH or succinate was able to reduce both bH and bL rapidly and completely. (ii) When NADH or succinate was added to SMP inhibited at complex III by antimycin and energized by ATP, the bis-heme cytochrome b was reduced only partially. Prereduction of the high potential centers was not necessary for this partial b reduction, but slowed down the reduction rate. Deenergization of SMP by uncoupling (or addition of oligomycin to inhibit ATP hydrolysis) resulted in further b reduction. Addition of ATP after b was reduced by substrate resulted in partial b oxidation, and the heme remaining reduced appeared to be mainly bL. Other experiments suggested that the redox changes of cytochrome b effected by energization and deenergization of SMP occurred via electronic communication with the ubiquinone pool. These results have been discussed in relation to current concepts regarding the mechanism of electron transfer by complex III.

High cyclic transhydrogenase activity catalyzed by expressed and reconstituted nucleotide-binding domains of Rhodospirillum rubrum transhydrogenase.

The hydrophilic, extramembranous domains I (alpha 1 subunit) and III of the Rhodospirillum rubrum nicotinamide nucleotide transhydrogenase were expressed in Escherichia coli and purified therefrom as soluble proteins. These domains bind NAD(H) and NADP(H). respectively, and together they form the enzyme's catalytic site. We have demonstrated recently that the isolated domains I and III of the bovine transhydrogenase (or domain I of R. rubrum plus domain III of the bovine enzyme) reconstitute to catalyze transhydrogenation in the absence of the membrane-intercalated domain II, which carries the enzyme's proton channel. Here we show that the expressed domains I and III of the R. rubrum transhydrogenase catalyze a very high NADP(H)-dependent cyclic transhydrogenation from NADH to AcPyAD (3-acetylpyridine adenine dinucleotide) with a Vmax of 214 mumol AcPyAD reduced (min x mg of domain I)-1. The reaction mechanism is 'ping-pong' with respect to NADH and AcPyAD, as these nucleotides bind interchangeably to domain I, and the stereospecificity of hydride ion transfer is from the 4A position of NADH to the 4A position of AcPyAD. The expressed domain I is dimeric, like the native alpha 1 subunit of the enzyme, but the expressed domain III is monomeric and contains 0.94 mol NADP(H) per mol.

Intersubunit interactions in the bovine mitochondrial complex I as revealed by ligand blotting.

Bovine mitochondrial complex I (NADH: ubiquinone oxidoreductase) is composed of 3 structural domains, designated FP (flavoprotein, 3 subunits), IP (iron-sulfur protein, 7-8 subunits) and HP (hydrophobic protein, > 30 subunits). IP intervenes between FP and HP, and in complex I its 75 kDa subunit appears to interact with the 51 kDa subunit of FP. In this study, we show by the technique of ligand blotting that isolated IP binds (a) only to the 51 kDa subunit of FP, and (b) to the 42, 39, 23, 20 and 16 kDa subunits of HP. Because a 23 kDa and a 20 kDa subunit of complex I are potential iron-sulfur proteins, these and our previous results are consistent with the following possible path of electrons in complex I: NADH-->51 and 24 kDa subunit of FP-->75 kDa subunit of IP-->23 and 20 kDa subunits of HP-->ubiquinone.

Membrane topography and near-neighbor relationships of the mitochondrial ATP synthase subunits e, f, and g.

The well characterized subunits of the bovine ATP synthase complex are the alpha, beta, gamma, delta, and epsilon subunits of the catalytic sector, F1; the ATPase inhibitor protein; and subunits a, b, c, and d, OSCP (oligomycin sensitivity-conferring protein), F6, and A6L, which are present in the membrane sector, F0, and the 45-A-long stalk that connects F1 to F0. It has been shown recently that bovine ATP synthase preparations also contain three small polypeptides, designated e, f, and g, with respective molecular masses of 8.2, 10. 2, and 11.3 kDa. To ascertain their involvement as bona fide subunits of the ATP synthase and to investigate their membrane topography and proximity to the above ATP synthase subunits, polyclonal antipeptide antibodies were raised in the rabbit to the COOH-terminal amino acid residues 57-70 of e, 75-86 of f, and 91-102 of g. It was shown that (i) e, f, and g could be immunoprecipitated with anti-OSCP IgG from a fraction of bovine submitochondrial particles enriched in oligomycin-sensitive ATPase; (ii) the NH2 termini of f and g are exposed on the matrix side of the mitochondrial inner membrane and can be curtailed by proteolysis; (iii) the COOH termini of all three polypeptides are exposed on the cytosolic side of the inner membrane; and (iv) f cross-links to A6L and to g, and e cross-links to g and appears to form an e-e dimer. Thus, the bovine ATP synthase complex appears to have 16 unlike subunits, twice as many as its counterpart in Escherichia coli.

Ubiquinol-cytochrome c oxidoreductase. The redox reactions of the bis-heme cytochrome b in ubiquinone-sufficient and ubiquinone-deficient systems.

Antimycin and myxothiazol are stoichiometric inhibitors of complex III (ubiquinol-cytochrome c oxidoreductase), exerting their highest degree of inhibition at I mol each/mol of complex III monomer. Phenomenologically, however, they each inhibit three steps in the redox reaction of the bis-heme cytochrome b in submitochondrial particles (SMP), and all three inhibitions are incomplete to various extents. (i) In SMP, reduction of hemes bH and bL by NADH or succinate is inhibited when the particles are treated with both antimycin and myxothiazol. Each inhibitor alone allows reduced bH and bL to accumulate, indicating that each inhibits the reoxidation of these hemes. (E)-Methyl-3-methoxy-2-(4')-trans-stilbenyl)acrylatc in combination with antimycin or 2-n-heptyl-4-hydroxyquinoline-N-oxide in combination with myxothiazol causes less inhibition of b reduction than the combination of antimycin and myxothiazol. (ii) Reoxidation of reduced b, is inhibited by either antimycin or myxothiazol (or 2-n-heptyl-4-hydroxyquinoline-N-oxide, (E)-methyl-3-methoxy-2-(4'-trans-stilbenyl)acrylate, or stigmatellin). (iii) Reoxidation of reduced bH is also inhibited by any one of these reagents. These inhibitions are also incomplete, and reduced bL is oxidized through the leaks allowed by these inhibitors at least 10 times faster than reduced bH. Heme bH can be reduced in SMP via cytochrome c, and the Rieske iron-sulfur protein by ascorbate and faster by ascorbate + TMPD (N,N,N',N'-tetramethyl-p-phenylenediamine). Energization of SMP by the addition of ATP affords reduction of bL as well. Reverse electron transfer to bH and bL is inhibited partially by myxothiazol, much more by antimycin. Ascorbate + TMPD also reduce bH in ubiquinone-extracted SMP in which the molar ratio of ubiquinone to cytochrome b has been reduced 200-fold from 12.5 to aproximately 0.06. Reconstitution of the extracted particles with ubiquinone-10 restores substrate oxidation but does not improve the rate or the extent of b, reduction by ascorbate + TMPD. These reagents also partially reduce cytochrome b in SMP from a ubiquinone-deficient yeast mutant. The above results are discussed in relation to the Q-cycle hypothesis.

Nicotinamide nucleotide transhydrogenase: a model for utilization of substrate binding energy for proton translocation.

The energy-transducing nicotinamide nucleotide transhydrogenases of mammalian mitochondria and bacteria are structurally related membrane-bound enzymes that catalyze the direct transfer of a hydride ion between NAD(H) and NADP(H) in a reaction that is coupled to transmembrane proton translocation. The protonmotive force alters the affinity of the transhydrogenase for substrates, accelerates the rate of hydride ion transfer from NADH to NADP, and shifts the equilibrium of this reaction toward NADPH formation. Transhydrogenation in the reverse direction from NADPH to NAD is accompanied by outward proton translocation and formation of a protonmotive force. In reverse transhydrogenation, the enzyme utilizes substrate binding energy for proton pumping. Therefore, with regard to the mechanism of energy transduction, the transhydrogenase works according to the same principles as the ATP synthase complex of mitochondria and bacteria, the proton and cation ATPases, and possibly certain redox-linked proton pumps. However, the relatively simple structure of the transhydrogenase recommends it as a model for study of the utilization of binding energy for vectorial translocation of protons and other cations.

Proton-translocating nicotinamide nucleotide transhydrogenase. Reconstitution of the extramembranous nucleotide-binding domains.

The nicotinamide nucleotide transhydrogenase of bovine mitochondria is a homodimer of monomer M(r) = 109,065. The monomer is composed of three domains, an NH2-terminal 430-residue-long hydrophilic domain I that binds NAD(H), a central 400-residue-long hydrophobic domain II that is largely membrane intercalated and carries the enzyme's proton channel, and a COOH-terminal 200-residue-long hydrophilic domain III that binds NADP(H). Domains I and III protrude into the mitochondrial matrix, where they presumably come together to form the enzyme's catalytic site. The two-subunit transhydrogenase of Escherichia coli and the three-subunit transhydrogenase of Rhodospirillum rubrum have each the same overall tridomain hydropathy profile as the bovine enzyme. Domain I of the R. rubrum enzyme (the alpha 1 subunit) is water soluble and easily removed from the chromatophore membranes. We have isolated domain I of the bovine transhydrogenase after controlled trypsinolysis of the purified enzyme and have expressed in E. coli and purified therefrom domain III of this enzyme. This paper shows that an active bidomain transhydrogenase lacking domain II can be reconstituted by the combination of purified bovine domains I plus III or R. rubrum domain I plus bovine domain III.

Proton-translocating nicotinamide nucleotide transhydrogenase of Escherichia coli. Involvement of aspartate 213 in the membrane-intercalating domain of the beta subunit in energy transduction.

Mutations in the beta subunit of Escherichia coli proton-translocating nicotinamide nucleotide transhydrogenase of the conserved residue beta Asp-213 to Asn (beta D213N) and Ile (beta D213I) resulted in the loss, respectively, of about 70% and 90% NADPH-->3-acetylpyridine adenine dinucleotide (AcPyAD) transhydrogenation and coupled proton translocation activities. However, the cyclic NADP(H)-dependent NADH-->AcPyAD transhydrogenase activities of the mutants were only approximately 35% inhibited. The latter transhydrogenation, which is not coupled to proton translocation, occurs apparently via NADP under conditions that enzyme-NADP(H) complex is stabilized. Mutations beta D213N and beta D213I also resulted in decreases in apparent KmNADPH for the NADPH-->AcPyAD and S0.5NADPH (NADPH concentration needed for half-maximal activity) for the cyclic NADH-->AcPyAD transhydrogenation reactions, and in KdNADPH, as determined by equilibrium binding studies on the purified wild-type and the beta D213I mutant enzymes. These results point to a structural role of beta Asp-213 in energy transduction and are discussed in relation to our previous suggestion that proton translocation coupled to NADPH-->NAD (or AcPyAD) transhydrogenation is driven mainly by the difference in the binding energies of NADPH and NADP.

ATP synthase complex. Proximities of subunits in bovine submitochondrial particles.

The catalytic sector, F1, and the membrane sector, F0, of the mitochondrial ATP synthase complex are joined together by a 45-A-long stalk. Knowledge of the composition and structure of the stalk is crucial to investigating the mechanism of conformational energy transfer between F0 and F1. This paper reports on the near neighbor relationships of the stalk subunits with one another and with the subunits of F1 and F0, as revealed by cross-linking experiments. The preparations subjected to cross-linking were bovine heart submitochondrial particles (SMP) and F1-deficient SMP. The cross-linkers were three reagents of different chemical specificities and different lengths of cross-linking from zero to 10 A. Cross-linked products were identified after gel electrophoresis of the particles and immunoblotting with subunit-specific antibodies to the individual subunits alpha, beta, gamma, delta, OSCP, F6, A6L, a (subunit 6), b, c, and d. The results suggested that the two b subunits form the principal stem of the stalk to which OSCP, d, and F6 are bound independent of one another. Subunits b, OSCP, d, and F6 cross-linked to alpha and/or beta, but not to gamma or delta. The COOH-terminal half of A6L, which is extramembranous, cross-linked to d but not to any other stalk or F1 subunit. No cross-links of subunits a and c with any stalk or F1 subunits were detected. In F1-deficient SMP, cross-linked b+b and d+F6 dimers appeared, and the extent of cross-linking between b and OSCP diminished greatly. The addition of F1 to F1-deficient particles appeared to reverse these changes. Treatment of F1-deficient particles with trypsin rapidly hydrolyzed away OSCP and F6, fragmented b to membrane-bound 18-, 12-, and 8-9-kDa antigenic fragments, which cross-linked to d and/or with one another. Trypsin also removed the COOH-terminal part of A6L, but the remainder still cross-linked to subunit d. Models showing the near neighbor relationships of the stalk subunits with one another and with the alpha and beta subunits at a level near the proximal end (bottom) of F1 and at the membrane-matrix interface are presented.

Studies on reconstitution of the Rhodospirillum rubrum nicotinamide nucleotide transhydrogenase.

The energy-transducing nicotinamide nucleotide transhydrogenase of Rhodospirillum rubrum is composed of 3 subunits alpha 1, alpha 2 and beta, with M(r) values, respectively, of 40.3, 14.9 and 47.8 kDa. Subunit alpha 1 is water-soluble, loosely bound to chromatophores, and can be easily and reversibly removed. Subunits alpha 2 and beta are integral membrane proteins, and their removal from chromatophores requires the use of detergents. Treatment of chromatophores with various detergents inhibited reconstitution of transhydrogenase activity when alpha 1 was added to the detergent-treated chromatophores. This apparent inhibition could be reversed by addition of a divalent metal ion. The best condition for extraction of alpha 2/beta from chromatophores was the use of 1% deoxycholate in the presence of 0.34 M KCl. Under these conditions, the extracted alpha 2/beta mixed with purified alpha 1 was completely inactive, but gained full activity when the assay medium was supplemented with 2-3 mM MgCl2 or CaCl2. It was shown that metal ions had little effect on the apparent Km of substrates, but greatly increased the affinity between purified alpha 1 and the detergent-treated or detergent-solubilized alpha 2/beta. It seems possible that the R. rubrum transhydrogenase contains a detergent-extractable metal ion, which is required for proper binding of the soluble alpha 1 subunit to the chromatophore-bound alpha 2/beta subunits.

Effect of ethoxyformic anhydride on the Rieske iron-sulfur protein of bovine heart ubiquinol: cytochrome c oxidoreductase.

Treatment of bovine heart ubiquinol-cytochrome c oxidoreductase (complex III, bc1 complex) with ethoxyformic anhydride (EFA) inhibits electron transfer between cytochromes b and c1 [Yagi et al., Biochemistry 21 (1982) 4777-4782]. This paper shows that EFA alters the EPR lineshape of the Rieske iron-sulfur cluster in complex III and in the isolated Rieske protein without a significant decrease of spin concentration. The effect of EFA on the Rieske iron-sulfur cluster is competitive with that of Qo site inhibitors, such as stigmatellin, and is completely reversed by hydroxylamine. These results are consistent with the possible ethoxyformylation by EFA of histidine ligands of the Rieske iron-sulfur cluster at the non-iron binding imidazole nitrogens.

Thermodynamic analysis of flavin in mitochondrial NADH:ubiquinone oxidoreductase (complex I).

This paper reports the first direct characterization of flavin (noncovalently bound FMN) in energy coupling site I of the mitochondrial respiratory chain. Thermodynamic parameters of its redox reactions were determined potentiometrically monitoring the g = 2.005 signal of its free radical form in isolated bovine heart NADH:ubiquinone oxidoreductase (complex I). The midpoint redox potentials of consecutive one-electron reduction steps are Em1/0 = -414 mV and Em2/1 = -336 mV at pH 7.5. This corresponds to a stability constant of the intermediate flavosemiquinone state of 4.5 x 10(-2). The pK values of the free radical (Fl.-<==>FlH.) and reduced flavin (FlH-<==>FlH2) were estimated as 7.7 and 7.1, respectively. The potentiometrically obtained g = 2.005 flavin free radical EPR signal revealed an unusually broad (2.4 mT) and pH-independent peak-to-peak line width. The spin relaxation of flavosemiquinone in complex I is much faster than that of flavodoxin due to strong dipole-dipole interaction with iron-sulfur cluster N3. Guanidine, an activator of NADH-ferricyanide reductase activity of complex I, was found to have a strong stabilizing effect on the flavin free radical generated both by equilibration with the NADH/NAD+ redox couple and by potentiometric redox titration. The addition of guanidine also leads to a slight modification of the EPR spectrum of iron-sulfur cluster N3. Anaerobic titration of flavosemiquinone free radical with the strictly n = 2 NADH/NAD+ and APADH/APAD+ redox couples revealed that nucleotide binding narrows the EPR signal line width of the flavin free radical to 1.7 mT and changes a shape of the titration curve.(ABSTRACT TRUNCATED AT 250 WORDS)

Energy-transducing nicotinamide nucleotide transhydrogenase: nucleotide sequences of the genes and predicted amino acid sequences of the subunits of the enzyme from Rhodospirillum rubrum.

Based on the amino acid sequence of the N-terminus of the soluble subunit of the Rhodospirillum rubrum nicotinamide nucleotide transhydrogenase, two oligonucleotide primers were synthesized and used to amplify the corresponding DNA segment (110 base pairs) by the polymerase chain reaction. Using this PCR product as a probe, one clone with the insert of 6.4 kbp was isolated from a genomic library of R. rubrum and sequenced. This sequence contained three open reading frames, constituting the genes nntA1, nntA2, and nntB of the R. rubrum transhydrogenase operon. The polypeptides encoded by these genes were designated alpha 1, alpha 2, and beta, respectively, and are considered to be the subunits of the R. rubrum transhydrogenase. The predicted amino acid sequence of the alpha 1 subunit (384 residues; molecular weight 40276) has considerable sequence similarity to the alpha subunit of the Escherichia coli and the N-terminal 43-kDa segment of the bovine transhydrogenases. Like the latter, it has a beta alpha beta fold in the corresponding region, and the purified, soluble alpha 1 subunit cross-reacts with antibody to the bovine N-terminal 43-kDa fragment. The predicted amino acid sequence of the beta subunit of the R. rubrum transhydrogenase (464 residues; molecular weight 47808) has extensive sequence identity with the beta subunit of the E. coli and the corresponding C-terminal sequence of the bovine transhydrogenases. The chromatophores of R. rubrum contain a 48-kDa polypeptide, which cross-reacts with antibody to the C-terminal 20-kDa fragment of the bovine transhydrogenase. The predicted amino acid sequence of the alpha 2 subunit of the R. rubrum enzyme (139 residues; molecular weight 14888) has considerable sequence identity in its C-terminal half to the corresponding segments of the bovine and the alpha subunit of the E. coli transhydrogenases.