Mutsuo Yamaguchi scite author profile

Sod2-/- mice, which are deficient in the mitochondrial form of superoxide dismutase (MnSOD), have a short survival time that is strongly affected by genetic background. This suggests the existence of genetic modifiers that are capable of modulating the degree of mitochondrial oxidative damage caused by the MnSOD deficiency, thereby altering longevity. To identify these modifier(s), we generated recombinant congenic mice with quantitative trait loci (QTL) containing the putative genetic modifiers on the short-lived C57BL/6J genetic background. MnSOD deficient C57BL/6J mice with a QTL from the distal region of chromosome 13 from DBA/2J were able to survive for as long as those generated on the long-lived DBA/2J background. Within this region, the gene encoding nicotinamide nucleotide transhydrogenase (Nnt) was found to be defective in C57BL/6J mice, and no mature NNT protein could be detected. The forward reaction of NNT, a nuclear-encoded mitochondrial inner membrane protein, couples the generation of NADPH to proton transport and provides NADPH for the regeneration of two important antioxidant compounds, glutathione and thioredoxin, in the mitochondria. This action of NNT could explain its putative protective role in MnSOD-deficient mice.

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

Hatefi

Yamaguchi

1996

FASEB j.

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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.

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Division of labor in transhydrogenase by alternating proton translocation and hydride transfer

Leung

Schurig-Briccio

Yamaguchi

et al. 2015

Science

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NADPH/NADP+ homeostasis is critical for countering oxidative stress in cells. Nicotinamide nucleotide transhydrogenase (TH), a membrane enzyme present in both bacteria and mitochondria, couples the proton motive force to the generation of NADPH. We present the 2.8 Å crystal structure of the transmembrane proton channel domain of TH from Thermus thermophilus and the 6.9 Å crystal structure of the entire enzyme (holo-TH). The membrane domain crystallized as a symmetric dimer, with each protomer containing a putative proton channel. The holo-TH is a highly asymmetric dimer with the NADP(H)-binding domain (dIII) in two different orientations. This unusual arrangement suggests a catalytic mechanism in which the two copies of dIII alternatively function in proton translocation and hydride transfer.

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

Yamaguchi

Hatefi

1997

Biochimica et Biophysica Acta (BBA) - Bioenergetics

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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.

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Crystal Structures of Transhydrogenase Domain I with and without Bound NADH^,

et al. 2002

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Transhydrogenase (TH) is a dimeric integral membrane enzyme in mitochondria and prokaryotes that couples proton translocation across a membrane with hydride transfer between NAD(H) and NADP(H) in soluble domains. Crystal structures of the NAD(H) binding R1 subunit (domain I) of Rhodospirillum rubrum TH have been determined at 1.8 Å resolution in the absence of dinucleotide and at 1.9 Å resolution with NADH bound. Each structure contains two domain I dimers in the asymmetric unit (AB and CD); the dimers are intimately associated and related by noncrystallographic 2-fold axes. NADH binds to subunits A and D, consistent with the half-of-the-sites reactivity of the enzyme. The conformation of NADH in subunits A and D is very similar; the nicotinamide is in the anti conformation, the A-face is exposed to solvent, and both N7 and O7 participate in hydrogen bonds. Comparison of subunits A and D to six independent copies of the subunit without bound NADH reveals multiple conformations for residues and loops surrounding the NADH site, indicating flexibility for binding and release of the substrate (product). The NADH-bound structure is also compared to the structures of R. rubrum domain I with NAD bound (PDB code 1F8G) and with NAD bound in complex with domain III of TH (PDB code 1HZZ). The NADH-vs NAD-bound domain I structures reveal conformational differences in conserved residues in the NAD(H) binding site and in dinucleotide conformation that are correlated with the net charge, i.e., oxidation state, of the nicotinamides. The comparisons illustrate how nicotinamide oxidation state can affect the domain I conformation, which is relevant to the hydride transfer step of the overall reaction.The energy-transducing nicotinamide nucleotide transhydrogenases of eukaryotic mitochondria and bacteria are homodimeric integral membrane proteins of monomer molecular mass of about 110 kDa. They catalyze the direct and stereospecific transfer of a hydride ion between the 4A position of NAD(H) 1 and the 4B position of NADP(H) in a reaction that is coupled to transmembrane proton translocation with a H + /H -stoichiometry of n ) 1 (eq 1) (1-4).In bovine submitochondrial particles, the proton motive force (pmf) accelerates the forward reaction 10-12-fold, and shifts the equilibrium toward product formation. In the reverse direction, transhydrogenation from NADPH to NAD results in outward proton translocation and creation of a pmf. Because there is essentially no difference in the reduction potential of the nicotinamide cofactors, the driving force for proton translocation coupled to the reverse reaction is the difference in binding affinities for substrates (NADPH, NAD) and products (NADH, NADP). In mammalian mitochondria, a function of TH is to produce NADPH for reduction of toxic H 2 O 2 by glutathione reductase and glutathione peroxidase.TH monomers are composed of three domains: a 400-430-residue hydrophilic domain I, a 360-400-residue hydrophobic domain II, and a 200-residue hydrophilic domain III. In mammalian TH, the ...

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