Purification and properties of the H(+)-nicotinamide nucleotide transhydrogenase from Rhodobacter capsulatus

Energy transfer between the nicotinamide nucleotide transhydrogenase and ATP synthase of Escherichia coli

Membrane bound nicotinamide nucleotide transhydrogenase (TH) catalyses the hydride transfer from NADH to NADP⁺. Under physiological conditions, this reaction is endergonic and must be energized by the pmf, coupled to transmembrane proton transport. Recent structures of transhydrogenase holoenzymes suggest new mechanistic details, how the long-distance coupling between hydride transfer in the peripheral nucleotide binding sites and the membrane-localized proton transfer occurs that now must be tested experimentally. Here, we provide protocols for the efficient expression and purification of the Escherichia coli transhydrogenase and its reconstitution into liposomes, alone or together with the Escherichia coli F₁F₀ ATP synthase. We show that E. coli transhydrogenase is a reversible enzyme that can also work as a NADPH-driven proton pump. In liposomes containing both enzymes, NADPH driven H⁺-transport by TH is sufficient to instantly fuel ATP synthesis, which adds TH to the pool of pmf generating enzymes. If the same liposomes are energized with ATP, NADPH production by TH is stimulated > sixfold both by a pH gradient or a membrane potential. The presented protocols and results reinforce the tight coupling between hydride transfer in the peripheral nucleotide binding sites and transmembrane proton transport and provide powerful tools to investigate their coupling mechanism.

NADPH-generating systems in bacteria and archaea

Reduced nicotinamide adenine dinucleotide phosphate (NADPH) is an essential electron donor in all organisms. It provides the reducing power that drives numerous anabolic reactions, including those responsible for the biosynthesis of all major cell components and many products in biotechnology. The efficient synthesis of many of these products, however, is limited by the rate of NADPH regeneration. Hence, a thorough understanding of the reactions involved in the generation of NADPH is required to increase its turnover through rational strain improvement. Traditionally, the main engineering targets for increasing NADPH availability have included the dehydrogenase reactions of the oxidative pentose phosphate pathway and the isocitrate dehydrogenase step of the tricarboxylic acid (TCA) cycle. However, the importance of alternative NADPH-generating reactions has recently become evident. In the current review, the major canonical and non-canonical reactions involved in the production and regeneration of NADPH in prokaryotes are described, and their key enzymes are discussed. In addition, an overview of how different enzymes have been applied to increase NADPH availability and thereby enhance productivity is provided.

Quantitative proteomic analysis of intracytoplasmic membrane development in Rhodobacter sphaeroides

The purple phototrophic bacteria elaborate a specialized intracytoplasmic membrane (ICM) system for the conversion of solar energy to ATP. Previous radiolabelling and ultrastructural experiments have shown that ICM assembly in Rhodobacter sphaeroides is initiated at indentations of the cytoplasmic membrane, termed UPB. Here, we report proteomic analyses of precursor (UPB) and mature (ICM) fractions. Qualitative data identified 387 proteins, only 43 of which were found in the ICM, reflecting its specialized role within the cell, the conversion of light into chemical energy; 236 proteins were found in the significantly more complex UPB proteome. Metabolic labelling was used to quantify the relative distribution of 173 proteins between the UPB and ICM fractions. Quantification reveals new information on assembly of the RC-LH1-PufX, ATP synthase and NAD(P)H transhydrogenase complexes, as well as showing that the UPB is enriched in enzymes for lipid, carbohydrate and amino acid metabolism, tetrapyrrole biosynthesis and proteins representing a wide range of other metabolic and biosynthetic functions. Proteins involved in light harvesting, photochemistry, electron transport and ATP synthesis are all enriched in ICM, consistent with the spatial proximity of energy capturing and transducing functions. These data provide further support to the developmental precursor-product relationship between UPB and ICM.

The specificity of proton-translocating transhydrogenase for nicotinamide nucleotides

In its forward direction, transhydrogenase couples the reduction of NADP(+) by NADH to the outward translocation of protons across the membrane of bacteria and animal mitochondria. The enzyme has three components: dI and dIII protrude from the membrane and dII spans the membrane. Hydride transfer takes place between nucleotides bound to dI and dIII. Studies on the kinetics of a lag phase at the onset of a "cyclic reaction" catalysed by complexes of the dI and dIII components of transhydrogenase from Rhodospirillum rubrum, and on the kinetics of fluorescence changes associated with nucleotide binding, reveal two features. Firstly, the binding of NADP(+) and NADPH to dIII is extremely slow, and is probably limited by the conversion of the occluded to the open state of the complex. Secondly, dIII can also bind NAD(+) and NADH. Extrapolating to the intact enzyme this binding to the "wrong" site could lead to slip: proton translocation without change in the nucleotide redox state, which would have important consequences for bacterial and mitochondrial metabolism.

Nucleotide binding affinities of the intact proton-translocating transhydrogenase from Escherichia coli

Transhydrogenase (E.C. 1.6.1.1) couples the redox reaction between NAD(H) and NADP(H) to the transport of protons across a membrane. The enzyme is composed of three components. The dI and dIII components, which house the binding site for NAD(H) and NADP(H), respectively, are peripheral to the membrane, and dII spans the membrane. We have estimated dissociation constants (K(d) values) for NADPH (0.87 microM), NADP(+) (16 microM), NADH (50 microM), and NAD(+) (100-500 microM) for intact, detergent-dispersed transhydrogenase from Escherichia coli using micro-calorimetry. This is the first complete set of dissociation constants of the physiological nucleotides for any intact transhydrogenase. The K(d) values for NAD(+) and NADH are similar to those previously reported with isolated dI, but the K(d) values for NADP(+) and NADPH are much larger than those previously reported with isolated dIII. There is negative co-operativity between the binding sites of the intact, detergent-dispersed transhydrogenase when both nucleotides are reduced or both are oxidized.

Conformational diversity in NAD(H) and interacting transhydrogenase nicotinamide nucleotide binding domains

Transhydrogenase (TH) couples direct and stereospecific hydride transfer between NAD(H) and NADP(H), bound within soluble domains I and III, respectively, to proton translocation across membrane bound domain II. The cocrystal structure of Rhodospirillum rubrum TH domains I and III has been determined in the presence of limiting NADH, under conditions in which the subunits reach equilibrium during crystallization. The crystals contain three heterotrimeric complexes, dI(2)dIII, in the asymmetric unit. Multiple conformations of loops and side-chains, and NAD(H) cofactors, are observed in domain I pertaining to substrate/product exchange, and highlighting electrostatic interactions during the hydride transfer. Two interacting NAD(H)-NADPH pairs are observed where alternate conformations of the NAD(H) phosphodiester and conserved arginine side-chains are correlated. In addition, the stereochemistry of one NAD(H)-NADPH pair approaches that expected for nicotinamide hydride transfer reactions. The cocrystal structure exhibits non-crystallographic symmetry that implies another orientation for domain III, which could occur in dimeric TH. Superposition of the "closed" form of domain III (PDB 1PNO, chain A) onto the dI(2)dIII complex reveals a severe steric conflict of highly conserved loops in domains I and III. This overlap, and the overlap with a 2-fold related domain III, suggests that motions of loop D within domain III and of the entire domain are correlated during turnover. The results support the concept that proton pumping in TH is driven by the difference in binding affinity for oxidized and reduced nicotinamide cofactors, and in the absence of a difference in redox potential, must occur through conformational effects.

Essential glycine in the proton channel of Escherichia coli transhydrogenase

The nicotinamide nucleotide transhydrogenases of mitochondria and bacteria are proton pumps that couple hydride ion transfer between NAD(H) and NADP(H) bound, respectively, to extramembranous domains I and III, to proton translocation by the membrane-intercalated domain II. Previous experiments have established the involvement of three conserved domain II residues in the proton pumping function of the enzyme: His91, Ser139, and Asn222, located on helices 9, 10, and 13, respectively. Eight highly conserved domain II glycines in helices 9, 10, 13, and 14 were mutated to alanine, and the mutant enzymes were assayed for hydride transfer between domains I and III and for proton translocation by domain II. One of the glycines on helix 14, Gly252, was further mutated to Cys, Ser, Thr, and Val, expression levels of the mutant enzymes were evaluated, and each was purified and assayed. The results show that Gly252 is essential for function and support a model for the proton channel composed of helices 9, 10, 13, and 14. Gly252 would allow spatial proximity of His91, Ser139, and Asn222 for proton conductance within the channel. Gly252 mutants are distinguished by high levels of cyclic transhydrogenation activity in the absence of added NADP(H) and by complete loss of proton pumping activity. The purified G252A mutant has <1% proton translocation and reverse transhydrogenation activity, retains 0.9 mol of NADP(H) per domain III, and has 96% intrinsic cyclic transhydrogenation activity, which does not exceed 100% upon the addition of NADP(H). These properties imply that Gly252 mutants exhibit a native-like domain II conformation while blocking proton translocation and coupled exchange of NADP(H) in domain III.

The proton channel of the energy-transducing nicotinamide nucleotide transhydrogenase of Escherichia coli

The nicotinamide nucleotide transhydrogenases of mitochondria and bacteria are proton pumps that couple direct hydride ion transfer between NAD(H) and NADP(H) bound, respectively, to extramembranous domains I and III to proton translocation by the membrane-intercalated domain II. To delineate the proton channel of the enzyme, 25 conserved and semiconserved prototropic amino acid residues of domain II of the Escherichia coli transhydrogenase were mutated, and the mutant enzymes were assayed for transhydrogenation from NADPH to an NAD analogue and for the coupled outward proton translocation. The results confirmed the previous findings of others and ourselves on the essential roles of three amino acid residues and identified another essential residue. Three of these amino acids, His-91, Ser-139, and Asn-222, occur in three separate membrane-spanning alpha helices of domain II of the beta subunit of the enzyme. Another residue, Asp-213, is probably located in a cytosolic-side loop that connects to the alpha helix bearing Asn-222. It is proposed that the three helices bearing His-91, Ser-139, and Asn-222 come together, possibly with another highly conserved alpha helix to form a four-helix bundle proton channel and that Asp-213 serves to conduct protons between the channel and domain III where NADPH binding energy is used via protein conformation change to initiate outward proton translocation.

Link between the membrane-bound pyridine nucleotide transhydrogenase and glutathione-dependent processes in Rhodobacter sphaeroides

The presence of a glutathione-dependent pathway for formaldehyde oxidation in the facultative phototroph Rhodobacter sphaeroides has allowed the identification of gene products that contribute to formaldehyde metabolism. Mutants lacking the glutathione-dependent formaldehyde dehydrogenase (GSH-FDH) are sensitive to metabolic sources of formaldehyde, like methanol. This growth phenotype is correlated with a defect in formaldehyde oxidation. Additional methanol-sensitive mutants were isolated that contained Tn5 insertions in pntA, which encodes the alpha subunit of the membrane-bound pyridine nucleotide transhydrogenase. Mutants lacking transhydrogenase activity have phenotypic and physiological characteristics that are different from those that lack GSH-FDH activity. For example, cells lacking transhydrogenase activity can utilize methanol as a sole carbon source in the absence of oxygen and do not display a formaldehyde oxidation defect, as determined by whole-cell (13)C-nuclear magnetic resonance. Since transhydrogenase can be a major source of NADPH, loss of this enzyme could result in a requirement for another source for this compound. Evidence supporting this hypothesis includes increased specific activities of other NADPH-producing enzymes and the finding that glucose utilization by the Entner-Doudoroff pathway restores aerobic methanol resistance to cells lacking transhydrogenase activity. Mutants lacking transhydrogenase activity also have higher levels of glutathione disulfide under aerobic conditions, so it is consistent that this strain has increased sensitivity to oxidative stress agents like diamide, which are known to alter the oxidation reduction state of the glutathione pool. A model will be presented to explain the role of transhydrogenase under aerobic conditions when cells need glutathione both for GSH-FDH activity and to repair oxidatively damaged proteins.

Stopped-flow reaction kinetics of recombinant components of proton-translocating transhydrogenase with physiological nucleotides

New information on the high resolution structure of the membrane proton pump, transhydrogenase, now provides a framework for understanding kinetic descriptions of the enzyme. Here, we have studied redox reactions catalyzed by mixtures of the recombinant NAD(H)-binding component (dI) of Rhodospirillum rubrum transhydrogenase, and the recombinant NADP(H)-binding component (dIII) of either the R. rubrum enzyme or the human enzyme. By recording changes in the fluorescence emission of native and engineered Trp residues, the rates of the redox reaction with physiological nucleotides have been measured under stopped-flow conditions, for the first time. Rate constants for the binding reaction between NAD(+)/NADH and the R. rubrum dI.dIII complex are much greater than those between nucleotide and isolated dI. For the redox step between the physiological nucleotides on the R. rubrum dI. dIII complex, the rate constant in the forward direction, k(f) approximately 2900 s(-1), and that for the reverse reaction, k(r) approximately 110 s(-1). Comparisons with reactions involving an analogue of NAD(H) indicate that the rate constants at this step are strongly affected by the redox driving force.

A catalytically active complex formed from the recombinant dI protein of Rhodospirillum rubrum transhydrogenase, and the recombinant dIII protein of the human enzyme

Transhydrogenase is a proton pump. It has three components: dI and dIII protrude from the membrane and contain the binding sites for NAD(H) and NADP(H), respectively, and dII spans the membrane. We have expressed dIII from Homo sapiens transhydrogenase (hsdIII) in Escherichia coli. The purified protein was associated with stoichiometric amounts of NADP(H) bound to the catalytic site. The NADP+ and NADPH were released only slowly from the protein, supporting the suggestion that nucleotide-binding by dIII is regulated by the membrane-spanning dII. HsdIII formed a catalytically active complex with recombinant dI from Rhodospirillum rubrum (rrdI), even in the absence of dII. The rates of forward and reverse transhydrogenation catalysed by this complex are probably limited by slow release from dIII of NADPH and NADP+, respectively. The hybrid complex also catalysed high rates of 'cyclic' transhydrogenation, indicating that hydride transfer, and exchange of nucleotides with dI, are rapid. Stopped-flow experiments revealed a rapid, monoexponential, single-turnover burst of reverse transhydrogenation in pre-steady-state. The apparent first-order rate constant of the burst increased with the concentration of rrdI. A deuterium isotope effect (kH/kD approximately 2 at 27 degrees C) was observed when [4B-1H]NADPH was replaced with [4B-2H]NADPH. The characteristics of the burst of transhydrogenation with rrdI:hsdIII differed from those previously reported for rrdI:rrdIII (J.D. Venning et al., Eur. J. Biochem. 257 (1998) 202-209), but the differences are readily explained by a greater dissociation constant of the hybrid complex. The steady-state rate of reverse transhydrogenation by the rrdI:hsdIII complex was almost independent of pH, but there was a single apparent pKa ( approximately 9.1) associated with the cyclic reaction. The reactions of the dI:dIII complex probably proceed independently of those protonation/deprotonation reactions which, in the complete enzyme, are associated with H+ translocation.

Interdomain hydride transfer in proton-translocating transhydrogenase

We describe the use of the recombinant, nucleotide-binding domains (domains I and III) of transhydrogenase to study structural, functional and dynamic features of the protein that are important in hydride transfer and proton translocation. Experiments on the transient state kinetics of the reaction show that hydride transfer takes place extremely rapidly in the recombinant domain I:III complex, even in the absence of the membrane-spanning domain II. We develop the view that proton translocation through domain II is coupled to changes in the binding characteristics of NADP+ and NADPH in domain III. A mobile loop region which emanates from the surface of domain I, and which interacts with NAD+ and NADH during nucleotide binding has been studied by NMR spectroscopy and site-directed mutagenesis. An important role for the loop region in the process of hydride transfer is revealed.

Role of methionine-239, an amino acid residue in the mobile-loop region of the NADH-binding domain (domain I) of proton-translocating transhydrogenase

Transhydrogenase couples the transfer of hydride equivalents between NAD(H) and NADP(H) to proton translocation across a membrane. The one-dimensional proton NMR spectrum of the recombinant NAD(H)-binding domain (domain I) of transhydrogenase from Rhodospirillum rubrum reveals well-defined resonances, several of which arise from a mobile loop at the protein surface. Four have been assigned to Met residues (MetA-MetD). Substitution of Met239 with either Ile (dI.M239I) or Phe (dI.M239F) resulted in loss of MetA from the NMR spectrum. Broadening and shifting of the mobile loop resonances consequent on NAD(H) binding indicate that the loop closes down on the protein surface. More NAD(H) had to be added to mutant domain I than to wild type to give comparable resonance broadening. The Kd of domain I for NADH, measured by equilibrium dialysis, was increased about three-fold by the Met239 mutations. Mutant and wild-type domain I were reconstituted with domain I-depleted membranes from R. rubrum, and with recombinant domain III of transhydrogenase. With membranes, the Km for acetylpyridine adenine dinucleotide during reverse transhydrogenation was 5x and > 6x greater in dI.M239I and dI.M239F, respectively, than in wild-type. Cyclic transhydrogenation (in membranes and the recombinant system) was substantially more inhibited (70% in dI.M239I, and 84% in dI.M239F) than either forward or reverse transhydrogenation. The docking affinities of dI.M239I and dI.M239F to the depleted membranes were similar to those of wild-type. It is concluded that Met239 is MetA in the mobile loop of domain I, and that in proteins with amino acid substitutions at this position, the binding affinity of NAD(H) is decreased, and the hydride transfer step is inhibited.

The pH dependences of reactions catalyzed by the complete proton-translocating transhydrogenase from Rhodospirillum rubrum, and by the complex formed from its recombinant nucleotide-binding domains

Transhydrogenase couples the translocation of protons across a membrane to the transfer of reducing equivalents between NAD(H) and NADP(H). Using transhydrogenase from Rhodospirillum rubrum we have examined the pH dependences of the 'forward' and 'reverse' reactions, and of the 'cyclic' reaction (NADP(H)-dependent reduction of the analogue, acetyl pyridine adenine dinucleotide, by NADH). In the case of the membrane-bound protein in chromatophores, the imposition of a protonmotive force through the action of the light-driven electron-transport system, stimulated forward transhydrogenation, inhibited reverse transhydrogenation, but had no effect on the cyclic reaction. The differential response at a range of pH values provides evidence that hydride transfer per se is not coupled to proton translocation and supports the view that energy transduction occurs at the level of NADP(H) binding. Chromatophore transhydrogenase and the detergent-dispersed enzyme both have bell-shaped pH dependences for forward and reverse transhydrogenation. The cyclic reaction, however, is rapid at low and neutral pH, and is attenuated only at high pH. A mixture of recombinant purified NAD(H)-binding domain I, and NADP(H)-binding domain III, of R. rubrum transhydrogenase carry out the cyclic reaction with a similar pH profile to that of the complete enzyme, but the forward and reverse reactions were much less pH dependent. The rates of release of NADP+ and of NADPH from isolated domain III were pH independent. The results are consistent with a model for transhydrogenation, in which proton binding from one side of the membrane is consequent upon the binding of NADP+ to the enzyme, and then proton release on the other side of the membrane precedes NADPH release.

Evidence that the transfer of hydride ion equivalents between nucleotides by proton-translocating transhydrogenase is direct

The molecular masses of the purified, recombinant nucleotide-binding domains (domains I and III) of transhydrogenase from Rhodospirillum rubrum were determined by electrospray mass spectrometry. The values obtained, 40,273 and 21,469 Da, for domains I and III, respectively, are similar to those estimated from the amino acid sequences of the proteins. Evidently, there are no prosthetic groups or metal centers that can serve as reducible intermediates in hydride transfer between nucleotides bound to these proteins. The transient-state kinetics of hydride transfer catalyzed by mixtures of recombinant domains I and III were studied by stopped-flow spectrophotometry. The data indicate that oxidation of NADPH, bound to domain III, and reduction of acetylpyridine adenine dinucleotide (an NAD+ analogue), bound to domain I, are simultaneous and very fast. The transient-state reaction proceeds as a biphasic burst of hydride transfer before establishment of a steady state, which is limited by slow release of NADP+. Hydride transfer between the nucleotides is evidently direct. This conclusion indicates that the nicotinamide rings of the nucleotides are in close apposition during the hydride transfer reaction, and it imposes firm constraints on the mechanism by which transhydrogenation is linked to proton translocation.

The reduction of acetylpyridine adenine dinucleotide by NADH: is it a significant reaction of proton-translocating transhydrogenase, or an artefact?

Transhydrogenase is a proton pump. It has separate binding sites for NAD+/NADH (on domain I of the protein) and for NADP+/NADPH (on domain III). Purified, detergent-dispersed transhydrogenase from Escherichia coli catalyses the reduction of the NAD+ analogue, acetylpyridine adenine dinucleotide (AcPdAD+), by NADH at a slow rate in the absence of added NADP+ or NADPH. Although it is slow, this reaction is surprising, since transhydrogenase is generally thought to catalyse hydride transfer between NAD(H)--or its analogues and NADP(H)--or its analogues, by a ternary complex mechanism. It is shown that hydride transfer occurs between the 4A position on the nicotinamide ring of NADH and the 4A position of AcPdAD+. On the basis of the known stereospecificity of the enzyme, this eliminates the possibilities of transhydrogenation(a) from NADH in domain I to AcPdAD+ wrongly located in domain III; and (b) from NADH wrongly located in domain III to AcPdAD+ in domain I. In the presence of low concentrations of added NADP+ or NADPH, detergent-dispersed E. coli transhydrogenase catalyses the very rapid reduction of AcPdAD+ by NADH. This reaction is cyclic; it takes place via the alternate oxidation of NADPH by AcPdAD+ and the reduction of NADP+ by NADH, while the NADPH and NADP+ remain tightly bound to the enzyme. In the present work, it is shown that the rate of the cyclic reaction and the rate of reduction of AcPdAD+ by NADH in the absence of added NADP+/NADPH, have similar dependences on pH and on MgSO4 concentration and that they have a similar kinetic character. It is therefore suggested that the reduction of AcPdAD+ by NADH is actually a cyclic reaction operating, either with tightly bound NADP+/NADPH on a small fraction (< 5%) of the enzyme, or with NAD+/NADH (or AcPdAD+/AcPdADH) unnaturally occluded within the domain III site. Transhydrogenase associated with membrane vesicles (chromatophores) of Rhodospirillum rubrum also catalyses the reduction of AcPdAD+ by NADH in the absence of added NADP+/NADPH. When the chromatophores were stripped of transhydrogenase domain I, that reaction was lost in parallel with 'normal reverse' transhydrogenation (e.g., the reduction of AcPdAD+ by NADPH). The two reactions were fully recovered upon reconstitution with recombinant domain I protein. However, after repeated washing of the domain I-depleted chromatophores, reverse transhydrogenation activity (when assayed in the presence of domain I) was retained, whereas the reduction of AcPdAD+ by NADH declined in activity. Addition of low concentrations of NADP+ or NADPH always supported the same high rate of the NADH-->AcPdAD+ reaction independently of how often the membranes were washed. It is concluded that, as with the purified E. coli enzyme, the reduction of AcPdAD+ by NADH in chromatophores is a cyclic reaction involving nucleotides that are tightly bound in the domain III site of transhydrogenase. However, in the case of R. rubrum membranes it can be shown with some certainty that the bound nucleotides are NADP+ or NADPH. The data are thus adequately explained without recourse to suggestions of multiple nucleotide-binding sites on transhydrogenase.

Properties of the purified, recombinant, NADP(H)-binding domain III of the proton-translocating nicotinamide nucleotide transhydrogenase from Rhodospirillum rubrum

Transhydrogenase comprises three domains. Domains I and III are peripheral to the membrane and possess the NAD(H)- and NADP(H)-binding sites, respectively, and domain II spans the membrane. Domain III of transhydrogenase from Rhodospirillum rubrum was expressed at high levels in Escherichia coli, and purified. The purified protein was associated with substoichiometric quantities of tightly bound NADP+ and NADPH. Fluorescence spectra of the domain III protein revealed emissions due to Tyr residues. Energy transfer was detected between Tyr residue(s) and the bound NADPH, indicating that the amino acid residue(s) and the nucleotide are spatially close. The rate constants for NADP+ release and NADPH release from domain III were 0.03 s-1 and 5.6 x 10(4) s-1, respectively. In the absence of domain II a mixture of the recombinant domain III protein, plus the previously described recombinant domain I protein, catalysed reduction of acetylpyridine-adenine dinucleotide (AcPdAD+) by NADPH (reverse transhydrogenation) at a rate that was limited by the release of NADP+ from domain III. Similarly, the mixture catalysed reduction of thio-NADP+ by NADH (forward transhydrogenation) at a rate limited by release of thio-NADPH from domain III. The mixture also catalysed very rapid reduction of AcPdAD+ by NADH, probably by way of a cyclic reaction mediated by the tightly bound NADP(H). Measurement of the rates of the transhydrogenation reactions during titrations of domain I with domain III and vice versa indicated (a) that during reduction of AcPdAD+ by NADPH, a single domain I protein can visit and transfer H equivalents to about 60 domain III proteins during the time taken for a single domain III to release its NADP+, whereas (b) the cyclic reaction is rapid on the timescale of formation and break-down of the domain I. III complex. The rate of the hydride transfer reaction was similar in the domain I.III complex to that in the complete membrane-bound transhydrogenase, but the rates of forward and reverse transhydrogenation were much slower in the I.III complex due to the greatly decreased rates of release of NADP+ and NADPH. It is concluded that, in the complete enzyme, conformational changes in the membrane-spanning domain II, which result from proton translocation, lead to changes in the binding affinity of domain III for NADP+ and for NADPH.

The binding of nucleotides to domain I proteins of the proton-translocating transhydrogenases from Rhodospirillum rubrum and Escherichia coli as measured by equilibrium dialysis

Transhydrogenase catalyses the transfer of reducing equivalents between NAD(H) and NADP(H) coupled to the translocation of protons across a membrane. The NAD(H)-binding domain of transhydrogenase (domain I protein) from Rhodospirillum rubrum and from Escherichia coli were overexpressed and purified. Nucleotide binding to the domain I proteins was determined by equilibrium dialysis. NADH and its analogue, acetylpyridine adenine dinucleotide (reduced form), bound with relatively high affinity (Kd = 32 microM and 120 microM, respectively, for the R. rubrum protein). The binding affinity was similar at pH 8.0 and pH 9.0 in zwitterionic buffers, and at pH 7.5 in sodium phosphate buffer. NAD+ bound with lower affinity (Kd = 300 microM). NADPH bound only very weakly (Kd > 1 mM). Using a centrifugation procedure, Yamaguchi and Hatefi [Yamaguchi, M. & Hatefi, Y. (1993) J. Biol. Chem. 268. 17871-17877] found that mitochondrial transhydrogenase, and a proteolytically derived domain I fragment from that enzyme, bound one NADH per dimer. They suggested that this result implied half-of-the-site reactivity for the interaction between the nucleotide ligand and the protein. However, our studies on both the E. coli and the R. rubrum recombinant transhydrogenase domain I proteins using equilibrium dialysis show that the binding stoichiometry for both NADH and the reduced form of acetylpyridine adenine dinucleotide (AcPdADH) is two nucleotides per dimer: no interaction between the monomeric units is evident. Reasons for the discrepancies between the work on bacterial and mitochondrial transhydrogenases are discussed.

Interaction of nucleotides with the NAD(H)-binding domain of the proton-translocating transhydrogenase of Rhodospirillum rubrum

Transhydrogenase catalyzes the reduction of NADP+ by NADH coupled to the translocation of protons across a membrane. The polypeptide composition of the enzyme in Rhodospirillum rubrum is unique in that the NAD(H)-binding domain (called Ths) exists as a separate polypeptide. Ths was expressed in Escherichia coli and purified. The binding of nucleotide substrates and analogues to Ths was examined by one-dimensional proton nuclear magnetic resonance (NMR) spectroscopy and by measuring the quenching of fluorescence of its lone Trp residue. NADH and reduced acetylpyridine adenine dinucleotide bound tightly to Ths, whereas NAD+, oxidized acetylpyridine adenine dinucleotide, deamino-NADH, 5'-AMP and adenosine bound less tightly. Reduced nicotinamide mononucleotide, NADPH and 2'-AMP bound only very weakly to Ths. The difference in the binding affinity between NADH and NAD+ indicates that there may be an energy requirement for the transfer of reducing equivalents into this site in the complete enzyme under physiological conditions. Earlier results had revealed a mobile loop at the surface of Ths (Diggle, C., Cotton, N. P. J., Grimley, R. L., Quirk, P. G., Thomas, C. M., and Jackson, J. B. (1995) Eur. J. Biochem. 232, 315-326); the loop loses mobility when Ths binds nucleotide; the reaction involves two steps. This was more clearly evident, even for tight-binding nucleotides, when experiments were carried out at higher temperatures (37 degrees C), where the resonances of the mobile loop were substantially narrower. The binding of adenosine was sufficient to initiate loop closure; the presence of a reduced nicotinamide moiety in the dinucleotide apparently serves to tighten the binding. Two-dimensional 1H NMR spectroscopy of the Ths-5'-AMP complex revealed nuclear Overhauser effect interactions between protons of amino acid residues in the mobile loop (including those in a Tyr residue) and the nucleotide. This suggests that, in the complex, the loop has closed down to within 0.5 nm of the nucleotide.

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.

Cyclic reactions catalysed by detergent-dispersed and reconstituted transhydrogenase from beef-heart mitochondria; implications for the mechanism of proton translocation

Transhydrogenase from beef-heart mitochondria was solubilised with Triton X-100 and purified by column chromatography. The detergent-dispersed enzyme catalysed the reduction of acetylpyridine adenine dinucleotide (AcPdAD+) by NADH, but only in the presence of NADP+. Experiments showed that this reaction was cyclic; NADP(H), whilst remaining bound to the enzyme, was alternately reduced by NADH and oxidised by AcPdAD+. A period of incubation of the enzyme with NADPH at pH 6.0 led to inhibition of the simple transhydrogenation reaction between AcPdAD+ and NADPH. However, after such treatment, transhydrogenase acquired the ability to catalyse the (NADPH-dependent) reduction of AcPdAD+ by NADH. It is suggested that this is a similar cycle to the one described above. Evidently, the binding affinity for NADP+ increases as a consequence of the inhibition process resulting from prolonged incubation with NADPH. The pH dependences of simple and cyclic transhydrogenation reactions are described. Though more complex than those in Escherichia coli transhydrogenase, they are consistent with the view [Hutton, M., Day, J.M., Bizouarn, T. and Jackson, J.B. (1994) Eur. J. Biochem. 219, 1041-1051] that, also in the mitochondrial enzyme, binding and release of NADP+ and NADPH are accompanied by binding and release of a proton. The enzyme was successfully reconstituted into liposomes by a cholate dilution procedure. The proteoliposomes catalysed cyclic NADPH-dependent reduction of AcPdAD+ by NADH only when they were tightly coupled. However, they catalysed cyclic NADP(+)-dependent reduction of AcPdAD+ by NADH only when they were uncoupled eg. by addition of carbonylcyanide-p-trifluoromethoxyphenyl hydrazone.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

The involvement of NADP(H) binding and release in energy transduction by proton-translocating nicotinamide nucleotide transhydrogenase from Escherichia coli

Proton-translocating transhydrogenase was solubilised and purified from membranes of Escherichia coli. Consistent with recent evidence [Hutton, M., Day, J., Bizouarn, T. and Jackson, J.B. (1994) Eur. J. Biochem. 219, 1041-1051], at low pH and salt concentration, the enzyme catalysed rapid reduction of the NAD+ analogue AcPdAD+ by a combination of NADH and NADPH. At saturating concentrations of NADPH, the dependence of the steady-state rate on the concentrations of NADH and AcPdAD+ indicated that, with respect to these two nucleotides, the reaction proceeds by a ping-pong mechanism. High concentrations of either NADH or AcPdAD+ led to substrate inhibition. These observations support the view that, in this reaction, NADP(H) remains bound to the enzyme: AcPdAD+ is reduced by enzyme-bound NADPH, and NADH is oxidised by enzyme-bound NADP+, in a cyclic process. When this reaction was carried out with [4A-2H]NADH replacing [4A-1H]NADH, the rate was decreased by 46%, suggesting that the H- transfer steps are rate-limiting. In simple 'reverse' transhydrogenation, the reduction of AcPdAD+ was slower with [4B-2H]NADPH than with [4B-1H]NADPH when the reaction was performed at pH 8.0, but there was no deuterium isotope effect at pH 6.0. This indicates that H- transfer is rate-limiting at pH 8.0 and supports our earlier suggestion that NADP+ release from the enzyme is rate-limiting at low pH. The lack of a deuterium isotope effect in the reduction of thio-NADP+ by NADH at low pH is also consistent with the view that NADPH release from the enzyme is slow under these conditions. A steady-state rate equation is derived for the reduction of AcPdAD+ by NADPH plus NADH, assuming operation of the cyclic pathway. It adequately accounts for the pH dependence of the enzyme, for the features described above and for kinetic characteristics of E. coli transhydrogenase described in the literature.

Properties of the soluble polypeptide of the proton-translocating transhydrogenase from Rhodospirillum rubrum obtained by expression in Escherichia coli

Transhydrogenase, which catalyses the reduction of NADP+ by NADH coupled to proton translocation across a membrane, may be unique in the photosynthetic bacterium Rhodospirillum rubrum. Unlike the homologous enzyme from animal mitochondria and other bacterial sources, it has a water-soluble polypeptide, which exists as a dimer (Ths), that can be reversibly dissociated from the membrane component [Williams, R., Cotton, N. P. J., Thomas, C. M. & Jackson, J. B. (1994) Microbiology, 140, 1595-1604]. We have expressed the gene for Ths in cells of Escherichia coli under control of the tac promoter and a strong ribosome binding site. The protein, purified by column chromatography, fully reconstituted transhydrogenation activity to everted membrane vesicles of Rhs. rubrum that had been washed to remove Ths. The purified expressed protein was prepared in quantities over 100-fold greater than were obtained from wild-type Rhs. rubrum. The fluorescence spectrum of purified expressed Ths had an intense and unusually short wavelength emission maximum at 310 nm with shoulders at 298 and 322 nm. Time-resolved measurements indicated that the fluorescence decay was almost monoexponential with a lifetime of 5.2 ns. On denaturation with 4 M guanidine hydrochloride, the emission band shifted to 352 nm and decreased in intensity. In the native protein, the fluorophore was relatively inaccessible to quenching solutes, such as iodide ions and acrylamide. It is concluded that the fluorescence emission arises mainly from the single tryptophan residue of Ths (Trp72), which is locked into a rigid conformation and is located in highly non-polar environment. The 310-nm fluorescence of Ths was quenched by NADH, maximally to 46%. The apparent binding constant was 18 microM. The fluorescence of Ths-bound NADH was enhanced relative to the nucleotide in free solution and its emission maximum was shifted to a shorter wavelength (440 nm). These data support previous indications that the NADH binding site is located in domain I of proton-translocating transhydrogenase. Excitation of Ths at 280 nm did not lead to sensitized emission at 440 nm from bound NADH. This indicates that the quenching of fluorescence of Ths by NADH does not result from resonance energy transfer from Trp72 to the bound nucleotide. NAD+, NADP+ and NADPH had little effect on the protein fluorescence. The kinetics of quenching of Ths fluorescence by NADH were examined after mixing in a stopped-flow device. The 'on' rate constant for nucleotide binding was approximately 8 x 10(6) M-1 s-1 and the 'off' constant approximately 150 s-1.

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.

Kinetic resolution of the reaction catalysed by proton-translocating transhydrogenase from Escherichia coli as revealed by experiments with analogues of the nucleotide substrates

The mechanism, by which transhydrogenase couples transfer of H- equivalents between NAD(H) and NADP(H) to the translocation of protons across a membrane, has been investigated in the solubilised, purified enzyme from Escherichia coli using analogues of the nucleotide substrates. The key observation was that, at low pH and ionic strength, solubilised transhydrogenase catalysed the very rapid reduction of acetylpyridine adenine dinucleotide (an analogue of NAD+) by NADH, but only in the presence of either NADP+ or NADPH. This indicates that the rates of release of NADP+ and NADPH from their binary complexes with the enzyme are slow. The dependences on pH and salt concentration suggest that (a) release of both NADP+ and NADPH are accompanied by the release of H+ from the enzyme and (b) increased ionic strength decreases the value of the pKa of the group responsible for H+ release. Modification of the enzyme with N,N1-dicyclohexylcarbodiimide led to inhibition of the rate of release of NADP+ and NADPH from the enzyme, but had a much smaller effect on the binding and release of NAD+, NADH and their analogues and on the interconversion of the ternary complexes of the enzyme with its substrates. It is considered that the binding and release of H+, which accompany the binding and release of NADP+/NADPH, might be central to the mechanism of proton translocation by the enzyme in its membrane-bound state.

The ratio of protons translocated/hydride ion equivalent transferred by nicotinamide nucleotide transhydrogenase in chromatophores from Rhodospirillum rubrum

The reduction of acetylpyridine adenine dinucleotide (AcPdAD+, an NAD+ analogue) by NADPH, in chromatophores treated with valinomycin, was accompanied by alkalinisation of the external medium, as measured by the absorbance change of added cresol red, a simple, non-binding pH indicator. Experiments with a stopped-flow spectrophotometer showed that initial (linear) rates of alkalinisation persisted for 1-2s. From the results of experiments in which H+ uptake was driven by a series of short flashes of light, the dependence of the outward proton leak on the extent of H+ uptake was established. Thus, the proton leak was subtracted from the initial rate of alkalinisation during transhydrogenation to give the true proton-uptake rate. The correction factor was usually about 10%. The ratio of protons translocated/H- transferred from NADPH to AcPdAD+ (the H+/H- ratio) was 0.60 +/- 0.06. The transhydrogenation reaction between NAD+ and NADPH was measured in the presence of a regeneration system for NAD+ (pyruvate and lactate dehydrogenase). In addition to the accompanying proton-translocation reaction, scalar H+ consumption linked to the regeneration system was observed and permitted internal checks on the calibration of the cresol red absorbance changes. After correction for the proton leak and scalar proton uptake, an H+/H- ratio of 0.60 +/- 0.30 was calculated from the initial rates. The water-soluble polypeptide of transhydrogenase (Ths) was washed from a sample of chromatophores to inhibit transhydrogenation activity and the accompanying H+ uptake. Re-addition of purified Ths to depleted chromatophores led to recovery of transhydrogenation activity and of H+ uptake. In this reconstituted system the H+/H- was similar to that in the native membranes. These results make it unlikely that the H+/H- ratio is artefactually low because chromatophores have a population of transhydrogenase which is not coupled to proton translocation. Further evidence that the mechanistic H+/H- ratio of chromatophore transhydrogenase is less than 1 was provided by an analysis of the kinetics of alkalinisation of the medium during reduction of AcPdAD+ by NADPH. It was shown that the progress of the transhydrogenation-induced alkalinisation was fitted by the sum of H+ uptake (the rate of transhydrogenation multiplied by the H+/H- ratio) plus the H+ leak, when the ratio was 0.6 but not when it was 1.0. The results are discussed in terms of the possible mechanism of energy coupling by transhydrogenase.(ABSTRACT TRUNCATED AT 400 WORDS)

Inhibition of proton-translocating transhydrogenase from photosynthetic bacteria by N,N'-dicyclohexylcarbodiimide

The effects of N,N'-dicyclohexylcarbodiimide [(cHxN)2C] on the proton-translocating enzyme, NAD(P) H(+)-transhydrogenase (H(+)-Thase), from two species of phototrophic bacteria have been investigated. The polypeptides of H(+)-Thase from Rhodobacter capsulatus are membrane-associated, requiring detergent to maintain solubility. The enzyme from Rhodospirillum rubrum, however, has a water soluble polypeptide (Ths) and a membrane-associated component (Thm) which, separately, have no activity but which can be fully reconstituted to give a functional complex. Two observations suggest that (cHxN)2C inhibited H(+)-Thase from both species by modification either close to or at the NADP(H)-binding site on the enzyme: (a) the presence of NADP+ or NADPH caused increased inhibition by (cHxN)2C and (b) after treatment of the purified enzyme from Rb. capsulatus with (cHxN)2C, the release of NADP+ became rate-limiting, as evidenced by a stimulated rate of NADPH-dependent reduction of acetylpyridine adenine dinucleotide by NADH. Experiments in which Ths and Thm from R. rubrum were separately treated with (cHxN)2C then reconstituted with the complementary, untreated component revealed that the NADP(H)-enhanced modification by (cHxN)2C was confined to Thm. In contrast to some experiments with mitochondrial H(+)-Thase [Wakabayashi, S. & Hatefi, Y. (1987) Biochem. Int. 15, 667-675], there was no protective effect of either NAD+ or NADH on the inhibition by (cHxN)2C of enzyme from photosynthetic bacteria. However, amino acid sequence analysis of proteolytic fragments of Ths revealed that the NAD(H)-protectable, (cHxN)2C-reactive glutamate residue in mitochondrial H(+)-Thase might be replaced by glutamine in R. rubrum.

The relation between the soluble factor associated with H(+)-transhydrogenase of Rhodospirillum rubrum and the enzyme from mitochondria and Escherichia coli

Although in mitochondria, Escherichia coli and Rhodobacter capsulatus the H(+)-transhydrogenases are intrinsic membrane proteins, in Rhodospirillum rubrum a water-soluble component (Ths) and a membrane-bound component are together required for activity. Ths was selectively removed from chromatophore membranes of Rhs. rubrum and was purified to homogeneity by precipitation with (NH4)2SO4 and ion-exchange, affinity dye and gel exclusion chromatography. The latter indicated an Mr of approx. 74,000 under non-denaturing conditions but analysis of the pure protein by SDS-PAGE revealed a single polypeptide, Mr 43,000. Antibodies against this polypeptide inhibited transhydrogenase activity of chromatophores and decreased the capacity of Ths to restore activity to depleted membranes. They reacted with a polypeptide of Mr 43,000 in crude cell extract, chromatophore membranes and chromatophore washings but not with transhydrogenase polypeptides from the membranes of E. coli, Rb. capsulatus or animal mitochondria. The N-terminal amino acid sequence of the 43,000 polypeptide was strongly homologous with the reported N-terminal regions of mitochondrial transhydrogenase and the alpha subunit of the E. coli protein. The break between the alpha and beta polypeptides of E. coli transhydrogenase is such that both components are membrane-associated. In contrast, these results suggest that in the Rhs. rubrum enzyme Ths has been formed by a break closer to the N-terminus, thus avoiding the putative trans-membrane helical segments and yielding a relatively hydrophilic subunit, which is water-soluble. There is a predicted similarity between Ths and the reported sequence of alanine dehydrogenase from Bacillus but Ths did not have any alanine dehydrogenase activity.

The proton-translocating nicotinamide adenine dinucleotide transhydrogenase

H(+)-transhydrogenase couples the reversible transfer of hydride ion equivalents between NAD(H) and NADP(H) to the translocation of protons across a membrane. There are separate sites on the enzyme for the binding of NAD(H) and of NADP(H). There are some indications of the position of the binding sites in the primary sequence of the enzymes from mitochondria and Escherichia coli. Transfer of hydride ion equivalents only proceeds when a reduced and an oxidized nucleotide are simultaneously bound to the enzyme. When delta p = 0 the rate of interconversion of the ternary complexes of enzyme and nucleotide substrates is probably limiting. An increase in delta p accelerates the rate of interconversion in the direction of NADH----NADP+ until another kinetic component, possibly product release, becomes limiting. The available data are consistent with either direct or indirect mechanisms of energy coupling.