Purification and properties of reconstitutively active nicotinamide nucleotide transhydrogenase of Escherichia coli

Mutations identified in engineered Escherichia coli with a reduced genome

Characterizing genes that regulate cell growth and survival in model organisms is important for understanding higher organisms. Construction of strains harboring large deletions in the genome can provide insights into the genetic basis of cell growth compared with only studying wild-type strains. We have constructed a series of genome-reduced strains with deletions spanning approximately 38.9% of the E. coli chromosome. Strains were constructed by combining large deletions in chromosomal regions encoding nonessential gene groups. We also isolated strains Δ33b and Δ37c, whose growth was partially restored by adaptive laboratory evolution (ALE). Genome sequencing of nine strains, including those selected following ALE, identified the presence of several Single Nucleotide Variants (SNVs), insertions, deletions, and inversions. In addition to multiple SNVs, two insertions were identified in ALE strain Δ33b. The first was an insertion at the promoter region of pntA, which increased cognate gene expression. The second was an insertion sequence (IS) present in sibE, encoding the antitoxin in a toxin-antitoxin system, which decreased expression of sibE. 5 strains of Δ37c independently isolated following ALE harboring multiple SNVs and genetic rearrangements. Interestingly, a SNV was identified in the promoter region of hcaT in all five strains, which increased hcaT expression and, we predict, rescued the attenuated Δ37b growth. Experiments using defined deletion mutants suggested that hcaT encodes a 3-phenylpropionate transporter protein and is involved in survival during stationary phase under oxidative stress. This study is the first to document accumulation of mutations during construction of genome-reduced strains. Furthermore, isolation and analysis of strains derived from ALE in which the growth defect mediated by large chromosomal deletions was rescued identified novel genes involved in cell survival.

The transferred translocases: An old wine in a new bottle

The role of translocases was underappreciated and was not included as a separate class in the enzyme commission until August 2018. The recent research interests in proteomics of orphan enzymes, ionomics, and metallomics along with high-throughput sequencing technologies generated overwhelming data and revamped this enzyme into a separate class. This offers a great opportunity to understand the role of new or orphan enzymes in general and specifically translocases. The enzymes belonging to translocases regulate/permeate the transfer of ions or molecules across the membranes. These enzyme entries were previously associated with other enzyme classes, which are now transferred to a new enzyme class 7 (EC 7). The entries that are reclassified are important to extend the enzyme list, and it is the need of the hour. Accordingly, there is an upgradation of entries of this class of enzymes in several databases. This review is a concise compilation of translocases with reference to the number of entries currently available in the databases. This review also focuses on function as well as dysfunction of translocases during normal and disordered states, respectively.

Undesirable effects of chemical inhibitors of NAD(P)+ transhydrogenase on mitochondrial respiratory function

NAD(P)⁺ transhydrogenase (NNT) is located in the inner mitochondrial membrane and catalyzes a reversible hydride transfer between NAD(H) and NADP(H) that is coupled to proton translocation between the intermembrane space and mitochondrial matrix. NNT activity has an essential role in maintaining the NADPH supply for antioxidant defense and biosynthetic pathways. In the present report, we evaluated the effects of chemical compounds used as inhibitors of NNT over the last five decades, namely, 4-chloro-7-nitrobenzofurazan (NBD-Cl), N,N'-dicyclohexylcarbodiimide (DCC), palmitoyl-CoA, palmitoyl-l-carnitine, and rhein, on NNT activity and mitochondrial respiratory function. Concentrations of these compounds that partially inhibited the forward and reverse NNT reactions in detergent-solubilized mouse liver mitochondria significantly impaired mitochondrial respiratory function, as estimated by ADP-stimulated and nonphosphorylating respiration. Among the tested compounds, NBD-Cl showed the best relationship between NNT inhibition and low impact on respiratory function. Despite this, NBD-Cl concentrations that partially inhibited NNT activity impaired mitochondrial respiratory function and significantly decreased the viability of cultured Nnt^-/- mouse astrocytes. We conclude that even though the tested compounds indeed presented inhibitory effects on NNT activity, at effective concentrations, they cause important undesirable effects on mitochondrial respiratory function and cell viability.

Bacterial membrane destabilization with cationic particles of nano-silver to combat efflux-mediated antibiotic resistance in Gram-negative bacteria

AIMS

With the purpose of exploring combinatorial options that could enhance the bactericide efficacy of linezolid against Gram-negative bacteria, we assessed the extent of combination of nano-silver and linezolid.

MAIN METHODS

In this study, we selected Escherichia coli MTCC 443 as a model to study the combinatorial effect of nano-silver and linezolid to combat efflux-mediated resistance in Gram-negative bacteria. The acting mechanism of nano-silver on E. coli MTCC 443 was investigated by evaluating interaction of nano-silver with bacterial membrane as well as bacterial surface charge, morphology, intracellular leakages and biological activities of membrane bound respiratory chain dehydrogenase and deoxyribonucleic acids (DNA) of the cells following treatment with nano-silver.

KEY FINDINGS

The alternation of zeta potential due to the interaction of nano-silver towards bacterial membrane proteins was correlated with enhancement of membrane permeability, which allows the penetration of linezolid into the cells. In addition, the binding affinity of nano-silver towards bacterial membrane depressed biological activities of membrane bound respiratory chain dehydrogenases and DNA integrity.

SIGNIFICANCE

Our findings suggested that nano-silver could not only obstruct the activities of efflux pumps, but also altered membrane integrity at the same time and thus increased the cytoplasmic concentration of the linezolid to the effective level.

Engineering furfural tolerance in Escherichia coli improves the fermentation of lignocellulosic sugars into renewable chemicals

Pretreatments such as dilute acid at elevated temperature are effective for the hydrolysis of pentose polymers in hemicellulose and also increase the access of enzymes to cellulose fibers. However, the fermentation of resulting syrups is hindered by minor reaction products such as furfural from pentose dehydration. To mitigate this problem, four genetic traits have been identified that increase furfural tolerance in ethanol-producing Escherichia coli LY180 (strain W derivative): increased expression of fucO, ucpA, or pntAB and deletion of yqhD. Plasmids and integrated strains were used to characterize epistatic interactions among traits and to identify the most effective combinations. Furfural resistance traits were subsequently integrated into the chromosome of LY180 to construct strain XW129 (LY180 ΔyqhD ackA::PyadC'fucO-ucpA) for ethanol. This same combination of traits was also constructed in succinate biocatalysts (Escherichia coli strain C derivatives) and found to increase furfural tolerance. Strains engineered for resistance to furfural were also more resistant to the mixture of inhibitors in hemicellulose hydrolysates, confirming the importance of furfural as an inhibitory component. With resistant biocatalysts, product yields (ethanol and succinate) from hemicellulose syrups were equal to control fermentations in laboratory media without inhibitors. The combination of genetic traits identified for the production of ethanol (strain W derivative) and succinate (strain C derivative) may prove useful for other renewable chemicals from lignocellulosic sugars.

Inhibition of proton-transfer steps in transhydrogenase by transition metal ions

Transhydrogenase couples proton translocation across a bacterial or mitochondrial membrane to the redox reaction between NAD(H) and NADP(H). Purified intact transhydrogenase from Escherichia coli was prepared, and its His tag removed. The forward and reverse transhydrogenation reactions catalysed by the enzyme were inhibited by certain metal ions but a "cyclic reaction" was stimulated. Of metal ions tested they were effective in the order Pb(2+)>Cu(2+)>Zn(2+)=Cd(2+)>Ni(2+)>Co(2+). The results suggest that the metal ions affect transhydrogenase by binding to a site in the proton-transfer pathway. Attenuated total-reflectance Fourier-transform infrared difference spectroscopy indicated the involvement of His and Asp/Glu residues in the Zn(2+)-binding site(s). A mutant in which betaHis91 in the membrane-spanning domain of transhydrogenase was replaced by Lys had enzyme activities resembling those of wild-type enzyme treated with Zn(2+). Effects of the metal ion on the mutant were much diminished but still evident. Signals in Zn(2+)-induced FTIR difference spectra of the betaHis91Lys mutant were also attributable to changes in His and Asp/Glu residues but were much smaller than those in wild-type spectra. The results support the view that betaHis91 and nearby Asp or Glu residues participate in the proton-transfer pathway of transhydrogenase.

Proton-translocating transhydrogenase: an update of unsolved and controversial issues

Proton-translocating transhydrogenases, reducing NADP(+) by NADH through hydride transfer, are membrane proteins utilizing the electrochemical proton gradient for NADPH generation. The enzymes have important physiological roles in the maintenance of e.g. reduced glutathione, relevant for essentially all cell types. Following X-ray crystallography and structural resolution of the soluble substrate-binding domains, mechanistic aspects of the hydride transfer are beginning to be resolved. However, the structure of the intact enzyme is unknown. Key questions regarding the coupling mechanism, i.e., the mechanism of proton translocation, are addressed using the separately expressed substrate-binding domains. Important aspects are therefore which functions and properties of mainly the soluble NADP(H)-binding domain, but also the NAD(H)-binding domain, are relevant for proton translocation, how the soluble domains communicate with the membrane domain, and the mechanism of proton translocation through the membrane domain.

Zinc ions selectively inhibit steps associated with binding and release of NADP(H) during turnover of proton-translocating transhydrogenase

Transhydrogenase couples the redox reaction between NAD(H) and NADP(H) to proton translocation across a membrane. In membrane vesicles from Escherichia coli and Rhodospirillum rubrum, the transhydrogenase reaction (measured in the direction driving inward proton translocation) was inhibited by Zn(2+) and Cd(2+). However, depending on pH, the metal ions either had no effect on, or stimulated, "cyclic" transhydrogenation. They must, therefore, interfere specifically with steps involving binding/release of NADP(+)/NADPH: the steps thought to be associated with proton translocation. It is suggested that Zn(2+) and Cd(2+) bind in the proton-transfer pathway and block inter-conversion of states responsible for changing NADP(+)/NADPH binding energy.

Purification of a recombinant membrane protein tagged with a calmodulin-binding domain: properties of chimeras of the Escherichia coli nicotinamide nucleotide transhydrogenase and the C-terminus of human plasma membrane Ca2+ -ATPase

A Ca2+ -dependent calmodulin-binding peptide (CBP) is an attractive tag for affinity purification of recombinant proteins, especially membrane proteins, since elution is simply accomplished by removing/chelating Ca2+. To develop a single-step calmodulin/CBP-dependent purification procedure for Escherichia coli nicotinamide nucleotide transhydrogenase, a 49 amino acid large CBP or a larger 149 amino acid C-terminal fragment of human plasma membrane Ca2+ -ATPase (hPMCA) was fused C-terminally to the beta subunit of transhydrogenase. Fusion using the 49 amino acid fragment resulted in a dramatic loss of transhydrogenase expression while fusion with the 149 amino acid fragment gave a satisfactory expression. This chimeric protein was purified by affinity chromatography on calmodulin-Sepharose with mild elution with EDTA. The purity and activity were comparable to those obtained with His-tagged transhydrogenase and showed an increased stability. CBP-tagged transhydrogenase contained a 4- to 10-fold higher amount of the alpha subunit relative to the beta subunit as compared to wild-type transhydrogenase. To determine whether the latter was due to the CBP tag, a double-tagged transhydrogenase with both an N-terminal 6x His-tag and a CBP-tag, purified by using either tag, gave no significant increase in purity as compared to the single-tagged protein. The reasons for the altered subunit composition are discussed. The results suggest that, depending on the construct, the CBP-tag may be a suitable affinity purification tag for membrane proteins in general.

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.

Properties of a proton-translocating nicotinamide nucleotide transhydrogenase from Escherichia coli with alpha and beta subunits linked through fused transmembrane helices

Proton-translocating nicotinamide nucleotide transhydrogenase from Escherichia coli is composed of an alpha and a beta subunit, whereas the homologues mitochondrial enzyme contains a single polypeptide. As compared to the latter transhydrogenase, using a 14-helix model for its membrane topology, the point of fusion is between the transmembrane helices 4 and 6 where the fusion linker provides the extra transmembrane helix 5. In order to clarify the potential role of this extra helix/linker, the alpha and the beta subunits were fused using three connecting peptides of different lengths, one (pAX9) involving essentially a direct coupling, a second (pKM) with a linking peptide of 18 residues, and a third (pKMII) with a linking peptide of 32 residues, as compared to the mitochondrial extra peptide of 27 residues. The results demonstrate that the plasma membrane-bound and purified pAX9 enzyme with the short linker was partly misfolded and strongly inhibited with regard to both catalytic activities and proton translocation, whereas the properties of pKM and pKMII with longer linkers were similar to those of wild-type E. coli transhydrogenase but partly different from those of the mitochondrial enzyme although pKMII generally gave higher activities. It is concluded that a mitochondrial-like linking peptide is required for proper folding and activity of the E. coli fused transhydrogenase, and that differences between the catalytic properties of the E. coli and the mitochondrial enzymes are unrelated to the linking peptide. This is the first time that larger subunits of a membrane protein with multiple transmembrane helices have been fused with retained activity.

Characterization of mutants of beta histidine91, beta aspartate213, and beta asparagine222, possible components of the energy transduction pathway of the proton-translocating pyridine nucleotide transhydrogenase of Escherichia coli

The roles of three residues (betaHis91, betaAsp213, and betaAsn222) implicated in energy transduction in the membrane-spanning domain II of the proton-translocating pyridine nucleotide transhydrogenase of Escherichia coli have been examined using site-directed mutagenesis. All mutations affected transhydrogenation and proton pumping activities, although to various extents. Replacing betaHis91 or betaAsn222 of domain II by the basic residues lysine or arginine resulted in occlusion of NADP(H) at the NADP(H)-binding site of domain III. This was not seen with betaD213K or betaD213R mutants. It is suggested that betaHis91 and betaAsn222 interact with betaAsp392, a residue probably involved in initiating conformational changes at the NADP(H)-binding site in the normal catalytic cycle of the enzyme (M. Jeeves et al. (2000) Biochim. Biophys. Acta 1459, 248-257). The introduced positive charges in the betaHis91 and betaAsn222 mutants might stabilize the carboxyl group of betaAsp392 in its anionic form, thus locking the NADP(H)-binding site in the occluded conformation. In comparison with the nonmutant enzyme, and those of mutants of betaAsp213, most mutant enzymes at betaHis91 and betaAsn222 bound NADP(H) more slowly at the NADP(H)-binding site. This is consistent with the effect of these two residues on the binding site. We could not demonstrate by mutation or crosslinking or through the formation of eximers with pyrene maleimide that betaHis91 and betaAsn222 were in proximity in domain II.

The presence of an aqueous cavity in the proton-pumping pathway of the pyridine nucleotide transhydrogenase of Escherichia coli is suggested by the reaction of the enzyme with sulfhydryl inhibitors

The pyridine nucleotide transhydrogenase of Escherichia coli carries out transmembrane proton translocation coupled to transfer of a hydride ion equivalent between NAD(+) and NADP(+). The membrane domain (domain II) of the enzyme is composed of 13 transmembrane helices. Previous studies (N. A. Glavas et al., Biochemistry 34, 7694-7702, 1995) have suggested that betaHis91 in transmembrane helix 9 is involved in the translocation pathway of protons across the membrane. In this study we have replaced amino acid residues on the same face of helix 9 as betaHis91 by single cysteine residues. We then examined the effect of the sulfhydryl inhibitors N-ethylmaleimide (NEM) and p-chloromercuriphenylsulfonate (pCMPS) on enzyme activity and, in the case of [(14)C]NEM, as an enzyme label. The pattern of enzyme inhibition and labelling is consistent with the presence of an aqueous cavity through domain II from the cytosolic surface to the region of betaHis91. Residue betaAsn222 in helix 13, which appears also to be involved in the proton pathway across domain II, may interface with this aqueous cavity. A further series of mutants of betaGlu124 on helix 10 confirms the proposal (P. D. Bragg and C. Hou, Arch. Biochem. Biophys. 363, 182-190, 1999) that this residue is involved in passive permeation of protons across domain II.

Crosslinking between alpha and beta subunits defines the orientation and spatial relationship of some of the transmembrane helices of the proton-translocating pyridine nucleotide transhydrogenase of Escherichia coli

The proton-translocating pyridine nucleotide transhydrogenase of Escherichia coli is composed of two types of subunits, alpha and beta, organized as an alpha(2)beta(2) tetramer. The protein contains three recognizable domains, of which domain II is the transmembrane region of the molecule containing the pathway for proton translocation. Domain II is composed of four transmembrane helices at the carboxyl-terminus of the alpha subunit and either eight or nine transmembrane helices at the amino-terminal region of the beta subunit. We have introduced pairs of cysteine residues into a cysteine-free transhydrogenase by site-directed mutagenesis. Disulfide bond formation between some of these cysteine residues occurred spontaneously or on treatment with cupric 1, 10-phenanthrolinate. Analysis of crosslinked products confirmed that there are nine transmembrane helices in the domain II region of the beta subunit. The proximity to one another of several of the transmembrane helices was determined. Thus, helices 2 and 4 are close to helix 6 (nomenclature of Meuller and Rydström, J. Biol. Chem. 274, 19072-19080, 1999), and helix 3 and the carboxyl-terminal eight residues of the alpha subunit are close to helix 7. In the alpha(2)beta(2) tetramer, helices 2 and 4 of one alpha subunit are close to the same pair of transmembrane helices of the other alpha subunit, and helix 6 of one beta subunit is close to helix 6 of the other beta subunit.

Effect of NBD chloride (4-chloro-7-nitrobenzo-2-oxa-1,3-diazole) on the pyridine nucleotide transhydrogenase of Escherichia coli

Pyridine nucleotide transhydrogenases of bacterial cytosolic membranes and mitochondrial inner membranes are proton pumps in which hydride transfer between NADP(+) and NAD(+) is coupled to proton translocation across cytosolic or mitochondrial membranes. The pyridine nucleotide transhydrogenase of Escherichia coli is composed of two subunits (alpha and beta). Three domains are recognized. The extrinsic cytosolic domain 1 of the amino-terminal region of the alpha subunit bears the NAD(H)-binding site. The NADP(H)-binding site is present in domain 3, the extrinsic cytosolic carboxyl-terminal region of the beta subunit. Domain 2 is composed of the membrane-intrinsic carboxyl-terminal region of the alpha subunit and the membrane-intrinsic amino-terminal region of the beta subunit. Treatment of the transhydrogenase of E. coli with 4-chloro-7-nitrobenzo-2-oxa-1,3-diazole (NBD chloride) inhibited enzyme activity. Analysis of inhibition revealed that several sites on the enzyme were involved. NBD chloride modified two (betaCys-147 and betaCys-260) of the seven cysteine residues present in the transhydrogenase. Modification of betaCys-260 in domain 2 resulted in inhibition of enzyme activity. Modification of residues other than cysteine residues also resulted in inhibition of transhydrogenation as shown by use of a cysteine-free mutant enzyme. The beta subunit was modified by NBD chloride to a greater extent than the alpha subunit. Reaction of domain 2 and domain 3 was prevented by NADPH. Modification of domain 3 is probably not associated with inhibition of enzyme activity. Modification of domain 2 of the beta subunit resulted in a decreased binding affinity for NADPH at its binding site in domain 3. The product resulting from the reaction of NBD chloride with NADPH was a very effective inhibitor of transhydrogenation. In experiments with NBD chloride in the presence of NADPH it is likely that all of the sites of reaction described above will contribute to the inhibition observed. The NBD-NADPH adduct will likely be more useful than NBD chloride in investigations of the pyridine nucleotide transhydrogenase.

Mutation of conserved polar residues in the transmembrane domain of the proton-pumping pyridine nucleotide transhydrogenase of Escherichia coli

The pyridine nucleotide transhydrogenase carries out transmembrane proton translocation coupled to transfer of a hydride ion equivalent between NAD+ and NADP+. Previous workers (E. Holmberg et al. Biochemistry 33, 7691-7700, 1994; N. A. Glavas et al. Biochemistry 34, 7694-7702, 1995) had examined the role in proton translocation of conserved charged residues in the transmembrane domain. This study was extended to examine the role of conserved polar residues of the transmembrane domain. Site-directed mutagenesis of these residues did not produce major effects on hydride transfer or proton translocation activities except in the case of betaAsn222. Most mutants of this residue were drastically impaired in these activities. Three phenotypes were recognized. In betaN222C both activities were impaired maximally by 70%. The retention of proton translocation indicated that betaAsn222 was not directly involved in proton translocation. In betaN222H both activities were drastically reduced. Binding of NADP+ but not of NADPH was impaired. In betaN222R, by contrast, NADP+ remained tightly bound to the mutant transhydrogenase. It is concluded that betaAsn222, located in a transmembrane alpha-helix, is part of the conformational pathway by which NADP(H) binding, which occurs outside of the transmembrane domain, is coupled to proton translocation. Some nonconserved or semiconserved polar residues of the transmembrane domain were also examined by site-directed mutagenesis. Interaction of betaGlu124 with the proton translocation pathway is proposed.

Effect of truncation and mutation of the carboxyl-terminal region of the beta subunit on membrane assembly and activity of the pyridine nucleotide transhydrogenase of Escherichia coli

The pyridine nucleotide transhydrogenase of Escherichia coli is a proton pump composed of two different subunits (alpha and beta) assembled as a tetramer (alpha 2 beta 2) in the cytoplasmic membrane. A series of mutants was generated in which the carboxyl-terminal region of the beta subunit was progressively truncated. Removal of the two carboxyl-terminal amino acid residues prevented incorporation of the enzyme into the cytoplasmic membrane. Deletion of the carboxyl-terminal amino acid allowed incorporation of the alpha subunit to near normal levels, but the amount of the beta subunit was much decreased. It is concluded that, although the alpha subunit can be incorporated into the cytoplasmic membrane without the beta subunit, the carboxyl-terminal region of the beta subunit is involved in determining the correct conformation of the alpha subunit for assembly. The carboxyl-terminal amino acid of the beta subunit, beta Leu462, and the penultimate residue, beta Ala461, were individually mutated and the effect on two transhydrogenase activities determined. The reduction of 3-acetylpyridine adenine dinucleotide (AcPyAD+) by NADPH, and by NADH in the presence of NADP+, was decreased maximally by about 60%. The reduction of AcPyAD+ by NADH in the absence of NADP+ was decreased to a greater extent. Most mutants of beta Leu462 showed at least an 80% reduction in activity as well as abnormal kinetics. The abnormal kinetics were explored in the beta A461P mutant and were attributed to tighter binding of the product AcPyADH. This compound competed with NADP+ at the NADP(H)-binding site. It is concluded that the carboxyl-terminal region of the beta subunit contributes to the NADP(H)-binding site on this subunit.

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.

Mechanism of hydride transfer during the reduction of 3-acetylpyridine adenine dinucleotide by NADH catalyzed by the pyridine nucleotide transhydrogenase of Escherichia coli

The pyridine nucleotide transhydrogenase is a proton pump which catalyzes the reversible transfer of a hydride ion equivalent between NAD+ and NADP+ coupled to translocation of protons across the cytoplasmic membrane. The enzyme also catalyzes the reduction of the NAD+ analog 3-acetylpyridine adenine dinucleotide (AcPyAD+) by NADH. It has been proposed (Hutton et al. (1994) Eur. J. Biochem. 219, 1041-1051) that this reaction requires NADP(H) as an intermediate. Thus, NADP+ bound at the NADP(H)-binding site on the transhydrogenase would be reduced by NADH and reoxidized by AcPyAD+ binding alternately to the NAD(H)-binding site. The reduction of AcPyAD+ by NADPH would be a partial reaction in the reduction of AcPyAD+ by NADH. Using cytoplasmic membrane vesicles from mutants having elevated activities for transhydrogenation of AcPyAD+ by NADH in the absence of added NADP(H), the kinetics of reduction of AcPyAD+ by NADH and NADPH have been compared. The Km values for the reductants NADPH and NADH over a range of mutants, and for the non-mutant enzyme, differed to a much lesser degree than the Km for AcPyAD+ in the two reactions. The Km(AcPyAD) values for the transhydrogenation of AcPyAD+ by NADH were over an order of magnitude greater than those for the transhydrogenation of AcPyAD+ by NADPH. It is unlikely that AcPyAD+ binds at the same site in both reactions. A plausible explanation is that this substrate binds to the NADP(H)-binding site for transhydrogenation by NADH. Thus, a hydride equivalent can be transferred directly between NADH and AcPyAD+ under these conditions.

The role of conserved histidine residues in the pyridine nucleotide transhydrogenase of Escherichia coli

The pyridine nucleotide transhydrogenase of Escherichia coli catalyzes the reversible transfer of hydride ion equivalents between NAD+ and NADP+, coupled to translocation of protons across the cytoplasmic membrane. The role of histidine residues in catalysis was investigated by chemical modification with diethylpyrocarbonate and by site-directed mutagenesis. Diethylpyrocarbonate inhibited both hydride ion transfer and coupled proton translocation. Histidine residues were modified as shown spectroscopically and by the ability of hydroxylamine to cause reversal of inhibition. Complete inhibition of hydride ion transfer occurred following modification of 10 residues/enzyme molecule. Site-directed mutagenesis of single conserved histidine residues or the presence of substrates did not provide resistance to inhibition by diethylpyrocarbonate. It is concluded that diethylpyrocarbonate inhibition was a consequence of the structural changes brought about by modification of many histidine residues. With the exception of beta-subunit residue His91 (beta His91), in which mutation can result in specific loss of proton translocation activity [Glavas, N. A., Hou, C. & Bragg, P. D. (1995) Biochemistry 34, 7694-7702], site-directed mutation of the remaining conserved residues alpha His450, beta His161, beta His345 and beta His354 did not demonstrate a direct role for these residues in catalysis. Mutation of beta His161 had relatively little effect on the properties of the enzyme. By contrast, mutation of alpha His450, beta His345 and beta His354 caused major loss of enzyme activities which was probably due to alterations in the structure of the enzyme. These alterations were reflected in changes in the K(m) values for transhydrogenation.

The mechanism of hydride transfer between NADH and 3-acetylpyridine adenine dinucleotide by the pyridine nucleotide transhydrogenase of Escherichia coli

The pyridine nucleotide transhydrogenase of Escherichia coli catalyzes the reversible transfer of hydride ion equivalents between NAD+ and NADP+ coupled to translocation of protons across the cytoplasmic membrane. Recently, transhydrogenation of 3-acetylpyridine adenine dinucleotide (AcPyAD+), an analog of NAD+, by NADH has been described using a solubilized preparation of E. coli transhydrogenase [Hutton, M., Day, J.M., Bizouarn, T., and Jackson, J.B. (1994) Eur. J. Biochem. 219, 1041-1051]. This reaction depended on the presence of NADP(H). We show that (a) this reaction did not require NADP(H) at pH 6 in contrast to pH 8; (b) the reaction occurred at pH 8 in the absence of NADP(H) in the mutant beta H91K and in a mutant in which six amino acids of the carboxy-terminus of the alpha subunit had been deleted; (c) the mutant transhydrogenases contained bound NADP+ and were in a conformation in which the beta subunit was digestible by trypsin; (d) the conformation of the beta subunit of the wild-type enzyme was made susceptible to trypsin digestion by NADP(H) or by placing the enzyme at pH 6 in the absence of NADP(H). It is concluded that reduction of AcPyAD+ by NADH does not involve NADPH as an intermediate and that the role of NADP(H) in this reaction at pH 8 is to cause the transhydrogenase to adopt a conformation favouring transhydrogenation between NADH and AcPyAD+.

Characterization of the interaction of NADH with proton pumping E. coli transhydrogenase reconstituted in the absence and in the presence of bacteriorhodopsin

(1) Proton-pumping nicotinamide nucleotide transhydrogenase from Escherichia coli was purified in a reconstitutively active form employing affinity chromatography on immobilized palmitoyl-Coenzyme A. Reconstituted transhydrogenase showed an active proton pumping and a stimulation of the rate of reduction of 3-acetylpyridine-NAD+ by NADPH by uncouplers. Reconstitution in the absence of a thiol-reducing agent, e.g. dithiothreitol, abolished proton pumping without affecting catalytic activity, giving a decoupled transhydrogenase. (2) Co-reconstitution of transhydrogenase with bacteriorhodopsin gave vesicles which catalyzed a 5-10-fold increased rate of reduction of thio-NADP+ by NADH in the light. The Km for NADH, but not that for thio-NADP+, decreased markedly in the light, indicating an effect of the electrochemical proton potential on the affinity of the enzyme for NADH. Inhibition by substrate derivatives in the absence or presence of light supported this conclusion. Replacement of NADH with 2'-deoxy-NADH gave a strongly sigmoidal concentration dependence, indicating an allosteric change induced by binding to the NAD(H)-site. (3) Reduction of 3-acetylpyridine-NAD+ by NADH in the presence of NADPH, previously demonstrated to be catalyzed by both reconstituted bovine transhydrogenase and detergent-dispersed E. coli transhydrogenase, occurred at a pH below 6.5. This reaction did not pump protons. Proton pumping by 3-acetylpyridine-NAD+ plus NADPH occurred at a pH above 5.5. The two reactions were thus close to mutually exclusive, with a cross point at pH 5.8. Assuming a helix bundle structure of the membrane domain of transhydrogenase, a model is proposed involving histidine 91 of the beta subunit which previously was shown to be essential by site-directed mutagenesis. According to the model the extent of protonation of this histidine determines whether proton pumping or the NADH-3-acetylpyridine-NAD+ reaction takes place.

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.

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.

A mutation at Gly314 of the beta subunit of the Escherichia coli pyridine nucleotide transhydrogenase abolishes activity and affects the NADP(H)-induced conformational change

Escherichia coli RH1 contains a mutation causing complete loss of pyridine nucleotide transhydrogenase activity. A single base change in the chromosomal DNA resulted in the replacement of Gly314 of the beta subunit by a Glu residue. The mutant enzyme was partially purified and its trypsin cleavage products examined. The distinct pattern of polypeptides given by proteolysis of the normal transhydrogenase in the presence of NADP(H) was absent when the mutant enzyme was treated with trypsin. However, the beta subunit of the mutant enzyme retained its ability to bind to NAD-agarose. Further substitutions were made at Gly314 converting it to Ala, Val or Cys by the use of site-directed mutagenesis. All substitutions for Gly314 abolished the activity completely. The enzyme containing the Gly314----Ala mutation was studied in detail and behaved exactly as the enzyme containing the Gly314----Glu mutation. It is concluded that the mutation in the beta subunit abolished the NADP(H)-induced conformational change in the mutant enzyme. This conformational change, caused by NADP(H) binding, is required to cleave the normal beta subunit at Arg265 by trypsin. The genes encoding the pyridine nucleotide transhydrogenase were completely resequenced and several corrections have been made to the previously published sequence [Clarke et al. (1986) Eur. J. Biochem. 158, 647-653].

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.

Anomalous effect of uncouplers on respiratory chain-linked transhydrogenation in Escherichia coli membranes: evidence for a localized proton pathway?

Energization of the pyridine nucleotide transhydrogenase in everted membrane vesicles from Escherichia coli JM83 was compared with the process in vesicles of the same strain transformed with the plasmid pDC21 overexpressing this enzyme. Proton translocation was assayed by the quenching of the fluorescence of the probe quinacrine. Agents able to discharge transmembrane proton gradients such as nigericin and the uncouplers 3,3',4',5-tetrachlorosalicylanilide and carbonyl cyanide m-chlorophenylhydrazone inhibited ATP-dependent transhydrogenation of NADP by NADH and discharged transmembrane proton gradients generated by transhydrogenation of AcNAD by NADPH, by oxidation of NADH, and by hydrolysis of ATP. This was observed in everted membrane vesicles of both strains JM83 and JM83pDC21. These strains differed significantly in the response of the NADH oxidation-dependent transhydrogenase. This reaction was inhibited by nigericin and uncouplers in membrane vesicles of JM83 but there was little inhibition or the reaction was stimulated in JM83pDC21, in spite of the discharge of the NADH oxidation-generated proton gradient measured by quinacrine fluorescence in the latter strain. It is proposed that the transhydrogenase is energized by direct or local (nonbulk phase) proton translocation in membranes of this strain. Uncouplers might facilitate these routes but would not discharge them. The generality of these observations was shown using other strains. NADH oxidase activity was severalfold lower in membrane vesicles of JM83pDC21 compared with JM83. The levels of ubiquinone and cytochromes, and the activities of NADH dehydrogenases I and II, and of cytochrome oxidase, were similar in the two strains. It is concluded that the NADH oxidase activity of JM83pDC21 is low because of the reduced rate of collision between electron-transferring complexes of the respiratory chain due to the large amount of transhydrogenase protein in the membranes of this strain. The large amount of transhydrogenase favors direct, nonbulk phase proton transfer. Transhydrogenase activity was stimulated by Ca2+, Mg2+, or Mn2+.

Topological analysis of the pyridine nucleotide transhydrogenase of Escherichia coli using proteolytic enzymes

The pyridine nucleotide transhydrogenase of Escherichia coli has an alpha 2 beta 2 structure (alpha: Mr, 54,000; beta: Mr, 48,700). Hydropathy analysis of the amino acid sequences suggested that the 10 kDa C-terminal portion of the alpha subunit and the N-terminal 20-25 kDa region of the beta subunit are composed of transmembranous alpha-helices. The topology of these subunits in the membrane was investigated using proteolytic enzymes. Trypsin digestion of everted cytoplasmic membrane vesicles released a 43 kDa polypeptide from the alpha subunit. The beta subunit was not susceptible to trypsin digestion. However, it was digested by proteinase K in everted vesicles. Both alpha and beta subunits were not attacked by trypsin and proteinase K in right-side out membrane vesicles. The beta subunit in the solubilized enzyme was only susceptible to digestion by trypsin if the substrates NADP(H) were present. NAD(H) did not affect digestion of the beta subunit. Digestion of the beta subunit of the membrane-bound enzyme by trypsin was not induced by NADP(H) unless the membranes had been previously stripped of extrinsic proteins by detergent. It is concluded that binding of NADP(H) induces a conformational change in the transhydrogenase. The location of the trypsin cleavage sites in the sequences of the alpha and beta subunits were determined by N- and C-terminal sequencing. A model is proposed in which the N-terminal 43 kDa region of the alpha subunit and the C-terminal 30 kDa region of the beta subunit are exposed on the cytoplasmic side of the inner membrane of E. coli. Binding sites for pyridine nucleotide coenzymes in these regions were suggested by affinity chromatography on NAD-agarose columns.

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.

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

1. H(+)-transhydrogenase from Rhodobacter capsulatus is an integral membrane protein which, unlike the enzyme from Rhodospirillum rubrum, does not require the presence of a water-soluble component for activity. 2. The enzyme from Rb. capsulatus was solubilised in Triton X-100 and subjected to ion-exchange, hydroxyapatite and then gel-exclusion column chromatography. SDS/PAGE of the purified enzyme revealed the presence of two polypeptides with apparent Mr 53,000 and 48,000. Other minor components which were stained on the electrophoresis gels or which were revealed on Western blots exposed to antibodies raised to total membrane proteins, were probably contaminants. 3. Antibodies raised to the 53-kDa and 48-kDa polypeptides cross-reacted with equivalent polypeptides in Western blots of solubilised membranes from Rb. capsulatus, Rhodobacter sphaeroides and Rhs. rubrum. The significance of this finding is discussed in the context of the hypothesis [Fisher, R.R. & Earle, S.R. (1982) The pyridine nucleotide coenzymes, pp. 279-324, Academic Press, New York] that the soluble component associated with H(+)-transhydrogenase from Rhs. rubrum is an integral part of the catalytic machinery. Antibodies against the 48-kDa and 53-kDa polypeptides of the Rb. capsulatus enzyme cross-reacted with equivalent polypeptides in solubilised membranes of Escherichia coli. 4. The dependence of the rate of H- transfer by purified H(+)-transhydrogenase on the nucleotide substrate concentrations under steady-state conditions, the effects of inhibition by nucleotide products and the inhibition by 2'-AMP and by 5'-AMP suggest that the reaction proceeds by the random addition of substrates to the enzyme with the formation of a ternary complex. 5. In conflict with this conclusion, the reduction of acetylpyridine adenine dinucleotide (AcPdAD+) by NADH in the absence of NADP+ by bacterial membranes was earlier taken as evidence for the existence of a reduced enzyme intermediate [Fisher, R.R. & Earle, S.R. (1982) The pyridine nucleotide coenzymes, pp. 279-324, Academic Press, New York]. However, it is shown here that although chromatophore membranes of Rb. capsulatus catalysed the reduction of AcPdAD+ by NADH, the reaction was not associated with the purified H(+)-transhydrogenase. Moreover, in contrast with the true transhydrogenase reaction, the reconstitution of AcPdAD+ reduction by NADH (in the absence of NADP+) in washed membranes of Rhs. rubrum with partially purified transhydrogenase factor, was only additive.

Crosslinking and radiation inactivation analysis of the subunit structure of the pyridine nucleotide transhydrogenase of Escherichia coli

The pyridine nucleotide transhydrogenase of Escherichia coli consists of two types of subunit (alpha: Mr 53,906; beta: Mr 48,667). The purified and membrane-bound enzymes were crosslinked with a series of bifunctional crosslinking agents and by catalyzing the formation of inter-chain disulfides in the presence of cupric 1,10-phenanthrolinate. Crosslinked dimers alpha 2, alpha beta and beta 2, and the trimer alpha 2 beta were obtained. A small amount of tetramer, probably alpha 2 beta 2, was also formed. Radiation inactivation was used to determine the molecular size of the transhydrogenase. The radiation inactivation size (217,000) and chemical crosslinking are consistent with the structure (Mr 205,146) being the oligomer that is responsible for biological activity.

The coupling between protonmotive force and the NAD(P)+ transhydrogenase in chromatophores from photosynthetic bacteria

1. The activity of NAD(P)+ transhydrogenase in chromatophores of Rhodobacter capsulatus relaxed from a high rate during illumination to a lower rate after darkening with a half-time of approximately 100 ms. 2. The dissipative ionic current flowing across the chromatophore membrane was increased in the presence of transhydrogenase substrates. This is attributed to proton current through the transhydrogenase enzyme. Subject to the assumption that transhydrogenase does not conduct in the absence of nucleotide substrates, the ratio of protons translocated across the membrane per hydride ion transferred was 0.4 +/- 0.5. Within the error and uncertainities in the calibration procedure, this ratio may be consistent with a stoichiometry of one but higher values seem unlikely. The ratio of hydride ion transferred in the transhydrogenase to electrons transferred through the cyclic electron transport system was approximately 0.2. 3. The Kappm values for the transhydrogenase substrates were determined for chromatophores in illuminated and darkened suspensions over a range of pH. These values are discussed in relation to the equivalent parameters reported for mitochondria transhydrogenase [Rydstrom, J. (1977) Biochim. Biophys. Acta 255, 9641-9646] and were used to calculate the concentrations of substrates which effectively saturate the enzyme. 4. At substrate concentrations which were in excess of 8 X Kappm the dependence of transhydrogenase rate on the value of the membrane potential (zero pH gradient) was determined at pH 6.3, 6.9, 7.6 and 9.0. The relation was similar at pH 6.9 and 7.6. At alkaline pH the apparent threshold in the relation became more prominent as it was shifted to slightly higher values of membrane potential. At acid pH a shift in the opposite direction diminished the apparent threshold and saturation at high membrane potential became more dominant. We use these data in an attempt to discriminate between two models of energy transduction: (a) the driving force exerted by the membrane potential is mediated by a pH gradient formed through the operation of a proton well in the transhydrogenase; (b) the membrane potential increases a rate constant for charge translocation through transhydrogenase by decreasing the effective height of the Eyring barrier for charge transfer across the membrane through the enzyme. The second model leads to a more simple description than the first of the pH dependence of transhydrogenase rate on membrane potential.4+ transhydrogenase activity in chromatopho

Nucleotide sequence of the pntA and pntB genes encoding the pyridine nucleotide transhydrogenase of Escherichia coli

A 3240-base-pair DNA fragment spanning the pyridine nucleotide transhydrogenase (pnt) genes of Escherichia coli has been sequenced. The sequence contains two open-reading frames, pntA and pntB of 1506 and 1386 base pairs, coding for the transhydrogenase alpha and beta subunits, respectively. The coding sequences are preceded by a promoter-like structure and are most likely co-transcribed. Each coding sequence is preceded by a Shine-Dalgarno sequence. The amino-terminal amino acid sequences were determined from the purified alpha and beta subunits of the transhydrogenase. These sequences agree with those predicted from the nucleotide sequences of the pntA and pntB genes. The predicted relative molecular masses of 53906 (alpha) and 48667 (beta) are close to the values obtained by analysis of the subunits by sodium dodecyl sulfate/polyacrylamide gel electrophoresis. Several hydrophobic regions large enough to span the cytoplasmic membrane were observed in each subunit. These results indicate that transhydrogenase is an intrinsic membrane protein.

Expression of the cloned subunits of Escherichia coli transhydrogenase from separate replicons

The pntA and pntB genes of Escherichia coli, encoding the alpha- and beta-subunits of the pyridine nucleotide transhydrogenase, were cloned individually in two different compatible plasmids into Escherichia coli mutants lacking transhydrogenase activity. Energy-linked and non-energy-linked transhydrogenase activities were produced only in cells carrying both plasmids thus showing that the products of both genes are required for the formation of an active enzyme. ATP-energized transhydrogenase activity was not increased in cells containing amplified levels of the transhydrogenase when the cell membrane ATPase was also amplified. It is suggested that the excess transhydrogenase is effectively uncoupled from the ATPase by compartmentalization in the cell.