Localization and Function of the Membrane-bound Riboflavin in the Na+-translocating NADH:Quinone Oxidoreductase (Na+-NQR) from Vibrio cholerae

The sodium ion-translocating NADH:quinone oxidoreductase (Na⁺-NQR) from the human pathogen Vibrio cholerae is a respiratory membrane protein complex that couples the oxidation of NADH to the transport of Na⁺ across the bacterial membrane. The Na⁺-NQR comprises the six subunits NqrABCDEF, but the stoichiometry and arrangement of these subunits are unknown. Redox-active cofactors are FAD and a 2Fe-2S cluster on NqrF, covalently attached FMNs on NqrB and NqrC, and riboflavin and ubiquinone-8 with unknown localization in the complex. By analyzing the cofactor content and NADH oxidation activity of subcomplexes of the Na⁺-NQR lacking individual subunits, the riboflavin cofactor was unequivocally assigned to the membrane-bound NqrB subunit. Quantitative analysis of the N-terminal amino acids of the holo-complex revealed that NqrB is present in a single copy in the holo-complex. It is concluded that the hydrophobic NqrB harbors one riboflavin in addition to its covalently attached FMN. The catalytic role of two flavins in subunit NqrB during the reduction of ubiquinone to ubiquinol by the Na⁺-NQR is discussed.     

The sodium pumping NADH:quinone oxidoreductase (Na+-NQR), a unique redox-driven ion pump

The Na⁺-translocating NADH:quinone oxidoreductase (Na⁺-NQR) is a unique Na⁺ pumping respiratory complex found only in prokaryotes, that plays a key role in the metabolism of marine and pathogenic bacteria, including Vibrio cholerae and other human pathogens. Na⁺-NQR is the main entrance for reducing equivalents into the respiratory chain of these bacteria, catalyzing the oxidation of NADH and the reduction of quinone, the free energy of this redox reaction drives the selective translocation of Na⁺ across the cell membrane, which energizes key cellular processes. In this review we summarize the unique properties of Na⁺-NQR in terms of its redox cofactor composition, electron transfer reactions and a possible mechanism of coupling and pumping.     

The Conformational Changes Induced by Ubiquinone Binding in the Na+-pumping NADH:Ubiquinone Oxidoreductase (Na+-NQR) Are Kinetically Controlled by Conserved Glycines 140 and 141 of the NqrB Subunit

Na⁺-pumping NADH:ubiquinone oxidoreductase (Na⁺-NQR) is responsible for maintaining a sodium gradient across the inner bacterial membrane. This respiratory enzyme, which couples sodium pumping to the electron transfer between NADH and ubiquinone, is not present in eukaryotes and as such could be a target for antibiotics. In this paper it is shown that the site of ubiquinone reduction is conformationally coupled to the NqrB subunit, which also hosts the final cofactor in the electron transport chain, riboflavin. Previous work showed that mutations in conserved NqrB glycine residues 140 and 141 affect ubiquinone reduction and the proper functioning of the sodium pump. Surprisingly, these mutants did not affect the dissociation constant of ubiquinone or its analog HQNO (2-n-heptyl-4-hydroxyquinoline N-oxide) from Na⁺-NQR, which indicates that these residues do not participate directly in the ubiquinone binding site but probably control its accessibility. Indeed, redox-induced difference spectroscopy showed that these mutations prevented the conformational change involved in ubiquinone binding but did not modify the signals corresponding to bound ubiquinone. Moreover, data are presented that demonstrate the NqrA subunit is able to bind ubiquinone but with a low non-catalytically relevant affinity. It is also suggested that Na⁺-NQR contains a single catalytic ubiquinone binding site and a second site that can bind ubiquinone but is not active.     

The single NqrB and NqrC subunits in the Na+-translocating NADH: Quinone oxidoreductase (Na+-NQR) from Vibrio cholerae each carry one covalently attached FMN

The Na⁺-translocating NADH:quinone oxidoreductase (Na⁺-NQR) is the prototype of a novel class of flavoproteins carrying a riboflavin phosphate bound to serine or threonine by a phosphodiester bond to the ribityl side chain. This membrane-bound, respiratory complex also contains one non-covalently bound FAD, one non-covalently bound riboflavin, ubiquinone-8 and a [2Fe–2S] cluster. Here, we report the quantitative analysis of the full set of flavin cofactors in the Na⁺-NQR and characterize the mode of linkage of the riboflavin phosphate to the membrane-bound NqrB and NqrC subunits. Release of the flavin by β-elimination and analysis of the cofactor demonstrates that the phosphate group is attached at the 5'-position of the ribityl as in authentic FMN and that the Na⁺-NQR contains approximately 1.7 mol covalently bound FMN per mol non-covalently bound FAD. Therefore, each of the single NqrB and NqrC subunits in the Na⁺-NQR carries a single FMN. Elimination of the phosphodiester bond yields a dehydro-2-aminobutyrate residue, which is modified with β-mercaptoethanol by Michael addition. Proteolytic digestion followed by mass determination of peptide fragments reveals exclusive modification of threonine residues, which carry FMN in the native enzyme. The described reactions allow quantification and localization of the covalently attached FMNs in the Na⁺-NQR and in related proteins belonging to the Rhodobacter nitrogen fixation (RNF) family of enzymes. This article is part of a Special Issue entitled: 17th European Bioenergetics Conference (EBEC 2012).     

NMR Reveals Double Occupancy of Quinone-type Ligands in the Catalytic Quinone Binding Site of the Na+-translocating NADH:Quinone Oxidoreductase from Vibrio cholerae

The sodium ion-translocating NADH:quinone oxidoreductase (Na⁺-NQR) from the pathogen Vibrio cholerae exploits the free energy liberated during oxidation of NADH with ubiquinone to pump sodium ions across the cytoplasmic membrane. The Na⁺-NQR consists of four membrane-bound subunits NqrBCDE and the peripheral NqrF and NqrA subunits. NqrA binds ubiquinone-8 as well as quinones with shorter prenyl chains (ubiquinone-1 and ubiquinone-2). Here we show that the quinone derivative 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (DBMIB), a known inhibitor of the bc₁ and b₆f complexes found in mitochondria and chloroplasts, also inhibits quinone reduction by the Na⁺-NQR in a mixed inhibition mode. Tryptophan fluorescence quenching and saturation transfer difference NMR experiments in the presence of Na⁺-NQR inhibitor (DBMIB or 2-n-heptyl-4-hydroxyquinoline N-oxide) indicate that two quinone analog ligands are bound simultaneously by the NqrA subunit with very similar interaction constants as observed with the holoenzyme complex. We conclude that the catalytic site of quinone reduction is located on NqrA. The two ligands bind to an extended binding pocket in direct vicinity to each other as demonstrated by interligand Overhauser effects between ubiquinone-1 and DBMIB or 2-n-heptyl-4-hydroxyquinoline N-oxide, respectively. We propose that a similar spatially close arrangement of the native quinone substrates is also operational in vivo, enhancing the catalytic efficiency during the final electron transfer steps in the Na⁺-NQR.     

The Kinetic Reaction Mechanism of the Vibrio cholerae Sodium-dependent NADH Dehydrogenase

The sodium-dependent NADH dehydrogenase (Na⁺-NQR) is the main ion transporter in Vibrio cholerae. Its activity is linked to the operation of the respiratory chain and is essential for the development of the pathogenic phenotype. Previous studies have described different aspects of the enzyme, including the electron transfer pathways, sodium pumping structures, cofactor and subunit composition, among others. However, the mechanism of the enzyme remains to be completely elucidated. In this work, we have studied the kinetic mechanism of Na⁺-NQR with the use of steady state kinetics and stopped flow analysis. Na⁺-NQR follows a hexa-uni ping-pong mechanism, in which NADH acts as the first substrate, reacts with the enzyme, and the oxidized NAD leaves the catalytic site. In this conformation, the enzyme is able to capture two sodium ions and transport them to the external side of the membrane. In the last step, ubiquinone is bound and reduced, and ubiquinol is released. Our data also demonstrate that the catalytic cycle involves two redox states, the three- and five-electron reduced forms. A model that gathers all available information is proposed to explain the kinetic mechanism of Na⁺-NQR. This model provides a background to understand the current structural and functional information.     

Reaction centers fromRhodopseudomonas sphaeroides in reconstituted phospholipid vesicles. II. Light-induced proton translocation

Unidirectional light-dependent proton translocation was demonstrated in a suspension of reconstituted reaction center (RC) vesicles supplemented with cytochromec and 2,3-dimethoxy-5-methyl-1,4-benzoquinone (UQ₀), a lipid-and water-soluble quinone. Proton translocation was detected only at alkaline pH. The pH dependence can be accounted for by the slow redox reaction between the reduced quinone (UQ₀H₂) and oxidized cytochromec. This conclusion is based on (i) the pH dependence of partial reactions of the reconstituted proton translocation cycle, measured either optically or electrometrically and (ii) titration studies with cytochromec and UQ₀. At 250 and 25 µM UQ₀ and cytochromec, respectively, maximal proton translocation was observed at pH 9.6. This pH optimum can be extended to a more acidic pH by increasing the concentration of the soluble redox mediators in the reconstituted cyclic electron transfer chain. At the alkaline side of the pH optimum, proton translocation appears to be limited by electron transfer from the endogenous primary to the secondary quinone within the RCs. The light intensity limits the reconstituted proton pump at the optimal pH. The results are discussed in the context of a reaction scheme for the cyclic redox reactions and the associated proton translocation events.Abbreviations RC reaction center - UQ₀/UQ₀H₂ oxidized and reduced form of 2,3-dimethoxy-5-methyl-1,4-benzoquinone - D/D⁺ reduced and oxidized form of the primary electron donor of the RCs - CCCP carbonylcyanide-trichloromethoxy phenylhydrazone - UQ_A/UQ _A ^– oxidized and semiquinone form of the primary electron acceptor of the RCs - UQ_B/UQ _B ^– /UQ_BH₂ oxidized, semiquinone, and reduced form of the secondary electron acceptor of the RCs - LDAO lauryldimethylamine-N-oxide During the course of this study K.J.H. was supported by a grant from the Netherlands Organization for the Advancement of Pure Research (Z.W.O.). This research was supported by grants from the National Institutes of Health (EY-02084) and from the Office of Naval Research (ONR-NOOO 14-79-C 0798) to M. Montal.     

Insights into the mechanism of electron transfer and sodium translocation of the Na+-pumping NADH:quinone oxidoreductase

Na⁺-NQR is a unique energy-transducing complex, widely distributed among marine and pathogenic bacteria. It converts the energy from the oxidation of NADH and the reduction of quinone into an electrochemical Na⁺-gradient that can provide energy for the cell. Na⁺-NQR is not homologous to any other respiratory protein but is closely related to the RNF complex. In this review we propose that sodium pumping in Na⁺-NQR is coupled to the redox reactions by a novel mechanism, which operates at multiple sites, is indirect and mediated by conformational changes of the protein. This article is part of a Special Issue entitled: 17th European Bioenergetics Conference (EBEC 2012).     

Riboflavin is an active redox cofactor in the Na+-pumping NADH: quinone oxidoreductase (Na+-NQR) from Vibrio cholerae

Here we present new evidence that riboflavin is present as one of four flavins in Na+-NQR. In particular, we present conclusive evidence that the source of the neutral radical is not one of the FMNs and that riboflavin is the center that gives rise to the neutral flavosemiquinone. The riboflavin is a bona fide redox cofactor and is likely to be the last redox carrier of the enzyme, from which electrons are donated to quinone. We have constructed a double mutant that lacks both covalently bound FMN cofactors (NqrB-T236Y/NqrC-T225Y) and have studied this mutant together with the two single mutants (NqrB-T236Y and NqrC-T225Y) and a mutant that lacks the noncovalently bound FAD in NqrF (NqrF-S246A). The double mutant contains riboflavin and FAD in a 0.6:1 ratio, as the only flavins in the enzyme; noncovalently bound flavins were detected. In the oxidized form, the double mutant exhibits an EPR signal consistent with a neutral flavosemiquinone radical, which is abolished on reduction of the enzyme. The same radical can be observed in the FAD deletion mutant. Furthermore, when the oxidized enzyme reacts with ubiquinol (the reduced form of the usual electron acceptor) in a process that reverses the physiological direction of the electron flow, a single kinetic phase is observed. The kinetic difference spectrum of this process is consistent with one-electron reduction of a neutral flavosemiquinone. The presence of riboflavin in the role of a redox cofactor is thus far unique to Na+-NQR.     

The Ferredoxin:NAD+ Oxidoreductase (Rnf) from the Acetogen Acetobacterium woodii Requires Na+ and Is Reversibly Coupled to the Membrane Potential

The anaerobic acetogenic bacterium Acetobacterium woodii has a novel Na⁺-translocating electron transport chain that couples electron transfer from reduced ferredoxin to NAD⁺ with the generation of a primary electrochemical Na⁺ potential across its cytoplasmic membrane. In previous assays in which Ti³⁺ was used to reduce ferredoxin, Na⁺ transport was observed, but not a Na⁺ dependence of the electron transfer reaction. Here, we describe a new biological reduction system for ferredoxin in which ferredoxin is reduced with CO, catalyzed by the purified acetyl-CoA synthase/CO dehydrogenase from A. woodii. Using CO-reduced ferredoxin, NAD⁺ reduction was highly specific and strictly dependent on ferredoxin and occurred at a rate of 50 milliunits/mg of protein. Most important, this assay revealed for the first time a strict Na⁺ dependence of this electron transfer reaction. The K_m was 0.2 mm. Na⁺ could be partly substituted by Li⁺. Na⁺ dependence was observed at neutral and acidic pH values, indicating the exclusive use of Na⁺ as a coupling ion. Electron transport from reduced ferredoxin to NAD⁺ was coupled to electrogenic Na⁺ transport, indicating the generation of Δ$\tilde{\mu }$_Na⁺. Vice versa, endergonic ferredoxin reduction with NADH as reductant was possible, but only in the presence of Δ$\tilde{\mu }$_Na⁺, and was accompanied by Na⁺ efflux out of the vesicles. This is consistent with the hypothesis that Rnf also catalyzes ferredoxin reduction at the expense of an electrochemical Na⁺ gradient. The physiological significance of this finding is discussed.     

Intracellular Na+ Regulates Epithelial Na+ Channel Maturation

Epithelial Na⁺ channel (ENaC) function is regulated by the intracellular Na⁺ concentration ([Na⁺]_i) through a process known as Na⁺ feedback inhibition. Although this process is known to decrease the expression of proteolytically processed active channels on the cell surface, it is unknown how [Na⁺]_i alters ENaC cleavage. We show here that [Na⁺]_i regulates the posttranslational processing of ENaC subunits during channel biogenesis. At times when [Na⁺]_i is low, ENaC subunits develop mature N-glycans and are processed by proteases. Conversely, glycan maturation and sensitivity to proteolysis are reduced when [Na⁺]_i is relatively high. Surface channels with immature N-glycans were not processed by endogenous channel activating proteases, nor were they sensitive to cleavage by exogenous trypsin. Biotin chase experiments revealed that the immature surface channels were not converted into mature cleaved channels following a reduction in [Na⁺]_i. The hypothesis that [Na⁺]_i regulates ENaC maturation within the biosynthetic pathways is further supported by the finding that Brefeldin A prevented the accumulation of processed surface channels following a reduction in [Na⁺]_i. Therefore, increased [Na⁺]_i interferes with ENaC N-glycan maturation and prevents the channel from entering a state that allows proteolytic processing.     

Cys377 residue in NqrF subunit confers Ag<Superscript>+</Superscript> sensitivity of Na<Superscript>+</Superscript>-translocating NADH:quinone oxidoreductase from <Emphasis Type="Italic">Vibrio harveyi</Emphasis>

The Na⁺-translocating NADH:quinone oxidoreductase (Na⁺-NQR) is a component of the respiratory chain of various bacteria that generates a redox-driven transmembrane electrochemical Na⁺ potential. The Na⁺-NQR activity is known to be specifically inhibited by low concentrations of silver ions. Replacement of the conserved Cys377 residue with alanine in the NqrF subunit of Na⁺-NQR from Vibrio harveyi resulted in resistance of the enzyme to Ag⁺ and to other heavy metal ions. Analysis of the catalytic activity also showed that the rate of electron input into the mutant Na⁺-NQR decreased by about 14-fold in comparison to the wild type enzyme, whereas all other properties of _NqrFC377A Na⁺-NQR including its stability remained unaffected.     

Localization-controlled specificity of FAD:threonine flavin transferases in Klebsiella pneumoniae and its implications for the mechanism of Na-translocating NADH:quinone oxidoreductase

The Klebsiella pneumoniae genome contains genes for two putative flavin transferase enzymes (ApbE1 and ApbE2) that add FMN to protein Thr residues. ApbE1, but not ApbE2, has a periplasm-addressing signal sequence. The genome also contains genes for three target proteins with the Dxx(s/t)gAT flavinylation motif: two subunits of Na⁺-translocating NADH:quinone oxidoreductase (Na⁺-NQR), and a 99.5 kDa protein, KPK_2907, with a previously unknown function. We show here that KPK_2907 is an active cytoplasmically-localized fumarate reductase. K. pneumoniae cells with an inactivated kpk_2907 gene lack cytoplasmic fumarate reductase activity, while retaining this activity in the membrane fraction. Complementation of the mutant strain with a kpk_2907-containing plasmid resulted in a complete recovery of cytoplasmic fumarate reductase activity. KPK_2907 produced in Escherichia coli cells contains 1 mol/mol each of covalently bound FMN, noncovalently bound FMN and noncovalently bound FAD. Lesion in the ApbE1 gene in K. pneumoniae resulted in inactive Na⁺-NQR, but cytoplasmic fumarate reductase activity remained unchanged. On the contrary, lesion in the ApbE2 gene abolished the fumarate reductase but not the Na⁺-NQR activity. Both activities could be restored by transformation of the ApbE1- or ApbE2-deficient K. pneumoniae strains with plasmids containing the Vibrio cholerae apbE gene with or without the periplasm-directing signal sequence, respectively. Our data thus indicate that ApbE1 and ApbE2 bind FMN to Na⁺-NQR and fumarate reductase, respectively, and that, contrary to the presently accepted view, the FMN residues are on the periplasmic side of Na⁺-NQR. A new, “electron loop” mechanism is proposed for Na⁺-NQR, involving an electroneutral Na⁺/electron symport. This article is part of a Special Issue entitled: 18th European Bioenergetic Conference.     

Relationship between Intracellular Na+ Concentration and Reduced Na+ Affinity in Na+,K+-ATPase Mutants Causing Neurological Disease

The neurological disorders familial hemiplegic migraine type 2 (FHM2), alternating hemiplegia of childhood (AHC), and rapid-onset dystonia parkinsonism (RDP) are caused by mutations of Na⁺,K⁺-ATPase α₂ and α₃ isoforms, expressed in glial and neuronal cells, respectively. Although these disorders are distinct, they overlap in phenotypical presentation. Two Na⁺,K⁺-ATPase mutations, extending the C terminus by either 28 residues (“+28” mutation) or an extra tyrosine (“+Y”), are associated with FHM2 and RDP, respectively. We describe here functional consequences of these and other neurological disease mutations as well as an extension of the C terminus only by a single alanine. The dependence of the mutational effects on the specific α isoform in which the mutation is introduced was furthermore studied. At the cellular level we have characterized the C-terminal extension mutants and other mutants, addressing the question to what extent they cause a change of the intracellular Na⁺ and K⁺ concentrations ([Na⁺]_i and [K⁺]_i) in COS cells. C-terminal extension mutants generally showed dramatically reduced Na⁺ affinity without disturbance of K⁺ binding, as did other RDP mutants. No phosphorylation from ATP was observed for the +28 mutation of α₂ despite a high expression level. A significant rise of [Na⁺]_i and reduction of [K⁺]_i was detected in cells expressing mutants with reduced Na⁺ affinity and did not require a concomitant reduction of the maximal catalytic turnover rate or expression level. Moreover, two mutations that increase Na⁺ affinity were found to reduce [Na⁺]_i. It is concluded that the Na⁺ affinity of the Na⁺,K⁺-ATPase is an important determinant of [Na⁺]_i.     

Ouabain switches Na+ transport to Na+/Na+ equivalent exchange in normal and apoptotic lymphoid cells

A theory of change of the ionic fluxes in the lymphoid cells in their transition from normal to apoptosis we have developed previously is applied to the analysis of Na⁺/Na⁺ exchange fluxes in human lymphoid cells U937 exposed to ouabain. We solve a system of equations describing changes in the intracellular concentrations of Na⁺, K⁺ and Cl^?, membrane potential and cell volume. It is shown that the Na⁺ influx (I _Na/Na) and output flux through the Na⁺/Na⁺ tract increased 4 times in 8 h after disconnecting Na⁺/K⁺-ATPase for normal cell U937. These fluxes increased 2.6 times for apoptotic cells. The value of I _Na/Na after 8 h off pump by ouabain is 97% of the total Na⁺ input for both cell types. It is concluded that ouabain not only inhibits the Na⁺/K⁺-ATPase, but also increases Na⁺ exchange fluxes through the Na⁺/Na⁺ tract, thereby switching sodium transport across the membrane of lymphoid cells to Na⁺/Na⁺ equivalent exchange.     

Rescue of Na+ Affinity in Aspartate 928 Mutants of Na+,K+-ATPase by Secondary Mutation of Glutamate 314

The Na⁺,K⁺-ATPase binds Na⁺ at three transport sites denoted I, II, and III, of which site III is Na⁺-specific and suggested to be the first occupied in the cooperative binding process activating phosphorylation from ATP. Here we demonstrate that the asparagine substitution of the aspartate associated with site III found in patients with rapid-onset dystonia parkinsonism or alternating hemiplegia of childhood causes a dramatic reduction of Na⁺ affinity in the α1-, α2-, and α3-isoforms of Na⁺,K⁺-ATPase, whereas other substitutions of this aspartate are much less disruptive. This is likely due to interference by the amide function of the asparagine side chain with Na⁺-coordinating residues in site III. Remarkably, the Na⁺ affinity of site III aspartate to asparagine and alanine mutants is rescued by second-site mutation of a glutamate in the extracellular part of the fourth transmembrane helix, distant to site III. This gain-of-function mutation works without recovery of the lost cooperativity and selectivity of Na⁺ binding and does not affect the E₁-E₂ conformational equilibrium or the maximum phosphorylation rate. Hence, the rescue of Na⁺ affinity is likely intrinsic to the Na⁺ binding pocket, and the underlying mechanism could be a tightening of Na⁺ binding at Na⁺ site II, possibly via movement of transmembrane helix four. The second-site mutation also improves Na⁺,K⁺ pump function in intact cells. Rescue of Na⁺ affinity and Na⁺ and K⁺ transport by second-site mutation is unique in the history of Na⁺,K⁺-ATPase and points to new possibilities for treatment of neurological patients carrying Na⁺,K⁺-ATPase mutations.     

Continuous fluorescence-based measurement of redox-driven sodium ion translocation

Investigation of the mechanism of sodium ion pumping enzymes requires methods to follow the translocation of sodium ions by the purified and reconstituted proteins in vitro. Here, we describe a protocol that allows following the accumulation of Na⁺ in proteoliposomes by the Na⁺-translocating NADH:quinone oxidoreductase (Na⁺-NQR) from Vibrio cholerae using the sodium-sensitive fluorophor sodium green. In the presence of a regenerative system for its substrate NADH, the Na⁺-NQR accumulates Na⁺ in the proteoliposomes which is visible as a change in fluorescence.     

The leak mode of type II Na+-Pi cotransporters

Na⁺-coupled phosphate cotransporters of the SLC34 gene family catalyze the movement of inorganic phosphate (P_i) across epithelia by using the free energy of the downhill electrochemical Na⁺ gradient across the luminal membrane. Electrogenic (NaPi-IIa/b) and electroneutral (NaPi-IIc) isoforms prefer divalent P_i and show strict Na⁺:P_i stoichiometries of 3:1 and 2:1, respectively. For electrogenic cotransport, one charge is translocated per transport cycle. When NaPi-IIa or NaPi-IIb are expressed in Xenopus oocytes, application of the Pi transport inhibitor phosphonoformic acid (PFA) blocks a leak current that is not detectable in the electroneutral isoform. In this review, we present the experimental evidence that this transport-independent leak originates from a Na⁺-dependent uniport carrier mode intrinsic to NaPi-IIa/b isoforms. Our findings, based on the characteristics of the PFA-inhibitable leak measured from wild-type and mutant constructs, can be incorporated into an alternating access class model in which the leak and cotransport modes are mutually exclusive and share common kinetic partial reactions.