Functional sulfhydryl groups of ferredoxin-NADP+ oxidoreductase

Chemical modification of membrane-bound ferredoxin-NADP⁺ oxidoreductase with oxidants of vicinal dithiols caused inactivation of NADP⁺ photoreduction, with no effect on the diaphorase activity. Inactivation was partially prevented by ferredoxin and reversed by dithioerythritol. N-Ethylmaleimide inhibited both activities, even though with a different kinetic pattern. Inactivation of NADP⁺ reduction by either N-ethylmaleimide or o-iodosobenzoate was greater in the light than in the dark. The results suggest the existence of essential sulfhydryl groups related with the ferredoxin site, in addition to those described in the soluble flavorprotein. The role of SH residues in the activity and regulation of membrane bound reductase is discussed.     

Structural Basis for a Bispecific NADP+ and CoA Binding Site in an Archaeal Malonyl-Coenzyme A Reductase

Autotrophic members of the Sulfolobales (crenarchaeota) use the 3-hydroxypropionate/4-hydroxybutyrate cycle to assimilate CO₂ into cell material. The product of the initial acetyl-CoA carboxylation with CO₂, malonyl-CoA, is further reduced to malonic semialdehyde by an NADPH-dependent malonyl-CoA reductase (MCR); the enzyme also catalyzes the reduction of succinyl-CoA to succinic semialdehyde onwards in the cycle. Here, we present the crystal structure of Sulfolobus tokodaii malonyl-CoA reductase in the substrate-free state and in complex with NADP⁺ and CoA. Structural analysis revealed an unexpected reaction cycle in which NADP⁺ and CoA successively occupy identical binding sites. Both coenzymes are pressed into an S-shaped, nearly superimposable structure imposed by a fixed and preformed binding site. The template-governed cofactor shaping implicates the same binding site for the 3′- and 2′-ribose phosphate group of CoA and NADP⁺, respectively, but a different one for the common ADP part: the β-phosphate of CoA aligns with the α-phosphate of NADP⁺. Evolution from an NADP⁺ to a bispecific NADP⁺ and CoA binding site involves many amino acid exchanges within a complex process by which constraints of the CoA structure also influence NADP⁺ binding. Based on the paralogous aspartate-β-semialdehyde dehydrogenase structurally characterized with a covalent Cys-aspartyl adduct, a malonyl/succinyl group can be reliably modeled into MCR and discussed regarding its binding mode, the malonyl/succinyl specificity, and the catalyzed reaction. The modified polypeptide surrounding around the absent ammonium group in malonate/succinate compared with aspartate provides the structural basis for engineering a methylmalonyl-CoA reductase applied for biotechnical polyester building block synthesis.     

Affinity labeling of spinach ferredoxin-NADP+ oxidoreductase with periodate-oxidized NADP+

Periodate-oxidized NADP⁺ (dialdehyde-NADP⁺) inactivated soluble ferredoxin-NADP⁺ oxidoreductase and combined covalently to the enzyme. This inactivation was first order with respect to dialdehyde-NADP⁺ and followed saturation kinetics, indicating that the enzyme initially forms a reversible complex with the inactivator. NADP⁺ afforded complete protection against inactivation, while spinach ferredoxin was uneffective. In the presence of exogenous ferredoxin and illuminated thylakoids, the nucleotide analog functioned as a coenzyme for the reductase, although with rather lower efficiency than NADP⁺. It also acted as a competitive inhibitor with respect to NADPH in diaphorase activity. Incorporation of radioactivity from periodate-oxidized [³H]NADP⁺ gave a stoichiometry of 0.85 mol of reagent/mol of reductase, indicating that the modification of a single residue in the flavoprotein is responsible for the loss of enzymatic activity.     

Structural prototypes for an extended family of flavoprotein reductases: Comparison of phthalate dioxygenase reductase with ferredoxin reductase and ferredoxin

The structure of phthalate dioxygenase reductase (PDR), a monomeric iron-sulfur flavoprotein that delivers electrons from NADH to phthalate dioxygenase, is compared to ferredoxin-NADP⁺ reductase (FNR) and ferredoxin, the proteins that reduce NADP⁺ in the final reaction of photosystem I. The folding patterns of the domains that bind flavin, NAD(P), and [2Fe-2S] are very similar in the two systems. Alignment of the X-ray structures of PDR and FNR substantiates the assignment of features that characterize a family of flavoprotein reductases whose members include cytochrome P-450 reductase, sulfite and nitrate reductases, and nitric oxide synthase. Hallmarks of this subfamily of flavoproteins, here termed the FNR family, are an antiparallel β-barrel that binds the flavin prosthetic group, and a characteristic variant of the classic pyridine nucleotide-binding fold. Despite the similarities between FNR and PDR, attempts to model the structure of a dissociable FNR:ferredoxin complex by analogy with PDR reveal features that are at odds with chemical crosslinking studies (Zanetti, G., Morelli, D., Ronchi, S., Negri, A., Aliverti, A., & Curti, B., 1988, Biochemistry 27, 3753–3759). Differences in the binding sites for flavin and pyridine nucleotides determine the nucleotide specificities of FNR and PDR. The specificity of FNR for NADP⁺ arises primarily from substitutions in FNR that favor interactions with the 2′ phosphate of NADP⁺. Variations in the conformation and sequences of the loop adjoining the flavin phosphate affect the selectivity for FAD versus FMN. The midpoint potentials for reduction of the flavin and [2Fe–2S] groups in PDR are higher than their counterparts in FNR and spinach ferredoxin, by about 120 mV and 260 mV, respectively. Comparisons of the structure of PDR with spinach FNR and with ferredoxin from Anabaena 7120, along with calculations of electrostatic potentials, suggest that local interactions, including hydrogen bonds, are the dominant contributors to these differences in potential.     

The role of electrostatic interactions in the formation of ferredoxin–ferredoxin NADP<Superscript>+</Superscript> reductase and ferredoxin–hydrogenase complexes

A competitive Brownian model for the interaction of ferredoxin, ferredoxin NADP⁺ reductase and hydrogenase has been built. In the model, molecules of three types of proteins are placed into a cubic reaction volume, where they move under Brownian and electrostatic forces created by neighboring molecules and the solution. It has been shown that the rate of ferredoxin binding with ferredoxin NADP⁺ reductase does not change at the pH range from 5.0 to 9.0. Thus, it may be suggested that regulation of ferredoxin NADP⁺ reductase activity is mediated by other processes. On the other hand, the rate of ferredoxin binding with hydrogenase in the model depends greatly on pH: if the pH value increases from 6.0 to 8.0 the rate increases by factor of three. The increase of the pH value in the stroma under illumination results in an increase of the rate of its interaction with ferredoxin, but decreases the level of protons that are the substrate for the reaction catalyzed by the protein. Thus, the rate of hydrogen production in the chloroplast stroma is low at low pH due to the reception of a small number of electrons by hydrogenase. When the pH increases, the number of electrons that are received by the enzyme from ferredoxin also increases; thus, the rate of hydrogen production increases as well.     

Complex formation by ferredoxin-NADP+ reductase with ferredoxin or NADP+

Complex formation by ferredoxin-NADP⁺ reductase (NADPH:ferredoxin oxidoreductase, EC 1.6.99.4) with ferredoxin was measured by the independent methods based on the changes of circular dichroism, fluorescence intensity and the chromatographic behavior on a Sephadex G-75 column of the two proteins after mixing. Complex formation between the flavoprotein and NADP⁺ was also detected from the changes of various optical properties of the protein. These experiments suggested that the optical changes accompanying the complex formation were due to a change of the chromophore group in ferredoxin-NADP⁺ reductase, but not due to that of ferredoxin.     

Tethering of ferredoxin:NADP+ oxidoreductase to thylakoid membranes is mediated by novel chloroplast protein TROL

Working in tandem, two photosystems in the chloroplast thylakoid membranes produce a linear electron flow from H₂O to NADP⁺. Final electron transfer from ferredoxin to NADP⁺ is accomplished by a flavoenzyme ferredoxin:NADP⁺ oxidoreductase (FNR). Here we describe TROL (t hylakoid r ho danese‐l ike protein), a nuclear‐encoded component of thylakoid membranes that is required for tethering of FNR and sustaining efficient linear electron flow (LEF) in vascular plants. TROL consists of two distinct modules; a centrally positioned rhodanese‐like domain and a C‐terminal hydrophobic FNR binding region. Analysis of Arabidopsis mutant lines indicates that, in the absence of TROL, relative electron transport rates at high‐light intensities are severely lowered accompanied with significant increase in non‐photochemical quenching (NPQ). Thus, TROL might represent a missing thylakoid membrane docking site for a complex between FNR, ferredoxin and NADP⁺. Such association might be necessary for maintaining photosynthetic redox poise and enhancement of the NPQ.     

Modification of ferredoxin-NADP+ reductase from the alga Bumilleriopsis with butanedione and dansyl chloride

Modification of ferredoxin-NADP⁺ reductase from the alga Bumilleriopsis with butanedione (diacetyl) and dansyl chloride results in loss of enzymatic activity. Under pseudo-first order conditions the rate of inactivation by butanedione is directly proportional to the concentration of the modifying reagent with a slope of unity. The protective effect of pyridine nucleotides, as well as their analogs against inactivation by butanedione indicates involvement of arginine in the binding of pyridine nucleotides at the active site. Inactivation by dansyl chloride suggests that a further amino acid is involved, possibly lysine. Amino acid analyses of the butanedione-treated reductase show that the degree of inactivation correlates well with the decrease in arginine. Furthermore, two arginine residues are modified concomitant with complete inactivation of the enzyme, although this does not imply that both residues participate necessarily in the binding of pyridine nucleotides. Fingerprint analysis of the carboxymethylated, trypsin-digested enzyme indicates loss of one arginine-containing peptide when the protein had been modified by butanedione. There was no change in cysteine-containing peptides.     

Ferredoxin:NADP+ Oxidoreductase Association with Phycocyanin Modulates Its Properties

In photosynthetic organisms, ferredoxin:NADP⁺ oxidoreductase (FNR) is known to provide NADPH for CO₂ assimilation, but it also utilizes NADPH to provide reduced ferredoxin. The cyanobacterium Synechocystis sp. strain PCC6803 produces two FNR isoforms, a small one (FNR_S) similar to the one found in plant plastids and a large one (FNR_L) that is associated with the phycobilisome, a light-harvesting complex. Here we show that a mutant lacking FNR_L exhibits a higher NADP⁺/NADPH ratio. We also purified to homogeneity a phycobilisome subcomplex comprising FNR_L, named FNR_L-PC. The enzymatic activities of FNR_L-PC were compared with those of FNR_S. During NADPH oxidation, FNR_L-PC exhibits a 30% decrease in the Michaelis constant K_m(NADPH), and a 70% increase in K_{m(ferredoxin)}, which is in agreement with its predicted lower activity of ferredoxin reduction. During NADP⁺ reduction, the FNR_L-PC shows a 29/43% decrease in the rate of single electron transfer from reduced ferredoxin in the presence/absence of NADP⁺. The increase in K_{m(ferredoxin)} and the rate decrease of single reduction are attributed to steric hindrance by the phycocyanin moiety of FNR_L-PC. Both isoforms are capable of catalyzing the NADP⁺ reduction under multiple turnover conditions. Furthermore, we obtained evidence that, under high ionic strength conditions, electron transfer from reduced ferredoxin is rate limiting during this process. The differences that we observe might not fully explain the in vivo properties of the Synechocystis mutants expressing only one of the isoforms. Therefore, we advocate that FNR localization and/or substrates availability are essential in vivo.     

The transient catalytically competent coenzyme allocation into the active site of Anabaena ferredoxin NADP+-reductase

Ferredoxin-NADP⁺ reductase (FNR) catalyses the electron transfer from ferredoxin to NADP⁺ via its flavin FAD cofactor. A molecular dynamics theoretical approach is applied here to visualise the transient catalytically competent interaction of Anabaena FNR with its coenzyme, NADP⁺. The particular role of some of the residues identified as key in binding and accommodating the 2′P-AMP moiety of the coenzyme is confirmed in molecular terms. Simulations also indicate that the architecture of the active site precisely contributes to the orientation of the N5 of the FAD isoalloxazine ring and the C4 of the coenzyme nicotinamide ring in the conformation of the catalytically competent hydride transfer complex and, therefore, contributes to the efficiency of the process. In particular, the side chain of the C-terminal Y303 in Anabaena FNR appears key to providing the optimum geometry by reducing the stacking probability between the isoalloxazine and nicotinamide rings, thus providing the required co-linearity and distance among the N5 of the flavin cofactor, the C4 of the coenzyme nicotinamide and the hydride that has to be transferred between them. All these factors are highly related to the reaction efficiency, mechanism and reversibility of the process.     

Electrochemical titrations of a ferredoxin-ferredoxin:NADP+ oxidoreductase complex

Potentiometric titrations employing an electrochemical thin-layer cell indicate that complex formation between ferredoxin and ferredoxin:NADP⁺ oxidoreductase alters the midpoint oxidation-reduction potentials of both proteins. The midpoint potential of ferredoxin in the complex becomes 22 ± 6 mV more negative compared to ferredoxin alone while the midpoint potential of ferredoxin:NADP⁺ oxidoreductase becomes 23 ± 4 mV more positive on complex formation.     

Einfluß von Ferredoxin auf Ferredoxin-NADP-Reduktase

Summary Transhydrogenase and diaphorase activity of ferredoxin-NADP reductase are enhanced by plant ferredoxins. This stimulation is specific; ferredoxin cannot be replaced by sulfhydryl compounds such as cysteine or dithiothreitol, the apoprotein of ferredoxin or Fe²⁺, Fe³⁺ ions.The effect is particularly obvious with the reductase from the heterokont algaBumilleriopsis filiformis Vischer.Reductase and ferredoxin form a complex in the molar ratio of 1:1, which is sensitive to high ionic strength. Under these conditions the complex is destroyed thus eliminating the enhancement by ferredoxin of both transhydrogenase and diaphorase activities. It is concluded that the effect is due to complex formation.Higher concentrations of NAD (>3 mM) and of NADPH (>0.01 mM) inhibit transhydrogenase activity without any effect on its enhancement by ferredoxin. A specific binding site on the reductase for ferredoxin is assumed for which NAD is a poor competitor. Only in the absence of ferredoxin does NAD seem to activate the reductase by occupying both the ferredoxin site and that of the pyridine nucleotides. Reaction kinetics (as a function of NAD concentration) therefore switch from a sigmoid shape when no ferredoxin is added to the normal hyperbolic shape in its presence. Kinetic studies further suggest a ping pong type reaction mechanism for the transhydrogenase and diaphorase reaction. A possible change of the underlying mechanism in the presence of ferredoxin is discussed.     

A hydrogen bond network in the active site of Anabaena ferredoxin-NADP+ reductase modulates its catalytic efficiency

Ferredoxin-nicotinamide–adenine dinucleotide phosphate (NADP⁺) reductase (FNR) catalyses the production of reduced nicotinamide–adenine dinucleotide phosphate (NADPH) in photosynthetic organisms, where its flavin adenine dinucleotide (FAD) cofactor takes two electrons from two reduced ferredoxin (Fd) molecules in two sequential steps, and transfers them to NADP⁺ in a single hydride transfer (HT) step. Despite the good knowledge of this catalytic machinery, additional roles can still be envisaged for already reported key residues, and new features are added to residues not previously identified as having a particular role in the mechanism. Here, we analyse for the first time the role of Ser59 in Anabaena FNR, a residue suggested by recent theoretical simulations as putatively involved in competent binding of the coenzyme in the active site by cooperating with Ser80. We show that Ser59 indirectly modulates the geometry of the active site, the interaction with substrates and the electronic properties of the isoalloxazine ring, and in consequence the electron transfer (ET) and HT processes. Additionally, we revise the role of Tyr79 and Ser80, previously investigated in homologous enzymes from plants. Our results probe that the active site of FNR is tuned by a H-bond network that involves the side-chains of these residues and that results to critical optimal substrate binding, exchange of electrons and, particularly, competent disposition of the C4n (hydride acceptor/donor) of the nicotinamide moiety of the coenzyme during the reversible HT event.     

Kinetic and functional characterization of a membrane-bound NAD(P)H dehydrogenase located in the chloroplasts of Pleurochloris meiringensis (Xanthophyceae)

Using isolated chloroplasts or purified thylakoids from photoautotrophically grown cells of the chromophytic alga Pleurochloris meiringensis (Xanthophyceae) we were able to demonstrate a membrane bound NAD(P)H dehydrogenase activity. NAD(P)H oxidation was detectable with menadione, coenzyme Q₀, decylplastoquinone and decylubiquinone as acceptors in an in vitro assay. K _m-values for both pyridine nucleotides were in the molar range (K _m[NADH]=9.8 M, K _m[NADPH]=3.2 M calculated according to Lineweaver-Burk). NADH oxidation was optimal at pH 9 while pH dependence of NADPH oxidation showed a main peak at 9.8 and a smaller optimum at pH 7.5–8. NADH oxidation could be completely inhibited with rotenone, an inhibitor of mitochondrial complex I dehydrogenase, while NADPH oxidation revealed the typical inhibition pattern upon addition of oxidized pyridine nucleotides reported for ferredoxin: NADP⁺ reductase. Partly-denaturing gel electrophoresis followed by NAD(P)H dehydrogenase activity staining showed that NADPH and NADH oxidizing proteins had different electrophoretic mobilities. As revealed by denaturing electrophoresis, the NADH oxidizing enzyme had one main subunit of 22 kDa and two further polypeptides of 29 and 44 kDa, whereas separation of the NADPH depending protein yielded five bands of different molecular weight. Measurement of oxygen consumption due to PS I mediated methylviologen reduction upon complete inhibition of PS II showed that the NAD(P)H dehydrogenase is able to catalyze an input of electrons from NADH to the photosynthetic electron transport chain in case of an oxidized plastoquinone-pool. We suggest ferredoxin: NADP⁺ reductase to be the main NADPH oxidizing activity while a thylakoidal NAD(P)H: plastoquinone oxidoreductase involved in the chlororespiratory pathway in the dark acts mainly as an NADH oxidizing enzyme.Abbreviations Coenzyme Q₀-2,3-dimethoxy-5-methyl-1,4-benzoquinone - FNR ferredoxin: NADP⁺ reductase - MD menadione - MV methylviologen - NDH NAD(P)H dehydrogenase - PQ plastoquinone - PQ₁₀ decylplastoquinone - SDH succinate dehydrogenase - UQ₁₀ decylubiquinone (2,3-dimethoxy-5-methyl-6-decyl-1,4-benzoquinone)     

Chemical cross-linking of ferredoxin to spinach thylakoids: Evidence for two independent binding sites of ferredoxin to the membrane

Ferredoxin has been chemically cross-linked to thylakoids by using N-ethyl-3-(3-dimethylaminopropyl)-carbodiimide. The membranes thus treated became able to photoreduce cytochrome c and to catalyze the NADPH-cytochrome c reductase reaction without adding exogenous ferredoxin. Preincubation of thylakoids with an antibody against ferredoxin-NADP⁺ reductase before carbodiimide treatment or removal of the reductase by mild trypsin treatment after the cross-linking reaction did not alter the cytochrome c photoreduction activity of the treated membranes. Two independent binding sites of ferredoxin to thylakoids are thus inferred: one site is shown to be the membrane-bound reductase, the second is suggested to be at the level of the photosystem I complex.     

Resolution and reconstitution of Rhodospirillum rubrum pyridine dinucleotide transhydrogenase: localization of substrate binding sites.

Butanedione in the presence of borate buffer reversibly inhibits Rhodospirillum rubrum chromatophore transhydrogenase complex and the separated membrane-bound and soluble factor components of the complex. NADP⁺ completely protected against inactivation of the membrane-bound component, whereas NAD⁺ was without effect. Soluble factor was maximally protected only partially by either NAD⁺ or NADP⁺, but a mixture of the substrates afforded complete protection. NADP⁺-dependent association of soluble factor with factor-depleted membranes was markedly decreased after incubation of membranes with butanedione in the absence, but not in the presence, of NADP⁺. Soluble factor was bound to agarose-NAD and was eluted by NAD⁺, but not by NADP⁺. These results demonstrate the presence of at least three nicotinamide adenine dinucleotide binding sites on R. rubrum transhydrogenase complex, including separate NADP and NAD binding sites on soluble factor and a NADP binding site on the membrane-bound component.     

Ferredoxin:NADP+ oxidoreductase as a target of Cd2+ inhibitory action--biochemical studies

The ferredoxin:NADP+ oxidoreductase (FNR) catalyses the ferredoxin-dependent reduction of NADP+ to NADPH in linear photosynthetic electron transport. The enzyme also transfers electrons from reduced ferredoxin (Fd) or NADPH to the cytochrome b₆f complex in cyclic electron transport. In vitro, the enzyme catalyses the NADPH-dependent reduction of various substrates, including ferredoxin, the analogue of its redox centre - ferricyanide, and the analogue of quinones, which is dibromothymoquinone. This paper presents results on the cadmium-induced inhibition of FNR. The K_i value calculated for research condition was 1.72 mM.FNR molecule can bind a large number of cadmium ions, as shown by the application of cadmium-selective electrode, but just one ion remains bound after dialysis. The effect of cadmium binding is significant disturbance in the electron transfer process from flavin adenine dinucleotide (FAD) to dibromothymoqinone, but less interference with the reduction of ferricyanide. However, it caused a strong inhibition of Fd reduction, indicating that Cd-induced changes in the FNR structure disrupt Fd binding. Additionally, the protonation of the thiol groups is shown to be of great importance in the inhibition process. A mechanism for cadmium-caused inhibition is proposed and discussed with respect to the in vitro and in vivo situation.     

Detailed characterization of Synechocystis PCC 6803 ferredoxin:NADP+ oxidoreductase interaction with model membranes

Direct interaction of ferredoxin:NADP⁺ oxidoreductase (FNR) with thylakoid membranes was postulated as a part of the cyclic electron flow mechanism. In vitro binding of FNR to digalactosyldiacylglycerol and monogalactosyldiacylglycerol membranes was also shown. In this paper we deal with the latter interaction in more detail describing the effect for two FNR forms of Synechocystis PCC 6803. The so-called short FNR (sFNR) is homologous to FNR from higher plant chloroplasts. The long FNR (lFNR) form contains an additional domain, responsible for the interaction with phycobilisomes. We compare the binding of both sFNR and lFNR forms to native and non-native lipids. We also include factors which could modulate this process: pH change, temperature change, presence of ferredoxin, NADP⁺ and NADPH and heavy metals. For the lFNR, we also include phycobilisomes as a modulating factor. The membrane binding is generally faster at lower pH. The sFNR was binding faster than lFNR. Ferredoxin isoforms with higher midpoint potential, as well as NADPH and NADP⁺, weakened the binding. Charged lipids and high phosphate promoted the binding. Heavy metal ions decreased the rate of membrane binding only when FNR was preincubated with them before injection beneath the monolayer. FNR binding was limited to surface lipid groups and did not influence hydrophobic chain packing. Taken together, FNR interaction with lipids appears to be non-specific, with an electrostatic component. This suggests that the direct FNR interaction with lipids is most likely not a factor in directing electron transfer, but should be taken into account during in vitro studies.     

Pyridine nucleotide transhydrogenases of parasitic helminths.

Mitochondria from the parasitic helminth, Hymenolepis diminuta, catalyzed both NADPH:NAD⁺ and NADH:NADP⁺ transhydrogenase reactions which were demonstrable employing the appropriate acetylpyridine nucleotide derivative as the hydride ion acceptor. Thionicotinamide NAD⁺ would not serve as the oxidant in the former reaction. Under the assay conditions employed, neither reaction was energy linked, and the NADPH:NAD⁺ system was approximately five times more active than the NADH:NADP⁺ system. The NADH:NADP⁺ reaction was inhibited by phosphate and imidazole buffers, EDTA, and adenyl nucleotides, while the NADPH:NAD⁺ reaction was inhibited only slightly by imidazole and unaffected by EDTA and adenyl nucleotides. Enzyme coupling techniques revealed that both transhydrogenase systems functioned when the appropriate physiological pyridine nucleotide was the hydride ion acceptor. An NADH:NAD⁺ transhydrogenase system, which was unaffected by EDTA, or adenyl nucleotides, also was demonstrable in the mitochondria of H. diminuta. Saturation kinetics indicated that the NADH:NAD⁺ reaction was the product of an independent enzyme system. Mitochondria derived from another parasitic helminth, Ascaris lumbricoides, catalyzed only a single transhydrogenase reaction, i.e., the NADH:NAD⁺ activity. Transhydrogenase systems from both parasites were essentially membrane bound and localized on the inner mitochondrial membrane. Physiologically, the NADPH:NAD⁺ transhydrogenase of H. diminuta may serve to couple the intramitochondrial metabolism of malate (via an NADP linked “malic” enzyme) to the anaerobic NADH-dependent ATP-generating fumarate reductase system. In A. lumbricoides, where the intramitochondrial metabolism of malate depends on an NAD-linked “malic” enzyme which is localized primarily in the intermembrane space, the NADH:NAD⁺ transhydrogenase activity may serve physiologically in the translocation of hydride ions across the inner membrane to the anaerobic energy-generating fumarate reductase system.     

Towards the competent conformation for catalysis in the ferredoxin-NADP+ reductase from the Brucella ovis pathogen

Brucella ovis encodes a bacterial subclass 1 ferredoxin-NADP(H) reductase (BoFPR) that, by similarity with other FPRs, is expected either to deliver electrons from NADPH to the redox-based metabolism and/or to oxidize NADPH to regulate the soxRS regulon that protects bacteria against oxidative damage. Such potential roles for the pathogen survival under infection conditions make of interest to understand and to act on the BoFPR mechanism. Here, we investigate the NADP⁺/H interaction and NADPH oxidation by hydride transfer (HT) to BoFPR. Crystal structures of BoFPR in free and in complex with NADP⁺ hardly differ. The latter shows binding of the NADP⁺ adenosine moiety, while its redox-reactive nicotinamide protrudes towards the solvent. Nonetheless, pre-steady-state kinetics show formation of a charge-transfer complex (CTC-1) prior to the hydride transfer, as well as conversion of CTC-1 into a second charge-transfer complex (CTC-2) concomitantly with the HT event. Thus, during catalysis nicotinamide and flavin reacting rings stack. Kinetic data also identify the HT itself as the rate limiting step in the reduction of BoFPR by NADPH, as well as product release limiting the overall reaction. Using all-atom molecular dynamics simulations with a thermal effect approach we are able to visualise a potential transient catalytically competent interaction of the reacting rings. Simulations indicate that the architecture of the FAD folded conformation in BoFPR might be key in catalysis, pointing to its adenine as an element to orient the reactive atoms in conformations competent for HT.