Carlos Gómez-Moreno

Ferredoxin-NADP(+) reductase uses the same site for the interaction with ferredoxin and flavodoxin.

Abstract The enzyme ferredoxin-NADP+ reductase (FNR) forms a 1 : 1 complex with ferredoxin (Fd) or flavodoxin (Fld) that is stabilised by both electrostatic and hydrophobic interactions. The electrostatic interactions occur between acidic residues of the electron transfer (ET) protein and basic residues on the FNR surface. In the present study, several charge-reversal mutants of FNR have been prepared at the proposed site of interaction of the ET protein: R16E, K72E, K75E, K138E, R264E, K290E and K294E. All of these mutants have been assayed for reactivity with Fd and Fld using steady-state and stopped-flow kinetics. Their abilities for complex formation with the ET proteins have also been tested. The data presented here indicate that the mutated residues situated within the FNR FAD-binding domain are more important for achieving maximal ET rates, either with Fd or Fld, than those situated within the NADP+-binding domain, and that both ET proteins occupy the same region for the interaction with the reductase. In addition, each individual residue does not appear to participate to the same extent in the different processes with Fd and Fld.

A redox-dependent interaction between two electron-transfer partners involved in photosynthesis

Ferredoxin:NADP+:reductase (FNR) catalyzes one terminal step of the conversion of light energy into chemical energy during photosynthesis. FNR uses two high energy electrons photoproduced by photosystem I (PSI) and conveyed, one by one, by a ferredoxin (Fd), to reduce NADP+ to NADPH. The reducing power of NADPH is finally involved in carbon assimilation. The interaction between oxidized FNR and Fd was studied by crystallography at 2.4 Å resolution leading to a three‐dimensional picture of an Fd–FNR biologically relevant complex. This complex suggests that FNR and Fd specifically interact prior to each electron transfer and disassemble upon a redox‐linked conformational change of the Fd.

Interaction of Ferredoxin–NADP+ Reductase with its Substrates: Optimal Interaction for Efficient Electron Transfer

Electron transfer (ET) reactions in systems involving proteins require an oriented interaction between electron donor and acceptor in order to accommodate their respective redox centres in optimal orientation for efficient ET. Such type of reactions are critical for the maintenance of the physiological functions of living organisms, since they are implicated in vital actions, as is, for example, in the photosynthetic ET chain that leads to NADPH reduction. In this particular case, a small redox protein ET chain is responsible for ET from Photosystem I (PS I) to NADP+. In this system the enzyme responsible for NADP+ reduction is ferredoxin–NADP+ reductase (FNR), a FAD-containing NADP+ dependent reductase. In order to produce such reduction, this enzyme receives electrons from a [2Fe–2S] plant-type ferredoxin (Fd), which is previously reduced by PS I. Moreover, in the case of some algae and cyanobacteria, an FMN-dependent protein, flavodoxin (Fld), has been shown to replace Fd in this function. The processes of interaction and ET between FNR and all of its substrates involved in the photosynthetic ET chain, namely Fd, Fld and NADP+/H have been extensively investigated in recent years using a large number of techniques, including the introduction of site-specific mutations in combination with kinetic and structural studies of the produced mutants. The present manuscript summarises the information so far reported for an efficient interaction between FNR and its substrates, compares such information with that revealed by other systems for which the FNR structure is a prototype and, finally, discusses the implications of the processes of association in ET between FNR and its substrates.

Consequences of the iron-dependent formation of ferredoxin and flavodoxin on photosynthesis and nitrogen fixation on Anabaena strains

Iron-dependent formation of ferredoxin and flavodoxin was determined in Anabaena ATCC 29413 and ATCC 29211 by a FPLC procedure. In the first species ferredoxin is replaced by flavodoxin at low iron levels in the vegetative cells only. In the heterocysts from Anabaena ATCC 29151, however, flavodoxin is constitutively formed regardless of the iron supply.Replacement of ferredoxin by flavodoxin had no effect on photosynthetic electron transport, whereas nitrogen fixation was decreased under low iron conditions. As ferredoxin and flavodoxin exhibited the same Km values as electron donors to nitrogenase, an iron-limited synthesis of active nitrogenase was assumed as the reason for inhibited nitrogen fixation. Anabaena ATCC 29211 generally lacks the potential to synthesize flavodoxin. Under iron-starvation conditions, ferredoxin synthesis is limited, with a negative effect on photosynthetic oxygen evolution.

Purification and properties of ferredoxin-NADP+ oxidoreductase from the nitrogen-fixing cyanobacteria Anabaena variabilis

The isolation and characterization of ferredoxin-NADP+ -oxidoreductase from Anabaena variabilis, a nitrogen-fixing, filamentous cyanobacterium, is described. Purified enzyme was obtained in four steps with a 55% yield and 300-fold purification utilizing chromatographic separations on DEAE-cellulose and Cibacron Blue-Sepharose columns. The enzyme is quite similar but not identical to the spinach enzyme as judged by isoelectric focusing, molecular weight determination, and amino acid composition. N-terminal sequence analysis allowed identification of 28 of the first 33 residues. Alignment with the corresponding sequences from spinach and Spirulina FNR preparations was possible. A higher degree of homology was found with the Spirulina enzyme than with the spinach enzyme. Small differences with the spinach enzyme were also shown by absorption and circular dichroism spectral measurements. Oxidation-reduction potential measurements of the bound FAD coenzyme show an Em = -320 mV at pH 7 for the two-electron process. Complex formation between the reductase and ferredoxin from the same organism was observed by difference absorption spectroscopy with a Kd = 4 microM. Similar Kd and difference absorption properties were observed on complex formation with spinach ferredoxin.

Flavodoxin from the nitrogen-fixing cyanobacterium Anabaena PCC 7119

Flavodoxin has been isolated and purified from cultures of the cyanobacterium Anabaena cultivated in a low-iron medium. This flavoprotein has a molecular weight of 20,000 and contains 1 molecule of flavin mononucleotide per mol of protein. Various biochemical characteristics are reported including amino-acid composition, isoelectric point and the fluorescence properties of the apoprotein. The extinction coefficients and isosbestic points were determined for the oxidized and semiquinone forms of flavodoxin. The electron paramagnetic resonance spectrum of the semiquinone exhibited a spectral linewidth of 23 G, which is typical for a neutral flavoprotein semiquinone. Kinetic measurements give a rate constant of 9.6×107 (M-1 min-1) for the reduction of flavodoxin in the photosynthetic electron-transport chain by the photosystem I and 6.6×106 for the reaction in which flavodoxin is reduced by ferredoxin-NADP+ oxidoreductase. The Michaelis constant for electron donation to nitrogenase by reduced flavodoxin is 8.5 μM.

Probing the Determinants of Coenzyme Specificity in Ferredoxin-NADP+ Reductase by Site-directed Mutagenesis

On the basis of sequence and three-dimensional structure comparison between Anabaena PCC7119 ferredoxin-NADP+ reductase (FNR) and other reductases from its structurally related family that bind either NADP+/H or NAD+/H, a set of amino acid residues that might determine the FNR coenzyme specificity can be assigned. These residues include Thr-155, Ser-223, Arg-224, Arg-233 and Tyr-235. Systematic replacement of these amino acids was done to identify which of them are the main determinants of coenzyme specificity. Our data indicate that all of the residues interacting with the 2′-phosphate of NADP+/H in Anabaena FNR are not involved to the same extent in determining coenzyme specificity and affinity. Thus, it is found that Ser-223 and Tyr-235 are important for determining NADP+/H specificity and orientation with respect to the protein, whereas Arg-224 and Arg-233 provide only secondary interactions in Anabaena FNR. The analysis of the T155G FNR form also indicates that the determinants of coenzyme specificity are not only situated in the 2′-phosphate NADP+/H interacting region but that other regions of the protein must be involved. These regions, although not interacting directly with the coenzyme, must produce specific structural arrangements of the backbone chain that determine coenzyme specificity. The loop formed by residues 261–268 inAnabaena FNR must be one of these regions.

Nitrate reductase from Spinacea oleracea: Reversible inactivation by NAD(P)H and by thiols☆

Abstract The enzymatic complex nitrate reductase from Spinacea oleracea is inactivated by NADH or NADPH and by simple thiols. The inactivation affects FNH2-nitrate reductase but not NADH-diaphorase. Reactivation can be achieved by addition of ferricyanide. The extent of inactivation by dithioerythritol is increased by NAD+, but not by NADP+. Nitrate protects against inactivation by NADH or NADPH, and abolishes the effect of NAD+ on the inactivation by dithioerythritol. The NAD(P)H-inactivation of nitrate reductase requires that the diaphorase moiety of the complex be functional. However, there is no proportionality between NADH-diaphorase or NADH-nitrate reductase activities and the susceptibility of the enzymatic preparation to NADH or NADPH. It seems likely that the nitrate reductase complex contains a specific regulatory site, different from the catalytic site, the reduction of which is accompanied by the production of an inactive form of the complex.

Selective oxidation: stabilisation by multipoint attachment of ferredoxin NADP+ reductase, an interesting cofactor recycling enzyme

Ferredoxin-NADP+ reductase (FNR, EC 1.18.1.2) is an enzyme that is able to catalyse the oxidation of NADPH + H+. A strategy to prepare industrial derivatives of this enzyme for use as an ‘NADP’ regenerating enzyme in oxidizing reactions is presented. The strategy is based on a strictly controlled process of multipoint covalent attachment between the enzyme, via its amino groups, and a pre-existing solid activated with a monolayer of simple aldehyde groups linked by a space-arm of moderate length to the surface of the support. Controlling the variables which may have an influence in the multi-interaction process, we have prepared a number of enzyme derivatives with very different activity/stability properties. The ‘optimum derivative’ was found to be much more stable than its corresponding soluble enzyme under all the denaturation conditions assayed (high temperatures, extreme pH, organic solvents, etc.). Because of the excellent properties of this enzyme derivative, we can regenerate NADP+ by using molecular oxygen directly as the oxidizing agent under a wide range of conditions. Coupling this oxidative system to other NADP-dependent redox enzymes, we should be able to develop a very specific and selective oxidative procedure under very mild oxidizing conditions.

Purification of ferredoxin-NADP+ reductase, flavodoxin and ferredoxin from a single batch of the cyanobacterium Anabaena PCC 7119

Methods are described for the simultaneous isolation of ferredoxin-NADP+ reductase, ferredoxin and flavodoxin from large quantities of the cyanobacterium Anabaena PCC 7119 allowing the use of a single batch of cells. The ultraviolet-visible spectra and the extinction coefficients of ferredoxin-NADP+ reductase and ferredoxin were determined. The purification procedure also yields enriched fractions of phycobiliproteins and cytochrome c553.