Structure of the electron transfer complex between ferredoxin and ferredoxin-NADP(+) reductase

All oxygenic photosynthetically derived reducing equivalents are utilized by combinations of a single multifuctional electron carrier protein, ferredoxin (Fd), and several Fd-dependent oxidoreductases. We report the first crystal structure of the complex between maize leaf Fd and Fd-NADP(+) oxidoreductase (FNR). The redox centers in the complex--the 2Fe-2S cluster of Fd and flavin adenine dinucleotide (FAD) of FNR--are in close proximity; the shortest distance is 6.0 A. The intermolecular interactions in the complex are mainly electrostatic, occurring through salt bridges, and the interface near the prosthetic groups is hydrophobic. NMR experiments on the complex in solution confirmed the FNR recognition sites on Fd that are identified in the crystal structure. Interestingly, the structures of Fd and FNR in the complex and in the free state differ in several ways. For example, in the active site of FNR, Fd binding induces the formation of a new hydrogen bond between side chains of Glu 312 and Ser 96 of FNR. We propose that this type of molecular communication not only determines the optimal orientation of the two proteins for electron transfer, but also contributes to the modulation of the enzymatic properties of FNR.     

Electron transfer of site-specifically cross-linked complexes between ferredoxin and ferredoxin-NADP(+) reductase

Ferredoxin (Fd) and Fd-NADP(+) reductase (FNR) are redox partners responsible for the conversion between NADP(+) and NADPH in the plastids of photosynthetic organisms. Introduction of specific disulfide bonds between Fd and FNR by engineering cysteines into the two proteins resulted in 13 different Fd-FNR cross-linked complexes displaying a broad range of activity to catalyze the NADPH-dependent cytochrome c reduction. This variability in activity was thought to be mainly due to different levels of intramolecular electron transfer activity between the FNR and Fd domains. Stopped-flow analysis revealed such differences in the rate of electron transfer from the FNR to Fd domains in some of the cross-linked complexes. A group of the cross-linked complexes with high cytochrome c reduction activity comparable to dissociable wild-type Fd/FNR was shown to assume a similar Fd-FNR interaction mode as in the native Fd:FNR complex by analyses of NMR chemical shift perturbation and absorption spectroscopy. However, the intermolecular electron transfer of these cross-linked complexes with two Fd-binding proteins, nitrite reductase and photosystem I, was largely inhibited, most probably due to steric hindrance by the FNR moiety linked near the redox center of the Fd domain. In contrast, another group of the cross-linked complexes with low cytochrome c reduction activity tends to mediate higher intermolecular electron transfer activity. Therefore, reciprocal relationship of intramolecular and intermolecular electron transfer abilities was conferred by the linkage of Fd and FNR, which may explain the physiological significance of the separate forms of Fd and FNR in chloroplasts.     

A structural basis of Equisetum arvense ferredoxin isoform II producing an alternative electron transfer with ferredoxin-NADP+ reductase

We have determined the crystal structure, at 1.2-A resolution, of Equisetum arvense ferredoxin isoform II (FdII), which lacks residues equivalent to Arg(39) and Glu(28) highly conserved among other ferredoxins (Fds). In other Fds these residues form an intramolecular salt bridge crucial for stabilization of the [2Fe-2S] cluster, which is disrupted upon complex formation with Fd-NADP(+) oxidoreductase (FNR) to form two intermolecular salt bridges. The overall structure of FdII resembles the known backbone structures of E. arvense isoform I (FdI) and other plant-type Fds. Dramatically, in the FdII structure a unique, alternative salt bridge is formed between Arg(22) and Glu(58). This results in a different relative orientation of the alpha-helix formed by Leu(23)-Glu(29) and eliminates the possibility of forming three of the five intermolecular salt bridges identified on formation of a complex between maize FdI and maize FNR. Mutation of FdII, informed by structural differences with FdI, showed that the alternative salt bridge and the absence of an otherwise conserved Tyr residue are important for the alternative stabilization of the FdII [2Fe-2S] cluster. We also investigated FdI and FdII electron transfer to FNR on chloroplast thylakoid membranes. The K(m) and V(max) values of FdII are similar to those of FdI, contrary to previous measurements of the reverse reaction, from FNR to Fd. The affinity between reduced FdI and oxidized FNR is much greater than that between oxidized FdI and reduced FNR, whereas this is not the case with FdII. The pH dependence of electron transfer by FdI, FdII, and an FdII mutant with FdI features was measured and further indicated that the binding mode to FNR differs between FdI and FdII. Based on this evidence, we hypothesize that binding modes with other Fd-dependent reductases may also vary between FdI and FdII. The structural differences between FdI and FdII therefore result in functional differences that may influence partitioning of electrons into different redox metabolic pathways.     

Interaction of ferredoxin and ferredoxin-NADP reductase with thylakoids

Ferredoxin-NADP reductase accounts for about 50% of the NADPH diaphorase activity of spinach leaf homogenates. The enzyme is bound to thylakoid membranes, but can be slowly extracted by aqueous buffers. Ferredoxin-NADP reductase can be extracted from the membranes by a 1- to 2-min treatment with a low concentration of trypsin. This treatment completely inactivates NADP photoreduction but does not affect electron transport from water to ferredoxin. It is shown that the inactivation is due to solubilization of ferredoxin-NADP reductase: the activity can be restored by addition of a very large excess of soluble enzyme in pure form. When ferredoxin-NADP reductase is added as a soluble enzyme after extraction or inactivation (by a specific antibody) of the membrane-bound enzyme, NADP photoreduction requires a very large excess of this enzyme, and the apparent K_m for ferredoxin is also increased. These observations are discussed as related to the interactions of thylakoids with ferredoxin-NADP reductase.     

Circular dichroism studies of the complex between ferredoxin and ferredoxin-NADP reductase

Circular dichroism (CD) spectra are presented of ferredoxin, ferredoxin-NADP reductase and their complex. A change in CD occurs on complex formation which is consistent with a decrease in the Cotton effects due to the ferredoxin. This change is interpreted as due to a decrease in interaction in ferredoxin between the iron-sulphur chromophore group and the protein.     

Anthracycline antibiotic reduction by spinach ferredoxin-NADP+ reductase and ferredoxin

Spinach NADPH:ferredoxin oxidoreductase (EC 1.6.7.1) catalyzes the NADPH-dependent reduction of the anthracyclines daunomycin, aclacinomycin A, and nogalamycin and their respective 7-deoxyanthracyclinones. Under anaerobic conditions, the endogenous rate of O2 reduction by NADPH catalyzed by ferredoxin reductase (0.12 s-1 at pH 7.4) is augmented by the anthracyclines and 7-deoxyanthracyclinones. The catalytic constants are approximately equivalent for this augmentation for all substrates (approximate V of 2 s-1 and KM of 75 microM). Both O2- and H2O2 are made. Under anaerobic conditions, anthracycline reduction catalyzed by ferredoxin reductase results in the elimination of the C-7 substituent to provide a quinone methide intermediate. Following tautomerization by C-7 protonation, 7-deoxyanthracyclinones are obtained. Under appropriate conditions these may be further reduced to the 7-deoxyanthracyclinone hydroquinones. For daunomycin, the quinone methide is formed rapidly after reduction and is easily monitored at 600 nm. It may react with electrophiles other than H+, as demonstrated by its competitive trapping by p-carboxybenzaldehyde. It may also react with nucleophiles, as demonstrated by its competitive trapping by N-acetylcysteine. For aclacinomycin, quinone methide formation is also rapid although no distinct transient near 600 nm occurs. In addition to protonation, it reacts with itself providing the 7,7'-dimer. With ethyl xanthate as a thiolate nucleophile, adducts derived from addition to C-7 are obtained. For nogalamycin, quinone methide formation is not rapid. Nogalamycin is reduced to its hydroquinone, which slowly converts in a first-order process [k = (1.2 +/- 0.2) X 10(-3) s-1, pH 8.0, 30 degrees C] to the quinone methide, which is then quenched by protonation. Spinach ferredoxin in its reduced form is chemically competent for anthracycline reduction. Its effect on both the aerobic and anaerobic reactions catalyzed by ferredoxin reductase is to increase severalfold the overall velocity for anthracycline reduction. In conclusion, the aerobic reaction pathways for the anthracyclines as mediated by ferredoxin reductase are remarkably similar, while the anaerobic reactions are remarkably different. If these anthracyclines exert their antitumor activity by a common anaerobic pathway, it is most likely that the pathway is determined by the properties of the anthracycline as complexed to its in vivo target. The behavior of ferredoxin further suggests that not only low-potential flavin centers but also iron-sulfur centers should be regarded as important loci for anthracycline reductive activation.     

Novel forms of ferredoxin and ferredoxin-NADP reductase from spinach roots

Ferredoxin and the enzyme catalyzing its reduction by NADPH, ferredoxin-NADP reductase (ferredoxin-NADP+ oxidoreductase or FNR), were found to be present in roots of spinach (Spinacia oleracea). Localization experiments with endosperm of germinating castor beans (Ricinus communis), a classical nonphotosynthetic tissue for cell fractionation studies, confirmed that ferredoxin and FNR are localized in the plastid fraction. Both proteins were purified from spinach roots and found to resemble their leaf counterparts in activity, spectral properties, and complex formation, but to differ in amino acid composition and amino terminal sequence. The results indicate that the primary structures of the FNR and ferredoxin of spinach roots differ from that of the corresponding leaf proteins. Together with earlier findings, the present results provide evidence that nonphotosynthetic plastids, including those of roots, are capable of reducing ferredoxin with heterotrophically generated NADPH.     

Laser flash photolysis studies of electron transfer between ferredoxin-NADP+ reductase and several high-potential redox proteins

Complex formation and the kinetics of electron transfer between ferredoxin-NADP+ reductase (FNR) and two structurally homologous acidic 4Fe-4S high-potential ferredoxins (HiPIP's) from Ectothiorhodospira halophila (HP1 and HP2) and two structurally homologous cytochromes c2 from Paracoccus denitrificans and Rhodospirillum rubrum (PC2, and RC2, respectively) have been investigated by gel filtration and laser flash photolysis techniques. Gel filtration studies indicated that complex formation occurred between FNRox and HP1ox or HP2ox at low ionic strength (10 mM) and that the complexes were completely dissociated at high ionic strength (310 mM). Laser flash photolysis using lumiflavin as the reductant demonstrated that both free HP1ox and HP2ox reacted primarily with the anionic form of fully reduced lumiflavin (LFH-), whereas FNR was unreactive. Second-order rate constants of 1 X 10(6) and 0.8 X 10(6) M-1 s-1 were obtained for these reactions at 10 mM ionic strength. Increasing the ionic strength to 310 mM resulted in an approximately 1.5-fold increase in the rate constant. Inclusion of stoichiometric amounts of FNRox into the reaction mixture at low ionic strength led to a 2.5-fold increase in the rate constants. The reaction of 5-deazariboflavin semiquinone (5-dRf.) with the oxidized HiPIP's was also investigated by laser flash photolysis. Second-order rate constants of 3.0 X 10(8) M-1 s-1 (HP1) and 2.5 X 10(8) M-1 s-1 (HP2) were obtained for the free proteins at 10 mM ionic strength. Under the same conditions, 5-dRf. reacted with free FNRox, resulting in the formation of the neutral protein-bound semiquinone (FNR.), with a second-order rate constant of 6 X 10(8) M-1 s-1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of the electrostatic binding sites on the surface of ferredoxin for two ferredoxin-dependent enzymes, ferredoxin-NADP(+) reductase and sulfite reductase.

Plant-type ferredoxin (Fd), a [2Fe-2S] iron-sulfur protein, functions as an one-electron donor to Fd-NADP(+) reductase (FNR) or sulfite reductase (SiR), interacting electrostatically with them. In order to understand the protein-protein interaction between Fd and these two different enzymes, 10 acidic surface residues in maize Fd (isoform III), Asp-27, Glu-30, Asp-58, Asp-61, Asp-66/Asp-67, Glu-71/Glu-72, Asp-85, and Glu-93, were substituted with the corresponding amide residues by site-directed mutagenesis. The redox potentials of the mutated Fds were not markedly changed, except for E93Q, the redox potential of which was more positive by 67 mV than that of the wild type. Kinetic experiments showed that the mutations at Asp-66/Asp-67 and Glu-93 significantly affected electron transfer to the two enzymes. Interestingly, D66N/D67N was less efficient in the reaction with FNR than E93Q, whereas this relationship was reversed in the reaction with SiR. The static interaction of the mutant Fds with each the two enzymes was analyzed by gel filtration of a mixture of Fd and each enzyme, and by affinity chromatography on Fd-immobilized resins. The contributions of Asp-66/Asp-67 and Glu-93 were found to be most important for the binding to FNR and SiR, respectively, in accordance with the kinetic data. These results allowed us to map the acidic regions of Fd required for electron transfer and for binding to FNR and SiR and demonstrate that the interaction sites for the two enzymes are at least partly distinct.     

Crystal structure of paprika ferredoxin-NADP+ reductase. Implications for the electron transfer pathway

cDNA of Capsicum annuum Yolo Wonder (paprika) has been prepared from total cellular RNA, and the complete gene encoding paprika ferredoxin-NADP(+) reductase (pFNR) precursor was sequenced and cloned from this cDNA. Fusion to a T7 promoter allowed expression in Escherichia coli. Both native and recombinant pFNR were purified to homogeneity and crystallized. The crystal structure of pFNR has been solved by Patterson search techniques using the structure of spinach ferredoxin-NADP(+) reductase as search model. The structure was refined at 2.5-A resolution to a crystallographic R-factor of 19.8% (R(free) = 26.5%). The overall structure of pFNR is similar to other members of the ferredoxin-NADP(+) reductase family, the major differences concern a long loop (residues 167-177) that forms part of the FAD binding site and some of the variable loops in surface regions. The different orientation of the FAD binding loop leads to a tighter interaction between pFNR and the adenine moiety of FAD. The physiological redox partners [2Fe-2S]-ferredoxin I and NADP(+) were modeled into the native structure of pFNR. The complexes reveal a protein-protein interaction site that is consistent with existing biochemical data and imply possible orientations for the side chain of tyrosine 362, which has to be displaced by the nicotinamide moiety of NADP(+) upon binding. A reasonable electron transfer pathway could be deduced from the modeled structures of the complexes.     

Complex formation between ferredoxin and ferredoxin-NADP+ reductase from Anabaena PCC 7119: cross-linking studies.

Ferredoxin-NADP+ reductase and ferredoxin from the cyanobacterium Anabaena PCC 7119 have been covalently cross-linked by incubation with 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide. The covalent adduct, which shows a molecular mass consistent with a 1:1 stoichiometry of the two proteins, maintains nearly 60% of the NADPH-cytochrome c reductase activity of the enzyme saturated with ferredoxin and this value is considerably higher than when equimolar amounts of both proteins are assayed. No ternary complexes with Anabaena flavodoxin or horse heart cytochrome c were formed, suggesting that the binding site on the enzyme is the same for ferredoxin and flavodoxin and that ferredoxin-NADP+ reductase and cytochrome c bind at a common site on ferredoxin. In the noncovalent complex, titrated at pH 7, the oxidation-reduction potential of ferredoxin becomes 15 mV more negative and that of ferredoxin-NADP+ reductase 27 mV more positive compared to the proteins alone. When covalently linked, the midpoint potential of the enzyme has a value similar to that in the noncovalent complex, while the ferredoxin potential is 20 mV more positive compared to ferredoxin alone. The changes in redox potentials have been used to estimate the dissociation constants for the interaction of the different redox forms of the proteins, based on the value of 1.21 microM calculated for the oxidized noncovalent complex.     

Molecular interaction of ferredoxin and ferredoxin-NADP+ reductase from human malaria parasite

The malaria parasite possesses plant-type ferredoxin (Fd) and ferredoxin-NADP(+) reductase (FNR) in a plastid-derived organelle called the apicoplast. This Fd/FNR redox system, which potentially provides reducing power for essential biosynthetic pathways in the apicoplast, has been proposed as a target for the development of specific new anti-malarial agents. We studied the molecular interaction of Fd and FNR of human malaria parasite (Plasmodium falciparum), which were produced as recombinant proteins in Escherichia coli. NMR chemical shift perturbation analysis mapped the location of the possible FNR interaction sites on the surface of P. falciparum Fd. Site-specific mutation of acidic Fd residues in these regions and the resulting analyses of electron transfer activity and affinity chromatography of those mutants revealed that two acidic regions (a region including Asp26, Glu29 and Glu34, and the other including Asp65 and Glu66) dominantly contribute to the electrostatic interaction with P. falciparum FNR. The combination of Asp26/Glu29/Glu34 conferred a larger contribution than that of Asp65/Glu66, and among Asp26, Glu29 and Glu34, Glu29 was shown to be the most important residue for the interaction with P. falciparum FNR. These findings provide the basis for understanding molecular recognition between Fd and FNR of the malaria parasite.     

Structure-function relationships in Anabaena ferredoxin/ferredoxin:NADP(+) reductase electron transfer: insights from site-directed mutagenesis,transient absorption spectroscopy and X-ray crystallography

The interaction between reduced Anabaena ferredoxin and oxidized ferredoxin:NADP(+) reductase (FNR), which occurs during photosynthetic electron transfer (ET), has been investigated extensively in the authors' laboratories using transient and steady-state kinetic measurements and X-ray crystallography. The effect of a large number of site-specific mutations in both proteins has been assessed. Many of the mutations had little or no effect on ET kinetics. However, non-conservative mutations at three highly conserved surface sites in ferredoxin (F65, E94 and S47) caused ET rate constants to decrease by four orders of magnitude, and non-conservative mutations at three highly conserved surface sites in FNR (L76, K75 and E301) caused ET rate constants to decrease by factors of 25-150. These residues were deemed to be critical for ET. Similar mutations at several other conserved sites in the two proteins (D67 in Fd; E139, L78, K72, and R16 in FNR) caused smaller but still appreciable effects on ET rate constants. A strong correlation exists between these results and the X-ray crystal structure of an Anabaena ferredoxin/FNR complex. Thus, mutations at sites that are within the protein-protein interface or are directly involved in interprotein contacts generally show the largest kinetic effects. The implications of these results for the ET mechanism are discussed.     

Chemical modification of the active site of ferredoxin-NADP reductase and conformation of the binary ferredoxin/ferredoxin-NADP reductase complex in solution

Ferredoxin-NADP⁺ reductase (EC 1.18.1.2) was chemically modified by the triplet probe eosin isothiocyanate (eosin-NES). Incorporation of 1 mol eosin-NCS/mol ferredoxin-NADP⁺ reductase completely inhibited binding of NADP⁺/NADPH to the enzyme. Binding of eosin without the reactive group to the enzyme was shown to be reversible but to compete with NADP⁺/NADPH with a K_i of approx. 5 μM. The binding site of eosin-NCS has been located in the primary sequence ferredoxin-NADP⁺ reductase. After specific cleavage of arginine with trypsin a single labelled peptide was obtained and identified as the fragment from residue 179–228 in the primary sequence. Binding of eosin-NCS occurred in either of two predicted helices (residues 179–189 or 212–228) which are both part of an /β structure characteristic for nucleotide binding folds. The rotational diffusion in solution of the eosin-labelled ferredoxin-NADP⁺ reductase and its complex with ferredoxin was measured with laser flash spectroscopy under photoselection. From the measured rotational correlation times and the known structure of ferredoxin-NADP⁺ reductase at 3.7 Å resolution, we propose that ferredoxin is bound to ferredoxin-NADP⁺ reductase between the two domains of the flavoprotein. The two ferredoxin-NADP⁺ reductase domains and ferredoxin form a triangle which results in a highly integrated binary complex.     

Role of a cluster of hydrophobic residues near the FAD cofactor in Anabaena PCC 7119 ferredoxin-NADP+ reductase for optimal complex formation and electron transfer to ferredoxin

In the ferredoxin-NADP(+) reductase (FNR)/ferredoxin (Fd) system, an aromatic amino acid residue on the surface of Anabaena Fd, Phe-65, has been shown to be essential for the electron transfer (ET) reaction. We have investigated further the role of hydrophobic interactions in complex stabilization and ET between these proteins by replacing three hydrophobic residues, Leu-76, Leu-78, and Val-136, situated on the FNR surface in the vicinity of its FAD cofactor. Whereas neither the ability of FNR to accept electrons from NADPH nor its structure appears to be affected by the introduced mutations, different behaviors with Fd are observed. Thus, the ET interaction with Fd is almost completely lost upon introduction of negatively charged side chains. In contrast, only subtle changes are observed upon conservative replacement. Introduction of Ser residues produces relatively sizable alterations of the FAD redox potential, which can explain the modified behavior of these mutants. The introduction of bulky aromatic side chains appears to produce rearrangements of the side chains at the FNR/Fd interaction surface. Thus, subtle changes in the hydrophobic patch influence the rates of ET to and from Fd by altering the binding constants and the FAD redox potentials, indicating that these residues are especially important in the binding and orientation of Fd for efficient ET. These results are consistent with the structure reported for the Anabaena FNR.Fd complex.     

Complex-forming properties of butanedione-modified ferredoxin-NADP+ reductase with NADP+ and ferredoxin.

The plastidic ferredoxin-NADP⁺ reductase from the xanthophycean alga Bumilleriopsis forms a stoichiometric 1:1 complex with ferredoxin and NADP⁺ which is demonstrated by difference spectra of both complexes. Butanedione modification of the flavoprotein results in loss of its enzymatic activities (transhydrogenase and diaphorase) concurrently with its capability to form a complex with NADP⁺, whereas the ferredoxin-binding site is practically not influenced by the modifying reagent and complex formation is still possible. It is assumed, therefore, that butanedione specifically reacts with the arginine residue of the protein involved in binding of pyridine nucleotides at the active site. Further, the data presented strongly support the previous proposal of different binding sites for ferredoxin and pyridine nucleotides at the reductase.