Effects of chemical modification of Anabaena flavodoxin and ferredoxin-NADP+ reductase on the kinetics of interprotein electron transfer reactions.

The influence of chemical modification of arginine residues (using phenylglyoxal) in ferredoxin-NADP+ reductase (FNR), and of carboxyl groups (using glycine ethyl ester) in flavodoxin (Fld), on the kinetics of electron transfer between FNR and Fld, and between ferredoxin (Fd) and FNR, was examined using laser flash photolysis methods. All proteins were obtained from the cyanobacterium Anabaena PCC7119. Reduction by laser-generated 5-deazariboflavin semiquinone of the FAD moiety of phenylglyoxal-modified FNR occurred with a second-order rate constant 2.5-fold smaller than that obtained for reduction of native FNR, indicating either a small degree of steric hindrance of the cofactor, or a decrease in its redox potential, upon chemical modification. In contrast, no changes were found in the kinetics of reduction of the FMN cofactor of Fld modified by glycine ethyl ester as compared with the native protein. The observed rate constants for reoxidation of Fdred (reduced Fd) by FNRox (oxidized FNR) were dramatically decreased (approximately 100-fold) when phenylglyoxal-modified FNR was used. In contrast to the reaction involving the native proteins, no ionic strength effects on kobs values were found. These results, and those obtained upon varying the protein concentration, indicate that the rate constant for complex formation and the attractive electrostatic interaction between the two proteins were greatly diminished by chemical modification of arginine residues of FNR. When phenylglyoxal-modified FNRsq (FNR semiquinone) was used to reduce Fldox (oxidized Fld), similar inhibitory effects were observed. In this case, the limiting first-order rate constant for Fldsq (Fld semiquinone) formation via intracomplex electron transfer from FNRsq was approximately 12-fold smaller than that obtained for the native FNR (600 s-1 vs 7000 s-1). Again, ionic strength effects were diminished. The glycine-ethyl-ester-modified Fld yielded a limiting first-order rate constant for intracomplex electron transfer from FNRsq to Fldox which was approximately 7-fold smaller (1000 s-1) than that obtained with native Fld, and ionic strength effects were again diminished. These results indicate that complex formation can still occur between modified FNR and native Fld, and between native FNR and modified Fld, but that the geometry of these complexes is altered so as to decrease the effectiveness of interprotein electron transfer. The results are discussed in terms of the specific structural features of the proteins involved.     

Comparison of the kinetics of reduction and intramolecular electron transfer in electrostatic and covalent complexes of ferredoxin-NADP+ reductase and flavodoxin from Anabaena PCC 7119

The kinetics of reduction and intracomplex electron transfer in electrostatically stabilized and covalently crosslinked complexes between ferredoxin-NADP+ reductase (FNR) and flavodoxin (Fld) from the cyanobacterium Anabaena PCC 7119 were compared using laser flash photolysis. The second-order rate constant for reduction by 5-deazariboflavin semiquinone (dRfH) of FNR within the electrostatically stabilized complex at 10 mM ionic strength (4.0 X 10(8) M-1 s-1) was identical to that for free FNR. This suggests that the FAD cofactor of FNR is not sterically hindered upon complex formation. A lower limit of approximately 7000 s-1 was estimated for the first-order rate constant for intracomplex electron transfer from FNRred to Fldox under these conditions. In contrast, for the covalently crosslinked complex, a smaller second-order rate constant (2.1 X 10(8) M-1 s-1) was obtained for the reduction of FNR by dRfH within the complex, suggesting that some steric hindrance of the FAD cofactor of FNR occurs due to crosslinking. A limiting rate constant of 1000 s-1 for the intracomplex electron transfer reaction was obtained for the covalent complex, which was unaffected by changes in ionic strength. The substantially diminished limiting rate constant, relative to that of the electrostatic complex, may reflect either a suboptimal orientation of the redox cofactors within the covalent complex or a required structural reorganization preceding electron transfer which is not allowed once the proteins have been covalently linked. Thus, although the covalent complex is biochemically competent, it is not a quantitatively precise model for the catalytically relevant intermediate along the reaction pathway.     

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.     

Highly nonproductive complexes with Anabaena ferredoxin at low ionic strength are induced by nonconservative amino acid substitutions at Glu139 in Anabaena ferredoxin:NADP+ reductase

Ferredoxin (Fd) and ferredoxin:NADP(+) reductase (FNR) from Anabaena function in photosynthetic electron transfer (et). The et interaction between the FNR charge-reversal mutant E139K and Fd at 12 mM ionic strength (mu) is extremely impaired relative to the reaction with wt FNR, and the dependency of k(obs) on E139K concentration shows strong upward curvature at protein concentrations > or = 10 microM. However, at values of mu > or = 200 mM, reaction rates approach those of wild-type FNR, and normal saturation kinetics are observed. For the E139Q mutant, which is also significantly impaired in its et interaction with Fd at low FNR concentrations and low mu values, the dependency of k(obs) on E139Q concentration shows a smaller degree of upward curvature at mu = 12 and 100 mM and shows saturation kinetics at higher values of mu. wt FNR and the E139D mutant both show a slight amount of upward curvature at FNR concentrations >30 microM at mu = 12 mM but show the expected saturation kinetics at higher values of mu. These results are explained by a mechanism in which the mutual orientation of the proteins in the complex formed at low ionic strength with the E139K mutant is so far from optimal that it is almost unreactive. At increased E139K concentrations, the added mutant FNR reacts via a collisional interaction with the reduced Fd present in the unreactive complex. The et reactivity of the low ionic strength complexes depends on the particular amino acid substitution, which via electrostatic interactions alters the specific geometry of the interface between the two proteins. The presence of a negative charge at position 139 of FNR allows the most optimal orientations for et at ionic strengths below 200 mM.     

Electrostatic forces involved in orienting Anabaena ferredoxin during binding to Anabaena ferredoxin:NADP+ reductase: site-specific mutagenesis, transient kinetic measurements, and electrostatic surface potentials.

Transient absorbance measurements following laser flash photolysis have been used to measure the rate constants for electron transfer (et) from reduced Anabaena ferredoxin (Fd) to wild-type and seven site-specific charge-reversal mutants of Anabaena ferredoxin:NADP+ reductase (FNR). These mutations have been designed to probe the importance of specific positively charged amino acid residues on the surface of the FNR molecule near the exposed edge of the FAD cofactor in the protein-protein interaction during et with Fd. The mutant proteins fall into two groups: overall, the K75E, R16E, and K72E mutants are most severely impaired in et, and the K138E, R264E, K290E, and K294E mutants are impaired to a lesser extent, although the degree of impairment varies with ionic strength. Binding constants for complex formation between the oxidized proteins and for the transient et complexes show that the severity of the alterations in et kinetics for the mutants correlate with decreased stabilities of the protein-protein complexes. Those mutated residues, which show the largest effects, are located in a region of the protein in which positive charge predominates, and charge reversals have large effects on the calculated local surface electrostatic potential. In contrast, K138, R264, K290, and K294 are located within or close to regions of intense negative potential, and therefore the introduction of additional negative charges have considerably smaller effects on the calculated surface potential. We attribute the relative changes in et kinetics and complex binding constants for these mutants to these characteristics of the surface charge distribution in FNR and conclude that the positively charged region of the FNR surface located in the vicinity of K75, R16, and K72 is especially important in the binding and orientation of Fd during electron transfer.     

Structural analysis of interactions for complex formation between Ferredoxin-NADP+ reductase and its protein partners

The three-dimensional structures of K72E, K75R, K75S, K75Q, and K75E Anabaena Ferredoxin-NADP+ reductase (FNR) mutants have been solved, and particular structural details of these mutants have been used to assess the role played by residues 72 and 75 in optimal complex formation and electron transfer (ET) between FNR and its protein redox partners Ferredoxin (Fd) and Flavodoxin (Fld). Additionally, because there is no structural information available on the interaction between FNR and Fld, a model for the FNR:Fld complex has also been produced based on the previously reported crystal structures and on that of the rat Cytochrome P450 reductase (CPR), onto which FNR and Fld have been structurally aligned, and those reported for the Anabaena and maize FNR:Fd complexes. The model suggests putative electrostatic and hydrophobic interactions between residues on the FNR and Fld surfaces at the complex interface and provides an adequate orientation and distance between the FAD and FMN redox centers for efficient ET without the presence of any other molecule as electron carrier. Thus, the models now available for the FNR:Fd and FNR:Fld interactions and the structures presented here for the mutants at K72 and K75 in Anabaena FNR have been evaluated in light of previous biochemical data. These structures confirm the key participation of residue K75 and K72 in complex formation with both Fd and Fld. The drastic effect in FNR activity produced by replacement of K75 by Glu in the K75E FNR variant is explained not only by the observed changes in the charge distribution on the surface of the K75E FNR mutant, but also by the formation of a salt bridge interaction between E75 and K72 that simultaneously "neutralizes" two essential positive charged side chains for Fld/Fd recognition.     

Binding of ferredoxin to ferredoxin:NADP+ oxidoreductase: the role of carboxyl groups, electrostatic surface potential, and molecular dipole moment.

The small, soluble, (2Fe-2S)-containing protein ferredoxin (Fd) mediates electron transfer from the chloroplast photosystem I to ferredoxin: NADP+ oxidoreductase (FNR), a flavoenzyme located on the stromal side of the thylakoid membrane. Ferredoxin and FNR form a 1:1 complex, which is stabilized by electrostatic interactions between acidic residues of Fd and basic residues of FNR. We have used differential chemical modification of Fd to locate aspartic and glutamic acid residues at the intermolecular interface of the Fd:FNR complex (both proteins from spinach). Carboxyl groups of free and FNR-bound Fd were amidated with carbodiimide/2-aminoethane sulfonic acid (taurine). The differential reactivity of carboxyl groups was assessed by double isotope labeling. Residues protected in the Fd:FNR complex were D-26, E-29, E-30, D-34, D-65, and D-66. The protected residues belong to two domains of negative electrostatic surface potential on either side of the iron-sulfur cluster. The negative end of the molecular dipole moment vector of Fd (377 Debye) is close to the iron-sulfur cluster, in the center of the area demarcated by the protected carboxyl groups. The molecular dipole moment and the asymmetric surface potential may help to orient Fd in the reaction with FNR. In support, we find complementary domains of positive electrostatic potential on either side of the FAD redox center of FNR. The results allow a binding model for the Fd:FNR complex to be constructed.     

Kinetics of intracomplex electron transfer and of reduction of the components of covalent and noncovalent complexes of cytochrome c and cytochrome c peroxidase by free flavin semiquinones

The kinetics of reduction of free flavin semiquinones of the individual components of 1:1 covalent and electrostatic complexes of yeast ferric and ferryl cytochrome c peroxidase and ferric horse cytochrome c have been studied. Covalent cross-linking between the peroxidase and cytochrome c at low ionic strength results in a complex that has kinetic properties both similar to and different from those of the electrostatic complex. Whereas the cytochrome c heme exposure to exogenous reductants is similar in both complexes, the apparent electrostatic environment near the cytochrome c heme edge is markedly different. In the electrostatic complex, a net positive charge is present, whereas in the covalent complex, an essentially neutral electrostatic charge is found. Intracomplex electron transfer within the two complexes is also different. For the covalent complex, electron transfer from ferrous cytochrome c to the ferryl peroxidase has a rate constant of 1560 s-1, which is invariant with respect to changes in the ionic strength. The rate constant for intracomplex electron transfer within the electrostatic complex is highly ionic strength dependent. At mu = 8 mM a value of 750 s-1 has been obtained [Hazzard, J. T., Poulos, T. L., & Tollin, G. (1987) Biochemistry 26, 2836-2848], whereas at mu = 30 mM the value is 3300 s-1. This ionic strength dependency for the electrostatic complex has been interpreted in terms of the rearrangement of the two proteins comprising the complex to a more favorable orientation for electron transfer. In the case of the covalent complex, such reorientation is apparently impeded.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Fd : FNR Electron Transfer Complexes: Evolutionary Refinement of Structural Interactions

During the evolution of higher-plant root and leaf-type-specific Fd : FNR complexes from an original cyanobacterial type progenitor, rearrangement of molecular interaction has altered the relative orientation of prosthetic groups and there have been changes in complex induced conformational change. Selection has presumably worked on mutation of residues responsible for interaction between the two proteins, favoring optimized electron flow in a specific direction, and efficient dissociation following specific oxidation of leaf Fd and reduction of root Fd. Major changes appear to be: loss in both leaf and root complexes of a cyanobacterial mechanism that ensures Fd dissociation from the complex following change in Fd redox state, development of a structural rearrangement of Fd on binding to leaf FNR that results in a negative shift in Fd redox potential favorable to photosynthetic electron flow, creation of a vacant space in the root Fd:FNR complex that may allow access to the redox centers of other enzymes to ensure efficient channeling of heterotrophic reductant into bioassimilation. Further structural analysis is essential to establish how root type FNR distinguishes between Fd isoforms, and discover how residues not directly involved in intermolecular interactions may affect complex formation.     

Kinetics of reduction of Clostridium pasteurianum rubredoxin by laser photoreduced spinach ferredoxin:NADP+ reductase and free flavins. Electron transfer within a protein-protein complex

The kinetics of reduction of oxidized Clostridium pasteurianum rubredoxin (Rdox) by free flavin semiquinones generated by the laser flash photolysis technique and by spinach ferredoxin:NADP+ reductase (FNR) semiquinone (also produced by flavin semiquinone reduction) have been investigated under anaerobic conditions. 5-Deazariboflavin semiquinone (5-dRf) rapidly reduces oxidized rubredoxin (Rdox) (k = 3.0 X 10(8) M-1 S-1) and oxidized ferredoxin:NADP+ reductase (FNRox) to the semiquinone level (k = 5.5 X 10(8) M-1 S-1). Lumiflavin semiquinone reduces Rdox more slowly (k = 1.3 X 10(7) M-1 S-1) and is not measurably reactive with FNRox. Absorption difference spectroscopy and difference CD indicate that Rdox and FNRox form a 1:1 complex at low ionic strength (10 mM), which is completely dissociated at higher ionic strength (310 mM). Apparent second order rate constants for reduction of Rdox in its free and complexed state by lumiflavin semiquinone are the same. Reduction of Rdox (both free and complexed) by free FNR semiquinone and intracomplex electron transfer were investigated using 5-dRf as the reductant. At I = 10 mM, a first order rate constant of 2.0 X 10(3) S-1 was obtained, which corresponds to the processes involved in intracomplex electron transfer from FNR semiquinone to Rdox. A second order reaction between free FNR semiquinone and complexed Rdox was also observed to occur (k = 5 X 10(7) M-1 S-1). At I = 310 mM, these reactions are not observed and the reaction of FNR semiquinone with free Rdox is second order (k = 4 X 10(6) M-1 S-1).     

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.     

Reduction kinetics of the ferredoxin-ferredoxin-NADP+ reductase complex: a laser flash photolysis study

The kinetics of reduction of spinach ferredoxin (Fd), ferredoxin-NADP+ reductase (FNR), and the Fd-FNR complex have been investigated by the laser flash photolysis technique. 5-Deazariboflavin semiquinone (5-dRf), generated in situ by laser flash photolysis under anaerobic conditions, rapidly reduced both oxidized Fd (Fdox) (k = 2 X 10(8) M-1 s-1) and oxidized FNR (FNRox) (K = 6.3 X 10(8) M-1 s-1) at low ionic strength (10 mM) at pH 7.0, leading to the formation of reduced Fd (Fdred) and FNR semiquinone (FNR.), respectively. At higher ionic strengths (310 and 460 mM), the rate constant for the reduction of the free Fdox increased about 3-fold (k = 6.7 X 10(8) M-1 s-1 at 310 mM and 6.4 X 10(8) M-1 s-1 at 460 mM). No change in the second-order rate constant for reduction of the free FNRox was observed at high ionic strength. At low ionic strength (10 mM), 5-dRf. reacted only with the FAD center of the preformed 1:1 Fdox-FNRox complex (k = 5.6 X 10(8) M-1 s-1), leading to the formation of FNR.. No direct reduction of Fdox in the complex was observed. No change in the kinetics occurred in the presence of excess NADP+. The second-order rate constant for reduction of Fdox by 5-dRf. in the presence of a stoichiometric amount of fully reduced FNR at low ionic strength was 7 X 10(6) M-1 s-1, i.e., about one-thirtieth the rate constant for reduction of free Fdox.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cytochrome P-450scc-adrenodoxin interactions. Ionic effects on binding, and regulation of cytochrome reduction by bound steroid substrates

The binding of adrenodoxin to cytochrome P-450scc and the intracomplex electron transfer from the iron-sulfur center to the heme have been studied. Salt sensitivity of the protein complex suggests the participation of electrostatic forces, as is also seen for the complex of adrenodoxin with NADPH-adrenodoxin reductase. Differences in ion specificities for the complexes of adrenodoxin with the other two proteins suggest some differences in binding requirements. Insensitivity of the heme reduction to solution conditions (salt, detergent) and kinetic analysis indicate that the protein complex is formed rapidly and that intracomplex electron transfer then occurs more slowly. Factors governing the rate of this electron transfer were investigated; binding of a series of cholesterol derivatives was used to perturb the spin state, midpoint potential, and reduction rate of the heme, and thus to test for relationships among these parameters. A linear free energy relationship between the substrate-induced midpoint potential and reduction rate is seen, but none of the other parameters (including the strength of substrate binding) are correlated. Data indicate that factors other than spin state (i.e. steric requirements and bonding groups within the steroid-binding site) regulate the strength of steroid binding. The bound steroid then modulates both midpoint potential/reduction rate and spin state but by independent mechanisms.     

Role of hydrophobic interactions in the flavodoxin mediated electron transfer from photosystem I to ferredoxin-NADP+ reductase in Anabaena PCC 7119

Hydrophobic interactions play an active role in effective complex formation between ferredoxin-NADP(+) reductase (FNR) and ferredoxin (Fd) from Anabaena, where an aromatic amino acid residue on the Fd surface (F65) and three hydrophobic residues (L76, L78, and V136) on the reductase surface have been shown to be essential for the efficient electron transfer (ET) reaction between Fd and FNR (Martínez-Júlvez et al. (2001) J. Biol. Chem. 276, 27498-27510). Since in this system flavodoxin (Fld) can efficiently replace Fd in the overall ET process, we have further investigated if such hydrophobic interactions are also critical in complex stabilization and ET in the FNR/Fld association. Different ET behaviors with Fld are observed for some of the mutations made at L76, L78, and V136 of Anabaena FNR. Thus, the ET interaction with Fld is almost completely lost upon introduction of negatively charged side chains at these positions, while more conservative changes in the hydrophobic patch can influence the rates of ET to and from Fld by altering the binding constants and the midpoint redox potentials of the flavin group. Therefore, our results confirm that nonpolar residues in the region close to the FAD group in FNR participate in the establishment of interactions with Fld, which serve to orient the two flavin groups in a manner such that ET is favored. In an attempt to look for the counterpart region of the Fld surface, the effect produced by the replacement of the only two nonpolar residues on the Fld surface, I59 and I92, by a Lys has also been analyzed. The results obtained suggest that these two hydrophobic residues are not critical in the interaction and ET processes with FNR. The reactivity of these I92 and I59 Fld mutants toward the membrane-anchored photosystem I (PSI) complex was also analyzed by laser flash absorption spectroscopy. From these data, significant effects are evident, especially for the I92 position of Fld, both in the association constant for complex formation and in the electron-transfer rate constant in the PSI/Fld system.     

Flavodoxin-mediated electron transfer from photosystem I to ferredoxin-NADP+ reductase in Anabaena: role of flavodoxin hydrophobic residues in protein-protein interactions

Three surface hydrophobic residues located at the Anabaena flavodoxin (Fld) putative complex interface with its redox partners were replaced by site-directed mutagenesis. The effects of these replacements on Fld interaction with both its physiological electron donor, photosystem I (PSI), and its electron acceptor, ferredoxin-NADP+ reductase (FNR), were analyzed. Trp57, Ile59, and Ile92 contributed to the optimal orientation and tightening of the FNR:Fld and PSI:Fld complexes. However, these side chains did not appear to be involved in crucial specific interactions, but rather contributed to the obtainment of the optimal orientation and distance of the redox centers required for efficient electron transfer. This supports the idea that the interaction of Fld with its partners is less specific than that of ferredoxin and that more than one orientation is efficient for electron transfer in these transient complexes. Additionally, for some of the analyzed processes, WT Fld seems not to be the most optimized molecular species. Therefore, subtle changes at the isoalloxazine environment not only influence the Fld binding abilities, but also modulate the electron exchange processes by producing different orientations and distances between the redox centers. Finally, the weaker apoflavodoxin interaction with FNR suggests that the solvent-accessible region of FMN plays a role either in complex formation with FNR or in providing the adequate conformation of the FNR binding region in Fld.     

Electron transfer by ferredoxin:NADP+ reductase. Rapid-reaction evidence for participation of a ternary complex

Rapid reaction studies presented herein show that ferredoxin:NADP+ oxidoreductase (FNR, EC 1.18.1.2) catalyzes electron transfer from spinach ferredoxin (Fd) to NADP+ via a ternary complex, Fd X FNR X NADP+. In the absence of NADP+, reduction of ferredoxin:NADP+ reductase by Fd was much slower than the catalytic rate: 37-80 s-1 versus at least 445 e-s-1; dissociation of oxidized spinach ferredoxin (Fdox) from one-electron reduced ferredoxin:NADP+ reductase (FNRsq) limited the reduction of FNR. This confirms the steady-state kinetic analysis of Masaki et al. (Masaki, R., Yoshikaya, S., and Matsubara, H. (1982) Biochim. Biophys. Acta 700, 101-109). Occupation of the NADP+ binding site of FNR by NADP+ or by 2',5'-ADP (a nonreducible NADP+ analogue) greatly increased the rate of electron transfer from Fd to FNR, releiving inhibition by Fdox. NADP+ (and 2',5'-ADP) probably facilitate the dissociation of Fdox; equilibrium studies have shown that nucleotide binding decreases the association of Fd with FNR (Batie, C. J. (1983) Ph.D. dissertation, Duke University; Batie, C. J., and Kamin, H. (1982) in Flavins and Flavoproteins VII (Massey, V., and Williams, C. H., Jr., eds) pp. 679-683, Elsevier, New York; Batie, C.J., and Kamin, H. (1982) Fed. Proc. 41, 888; and Batie, C.J., and Kamin, H. (1984) J. Biol. Chem. 259, 8832-8839). Premixing Fd with FNR was found to inhibit the reaction of the flavoprotein with NADP+ and with NADPH; thus, substrate binding may be ordered, NADP+ first, then Fd. FNRred and NADP+ very rapidly formed an FNRred X NADP+ complex with flavin to nicotinamide charge transfer bands. The Fdred X NADP+ complex then relaxed to an equilibrium species; the spectrum indicated a predominance of FNRox X NADPH charge-transfer complex. However, charge-transfer species were not observed during turnover; thus, their participation in catalysis of electron transfer from Fd to NADP+ remains uncertain. The catalytic rate of Fd to NADP+ electron transfer, as well as the rates of electron transfer from Fd to FNR, and from FNR to NADP+ were decreased when the reactants were in D2O; diaphorase activity was unaffected by solvent. On the basis of the data presented, a scheme for the catalytic mechanism of catalysis by FNR is presented.     

Docking analysis of transient complexes: interaction of ferredoxin-NADP+ reductase with ferredoxin and flavodoxin

Ferredoxin (Fd) interacts with ferredoxin-NADP(+) reductase (FNR) to transfer two electrons to the latter, one by one, which will finally be used to reduce NADP(+) to NADPH. The formation of a transient complex between Fd and FNR is required for the electron transfer (ET), and extensive mutational and crystallographic studies have been reported to characterize such protein-protein interaction. However, some aspects of the association mechanism still remain unclear. Moreover, in spite of their structural differences, flavodoxin (Fld) can replace Fd in its function and interact with FNR to transfer electrons with only slightly lower efficiency. Although crystallographic structures for the FNR:Fd association have been reported, experimental structural data for the FNR:Fld interaction are highly elusive. We have modeled here the interactions between FNR and both of its protein partners, Fd and Fld, using surface energy analysis, computational rigid-body docking simulations, and interface side-chain refinement. The results, consistent with previous experimental data, suggest the existence of alternative binding modes in these ET proteins.     

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.     

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

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.