Reactivity of cytochromes c and f with mutant forms of spinach plastocyanin.

The reduction of plastocyanin by cytochromes c and f has been investigated with mutants of spinach plastocyanin in which individual, highly conserved surface residues have been modified. These include Leu-12 and Phe-35 in the 'northern' hydrophobic patch and Tyr-83 and Asp-42 in the 'eastern' acidic patch. The differences observed all involved binding rather than the intrinsic rates of electron transfer. The Glu-12 and Ala-12 mutants showed small but significant decreases in binding constant with cytochrome c, even though the cytochrome is not expected to make contact with the northern face of plastocyanin. These results, and small changes in the EPR parameters, suggested that these mutations cause small conformational changes in surface residues on the eastern face of plastocyanin, transmitted through the copper centre. In the case of cytochrome f, the Glu-12 and Ala-12 mutants also bound less strongly, but Leu12Asn showed a marked increase in binding constant, suggesting that cytochrome f can hydrogen bond directly to Asn-12 in the reaction complex. A surprising result was that the kinetics of reduction of Asp42Asn were not significantly different from wild type, despite the loss of a negative charge.     

Electrostatic analysis and Brownian dynamics simulation of the association of plastocyanin and cytochrome f.

The oxidation of cytochrome f by the soluble cupredoxin plastocyanin is a central reaction in the photosynthetic electron transfer chain of all oxygenic organisms. Here, two different computational approaches are used to gain new insights into the role of molecular recognition and protein-protein association processes in this redox reaction. First, a comparative analysis of the computed molecular electrostatic potentials of seven single and multiple point mutants of spinach plastocyanin (D42N, E43K, E43N, E43Q/D44N, E59K/E60Q, E59K/E60Q/E43N, Q88E) and the wt protein was carried out. The experimentally determined relative rates (k(2)) for the set of plastocyanin mutants are found to correlate well (r(2) = 0.90 - 0.97) with the computed measure of the similarity of the plastocyanin electrostatic potentials. Second, the effects on the plastocyanin/cytochrome f association rate of these mutations in the plastocyanin "eastern site" were evaluated by simulating the association of the wild type and mutant plastocyanins with cytochrome f by Brownian dynamics. Good agreement between the computed and experimental relative rates (k(2)) (r(2) = 0.89 - 0.92) was achieved for the plastocyanin mutants. The results obtained by applying both computational techniques provide support for the fundamental role of the acidic residues at the plastocyanin eastern site in the association with cytochrome f and in the overall electron-transfer process.     

The surface-exposed tyrosine residue Tyr83 of pea plastocyanin is involved in both binding and electron transfer reactions with cytochrome f.

Site-directed mutants of the pea plastocyanin gene in which the codon for the surface-exposed Tyr83 has been changed to codons for Phe83 and Leu83 have been expressed in transgenic tobacco plants. The mutant proteins have been purified to homogeneity and their conformations shown not to differ significantly from the wild-type plastocyanin by 1H-NMR and CD. Overall rate constants for electron transfer (k2) from cytochrome f to plastocyanin have been measured by stopped-flow spectrophotometry and rate constants for binding (ka) and association constants (KA) have been measured from the enhanced Soret absorption of cytochrome f on binding plastocyanin. These measurements allow the calculation of the intrinsic rate of electron transfer in the binary complex. An 8-fold decrease in the overall rate of electron transfer to the Phe83 mutant is due entirely to a decreased association constant for cytochrome f, whereas the 40-fold decrease in the overall rate of electron transfer to the Leu83 mutant is due to weaker binding and a lower intrinsic rate of electron transfer. This indicates that Tyr83 is involved in binding to cytochrome f and forms part of the main route of electron transfer.     

A comparative flash-photolysis study of electron transfer from pea and spinach plastocyanins to spinach Photosystem 1. A reaction involving a rate-limiting conformational change

Two mutants of plastocyanin have been constructed by site-directed mutagenesis in spinach and pea to elucidate the binding and electron transfer properties between plastocyanin and spinach Photosystem 1. The conserved, surface-exposed Tyr-83 has been replaced by phenylalanine and leucine in plastocyanin from both species and the proteins have been expressed in Escherichia coli. The reaction mechanism of electron transfer from plastocyanins to photooxidized P700 in Photosystem 1 has been studied by laser-flash absorption spectroscopy. The experimental data were interpreted with a model involving a rate-limiting conformational change, preceding the intracomplex electron transfer. The pea proteins show an overall facilitated reaction with spinach Photosystem 1, compared to spinach plastocyanins. The changes are small but significant, indicating a more efficient electron transfer within the transient complex. In addition, for the spinach leucine mutant, the equilibrium within the plastocyanin-Photosystem 1 complex is more displaced towards the active conformation than for the corresponding wild-type. Absorption spectra, EPR and reduction potentials for the mutants are similar to those of the corresponding wild-type, although small shifts are observed in the spectra of the Tyr83Leu proteins. Based on these results, it is suggested that Photosystem 1 from spinach is capable of using both pea and spinach plastocyanin as an efficient electron donor and that the former even can stimulate the Photosystem 1 reduction. The origin of the stimulation is discussed in terms of differences in surface-exposed residues. Since the effects of the mutations are small, it can be concluded that electron transfer to Photosystem 1 does not occur via Tyr-83.Abbreviations cyt- cytochrome - IPTG- isopropyl--d-thiogalactopyranoside - P,P700- reaction-center chlorophyll - Pc- plastocyanin - PS 1- Photosystem 1 - SDS-PAGE- sodium dodecyl sulfate polyacrylamide gel electrophoresis - WT- wild-type     

Dynamic interaction of plastocyanin with the cytochrome bf complex

The interaction between plastocyanin and the intact cytochrome bf complex, both from spinach, has been studied by stopped-flow kinetics with mutant plastocyanin to elucidate the site of electron transfer and the docking regions of the molecule. Mutation of Tyr-83 to Arg or Leu provides no evidence for a second electron transfer path via Tyr-83 of plastocyanin, which has been proposed to be the site of electron transfer from cytochrome f. The data found with mutations of acidic residues indicate that both conserved negative patches are essential for the binding of plastocyanin to the intact cytochrome bf complex. Replacing Ala-90 and Gly-10 at the flat hydrophobic surface of plastocyanin by larger residues slowed down and accelerated, respectively, the rate of electron transfer as compared with wild-type plastocyanin. These opposing effects reveal that the hydrophobic region around the electron transfer site at His-87 is divided up into two regions, of which only that with Ala-90 contributes to the attachment to the cytochrome bf complex. These binding sites of plastocyanin are substantially different from those interacting with photosystem I. It appears that each of the two binding regions of plastocyanin is split into halves, which are used in different combinations in the molecular recognition at the two membrane complexes.     

Electron transfer reactions of chemically modified plastocyanin with P700 and cytochrome f. Importance of local charges

Chemically modified spinach plastocyanin, in which negatively charged carboxyl residues are replaced with positively charged amino residues, has been prepared. Four distinct species of chemically modified plastocyanin, having 1 to 4 mol of modified carboxyl residue per mol of plastocyanin, could be separated by ion-exchange chromatography on DEAE-Sephacel. The rate of electron transfer from reduced cytochrome f to oxidized singly substituted plastocyanin was 30% of that of the native unmodified plastocyanin, and the reaction rate decreased further with increasing number of modified carboxyl residues. These results indicate the importance of electrostatic interactions between the negative charges on plastocyanin and the positive charges on cytochrome f in this reaction. Since the overall net charge of cytochrome f is negative at neutral pH, the positive charges on cytochrome f involved in the reaction should be localized ones. On the other hand, the rates of electron transfer from reduced singly and doubly substituted plastocyanin to photooxidized P700 in the P700-chlorophyll alpha protein complex were similar to that of native plastocyanin, which suggests that these carboxyl residues have only a minor role in the electron transfer to P700. Although divalent cation is essential for the electron transfer from native plastocyanin to P700 at neutral pH, the triply substituted plastocyanin could donate electrons to P700 even without MgCl2, and the rate of this reaction reached the maximum at a low concentration of MgCl2 (less than 2.5 mM). The modification of four carboxyl residues per plastocyanin molecule activated this reaction to the maximum level without MgCl2.(ABSTRACT TRUNCATED AT 250 WORDS)     

Surface interactions in the complex between cytochrome f and the E43Q/D44N and E59K/E60Q plastocyanin double mutants as determined by 1H-NMR chemical shift analysis

A combination of site-directed mutagenesis and NMR chemical shift perturbation analysis of backbone and side-chain protons has been used to characterize the transient complex of the photosynthetic redox proteins plastocyanin and cytochrome f. To elucidate the importance of charged residues on complex formation, the complex of cytochrome f and E43Q/D44N or E59K/E60Q spinach plastocyanin double mutants was studied by full analysis of the (1)H chemical shifts by use of two-dimensional homonuclear NMR spectra. Both mutants show a significant overall decrease in chemical shift perturbations compared with wild-type plastocyanin, in agreement with a large decrease in binding affinity. Qualitatively, the E43Q/D44N mutant showed a similar interaction surface as wild-type plastocyanin. The interaction surface in the E59K/E60Q mutant was distinctly different from wild type. It is concluded that all four charged residues contribute to the affinity and that residues E59 and E60 have an additional role in fine tuning the orientation of the proteins in the complex.     

Role of charges on cytochrome f from the cyanobacterium Phormidium laminosum in its interaction with plastocyanin

The role of charge on the surface of cytochrome f from the cyanobacterium Phormidium laminosum in the reaction with plastocyanin was investigated in vitro using site-directed mutagenesis. Charge was neutralized at five acidic residues individually and introduced at a residue close to the interface between the two proteins. The effects on the kinetics of the reaction were measured using stopped-flow spectrophotometry, and the midpoint potentials of the mutant proteins were determined. The dependence of the bimolecular rate constant of reaction, k(2), on ionic strength was determined for the reactions of the cytochrome f mutants with wild-type and mutant forms of plastocyanin. Double mutant cycle analysis was carried out to probe for the presence of specific electrostatic interactions. The effects of mutations on Cyt f were smaller than those seen previously for mutants of plastocyanin [Schlarb-Ridley, B. G. et al. (2002) Biochemistry 41, 3279-3285]. One specific short-range interaction between charged residues of wild-type plastocyanin (Arg93) and wild-type cytochrome f (Asp63) was identified. The kinetic evidence from this study and that of Schlarb-Ridley et al., 2002, appears to conflict with the NMR structure of the P. laminosum complex, which suggests the absence of electrostatic interactions in the final complex [Crowley, P. et al. (2001) J. Am. Chem. Soc. 123, 10444-10453]. The most likely explanation of the apparent paradox is that the overall rate is diffusion controlled and that electrostatics specifically influence the encounter complex and not the reaction complex.     

The specificity in the interaction between cytochrome f and plastocyanin from the cyanobacterium Nostoc sp. PCC 7119 is mainly determined by the copper protein

The plastocyanin-cytochrome f complex from Nostoc exhibits relevant structural differences when compared with the homologous complexes from other cyanobacteria and plants, with electrostatic and hydrophobic interactions being differently involved in each case. Here, five negatively charged residues of a recombinant form of cytochrome f from Nostoc have been replaced with either neutral or positively charged residues, and the effects of mutations on the kinetics of electron transfer to wild-type and mutant forms of plastocyanin have been measured by laser flash absorption spectroscopy. Cytochrome f mutants with some negative charges replaced with neutral residues exhibit an apparent electron transfer rate constant with wild-type plastocyanin similar to or slightly higher than that of the wild-type species, whereas the mutants with negative charges replaced with positive residues exhibit a significantly lower reactivity. Taken together, these results indicate that the effects of neutralizing residues at the electrostatically charged patch of cytochrome f are smaller than those previously observed for mutants of plastocyanin, thus suggesting that it is the copper protein which determines the specificity of the electrostatic interaction with the heme protein. Moreover, cross reactions between mutants of both proteins reveal the presence of some short-range specific electrostatic interactions. Our findings also make evident the fact that in Nostoc the main contribution to the electrostatic nature of the complex is provided by the small domain of cytochrome f.     

Electron transfer to photosystem 1 from spinach plastocyanin mutated in the small acidic patch: ionic strength dependence of kinetics and comparison of mechanistic models

A set of plastocyanin (Pc) mutants, probing the small acidic patch (Glu59, Glu60, and Asp61) and a nearby residue, Gln88, has been constructed to provide further insight into the electron transfer process between Pc and photosystem 1. The negatively charged residues were changed into their neutral counterparts or to a positive lysine. All mutant proteins exhibited electron transfer kinetics qualitatively similar to those of the wild type protein over a wide range of Pc concentrations. The kinetics were slightly faster for the Gln88Lys mutant, while they were significantly slower for the Glu59Lys mutant. The data were analyzed with two different models: one involving a conformational change of the Pc-photosystem 1 complex that precedes the electron transfer step (assumed to be irreversible) [Bottin, H., and Mathis, P. (1985) Biochemistry 24, 6453-6460] and another where no conformational change occurs, the electron transfer step is reversible, and dissociation of products is explicitly taken into account [Drepper, F., Hippler, M., Nitschke, W., and Haehnel, W. (1996) Biochemistry 35, 1282-1295]. Both models can account for the observed kinetics in the limits of low and high Pc concentrations. To discriminate between the models, the effects of added magnesium ions on the kinetics were investigated. At a high Pc concentration (0.7 mM), the ionic strength dependence was found to be consistent with the model involving a conformational change but not with the model where the electron transfer is reversible. One residue in the small acidic patch, Glu60, seems to be responsible for the major part of the ionic strength dependence of the kinetics.     

The role of amino-acid residues in the hydrophobic patch surrounding the haem group of cytochrome f in the interaction with plastocyanin.

Soluble turnip cytochrome f has been purified from the periplasmic fraction of Escherichia coli expressing a truncated petA gene encoding the precursor protein lacking the C-terminal 33 amino-acid residues. The protein is identical [as judged by 1H-NMR spectroscopy, midpoint redox potential (+ 365 mV) and electron transfer reactions with plastocyanin] to cytochrome f purified from turnip leaves. Several residues in the hydrophobic patch surrounding the haem group have been changed by site-directed mutagenesis, and the proteins purified from E. coli. The Y1F and Q7N mutants showed only minor changes in the plastocyanin-binding constant Ka and the second-order rate constant for electron transfer to plastocyanin, whereas the Y160S mutant showed a 30% decrease in the overall rate of electron transfer caused in part by a 60% decrease in binding constant and partially compensated by an increased driving force due to a 27-mV decrease in redox potential. In contrast, the F4Y mutant showed increased rates of electron transfer which may be ascribed to an increased binding constant and a 14-mV decrease in midpoint redox potential. This indicates that subtle changes in the hydrophobic patch can influence rates of electron transfer to plastocyanin by changing the binding constants and altering the midpoint redox potential of the cytochrome haem group.     

Structure of the intermolecular complex between plastocyanin and cytochrome f from spinach

In oxygenic photosynthesis, plastocyanin shuttles electrons between the membrane-bound complexes cytochrome b6f and photosystem I. The homologous complex between cytochrome f and plastocyanin, both from spinach, is the object of this study. The solution structure of the reduced spinach plastocyanin was determined using high field NMR spectroscopy, whereas the model structure of oxidized cytochrome f was obtained by homology modeling calculations and molecular dynamics. The model structure of the intermolecular complex was calculated using the program AUTODOCK, taking into account biological information obtained from mutagenesis experiments. The best electron transfer pathway from the heme group of cytochrome f to the copper ion of plastocyanin was calculated using the program HARLEM, obtaining a coupling decay value of 1.8 x 10(-4). Possible mechanisms of interaction and electron transfer between plastocyanin and cytochrome f were discussed considering the possible formation of a supercomplex that associates one cytochrome b6f, one photosystem I, and one plastocyanin.     

A Brownian dynamics study of the interaction of Phormidium cytochrome f with various cyanobacterial plastocyanins

Brownian dynamics simulations were used to study the role of electrostatic forces in the interactions of cytochrome f from the cyanobacterium Phormidium laminosum with various cyanobacterial plastocyanins. Both the net charge on the plastocyanin molecule and the charge configuration around H92 (H87 in higher plants) are important in determining the interactions. Those plastocyanins (PCs) with a net charge more negative than -2.0, including those from Synechococcus sp. PCC7942, Synechocystis sp. 6803, and P. laminosum showed very little complex formation. On the other hand, complex formation for those with a net charge more positive than -2.0 (including Nostoc sp. PCC7119 and Prochlorothrix hollandica) as well as Nostoc plastocyanin mutants showed a linear dependence of complex formation upon the net charge on the plastocyanin molecule. Mutation of charged residues on the surface of the PC molecules also affected complex formation. Simulations involving plastocyanin mutants K35A, R93A, and K11A (when present) showed inhibition of complex formation. In contrast, D10A and E17A mutants showed an increase in complex formation. All of these residues surround the H92 (H87 in higher plant plastocyanins) ligand to the copper. An examination of the closest electrostatic contacts shows that these residues interact with D63, E123, R157, D188, and the heme on Phormidium cytochrome f. In the complexes formed, the long axis of the PC molecule lies perpendicular to the long axis of cytochrome f. There is considerable heterogeneity in the orientation of plastocyanin in the complexes formed.     

Electron transfer from plastocyanin to photosystem I.

Mutant plastocyanins with Leu at position 10, 90 or 83 (Gly, Ala and Tyr respectively in wildtype) were constructed by site-specific mutagenesis of the spinach gene, and expressed in transgenic potato plants under the control of the authentic plastocyanin promoter, as well as in Escherichia coli as truncated precursor intermediates carrying the C-terminal 22 amino acid residues of the transit peptide, i.e. the thylakoid-targeting domain that acts as a bacterial export signal. The identity of the purified plastocyanins was verified by matrix-assisted laser desorption/ionization mass spectrometry. The formation of a complex between authentic or mutant spinach plastocyanin and isolated photosystem I and the electron transfer has been studied from the biphasic reduction kinetics of P700+ after excitation with laser flashes. The formation of the complex was abolished by the bulky hydrophobic group of Leu at the respective position of G10 or A90 which are part of the conserved flat hydrophobic surface around the copper ligand H87. The rate of electron transfer decreased by both mutations to < 20% of that found with wildtype plastocyanin. We conclude that the conserved flat surface of plastocyanin represents one of two crucial structural elements for both the docking at photosystem I and the efficient electron transfer via H87 to P700+. The Y83L mutant exhibited faster electron transfer to P700+ than did authentic plastocyanin. This proves that Y83 is not involved in electron transfer to P700 and suggests that electron transfer from cytochrome f and to P700 follows different routes in the plastocyanin molecule. Plastocyanin (Y83L) expressed in either E. coli or potato exhibited different isoelectric points and binding constants to photosystem I indicative of differences in the folding of the protein. The structure of the binding site at photosystem I and the mechanism of electron transfer are discussed.     

Electrostatic properties of cytochrome f: implications for docking with plastocyanin.

The electrostatic properties of cytochrome f (cyt f), a member of the cytochrome b6f complex and reaction partner with plastocyanin (PC) in photosynthetic electron transport, are qualitatively studied with the goal of determining the mechanism of electron transfer between cyt f and PC. A crystal structure for cyt f was analyzed with the software package GRASP, revealing a large region of positive potential generated by a patch of positively charged residues (including K58, K65, K66, K122, K185, K187, and R209) and reinforced by the iron center of the heme. This positive field attracts the negative charges of the two acidic patches on the mobile electron carrier PC. Three docked complexes are obtained for the two proteins, based on electrostatic or hydrophobic interactions or both and on steric fits by manual docking methods. The first of these three complexes shows strong electrostatic interactions between K187 on cyt f and D44 on PC and between E59 on PC and K58 on cyt f. Two other manually docked complexes are proposed, implicating H87 on PC as the electron-accepting site from the iron center of cyt f through Y1. The second complex maintains the D44/K187 cross-link (but not the E59/K58 link) while increasing hydrophobic interactions between PC and cyt f. Hydrophobic interactions are increased still further in the third complex, whereas the link between K187 on cyt f and D44 on PC is broken. The proposed reaction mechanism, therefore, involves an initial electrostatic docking complex that gives rise to a nonpolar attraction between the regions surrounding H87 on PC and Y1 on cyt f, providing for an electron-transfer active complex.     

Laser flash-induced kinetic analysis of cytochrome f oxidation by wild-type and mutant plastocyanin from the cyanobacterium Nostoc sp. PCC 7119

Oxidation of the soluble, truncated form of cytochrome f by wild-type and mutant species of plastocyanin has been analyzed by laser flash absorption spectroscopy in the cyanobacterium Nostoc (formerly, Anabaena) sp. PCC 7119. At low ionic strengths, the apparent electron transfer rate constant of cytochrome f oxidation by wild-type plastocyanin is 1.34 x 10(4) s(-)(1), a value much larger than those determined for the same proteins from other organisms. Upon site-directed mutagenesis of specific residues at the plastocyanin interaction area, the rate constant decreases in all cases yet to varying extents. The only exception is the D54K variant, which exhibits a higher reactivity toward cytochrome f. In most cases, the reaction rate constant decreases monotonically with an increase in ionic strength. The observed changes in the reaction mechanism and rate constants are in agreement with the location of the mutated residues at the interface area, as well as with the peculiar orientation of the two partners within the Nostoc plastocyanin-cytochrome f transient complex, whose NMR structure has been determined recently. Furthermore, the experimental data herein reported match well the kinetic behavior exhibited by the same set of plastocyanin mutants when acting as donors of electrons to photosystem I [Molina-Heredia, F. P., et al. (2001) J. Biol. Chem. 276, 601-605], thus indicating that the copper protein uses the same surface areas-one hydrophobic and the other electrostatic-to interact with both cytochrome f and photosystem I.     

Direct simulation of plastocyanin and cytochrome f interactions in solution

Most biological functions, including photosynthetic activity, are mediated by protein interactions. The proteins plastocyanin and cytochrome f are reaction partners in a photosynthetic electron transport chain. We designed a 3D computer simulation model of diffusion and interaction of spinach plastocyanin and turnip cytochrome f in solution. It is the first step in simulating the electron transfer from cytochrome f to photosystem 1 in the lumen of thylakoid. The model is multiparticle and it can describe the interaction of several hundreds of proteins. In our model the interacting proteins are represented as rigid bodies with spatial fixed charges. Translational and rotational motion of proteins is the result of the effect of stochastic Brownian force and electrostatic force. The Poisson-Boltzmann formalism is used to determine the electrostatic potential field generated around the proteins. Using this model we studied the kinetic characteristics of plastocyanin-cytochrome f complex formation for plastocyanin mutants at pH 7 and a variety of ionic strength values.     

Site-directed mutagenesis of cytochrome c6 from Synechocystis sp. PCC 6803. The heme protein possesses a negatively charged area that may be isofunctional with the acidic patch of plastocyanin

This paper reports the first site-directed mutagenesis analysis of any cytochrome c6, a heme protein that performs the same function as the copper-protein plastocyanin in the electron transport chain of photosynthetic organisms. Photosystem I reduction by the mutants of cytochrome c6 from the cyanobacterium Synechocystis sp. PCC 6803 has been studied by laser flash absorption spectroscopy. Their kinetic efficiency and thermodynamic properties have been compared with those of plastocyanin mutants from the same organism. Such a comparative study reveals that aspartates at positions 70 and 72 in cytochrome c6 are located in an acidic patch that may be isofunctional with the well known "south-east" patch of plastocyanin. Calculations of surface electrostatic potential distribution in the mutants of cytochrome c6 and plastocyanin indicate that the changes in protein reactivity depend on the surface electrostatic potential pattern rather than on the net charge modification induced by mutagenesis. Phe-64, which is close to the heme group and may be the counterpart of Tyr-83 in plastocyanin, does not appear to be involved in the electron transfer to photosystem I. In contrast, Arg-67, which is at the edge of the cytochrome c6 acidic area, seems to be crucial for the interaction with the reaction center.     

Reconstitution of mature plastocyanin from precursor apo-plastocyanin expressed in Escherichia coli

The precursor plastocyanin from Silene pratensis (white campion) has been expressed in Escherichia coli. The precursor protein was accumulated in insoluble aggregates and partially purified as an apo-protein. The purified precursor apo-plastocyanin was processed to the mature apo-plastocyanin by chloroplast extracts. N-terminal amino-acid sequencing indicated that the processed protein was identical to the N-terminal amino-acid residues of mature plastocyanin that was deduced from the nucleotide sequence. The copper could be incorporated into the apo-plastocyanin of mature size in vitro, but could not into the precursor apo-plastocyanin under the same conditions. Absorption spectra and reduction potential of the reconstituted mature plastocyanin were indistinguishable from those of the purified spinach plastocyanin. The electron transfer activities of the reconstituted plastocyanin with both the Photosystem I reaction center (P700) and cytochrome f were almost the same as those of the purified spinach plastocyanin.     

Kinetic studies on a cross-linked complex between plastocyanin cytochrome f

A cross-linked complex between plastocyanin and cytochrome f was prepared by incubation in the presence of a water soluble carbodiimide and its kinetic properties were studied. The optical spectra, oxidation-reduction potentials and isoelectric pH of plastocyanin and cytochrome f did not change upon the formation of the cross-linked complex. Studies on the ionic strength effect on the electron transfer rate from cross-linked plastocyanin to ferricyanide indicated that the negative charge on the reaction site of plastocyanin was masked upon the cross-linking. It was also suggested that the sign of the net charge near the cytochrome f heme edge changed from positive to negative upon the cross-linking. On the other hand, electrostatic interactions between cross-linked plastocyanin and P700 seemed to be essentially the same as those in the case of native plastocyanin, although the rate of electron transfer from cross-linked plastocyanin to P700 was severely reduced. We also measured the intra-complex electron transfer from cytochrome f to plastocyanin. This suggested that the covalently cross-linked complex is a valid model of the electron transfer encounter complex. Based on these results, the reaction sites of plastocyanin with P700 and cytochrome f were discussed.