The effect of ethylenediamine chemical modification of plastocyanin on the rate of cytochrome f oxidation and P-700+ reduction

Chemical modification of plastocyanin was carried out using ethylenediamine plus a water-soluble carbodiimide, which has the effect of replacing a negatively charged carboxylate group with a positively charged amino group at pH 6-8. The conditions were adjusted to produce a series of singly and doubly modified forms of plastocyanin. Differences in charge configuration allowed separation of these forms on a Pharmacia fast protein liquid chromatograph using a Mono Q anion exchange column. These forms were used to study the interaction of plastocyanin with its reaction partner cytochrome f. The rate of cytochrome f oxidation was progressively inhibited upon incorporation of increasing numbers of ethylenediamine moieties indicating a positively charged binding site on cytochrome f. However, differential inhibition was obtained for the various singly modified forms allowing mapping of the binding site on plastocyanin. The greatest inhibition was found for forms modified at negatively charged residues Nos. 42-45 and Nos. 59-61 which comprise a negative patch surrounding Tyr-83. In contrast, the form modified at residue No. 68, on the opposite side of the globular plastocyanin molecule, showed the least inhibition. It can be concluded that the binding site for cytochrome f is located in the vicinity of residues Nos. 42-45 and Nos. 59-61. Modification of plastocyanin at residues Nos. 42-45 showed no effect on the rate of P-700+ reduction, suggesting that these residues are not involved in the binding of Photosystem I. However, an increase in the rate of P-700+ reduction was observed for plastocyanins modified at residue No. 68 or Nos. 59-61, which is consistent with the idea that the reaction domain of Photosystem I is negatively charged and Photosystem I binds at the top of the molecule and accepts electrons via His-87 in plastocyanin. These results raise the possibility that plastocyanin can bind both cytochrome f and Photosystem I simultaneously. The effect of ethylenediamine modification on the formal potential of plastocyanin was also examined. The formal potential of control plastocyanin was found to be +372 +/- 5 mV vs. normal hydrogen electrode at pH 7. All modified forms showed a positive shift in formal potential. Singly modified forms showed increases in formal potentials between +8 and +18 mV with the largest increases being observed for plastocyanins modified at residues Nos. 42-45 or Nos. 59-61.     

Chemical modification of spinach plastocyanin using 4-chloro-3,5-dinitrobenzoic acid: characterization of four singly-modified forms

Chemical modification of plastocyanin was carried out using 4-chloro-3,5-dinitrobenzoic acid, which has the effect of replacing positive charges on amino groups with negatively charged carboxyl groups. Four singly-modified forms were obtained which were separated using anion exchange FPLC. The four forms were modified at the N-terminal valine and at lysines 54, 71 and 77. The rates of reaction with mammalian cytochrome c were increased for all four modified plastocyanins. In contrast, the rates of reaction with cytochrome f were inhibited for the forms modified at residues 1, 54 and 77, whereas no effect was observed for the form modified at residue 71. Modification had no effect on either the midpoint redox potential or the reaction with K3Fe(CN)6. These results are consistent with a model in which charged residues on plastocyanin located at or near the binding site for cytochrome f recognize the positively-charged binding site on cytochrome f. In contrast, charged residues located at points on plastocyanin distant from the cytochrome f binding site recognize the net negative charge on the cytochrome f molecule. Based on these considerations, Glu-68 may be within the interaction sphere of cytochrome f, suggesting that cytochrome f may donate electrons to plastocyanin at either Tyr-83 or His-87.     

Evidence for complexed plastocyanin as the immediate electron donor of P-700

The reduction of P-700 by its electron donors shows two fast phases with half-times of 20 and 200 μs in isolated spinach chloroplasts. We have studied this electron transfer and the oxidation kinetics of cytochrome f.

Incubation of chloroplasts with KCN or HgCl₂ decreased the amplitude of the 20 μs phase. This provides evidence for a function of plastocyanin as the immediate electron donor of P-700.

At low concentrations of salt and sugar the fast phases of P-700⁺ reduction were largely inhibited. Increasing concentrations of MgCl₂, KCl and sorbitol (up to 5, 150 and 200 mM, respectively) were found to increase the relative amplitudes of the fast phases to about one-third of the total P-700 signal. Addition of both 3 mM MgCl₂ and 200 mM sorbitol increased the relative amplitude of the 20 μs phase to 70%. The interaction between P-700 and plastocyanin is concluded to be favoured by a low internal volume of the thylakoids and compensation of surface charges of the membrane.

The half-time of 20 μs was not changed when the amplitude of this phase was altered either by salt and sorbitol, or by inhibition of plastocyanin. This is evidence for the existence of a complex between plastocyanin and P-700 with a lifetime long compared to the measuring time. The 200 μs phase exhibited changes in its half-time that indicated the participation of a more mobile pool of plastocyanin.

Cytochrome f was oxidized with a biphasic time course with half-times of 70–130 μs and 440–860 μs at different salt and sorbitol concentrations. The half-time of the faster phase and a short lag of 30–50 μs in the beginning of the kinetics indicate an oxidation of cytochrome f via the 20 μs electron transfer to P-700. An inhibition of this oxidation by MgCl₂ suggests that the electron transfer from cytochrome f to complexed plastocyanin is not controlled by negative charges in contrast to that from plastocyanin to P-700.     

Reactions of plastocyanin and cytochrome 553 with Photosystem I of Scenedesmus

Chloroplast material active in photosynthetic electron transport has been isolated from Scenedesmus acutus (strain 270/3a). During homogenization, part of cytochrome 553 was solubilized, and part of it remained firmly bound to the membrane. A direct correlation between membrane cytochrome 553 and electron transport rates could not be found. Sonification removes plastocyanin, but leaves bound cytochrome 553 in the membrane. Photooxidation of the latter is dependent on added plastocyanin. In contrast to higher plant chloroplasts, added soluble cytochrome 553 was photooxidized by 707 nm light without plastocyanin present. Reduced plastocyanin or cytochrome 553 stimulated electron transport by Photosystem I when supplied together or separately. These reactions and cytochrome 553 photooxidation were not sensitive to preincubation of chloroplasts with KCN, indicating that both redox proteins can donate their electrons directly to the Photosystem I reaction center. Scenedesmus cytochrome 553 was about as active as plastocyanin from the same alga, whereas the corresponding protein from the alga Bumilleriopsis was without effect on electron transport rates.

It is suggested that besides the reaction sequence cytochrome 553 → plastocyanin → Photosystem I reaction center, a second pathway cytochrome 553 → Photosystem I reaction center may operate additionally.     

Electron transfer components of wild-type and photosynthetic mutant strains of Scenedesmus obliquus D3

To investigate the possible alteration of various components of the photosynthetic electron transport system of certain mutants of Scenedesmus techniques were developed for their extraction and purification from whole cells of this alga. The components identified in the normal alga were cytochrome c 549, cytochrome b 562, a cytochrome c 551, flavoprotein-ferredoxin reductase, plastocyanin, cytochrome c 552, and ferredoxin. Lamellar-bound cytochrome c 552 and cytochromes b were also detected. Application of the extraction and purification techniques to two photosynthetic mutants revealed that Mutants 26 and 50 lacked cytochrome f in both the bound and soluble forms (Mutant 50) or in only the bound form (Mutant 26). Chloroplasts prepared from either of these mutants lacked Hill reaction activity with a variety of oxidants with water as the electron donor but photoreduced NADP⁺ with 2,6-dichlorophenolindophenol and ascorbate as the electron donor system. No photophosphorylation in vivo was detected with either mutant, but isolated chloroplasts performed a cyclic photophosphorylation with phenazine methosulphate as cofactor. Fluorescence analysis revealed that both mutants possess a measurable Photosystem II activity.

It was concluded that the loss of cytochrome f prevents the normal flow of electrons from Photosystem II to NADP and also to a variety of other Hill reaction oxidants. Furthermore, cytochrome f is not required for the reduction of NADP with electron donor systems other than water nor is it an essential component of the mechanism of cyclic photophosphorylation with phenazine methosulphate as cofactor.     

Concentration-dependent effects of salicylaldoxime on chloroplast reactions

Salicylaldoxime has been found to have a variety of concentration-dependent effects on chloroplast activities. At low concentrations (< 10 mM), salicylaldoxime reversibly inhibits all reactions which involve Photosystem II. Since the DCMU-insensitive silicomolybdate Hill reaction is also inhibited, one site of inhibition is definitely located before the DCMU-sensitive site, possibly before the photoact. The inhibition kinetics and the response of chloroplast fluorescence may indicate another site in the DCMU-sensitive region. At almost exactly the same concentrations (< 10 mM), salicylaldoxime uncouples phosphorylation reversibly, whether it is supported by Photosystem II or by Photosystem I. At higher concentrations (approx. 20 mM) salicylaldoxime inhibits Photosystem II irreversibly, uncouples irreversibly, and begins to cause changes in chloroplast light scattering which could be manifestations of membrane damage. At very high concentrations (approx. 45 mM) salicylaldoxime irreversibly inhibits Photosystem I activity in the region of plastocyanin. This is indicated by the ability of salicylaldoxime to inhibit the photooxidation of cytochrome f but not the photooxidation of P-700.     

The plastocyanin binding domain of photosystem I.

The molecular recognition between plastocyanin and photosystem I was studied. Photosystem I and plastocyanin can be cross-linked to an active electron transfer complex. Immunoblots and mass spectrometric analysis of proteolytic peptides indicate that the two negative patches conserved in plant plastocyanins are cross-linked with lysine residues of a domain near the N-terminus of the PsaF subunit of photosystem I. Conversion of these negative to uncharged patches of plastocyanin by site-directed mutation D42N/E43Q/D44N/E45Q and E59Q/E60Q/D61N respectively, reveals the first patch to be essential for the electrostatic interaction in the electron transfer complex with photosystem I and the second one to lower the redox potential. The domain in PsaF, not found in cyanobacteria, is predicted to fold into two amphipathic alpha-helices. The interacting N-terminal helix lines up six lysines on one side which may guide a fast one-dimensional diffusion of plastocyanin and provide the electrostatic attraction at the attachment site, in addition to the hydrophobic interaction in the area where the electron is transferred to P700 in the reaction center of photosystem I. This two-step interaction is likely to increase the electron transfer rate by more than two orders of magnitude in plants as compared with cyanobacteria. Our data resolve the controversy about the function of PsaF.     

The oxidation—reduction potential of membrane-bound chloroplast plastocyanin and cytochrome f

The in situ oxidation—reduction potentials of plastocyanin and cytochrome f have been measured in the same preparation of spinach chloroplasts using electron paramagnetic resonance spectroscopy and dual-wavelength absorbance spectroscopy, respectively. A midpoint potential of 340 mV (n = 1.0) at pH 7.8 was found for the bound plastocyanin and a value of 385 mV (n = 1.0) was found for the bound cytochrome f.     

The site of KCN inhibition in the photosynthetic electron transport pathway

Treatment of chloroplasts with high concentrations of KCN inhibits reactions which involve Photosystem I (e.g. electron transport from water or diaminodurene to methylviologen), but not those assumed to by-pass Photosystem I (e.g. electron transport from water to quinonediimides). The spectrophotometric experiments described in this paper showed that KCN inhibits the oxidation of cytochrome f by far-red light without blocking its reduction by red light. Both optical and EPR experiments indicated that KCN does not inhibit the photooxidation of P700 but markedly slows down the subsequent dark decay (reduction). Reduction of P700 by Photosystem II is prevented by KCN. It is concluded that KCN blocks electron transfer between cytochrome f and P700, i.e. the reaction step which is believed to be mediated by plastocyanin. In KCN-poisoned chloroplasts the slow dark reduction of P700 following photooxidation is greatly accelerated by reduced 2,6-dichlorophenolindophenol or by reduced N-methylphenazonium methosulfate (PMS), but not by diaminodurene. It appears that the reduced indophenol dye and reduced PMS are capable of donating electrons directly to P700, at least partially by-passing the KCN block.     

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     

On the site of action of plastocyanin in isolated chloroplasts

Adding plastocyanin to plastocyanin-depleted chloroplast particles, restored both their ability to catalyse the photoinduced electron transfer from ascorbate-DCIP to NADP, and to induce the photooxidation of cytochrome f. It is concluded, therefore, that plastocyanin mediates the photoinduced oxidation of cytochrome f, as previously suggested.     

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.     

The role of individual lysine residues in the basic patch on turnip cytochrome f for electrostatic interactions with plastocyanin in vitro.

The role of electrostatic interactions in determining the rate of electron transfer between cytochrome f and plastocyanin has been examined in vitro with mutants of turnip cytochrome f and mutants of pea and spinach plastocyanins. Mutation of lysine residues Lys58, Lys65 and Lys187 of cytochrome f to neutral or acidic residues resulted in decreased binding constants and decreased rates of electron transfer to wild-type pea plastocyanin. Interaction of the cytochrome f mutant K187E with the pea plastocyanin mutant D51K gave a further decrease in electron transfer rate, indicating that a complementary charge pair at these positions could not compensate for the decreased overall charge on the proteins. Similar results were obtained with the interaction of the cytochrome f mutant K187E with single, double and triple mutants of residues in the acidic patches of spinach plastocyanin. These results suggest that the lysine residues of the basic patch on cytochrome f are predominantly involved in long-range electrostatic interactions with plastocyanin. However, analysis of the data using thermodynamic cycles provided evidence for the interaction of Lys187 of cytochrome f with Asp51, Asp42 and Glu43 of plastocyanin in the complex, in agreement with a structural model of a cytochrome f-plastocyanin complex determined by NMR.     

Isolation and properties of plastocyanin from Anabaena variabilis

Plastocyanin is a copper protein found in photosynethetic tissue and it exhibits the properties of a physiological redox reagent. This protein has been purified from the blue-green alga Anabaena variabilis. Plastocyanin is required for a number of partial reactions of the photosynthetic electron transfer chain. These reactions include the transfer of electrons from reduced 2,3′,6-trichlorophenolindophenol,N,N,N′,N′- tetramethyl-p-phenylenediamine and 2,3,5,6-tetramethyl-p-phenylenediamine to low potential oxidants. Reduced cytochrome c photooxidation does not appear to be dependent on plastocyanin. Cytochrome f, isolated from this alga, will partially replace plastocyanin in many of these reations. Inhibition of photosynthetic reactions by copper chelators appears to occur at some site other than the site of plastocyanin function.     

Genetic variation in soybean photosynthetic electron transport capacity is related to plastocyanin concentration in the chloroplast

Fifteen ancestral genotypes of United States soybean cultivars were screened for differences in photosynthetic electron transport capacity using isolated thylakoid membranes. Plants were grown in controlled environment chambers under high or low irradiance conditions. Thylakoid membranes were isolated from mature leaves. Photosynthetic electron transport was assayed as uncoupled Hill activity using 2,6-dichlorophenolindophenol (DCIP). Soybean electron transport activity was dependent on genotype and growth irradiance and ranged from 6 to 91 mmol DCIP reduced [mol chlorophyll]^–1 s^–1. Soybean plastocyanin pool size ranged from 0.1 to 1.3 mol plastocyanin [mol Photosystem I]^–1. In contrast, barley and spinach electron transport activities were 140 and 170 mmol DCIP reduced [mol chlorophyll]^–1 s^–1, respectively, with plastocyanin pool sizes of 3 to 4 mol plastocyanin [mol Photosystem I]^–1. No significant differences in the concentrations of Photosystem II, plastoquinone, cytochrome b₆f complexes, or Photosystem I were observed. Thus, genetic differences in electron transport activity were correlated with plastocyanin pool size. The results suggested that plastocyanin pool size can vary significantly and may limit photosynthetic electron transport capacity in certain species such as soybean. Soybean plastocyanin consisted of two isoforms with apparent molecular masses of 14 and 11 kDa, whereas barley and spinach plastocyanins each consisted of single polypeptides of 8 and 12 kDa, respectively.Abbreviations DAP days after planting - DCIP 2,6-dichlorophenolindophenol - LiDS lithium dodecyl sulfate - PPFD photosynthetic photon flux density (mol photons m^–2 s^–1) - PS I Photosystem I - PS II Photosystem II - P700 reaction center of Photosystem I The US Government right to retain a non-exclusive, royalty free licence in and to any copyright is acknowledged.     

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)     

Photochemical systems in mesophyll and bundle sheath chloroplasts of C4 plants

1. The agranal bundle sheath chloroplasts of Sorghum bicolor possess very low Photosystem II activity compared with the grana-containing mesophyll chloroplasts.

2. Sorghum mesophyll chloroplasts have a chlorophyll (chl) and carotenoid composition similar to that of spinach chloroplasts. In contrast, the sorghum bundle sheath chloroplasts have a higher chl a/chl b ratio; they are enriched in β-carotene and contain relatively less xanthophylls as compared to sorghum mesophyll or spinach chloroplasts.

3. Sorghum mesophyll chloroplasts with 1 cytochrome f, 2 cytochrome b₆ and 2 cytochrome b-559 per 430 chlorophylls have a cytochrome composition similar to spinach chloroplasts. Sorghum bundle sheath chloroplasts contain cytochrome f and cytochrome b₆ in the same molar ratios as for the mesophyll chloroplasts, but cytochrome b-559 is barely detectable.

4. The chl/P700 ratios of mesophyll chloroplasts of S. bicolor and mesophyll and bundle sheath chloroplasts of Atriplex spongiosa are similar to that of spinach chloroplasts suggesting that these chloroplasts possess an identical photosynthetic unit size to that of spinach. The agranal bundle sheath chloroplasts of S. bicolor possess a photosynthetic unit which contains only about half as many chlorophyll molecules per P700 as found in the grana-containing chloroplasts.

5. The similarity of the composition of the bundle sheath chloroplasts of S. bicolor with that of the Photosystem I subchloroplast fragments, together with their smaller photosynthetic unit and low Photosystem II activities suggests that these chloroplasts are highly deficient in the pigment assemblies of Photosystem II.     

Photooxidation of cytochrome b-559 in leaves and chloroplasts at room temperature

1. Light-induced absorbance changes of cytochrome b-559 and cytochrome f in the -band region were examined in leaves and in isolated chloroplasts.

2. Absorbance changes of cytochrome b-559 were not detected in untreated leaves or in most preparations of isolated chloroplasts. After treatment of leaves or chloroplasts with carbonyl cyanide m-chlorophenylhydrazone, high rates of photooxidation of cytochrome b-559 were obtained, both in far-red (>700 nm) and red actinic light. Cytochrome f was photooxidized in far-red light, but in red light it remained mainly in the reduced state. The initial rates of photooxidation of cytochrome b-559 in leaves or chloroplasts treated with carbonyl cyanide m-chlorophenylhydrazone were considerably decreased by 3-(3′,4′-dichlorophenyl)-1,1-dimethyl urea.

3. A slow photoreduction of cytochrome b-559 was observed in aged mutant pea chloroplasts in red light.

4. The results do not support the view that cytochrome b-559 is a component of the electron transport chain between the light reactions. It is suggested that cytochrome b-559 is located on a side path from Photosystem II, but with a possible additional link to Photosystem I.     

Studies on well-coupled Photosystem I-enriched subchloroplast vesicles — characteristics and reinterpretation of single-turnover cyclic electron transfer

The contributions of ferredoxin, P-700, plastocyanin and the cytochromes c-554, and b-563 to single-turnover electron transfer in Photosystem (PS) I-enriched subchloroplast vesicles were deconvoluted by fitting the literature-derived spectra of these components to the observed absorption data at a series of wavelengths, according to a linear least-squares method. The obtained corresponding residuals showed that the applied component spectra were satisfactory. The deconvoluted signals of cytochromes c-554 and b-563 differed in some cases significantly from the classical dual-wavelength signals recording at 554–545 nm and 563–575 (or −572) nm, due to interference from other electron-transferring components. KCN, DNP-INT (2-iodo-6-isopropyl-3-methyl-2′,4,4′-trinitrodiphenyl ether), DBMIB (2,5-dibromo-3-methyl-6-isopropyl-p-benzo-quinone) and antimycin A all inhibited electron transfer, although antimycin and DBMIB inhibited only after a few turnovers of the cytochrome bf complex. Fast flash-induced reduction of cytochrome b-563 exclusively reflected oxidant-induced reduction. Fast electron flow from cytochrome c-554 to plastocyanin and P-700 resulted in an apparent rereduction of cytochrome c-554 that was slower than the reduction of cytochrome b-563. Model simulations indicate that under highly oxidizing conditions for the Rieske FeS centre and reducing conditions for cytochrome b-563, the semiquinone at the Q_z site cannot only reduce cytochrome b-563, but can also oxidize cytochrome b-563 and reduce the Rieske FeS centre. The effect of 10 μM gramicidin D was evaluated in order to determine the contributions by electrochromic absorption changes around 518 nm. Gramicidin left electron transfer, monitored in the 550–600 nm range, unchanged. The gramicidin-sensitive (membrane potential-associated) signal at 518 nm differed from the signals recorded in the absence of gramicidin at 518 nm or 518–545 nm, due to spectral interference from electron-transferring components in the latter signals. KCN, DBMIB and antimycin A affected both the fast and slow components of the electrochromic signal, but did not proportionally affect the initial electron transfer from P-700 to ferredoxin (charge separation in PS I). Not only the slow (10–100 ms) component of the 518 nm absorption change, but also part of the fast (less than 1 ms) component appears to minitor electrogenic events in the cytochrome bf complex.     

Laser-induced reactions of P700 and cytochrome f in a blue-green alga, Plectonema boryanum

Kinetics of the absorption change of P700 (blue band) and cytochrome f in whole cells of a blue-green alga, Plectonema boryanum, have been studied by Q-switched ruby-laser flash excitation (694 nm; approx. 20 nsec) to elucidate the sequential relationship of these two components in photosynthetic electron transport. “P700” was photooxidized within 2 μsec and recovered in two phases t_1/2 10 μsec and 200 μsec). Under the same conditions cytochrome f was oxidized with a half time of 15 μsec. The magnitude of the fast phase of “P700” recovery, however, diminished at lower laser intensity while the cytochrome f change remained unaffected. The result suggests that cytochrome f and P700 may not be on the same electron-transport chain.