Electron donation to photosystem I

Electron donation to photosystem I was studied in highly resolved particles from spinach. Divalent cations increased the efficiency of electron donation from spinach plastocyanin to P700⁺ through a decrease in the apparent K_m for plastocyanin. Cytochrome f was not an efficient electron donor for P700⁺ in the presence or absence of divalent cations. Cytochrome f photooxidation could be observed in the presence of both plastocyanin and divalent cations.     

Effect of trypsin treatment of photosystem I particles on the electron donation to p700

Proteolysis of photosystem I particles had no effect on P700 oxidation but did inhibit the rate of P700⁺ reduction. The V_max values were decreased for both dichlorophenol and plastocyanin, but the K_m values were unaffected indicating that trypsin treatment altered electron transfer rather than the binding of the donor to the photosystem I complex. The salt dependence of P700⁺ reduction was unaffected. The effects of P700⁺ reduction were the same for the preparations of different workers (Shiozawa, Alberte, Thornber 1974 Arch Biochem Biophys 165: 388; and Bengis, Nelson 1975 J Biol Chem 250: 2783).

In both cases, the 70-kilodalton, chlorophyll-containing polypeptide was digested confirming its role in transferring electrons from plastocyanin to P700. The fact that the preparation of Shiozawa et al. lacks subunit (III) but still used plastocyanin as the electron donor rules out a role for this subunit as “the plastocyanin binding protein.” Subunit III was also digested in the Bengis and Nelson preparation.

     

Kinetic analysis of P-700 photoconversion: Effect of secondary electron donation and plastocyanin inhibition

The kinetics of P-700 photoconversion under weak continuous actinic illumination were quantitatively analyzed to provide information on the relative absorption cross-section σ_PSI of the light-harvesting pigments associated with photosystem I and on the number of electrons stored between the two photosystems in dark-adapted chloroplasts. The theory of chemical kinetics for a system of monomolecular consecutive first-order reactions is reviewed briefly to provide support for the experimental approach taken. A complete inhibition of plastocyanin by cyanide eliminated all secondary electron donation to P-700⁺ and allowed the registration of the exponential (monomolecular) P-700 photoconversion at room temperature. The rate constant K_p-700 of the exponential kinetics was independent of the ionic (± Mg²⁺) and osmotic (± sucrose) strength of the chloroplast suspension medium, and of the oxidation-reduction state of photosystem II. The extent of plastocyanin inhibition in partially inhibited samples was greater under low ionic and low osmotic conditions. In dark-adapted chloroplast samples that were not cyanide treated, the number of electrons stored between the two photosystems was 3.9 ± 0.2 and independent of divalent cations. It is concluded that plastocyanin inhibition by cyanide is favored under low ionic and low osmotic conditions. The Mg²⁺ ion and redox state of photosystem II-independent photoconversion of P-700 does not support significant changes in the spillover of excitation from photosystem II to photosystem I in isolated chloroplasts.     

On the functional organization of electron transport from plastoquinone to Photosystem I

Signal I, the EPR signal of P-700, induced by long flashes as well as the rate of linear electron transport are investigated at partial inhibition of electron transport in chloroplasts. Inhibition of plastoquinol oxidation by dibromothymoquinone and bathophenanthroline, inhibition of plastocyanin by KCN and HgCl₂, and inhibition by 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide are used to study a possible electron exchange between electron-transport chains after plastoquinone. (1) At partial inhibition of plastocyanin the reduction kinetics of P-700⁺ show a fast component comparable to that in control chloroplasts and a new slow component. The slow component indicates P-700⁺ which is not accessible to residual active plastocyanin under these conditions. We conclude that P-700 is reduced via complexed plastocyanin. (2) The rate of linear electron transport at continuous illumination decreases immediately when increasing amounts of plastocyanin are inhibited by KCN incubation. This is not consistent with an oxidation of cytochrome f by a mobile pool of plastocyanin with respect to the reaction rates of plastocyanin being more than an order of magnitude faster than the rate-limiting step of linear electron transport. It is evidence for a complex between the cytochrome b₆ - f complex and plastocyanin. The number of these complexes with active plastocyanin is concluded to control the rate-limiting plastoquinol oxidation. (3) Partial inhibition of the electron transfer between plastoquinone and cytochrome f by dibromothymoquinone and bathophenanthroline causes decelerated monophasic reduction of total P-700⁺. The P-700 kinetics indicate an electron transfer from the cytochrome b₆ - f complex to more than ten Photosystem I reaction center complexes. This cooperation is concluded to occur by lateral diffusion of both complexes in the membrane. (4) The proposed functional organization of electron transport from plastoquinone to P-700 in situ is supported by further kinetic details and is discussed in terms of the spatial distribution of the electron carriers in the thylakoid membrane.     

Functional effects of chemical modification of unstacked and stacked chloroplasts with glutaraldehyde.

Although glutaraldehyde alkylates protein NH₂ groups to the same extent in unstacked and stacked thylakoids, the photosynthetic electron transport of the stacked membranes is always more inhibited. Inhibition of photosystem II electron transport, measured in the presence of lipophilic Hill oxidants, is 20–30% in unstacked and 60–70% in stacked thylakoids. Photosystem I electron transport is nearly completely inhibited in both preparations, but in the case of stacked thylakoids maximal inhibition occurs at a lower glutaraldehyde level than in unstacked thylakoids. In contrast, the photooxidation of the reaction center chromophore of photosystem I (P700) is unaffected by the glutaraldehyde treatment of either stacked or unstacked chloroplasts. The results are discussed with regard to the accessibility of membrane sites to exogenous electron transport cofactors, in view of the observation that N-methylphenazonium methosulfate, a quencher of electronically excited chlorophyll a, partitions more easily into the pigment domains of the glutaraldehyde-fixed unstacked thylakoids.     

In vivo electron donation from plastocyanin and cytochrome c6 to PSI in Synechocystis sp. PCC6803

Many cyanobacteria species can use both plastocyanin and cytochrome c₆ as lumenal electron carriers to shuttle electrons from the cytochrome b₆f to either photosystem I or the respiratory cytochrome c oxidase. In Synechocystis sp. PCC6803 placed in darkness, about 60% of the active PSI centres are bound to a reduced electron donor which is responsible for the fast re-reduction of P₇₀₀ in vivo after a single charge separation. Here, we show that both cytochrome c₆ and plastocyanin can bind to PSI in the dark and participate to the fast phase of P₇₀₀ reduction, but the fraction of pre-bound PSI is smaller in the case of cytochrome c₆ than with plastocyanin. Because of the inter-connection of respiration and photosynthesis in cyanobacteria, the inhibition of the cytochrome c oxidase results in the over-reduction of the photosynthetic electron transfer chain in the dark that translates into a lag in the kinetics of P₇₀₀ oxidation at the onset of light. We show that this is true both with plastocyanin and cytochrome c₆, indicating that the partitioning of electron transport between respiration and photosynthesis is regulated in the same way independently of which of the two lumenal electron carriers is present, although the mechanisms of such regulation are yet to be understood.     

Effects of O(2) and CO(2) Concentrations on Quantum Yields of Photosystems I and II in Tobacco Leaf Tissue

The interactive effects of irradiance and O₂ and CO₂ levels on the quantum yields of photosystems I and II have been studied under steady-state conditions at 25°C in leaf tissue of tobacco (Nicotiana tabacum). Assessment of radiant energy utilization in photosystem II was based on changes in chlorophyll fluorescence yield excited by a weak measuring beam of modulated red light. Independent estimates of photosystem I quantum yield were based on the light-dark in vivo absorbance change at 830 nanometers, the absorption band of P700⁺. Normal (i.e. 20.5%, v/v) levels of O₂ generally enhanced photosystem II quantum yield relative to that measured under 1.6% O₂ as the irradiance approached saturation. Photorespiration is suspected to mediate such positive effects of O₂ through increases in the availability of CO₂ and recycling of orthophosphate. Conversely, at low intercellular CO₂ concentrations, 41.2% O₂ was associated with lower photosystem II quantum yield compared with that observed at 20.5% O₂. Inhibitory effects of 41.2% O₂ may occur in response to negative feedback on photosystem II arising from a build-up in the thylakoid proton gradient during electron transport to O₂. Covariation between quantum yields of photosystems I and II was not affected by concentrations of either O₂ or CO₂. The dependence of quantum yield of electron transport to CO₂ measured by gas exchange upon photosystem II quantum yield as determined by fluorescence was unaffected by CO₂ concentration.     

Kinetics of photosystem II electron transport: a mathematical analysis based on chlorophyll fluorescence induction

The OJDIP rise in chlorophyll fluorescence during induction at different light intensities was mathematically modeled using 24 master equations describing electron transport through photosystem II (PSII) plus ordinary differential equations for electron budgets in plastoquinone, cytochrome f, plastocyanin, photosystem I, and ferredoxin. A novel feature of the model is consideration of electron in- and outflow budgets resulting in changes in redox states of Tyrosine Z, P680, and Q_A as sole bases for changes in fluorescence yield during the transient. Ad hoc contributions by transmembrane electric fields, protein conformational changes, or other putative quenching species were unnecessary to account for primary features of the phenomenon, except a peculiar slowdown of intra-PSII electron transport during induction at low light intensities. The lower than F _m post-flash fluorescence yield F _f was related to oxidized tyrosine Z. The transient J peak was associated with equal rates of electron arrival to and departure from Q_A and requires that electron transfer from Q_A ^? to Q_B be slower than that from Q_A ^? to Q_B ^?. Strong quenching by oxidized P680 caused the dip D. Reduced plastoquinone, a competitive product inhibitor of PSII, blocked electron transport proportionally with its concentration. Electron transport rate indicated by fluorescence quenching was faster than the rate indicated by O₂ evolution, because oxidized donor side carriers quench fluorescence but do not transport electrons. The thermal phase of the fluorescence rise beyond the J phase was caused by a progressive increase in the fraction of PSII with reduced Q_A and reduced donor side.     

Reduction of photosystem I reaction center, P-700, by plastocyanin in stroma thylakoids from spinach: Lateral diffusion of plastocyanin

The reduction kinetics of the photooxidized photosystem I reaction center (P-700⁺) by plastocyanin was studied in the stroma thylakoids prepared by the Yeda press treatment. The kinetics of the P-700⁺ reduction after flash excitation were biphasic and separated into two independent first-order reactions, the fast phase with a half-time of about 4 ms and the slow phase with a half-time of about 18 ms. Only the fast phase of the P-700⁺ reduction was sensitive to KCN and glutaraldehyde treatments of the thylakoids which block the plastocyanin site in the photosynthetic electron flow indicating that the fast phase is mediated by plastocyanin. However, the content of plastocyanin in the stroma thylakoids used was greatly decreased by the Yeda press treatment to only half that of P-700⁺ reduced in the fast phase. This indicates that one plastocyanin molecule turns over more than once in the single turnover of P-700⁺ rather than forming a fixed complex with P-700. On the other hand, the slow phase was not affected by KCN or glutaraldehyde treatment and its apparent rate constant linearly depended on the concentration of reduced dichlorophenolindophenol. These results indicate that the slow phase shows direct reduction of P-700⁺ by dichlorophenolindophenol. A second-order rate constant of 3.96 × 10⁵m^?1 s^?1 was obtained for the slow phase at pH 7.6, 25 °C. Analysis of reaction kinetics in the initial portion of the fast phase indicated initial interaction between P-700⁺ and the reduced plastocyanin and gave a half-time of 0.53 ms for the bimolecular reaction. We assumed the lateral diffusion of plastocyanin on the thylakoid membrane and calculated the two-dimensional diffusion coefficient for plastocyanin from the half-time of the initial reduction of P-700⁺ as about 2 × 10^?9 cm² s^?1.     

Lumenal proteins involved in respiratory electron transport in the cyanobacterium Synechocystis sp. PCC6803

Cyanobacterial thylakoids catalyze both photosynthetic and respiratory activities. In a photosystem I-less Synechocystis sp. PCC 6803 strain, electrons generated by photosystem II appear to be utilized by cytochrome oxidase. To identify the lumenal electron carriers (plastocyanin and/or cytochromes c ₅₅₃, c ₅₅₀, and possibly c _M) that are involved in transfer of photosystem II-generated electrons to the terminal oxidase, deletion constructs for genes coding for these components were introduced into a photosystem I-less Synechocystis sp. PCC 6803 strain, and electron flow out of photosystem II was monitored in resulting strains through chlorophyll fluorescence yields. Loss of cytochrome c ₅₅₃ or plastocyanin, but not of cytochrome c ₅₅₀, decreased the rate of electron flow out of photosystem II. Surprisingly, cytochrome c _M could not be deleted in a photosystem I-less background strain, and also a double-deletion mutant lacking both plastocyanin and cytochromec ₅₅₃ could not be obtained. Cytochrome c _M has some homology with the cytochrome c-binding regions of the cytochromecaa₃ -type cytochrome oxidase from Bacillus spp. and Thermus thermophilus. We suggest that cytochrome c _M is a component of cytochrome oxidase in cyanobacteria that serves as redox intermediate between soluble electron carriers and the cytochromeaa₃ complex, and that either plastocyanin or cytochrome c ₅₅₃ can shuttle electrons from the cytochrome b_6f complex to cytochrome c _M.     

The photochemical activities and electron carriers of developing barley leaves

The development of photochemical activities in isolated barley plastids during illumination of dark-grown plants has been studied and compared with the behaviour of plastocyanin, cytochromes f, b-559_LP, b-563 and b-559_HP and pigments P546 (C550) and P700. Electron-transport activity dependent on Photosystem 1 and cyclic photophosphorylation dependent on N-methylphenazonium methosulphate (phenazine methosulphate) were very active relative to the chlorophyll content after only a few minutes of illumination of etiolated leaves, and then rapidly declined during the first few hours of greening. By contrast, Photosystem 2 activity (measured with ferricyanide as electron acceptor) and non-cyclic photophosphorylation were not detectable during the first 2½h of greening, but then increased in total amount in parallel with chlorophyll. The behaviour of the electron carriers suggested their association with either Photosystem 1 or 2 respectively. In the first group were plastocyanin, cytochrome f and cytochrome b-563, whose concentrations in the leaf did not change during greening, and cytochrome b-559_LP whose concentration fell to one-half its original value, and in the second group were cytochrome b-559_HP and pigment P546, the concentrations of which closely followed the activities of Photosystem 2. Pigment P700 could not be detected during the first hour, during which time some other form of chlorophyll may take its place in the reaction centre of Photosystem 1. The plastids started to develop grana at about the time that Photosystem 2 activity became detectable.     

Connectivity between electron transport complexes and modulation of photosystem II activity in chloroplasts

In chloroplasts, photosynthetic electron transport complexes interact with each other via the mobile electron carriers (plastoquinone and plastocyanin) which are in surplus amounts with respect to photosystem I and photosystem II (PSI and PSII), and the cytochrome b ₆ f complex. In this work, we analyze experimental data on the light-induced redox transients of photoreaction center P₇₀₀ in chloroplasts within the framework of our mathematical model. This analysis suggests that during the action of a strong actinic light, even significant attenuation of PSII [for instance, in the result of inhibition of a part of PSII complexes by DCMU or due to non-photochemical quenching (NPQ)] will not cause drastic shortage of electron flow through PSI. This can be explained by “electronic” and/or “excitonic” connectivity between different PSII units. At strong AL, the overall flux of electrons between PSII and PSI will maintain at a high level even with the attenuation of PSII activity, provided the rate-limiting step of electron transfer is beyond the stage of PQH₂ formation. Results of our study are briefly discussed in the context of NPQ-dependent mechanism of chloroplast protection against light stress.     

Cytochrome b6f – Orchestrator of photosynthetic electron transfer

Cytochrome b₆f (cytb₆f) lies at the heart of the light-dependent reactions of oxygenic photosynthesis, where it serves as a link between photosystem II (PSII) and photosystem I (PSI) through the oxidation and reduction of the electron carriers plastoquinol (PQH₂) and plastocyanin (Pc). A mechanism of electron bifurcation, known as the Q-cycle, couples electron transfer to the generation of a transmembrane proton gradient for ATP synthesis. Cytb₆f catalyses the rate-limiting step in linear electron transfer (LET), is pivotal for cyclic electron transfer (CET) and plays a key role as a redox-sensing hub involved in the regulation of light-harvesting, electron transfer and photosynthetic gene expression. Together, these characteristics make cytb₆f a judicious target for genetic manipulation to enhance photosynthetic yield, a strategy which already shows promise. In this review we will outline the structure and function of cytb₆f with a particular focus on new insights provided by the recent high-resolution map of the complex from Spinach.     

Comparison of photosynthetic activities of spinach chloroplasts with those of corn mesophyll and corn bundle sheath tissue

Bundle sheath and mesophyll chloroplasts from Zea mays showed comparable rates of O₂ evolution, which amounted to about half of the rate observed in spinach (Spinacia oleracea) chloroplasts.

Ratios of 4.5, 4.6, and 6.2 Mn²⁺ atoms per 400 chlorophylls were observed in mesophyll, bundle sheath, and spinach chloroplasts, respectively. These ratios roughly correspond to the observed O₂ evolution rates.

Rates of electron transport from water to methylviologen (photosystem I and II) in both types of corn chloroplasts were about one-third that in spinach. Compared to spinach, transport rates from reduced diaminodurene to methylviologen (photosystem I) were about one-third and greater than one-half in mesophyll and bundle sheath material, respectively.

In both types of corn chloroplasts, electron flow from photosystem II to P700 was abnormal. This observation, together with the low rates of all activities, suggests that damage occurred during isolation. Such damage may limit the quantitative significance of observations made with these materials (including the following data).

Measurements of flash yields of O₂ evolution or O₂ uptake showed that the size of the photosynthetic unit was the same in photosystems I and II and in all three types of chloroplasts (about 400 chlorophylls per equivalent).

Similarity of the photochemical cross-section of the two photosystems in the three preparations was also found in optical experiments: that is the half-times of the fluorescence rise in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) (photosystem II) and of the photooxidation of P700 (photosystem I).

The ratio of P700 to chlorophyll appeared to be about 2-fold higher in bundle sheath chloroplasts than in the other materials (1/200 versus 1/400).

     

Biosynthesis of P700-Chlorophyll a Protein Complex, Plastocyanin, and Cytochrome b(6)/f Complex

Changes in the amount of P700-chlorophyll a protein complex, plastocyanin, and cytochrome b₆/f complex during greening of pea (Pisum sativum L.), wheat (Triticum aestivum L.), and barley (Hordeum vulgare L.) leaves were analyzed by an immunochemical quantification method. Neither subunit I nor II of P700-chlorophyll a protein complex could be detected in the etiolated seedlings of all three plants and the accumulation of these subunits was shown to be light dependent. On the other hand, a small amount of plastocyanin was present in the etiolated seedlings of all three plants and its level increased about 30-fold during the subsequent 72-hour greening period. Furthermore, cytochrome f, cytochrome b₆, and Rieske Fe-S center protein in cytochrome b₆/f complex were also present in the etiolated seedings of all three plants. The level of each subunit component increased differently during greening and their induction pattern differed from species to species. The accumulation of cytochrome b₆/f complex was most profoundly affected by light in pea leaves, and the levels of cytochrome f, cytochrome b₆, and Rieske Fe-S center protein increased during greening about 10-, 20-, and more than 30-fold, respectively. In comparison to the case of pea seedlings, in wheat and barley leaves the level of each subunit component increased much less markedly. The results suggest that light regulates the accumulation of not only the chlorophyll protein complex but also the components of the electron transport systems.     

Electron Transport Reactions in Grana Preparations from Spinach Chloroplasts

Fraction 2 (grana-stack) particles prepared with the French press showed absorbance changes, at room temperature and with sodium ascorbate and methyl-viologen, that were produced by the oxidation of cytochrome b-559. This oxidation was inhibited by 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) and sensitized by system II of photosynthesis. The oxidation is too slow to account for the rates of the Hill reaction that have been observed with nicotinamide-adenine dinucleotide phosphate (NADP⁺). It appears that this cytochrome is not functioning in the main pathway of electron transport. In the presence of 2,3,5,6-tetramethyl-p-phenylene-diamine (DAD) and ascorbate, light-induced oxidation of cytochrome f took place within 3 msec (or faster) in the grana-stack particles. Treatment with the detergent Triton X-100 disrupted this rapid cytochrome f oxidation as well as the oxidation of cytochrome b-559. Subsequent plastocyanin addition did not restore the rapid oxidation of cytochrome f (nor of cytochrome b-559) but only slow changes of cytochrome f. In view of the fact that these particles contain almost no plastocyanin, it is unlikely that plastocyanin functions in electron transport between cytochrome f and P-700 in the particles derived from the grana-stack regions of the chloroplast.     

Effect of light quality on the organization of photosynthetic electron transport chain of pea seedlings

The activity of NADP and O₂ photoreduction by water is essentially higher in chloroplasts isolated from pea seedlings (Pisum sativum L.) grown under blue light as compared with that from plants grown under red light. In contrast, the photoreduction of NADP and O₂ with photosystem I only is practically the same or even lower in chloroplasts isolated from plants grown under blue light. The addition of plastocyanin does not affect the rate or the extent of NADP photoreduction by water in the chloroplasts isolated from plants grown under blue light, whereas it sharply activates NADP reduction in the chloroplasts isolated from plants grown under red light. The extent of the light-induced oxidation of cytochrome f is appreciably higher in chloroplasts isolated from plants grown under blue light. Cytochrome b₅₅₉ plays the predominant role in the oxidoreductive reactions of these chloroplasts. Furthermore, the fluorescence measurements indicate more effective transfer of excitation energy from chlorophyll to the photosystem II reaction center in chloroplasts isolated from plants grown under blue light.     

Rate-Limiting Steps of Electron Transport in Chloroplasts during Ontogeny and Senescence of Barley

Partial photochemical activities and concentrations of electron carriers were measured relative to chlorophyll in barley (Hordeum vulgare L.) thylakoids, isolated from primary leaves during ontogeny and senescence. Thylakoids from mature leaves generated somewhat higher quantum efficiencies than thylakoids from premature or senescing leaves; this phenomenon did not appear to be caused by any deficiency of water-splitting enzyme. Under conditions of saturating light, the noncyclic electron flux from water to the reducing side of photosystem I increased during leaf ontogeny, peaked at maturity, and declined during senescence. However, electron fluxes appeared to be limited at different steps before and after leaf maturity. Before leaf maturity, the rate-limiting step was located prior to the reoxidation of plastohydroquinone. After leaf maturity, the decline in noncyclic electron flux correlated with a decrease in the concentration of cytochromes f and b₆. This correlation, together with a consideration of mechanisms of entry and exit of electrons in 3-(3,4-dichlorophenyl)-1,1-dimethylurea-treated thylakoids, suggests that the cytochrome f/b₆-containing complex, and not plastocyanin or P700, is the site of entry of electrons from the reduced forms of 2,6-dichlorophenolindophenol and diaminodurene. It is therefore proposed that in senescing leaves the cytochrome f/b₆-containing complex limited electron transport by constraining the rate of reduction of cytochrome f by plastohydroquinone.     

Quantitation of the rapid electron donors to P700, the functional plastoquinone pool, and the ratio of the photosystems in spinach chloroplasts

Recent studies of chloroplast architecture have emphasized the segregation of photosystem I and photosystem II in different regions of the lamellar membrane. The apparent localization of photosystem II reaction centers in regions of membrane appression and of photosystem I reaction centers in regions exposed to the chloroplast stroma has focused attention on the intervening electron carriers, carriers which must be present to catalyze electron transfer between such spatially separated reaction sites. Information regarding the stoichiometries of these intermediate carriers is essential to an understanding of the processes that work together to establish the mechanism and to determine the rate of the overall process. We have reinvestigated the numbers of photosystem I and photosystem II reaction centers, the numbers of intervening cytochrome b6/f complexes, and the numbers of molecules of the relatively mobile electron carriers plastoquinone and plastocyanin that are actively involved in electron transfer. Our investigations were based on a new experimental technique made possible by the use of a modified indophenol dye, methyl purple, the reduction of which provides a particularly sensitive and accurate measure of electron transfer. Using this dye, which accepts electrons exclusively from photosystem I, it was possible to drain electrons from each of the carriers. Thus, by manipulation of the redox condition of the various carriers and through the use of specific inhibitors we could measure the electron storage capacity of each carrier in turn. We conclude that the ratio of photosystem I reaction centers to cytochrome b6/f complexes to photosystem II reaction centers is very nearly 1:1:1. The pool of rapid donors of electrons to P700 includes not only the 2 reducing equivalents stored in the cytochrome b6/f complex but also those stored in slightly more than 2 molecules of plastocyanin per P700. More slowly available are the electrons from about 6 plastoquinol molecules per P700.     

Cytochrome f and plastocyanin kinetics in Chlorella pyrenoidosa II. Reduction kinetics and electric field increase in the 10 ms range

On dark-adapted Chlorella, after one flash, plastocyanin (PC) undergoes reduction with a half-time of 7 ms. After 4 or 5 flashes, the reduction of PC⁺ in the 10 ms range is suppressed, and the level of oxidized plastocyanin increases during the next few flashes before reaching a stationary value. Cytochrome f exhibits approximately the same pattern.The reduction of PC⁺ and cytochrome f⁺ in the 10 ms range is correlated with an increase of the electrice field named phase b (Joliot, P. and Delosme, R., Biochim. Biophys. Acta 357 (1974) 267–284). Both need the presence of a compound R′ in the reduced state. A dark electron transfer involving a carrier of electrons across the membrane, a proton carrier, R′ as terminal reducant, PC⁺ and cytochrome f⁺ as terminal oxidants, would account for this field generation.Cooperation between the electron transfer chains is implied at the level of plastocyanin oxidation. An equilibrium constant of about 2 is observed between cytochrome f and plastocyanin before 1 ms and after 500 ms after the photochemical reactions. We observe that cytochrome f and plastocyanin are not connected from 1 to 100 ms after a photochemical reaction. The equilibrium constant between plastocyanin and P-700 remains large [20] under these conditions.