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.     

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.     

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.     

Cytochrome f and plastocyanin kinetics in Chlorella pyrenoidosa. I. Oxidation kinetics after a flash

P-700, plastocyanin and cytochrome f redox kinetics were measured after one flash, using dark-adapted Chlorella in the presence of hydroxylamine and 3(3,4-dichlorophenyl)-1,1-dimethylurea. Plastocyanin becomes increasingly oxidized with a half-time of 70 μs, then undergoes reduction with a half-time of 7 ms. Cytochrome f oxidation has a sigmoidal time-course and a half-time of 100 μs. Its reduction exhibits a half-time of 4 ms. These results are interpreted in a linear scheme:

An equilibrium constant of 2 between cytochrome f and plastocyanin (PC), which contrasts with the large equilibrium constant between PC and P-700 is computed.The presence of cytochrome b₆ in a cyclic path around Photosystem I is confirmed under these conditions.     

Flash photolysis-electron spin resonance studies of Photosystem I. A fast reduction component of P-700+

A 300 μs decay component of ESR Signal I (P-700⁺) in chloroplasts is observed following a 10 μs actinic xenon flash. This transient is inhibited by treatments which block electron transfer from Photosystem II to Photosystem I (e.g. 3-(3,4-dichlorophenyl)-1, 1-dimethylurea (DCMU), 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (DBMIB), KCN and HgCl₂). The fast transient reduction of P-700⁺ can be restored in the case of DCMU or DBMIB inhibition by addition of an electron donor couple (2,6-dichlorophenol indophenol (Cl₂Ind)/ascorbate) which supplies electrons to cytochrome f. However, this donor couple is inefficient in restoring electron transport in chloroplasts which have been inhibited with the plastocyanin inactivators, KCN and HgCl₂. Oxidation-reduction measurements reveal that the fast P-700⁺ reduction component reflects electron transfer from a component with E_m = 375±10 mV (pH = 7.5). These data suggest the assignment of the 300-μs decay kinetics to electron transfer from cytochrome f (Fe²⁺) to P-700⁺, thus confirming the recent observations of Haehnel et al. (Z. Naturforsch. 26b, 1171–1174 (1971)).     

Localization of the reaction side of plastocyanin from immunological and kinetic studies with inside-out thylakoid vesicles

(1) The effect of four active antisera against plastocyanin on Photosystem I-driven electron transport and phosphorylation was investigated in spinach chloroplasts. Partial inhibition of electron transport and stimulation of plastocyanin-dependent phosphorylation were sometimes observed after adding amounts of antibodies which were in large excess and not related to the plastocyanin content of the chloroplasts. This indicates effects of the antibodies on the membrane. (2) The antibodies against plastocyanin neither directly nor indirectly agglutinated unbroken chloroplast membranes. (3) The plastocyanin content of right-side-out and inside-out thylakoid vesicles isolated by aqueous polymer two-phase partition from chloroplasts disrupted by Yeda press treatment was determined by quantitative rocket electroimmunodiffusion. Right-side-out vesicles retained about 25%, inside-out vesicles none of the original amount of plastocyanin. (4) The effect of externally added plastocyanin on the reduction of P-700 was studied by monitoring the absorbance changes at 703 nm after a long flash. In inside-out vesicles P-700 was reduced by the added plastocyanin but not in right-side-out vesicles and class II chloroplasts. These results provide strong evidence for a function of plastocyanin at the internal side of the thylakoid membrane.     

Heterogeneity of Photosystem I reaction centers in barley leaves as related to the donation from stromal reductants

The light-response curves of P700 oxidation and time-resolved kinetics of P700⁺ dark re-reduction were studied in barley leaves using absorbance changes at 820 nm. Leaves were exposed to 45 °C and treated with either diuron or diuron plus methyl viologen (MV) to prevent linear electron flow from PS II to PSI and ferredoxin-dependent cyclic electron flow around PSI. Under those conditions, P700⁺ could accept electrons solely from soluble stromal reductants. P700 was oxidized under weak far-red light in leaves treated with diuron plus MV, while identical illumination was nearly ineffective in diuron-treated leaves in the absence of MV. When heat-exposed leaves were briefly illuminated with strong far-red light, which completely oxidized P700, the kinetics of P700⁺ dark reduction was fitted by a single exponential term with half-time of about 40 ms. However, two first-order kinetic components of electron flow to P700⁺ (fast and slow) were found after prolonged leaf irradiation. The light-induced modulation of the kinetics of P700⁺ dark reduction was reversed following dark adaptation. The fast component (half time of 80–90 ms) was 1.5 larger than the slow one (half time of about 1 s). No kinetic competition occurred between two pathways of electron donation to P700⁺ from stromal reductants. This suggests the presence of two different populations of PSI. This revised version was published online in June 2006 with corrections to the Cover Date.     

Origin of Multiphase Reduction of P700<Superscript>+</Superscript> in Broad Bean Leaves after Irradiation with Far-Red Light

The kinetic curves of dark reduction of P700⁺ (oxidized primary donor of PSI) after far-red light irradiation were studied on broad bean (Vicia faba L.) leaves treated with antimycin A, methyl viologen, or diuron. Four components of P700⁺ reduction were found in untreated leaves, namely, an ultrafast component with a half-time of 25 ms, and fast (210 ms), middle (790 ms), and slow (6100 ms) components. The fast component disappeared in leaves treated with antimycin A or methyl viologen. At the same time, these substances did not affect other components of P700⁺ reduction. Treatment of leaves with diuron abolished both the ultrafast and fast components of P700⁺ reduction. As the length of far-red light exposure was increased, a lag phase appeared in the development of middle component in leaves treated with diuron, antimycin A, or methyl viologen. In thus treated leaves, an exponential pattern of the middle component was displayed with a certain delay after darkening. A conclusion was drawn that the minor ultrafast component of P700⁺ dark reduction in broad bean leaves was caused by electron donation to PSI from PSII, whereas the fast component of this process was determined by the operation of ferredoxin-dependent electron transport around PSI. The middle and slow components were supposed to be related to electron input to PSI from reductants localized in the chloroplast stroma.From Fiziologiya Rastenii, Vol. 52, No. 4, 2005, pp. 492–498.Original English Text Copyright © 2005 by Egorova, Nikolaeva, Bukhov.The article was translated by the authors.     

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.     

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.     

Monophasic kinetics of electron donation from stromal reductants in unicellular halophytic alga Tetraselmis viridis: Relation of the function to characteristic structure of chloroplast membrane system

Redox conversions of P700, the primary donor of photosystem I (PSI), were investigated in cells of a halophytic alga Tetraselmis viridis Rouch. under irradiation with white light pulses that excite both photosystems of the chloroplast and with far-red light initiating photochemical reactions in PSI only. The P700⁺ dark reduction after irradiation with 50-ms pulse of white light comprised three kinetic components. The half-decay times and relative contributions of the fast, middle, and slow components were 38 ms (49%), 295 ms (26%), and 1690 ms (23%), respectively. The treatment with diuron, known to block electron transport between the photosystems, eliminated the middle exponential term having the half-decay time of 295 ms. After irradiation with far-red light, the kinetics of P700⁺ dark reduction comprised only two components with half-deacy times of 980 ms (72%) and 78 ms (31%). The component with a decay halftime of about 100 ms was fully inhibited after treating the cells with antimycin A, a specific inhibitor of ferredoxin-dependent cyclic electron flow around PSI. In addition, this kinetic component was strongly suppressed by methyl viologen known to inhibit this alternative pathway of electron transport. Both aforementioned reagents had no effect on the slow component of P700⁺ reduction; this component remained monophasic. Unlike higher plant chloroplasts, the chloroplasts of Tetraselmis viridis contained no stacked grana. Based on inhibitor analysis and electron microscopy data, it was concluded that the slow component of P700⁺ reduction in the cells of halophytic microalga reflects the electron donation to PSI from reductants localized in the chloroplast stroma. The monophasic kinetics of this process in the halophytic microalga, compared to the biphasic kinetic pattern in higher plants, is related to the lack of stacked grana in Tetraselmis viridis cells.     

Kinetics of electron transfer between the tetrahemic cytochrome and the special pair in isolated reaction centers of Roseobacter denitrificans

We have analyzed the rate of electron transfer between the tetrahemic cytochrome and the primary electron donor in isolated reaction centers of Roseobacter denitrificans as a function of the ambient redox potential. Three different phases are observed: a slow phase (half-time > ms), and two fast phases with half-times of 5 µs and 380 ns. The slow phase is present at high redox potential, it corresponds to the kinetics of charge recombination between the photo-oxidized primary electron acceptor P⁺ and the reduced primary acceptor (Q _A ^– ). The 5 µs phase titrates with the reduction of the highest potential heme (HP₁). This phase corresponds to the electron transfer between heme HP₁ and P⁺. At redox potentials where the second high potential heme HP₂ becomes reduced, the 5 µs phase disappears and is replaced by the 380 ns phase, which is therefore related to the electron transfer between the high potential heme HP₂ and P⁺. To explain the large difference in the rate of oxidation of HP₁ and HP₂ we propose a tentative model where the heme HP₂ is closest to P.     

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.     

Effect of temperature on the photoreduction of centres A and B in Photosystem I,and the kinetics of recombination

When spinach Photosystem I particles, frozen in the dark with ascorbate, are illuminated at low temperatures, one electron is transferred from P-700 to either iron-sulphur centre A or B. It was found that the proportion of centre A or B reduced depended on the temperature of illumination. At 25 K, reduction of centre A, as detected by ESR spectroscopy, was strongly preferred. At higher temperatures, at about 150K, there was an increased proportion of reduced centre B. Reduction of B was more strongly preferred in particles frozen in 50% glycerol. The kinetics of dark reoxidation of A^? and B^? at various temperatures were followed by observing the radical signal of P-700⁺, and also by periodically cooling to 25 K to measure the ESR spectra of the iron-sulphur centres. The recombination of A^? and P-700⁺ occurred at lower temperatures than that at of B^?; at 150–200 K, centre B was the more stable electron trap. Dark reoxidation of both centres was more rapid in samples that were illuminated at 25 K than in samples illuminated at 150–215 K. In no case was net electron transfer between centres A and B observed. Differences in g values of the ESR spectra in particles illuminated at 25 and 200 K indicate that the iron-sulphur centres are in altered conformational states. It is concluded firstly that, in the frozen state, the rates of dark electron transfer decrease in the sequence A^? → P-700⁺ > B^? → P-700⁺ > B^? → A; secondly, that when centres A or B are photoreduced, a temperature-dependent conformational change takes place which slows down the rate of recombination with P-700⁺.     

Transient kinetics of the electron transfer between P-700, plastocyanin and cytochrome f in chloroplasts suspended in fluid media at sub-zero temperatures

The kinetics of redox changes of P-700, plastocyanin and cytochrome f in chloroplasts suspended in a fluid medium at sub-zero temperatures have been studied following excitation of the chloroplasts with either a single-turnover flash, a series of flashes or continuous light. The results show that: (1) The kinetics of reduction of P-700⁺ and those of oxidation of plastocyanin are consistent with a bimolecular reaction between these two components as previously suggested (Olsen, L.F., Cox, R.P. and Barber, J. (1980) FEBS Lett. 122, 13–16). (2) Cytochrome f shows heterogeneity with respect to its kinetics of oxidation by Photosystem I. (3) In contrast to the situation when plastoquinol is the electron donor, reduction of cytochrome f by electrons derived from diaminodurene occurs with sigmoidal kinetics that shows a good fit to an apparent equilibrium constant of 12 between the cytochrome and P-700. (4) The rate of electron transfer from plastoquinol to Photosystem I depends on the redox state of the plastoquinone pool. (5) In relation to current ideas about the lateral heterogeneity of Photosystem I and Photosystem II in the thylakoid membrane, the results are consistent with the function of plastocyanin as a mobile carrier of electrons in the intrathylakoid space.     

Bicarbonate effect on electron flow in a cyanobacteriumSynechocystis PCC 6803

In this communication, evidence is presented from the kinetics of Q_A ^? decay (where Q_A is the first plastoquinone electron acceptor of photosystem II) and oxygen evolution for the requirement of bicarbonate in the electron transport in a cyanobacteriumSynechocystis (Pasteur Culture Collection 6803). A large slowing down of Q_A ^? oxidation, measured from the variable chlorophylla fluorescence after saturating actinic flashes, was observed in the thylakoids ofSynechocystis 6803 depleted of bicarbonate in the presence of 25 mM formate. Qualitatively similar results were obtained with DCMU-treated thylakoids. This shows that bicarbonate depletion inhibits electron transport on the acceptor side of photosystem II between Q_A and the plastoquinone (PQ) pool in cyanobacteria. Addition of 2.5 mM HCO₃ ^? fully reversed the inhibition of electron flow caused by bicarbonate depletion. Two exponential phases of Q_A ^? decay, a fast one and a slow one, were observed with halftimes of approx. 400 μs (fast) and 26 ms (slow) at pH 6.5. At pH 7.5, these phases were approx. 330 μs (fast) and 21 ms (slow), respectively. The amplitude, but not the halftime, of the fast component decreased by about 70% (pH 6.5) or 50% (pH 7.5); this was accompanied by a concomittant increase in the slow phase. Twenty mM bicarbonate stimulated, by a factor of 4, the Hill reaction in bicarbonate-depletedSynechocystis cells. This effect is independent of CO₂ fixation as it was observed even in the presence of an inhibitor DBMIB.     

Effects of hydrostatic pressure on the kinetics of electron transfer in an isolated system of chloroplast cytochrome bf complex,plastocyanin and P700

The effects of pressure on the kinetics of redox reactions in and around the chloroplast cytochrome bf complex were studied using a reconstituted system consisting of Photosystem I (PS I) particles, cytochrome bf complex and plastocyanin (PC), all derived from pea chloroplasts. There were no significant permanent effects of pressure in the range 0.1–191 MPa on the reaction kinetics, or on the shape of the absorption spectra of components studied. Discernable effects on rate-coefficients of increasing pressure were observed on the reduction of P700⁺ by PC^I, on the reduction of PC^II by ascorbate, and on the oxidation of decyl plastoquinol by the bf complex. The volumes of activation ΔV^# were determined from the dependence of the rate-coefficient on pressure using: $$(\partial lnk/\partial P)_T = - \Delta V^\# /RT.$$ The volume of activation is the difference in partial molar volume between the activated state and the reactants for the redox reaction. Such data was sought to help define in detail those redox reactions and the corresponding activated states. For the reduction of P700⁺ by PC^I and the oxidation of decyl plastoquinol by the bf complex, the rate coefficient decreased with increase in pressure, whilst for the reduction of PC^II by ascorbate it increased. The corresponding volumes of activation were 9.6±0.6×10^-6 m³ mol^-1, 18±2×10^-6 m³ mol^-1 and -14±1×10^-6 m³ mol^-1, respectively. Much of the pressure-dependence of PC^II reduction by ascorbate was ascribed to an increase in ascorbate ionisation with increase in pressure. There was little effect of pressure on the kinetics of oxidation of ferrocytochrome f by PC^II, or on the equilibrium constant of the redox pair ferrocytochrome f/ferricytochrome f: PC^II/PC^I. Possible physical bases for these activation volumes are discussed, and they are compared with literature values.     

Plastocyanin redox kinetics in spinach chloroplasts: evidence for disequilibrium in the high potential chain

Reduction kinetics of cytochrome f, plastocyanin (PC) and P₇₀₀ (‘high-potential chain’) in thylakoids from spinach were followed after pre-oxidation by a saturating light pulse. We describe a novel approach to follow PC redox kinetics from deconvolution of 810-860 nm absorption changes. The equilibration between the redox-components was analyzed by plotting the redox state of cytochrome f and PC against that of P₇₀₀. In thylakoids with (1) diminished electron transport rate (adjusted with a cytochrome bf inhibitor) or (2) de-stacked grana, cytochrome f and PC relaxed close to their thermodynamic equilibriums with P₇₀₀. In stacked thylakoids with non-inhibited electron transport, the equilibration plots were complex and non-hyperbolic, suggesting that during fast electron flux, the ‘high-potential chain’ does not homogeneously equilibrate throughout the membrane. Apparent equilibrium constants <5 were calculated, which are below the thermodynamic equilibrium known for the ‘high potential chain’. The disequilibrium found in stacked thylakoids with high electron fluxes is explained by restricted long-range PC diffusion. We develop a model assuming that about 30% of Photosystem I mainly located in grana end-membranes and margins rapidly equilibrate with cytochrome f via short-distance transluminal PC diffusion, while long-range lateral PC migration between grana cores and distant stroma lamellae is restricted. Implications for the electron flux control are discussed.     

Photosynthesis in Tall Fescue : V. Analysis of High PSI Activity in a Decaploid Genotype

Previous work in our laboratory (Krueger, Miles 1981 Plant Physiol 68: 1110-1114) indicated that a decaploid genotype (I-16-2) of tall fescue (Festuca arundinacea Schreb.) which exhibits unusually high net photosynthesis rates also had high potential rates of photosynthetic electron transport through photosystem I (PSI) compared to the typical hexaploid genotype (V6-802). Analysis of electron transport activity revealed that the oxidizing side of PSI as the major site of difference. Examination of the whole thylakoids and subchloroplast particle protein components of the common hexaploid and the decaploid genotypes had major polypeptide differences at 30, 21, and 12.5 kilodaltons. These differences could not be assigned to a specific physiological function in PSI. The decaploid had increased P₇₀₀ and plastocyanin content on a chlorophyll basis. Antibodies raised against fescue plastocyanin were used to quantitate plastocyanin in crude (Triton X-100) solubilized extracts of plant material. Results showed that the decaploid had 16% and 40% more plastocyanin on a weight and area basis, respectively. The antibodies did not inhibit electron transport (diaminodiurene to methyl viologen) in isolated thylakoids strengthening the hypothesis of plastocyanin as an internal mobile electron shuttle. The trend of inhibition of plastocyanin by KCN was similar in the two genotypes but the decaploid had 15 to 20% higher rates of electron flow under nearly all inhibiting conditions.