Flash photolysis electron spin resonance studies of the electron acceptor species at low temperatures in photosystem I of spinach subchloroplast particles.

The light-induced electron spin resonance signals of Photosystem I spinach subchloroplast particles have been studied at approximately 6 degrees K. Using the technique of flash photolysis-electron spin resonance with actinic illumination at 647 nm, a kinetic analysis of the previously observed bound ferredoxin ESR signals was carried out. Signal I (P700+) exhibits a partial light-reversible behavior at 6 degrees K so it was expected that if the bound ferredoxin is the primary acceptor of Photosystem I, it should also exhibit a partial reversible behavior. However, none of the bound ferredoxin ESR signals showed any such light reversible behavior. A search to wider fields revealed two components which did exhibit the expected kinetic behavior. These components are very broad (about 80 G) and are centered at g equals to 1.75 and g equals to 2.07. These two components exhibit the expected characteristics of the primary electron acceptor. A model is presented to account for the reversible and irreversible photochemical changes in Photosystem I. The possible identity of the primary acceptor responsible for these two new components, is discussed in terms of the available information. The primary acceptor may be an iron-sulfur protein, but not of the type characteristic of the bound or water-soluble ferredoxins found so far in chloroplasts.     

Properties of the primary electron acceptor complex of photosystem I in the blue green alga Chlorogloea fritschii.

Photooxidation of P700 at low temperatures in membrane fractions from the blue-green alga $\text{Chlorogloea fritschii}$ may be coupled irreversibly to the reduction of a bound ferredoxin. If this ferredoxin is reduced before freezing, P700 photooxidation at low temperatures becomes reversible. This reversible photooxidation is coupled to the reduction of a component with an EPR signal at g = 2.08, 1.88 and 1.78. A complete spectrum of this component has been obtained for the first time. We propose that as in higher plants this component is the primary electron acceptor of Photosystem I, the bound ferredoxin is a secondary electron acceptor. Using ⁵⁷Fe enriched preparations we have shown that the ERP signals attributed to the bound ferredoxin are due to iron containing centres. This experiment did not show the presence of iron in the primary electron acceptor.     

Chemical modification studies of chloroplast membranes. Effects of diazonium coupling on electron transfer in photosystem I

p-Diazonium benzene sulfonate reacts with at least two chloroplast membrane components on the reducing side of Photosystem I leading to inhibition of electron flow from the Photosystem I primary acceptor (X) to ferredoxin, and inhibiting the function of bound ferredoxin-NADP⁺ reductase. While some inhibition of these two components attends p-diazonium benzene sulfonate treatment in the dark, a much more severe inhibition results when p-diazonium benzene sulfonate is given to light-energized membranes.Of particular interest is that electron flux through Photosystem II (3-(3,4-dichlorophenyl)-1, 1-dimethylurea sensitive) is required for potentiating the light-dependent p-diazonium benzene sulfonate inhibition, cyclic electron flow around Photosystem I not being an effective potentiator. We interpret these data as due to Photosystem II-driven conformational changes unmasking additional diazoreactive sites in the bound membrane components.     

Evidence for the role of a bound ferredoxin as the primary electron acceptor of Photosystem I in spinach chloroplasts

The presence of a bound electron transport component in spinach chloroplasts with an EPR spectrum characteristic of a ferredoxin has been confirmed. The ferredoxin is photoreduced at 77 °K or at room temperature, it is not reduced in the dark by Na₂S₂O₄. The distribution of the ferredoxin in subchloroplast particles has been investigated. The ferredoxin is enriched in Photosystem I particles and it is proposed that it functions as primary electron acceptor for Photosystem I.

The EPR spectra indicate the presence of two components which are photoreduced sequentially. It is proposed that they may represent two active centres of a single protein.     

Photosystem I charge separation in the absence of centers A and B. II. ESR spectral characterization of center ‘X’ and correlation with optical signal ‘A2’

The Photosystem I electron acceptor complex was characterized by optical flash photolysis and electron spin resonance (ESR) spectroscopy after treatment of a subchloroplast particle with lithium dodecyl sulfate (LDS). The following properties were observed after 60 s of incubation with 1% LDS followed by rapid freezing. (i) ESR centers A and B were not observed during or after illumination of the sample at 19 K, although the P-700⁺ radical at g = 2.0026 showed a large, reversible light-minus-dark difference signal. (ii) Center ‘X’, characterized by g factors of 2.08, 1.88 and 1.78, exhibited reversible photoreduction at 8 K in the absence of reduced centers A and B. (iii) The backreaction kinetics at 8 K between P-700, observed at g = 2.0026, and center X, observed at g = 1.78, was 0.30 s. (iv) The amplitudes of the reversible g = 2.0026 radical observed at 19 K and the 1.2 ms optical 698 nm transient observed at 298 K were diminished to the same extent when treated with 1% LDS at room temperature for periods of 1 and 45 min. We interpret the strict correlation between the properties and lifetimes of the optical P-700⁺ A⁻₂ reaction pair and the ESR P-700⁺ center X⁻ reaction pair to indicate that signal A₂ and center X represent the same iron-sulfur center in Photosystem I.     

EPR spectra of Photosystem I and other iron protein components in intact cells of cyanobacteria

Electron paramagnetic resonance (EPR) spectra were recorded of whole filaments of the cyanobacteria Nostoc muscorum and Anabaena cylindrica. Signals due to manganese were removed by freezing and thawing the cells in EDTA. EPR spectra were assigned on the basis of their g values, linewidths, temperature dependence and response to dithionite and light treatments. The principal components identified were: (i) rhombic Fe³⁺ (signal at g = 4.3), probably a soluble storage form of iron; (ii) iron-sulfur centers A and B of Photosystem I; (iii) the photochemical electron acceptor ‘X’ of Photosystem I; this component was also observed for the first time in isolated heterocysts; (iv) soluble ferredoxin which was present at a concentration of 1 molecule per 140 ± 20 chlorophyll molecules; (v) a membrane-bound iron-sulfur protein (g = 1.92). A signal g = 6 in the oxidized state was probably due to an unidentified heme compound. During deprivation of iron the rhombic Fe³⁺, centers A, B and X of Photosystem I, and soluble ferredoxin were all observed to decrease.     

Laser-flash-activated electron paramagnetic resonance studies of primary photochemical reactions in chloroplasts

Electron paramagnetic resonance studies of the primary reactants of Photosystems I and II have been conducted at cryogenic temperatures after laser-flash activation with monochromatic light.P-700 photooxidation occurs irreversibly in chloroplasts and in Photosystem I fragments after activation with a 730 nm laser flash at a temperature of 35 °;K. Flash activation of chloroplasts or Photosystem II chloroplast fragments with 660 nm light results in the production of a free-radical signal (g = 2.002, linewidth ～ 8 gauss) which decays with a half-time of 5.0 ms at 35 °;K. The half-time of decay is independent of temperature in the range of 10–77 °;K. This reversible signal can be eliminated by preillumination of the sample at 35 °;K with 660 nm light (but not by 730 nm light), by preillumination with 660 nm light at room temperature in the presence of 3-(3′, 4′-dichlorophenyl)-1,1′-dimethylurea (DCMU) plus hydroxylamine, or by adjustment of the oxidation-reduction potential of the chloroplasts to — 150 mV prior to freezing. In the presence of ferricyanide (20–50 mM), two free-radical signals are photoinduced during a 660 nm flash at 35 °;K. One signal decays with a half-time of 5 ms, whereas the second signal is formed irreversibly. These results are discussed in terms of a current model for the Photosystem II primary reaction at low temperature which postulates a back-reaction between P-680⁺ and the primary electron acceptor.     

Photoreduction of ferredoxin-NADP in the presence and absence of ferredoxin-reducing substance (FRS)

Preparations of ferredoxin-reducing substance (FRS) were obtained from spinach chloroplasts within the elution volume range and with the spectral characteristics described by Yocum and San Pietro (8). However, no support was found for the view that FRS is the primary electron acceptor of Photosystem I. The FRS-depleted chloroplast fragments retained their Photosystem I activity, which was not enhanced by the addition of FRS. No evidence was found for a prior photoreduction of FRS by chloroplasts followed by a dark reduction of ferredoxin and NADP by reduced FRS. The FRS-depleted chloroplast fragments were found to retain and to photoreduce bound ferredoxin upon illumination by Photosystem I light at 25°K. These results suggest that the role of a primary electron acceptor of Photosystem I ascribed to FRS may belong to bound ferredoxin.     

Quantitative EPR studies of the primary reaction of Photosystem I in chloroplasts

Quantitative electron paramagnetic resonance studies of the primary event associated with Photosystem I in chloroplasts have been carried out at 25 °K. After illumination of either whole chloroplasts or Photosystem I subchloroplast fragments (D-144) with 715-nm actinic light at 25 °K, equal spin concentrations of oxidized P700 and reduced bound iron-sulfur protein (bound ferredoxin) have been measured. Quantitative determination of the concentration of these two carriers by EPR spectroscopy after illumination at low temperature indicates that Photosystem I fragments are enriched in P700 and the bound iron-sulfur protein as compared with unfractionated chloroplasts. These results indicate that P700 and the bound iron-sulfur protein function as the donor-acceptor complex of chloroplast Photosystem I.     

Properties of the low-temperature Photosystem I primary reaction in the P-700-chlorophyll a-protein

The Photosystem I primary reaction, as measured by electron paramagnetic resonance changes of P-700 and a bound iron-sulfur center, has been studied at 15°K in P-700-chlorophyll a-protein complexes isolated from a blue-green alga. One complex, prepared with sodium dodecyl sulfate shows P-700 photooxidation only at 300°K, whereas a second complex, prepared with Triton X-100, is photochemically active at 15°K as well as at 300°K. Analysis of these two preparations shows that the absence of low-temperature photoactivity in the sodium dodecyl sulfate complex reflects a lack of bound iron-sulfur centers in this preparation and supports the assignment of an iron-sulfur center as the primary electron acceptor of Photosystem I.     

Evidence that the intermediate electron acceptor,A2, in Photosystem I is a bound iron-sulfur protein

Absorption changes accompanying the formation of light-induced P-700⁺ were investigated in a highly enriched Photosystem I preparation where an intermediate electron acceptor preceding P-430 could be detected. In an enriched Photosystem I particle, light-induced reversible absorption changes observed at 700 nm in the presence of dithionite resembled those previously seen at 703 nm and 820 nm [9], thus indicating the presence of a backreaction between P-700⁺ and A^?₂. After this same Photosystem I particle was treated to denature the bound iron-sulfur centers, the photochemical changes that could be attributed to P-700 A₂ were completely lost. These results provide evidence that the intermediate electron acceptor, A₂, is a bound iron-sulfur protein. Additional studies in the 400–500 nm region with Photosystem I particles prepared by sonication indicate that the spectrum of A₂ is different from that of P-430.     

Electron spin resonance studies of the bound iron-sulfur centers in Photosystem I. Photoreduction of center A occurs in the absence of center B

The Photosystem I acceptor system of a subchloroplast particle from spinach was investigated by optical and electron spin resonance (ESR) spectroscopy following graduated inactivation of the bound iron-sulfur proteins by urea/ferricyanide solution. The chemical analysis of iron and sulfur and the ESR properties of centers A, B and X are consistent with the participation of three iron-sulfur centers in Photosystem I. A differential decrease in centers A, B and X is observed under conditions that induce S^2? →S⁰ conversion in the bound iron-sulfur proteins. Center B is shown to be the most susceptible, while center ‘X’ is the least susceptible component to oxidative denaturation. Stepwise inactivation experiments suggest that electron transport in Photosystem I does not occur sequentially from X→B→A, since there is quantitative photoreduction of center A in the absence of center B. We propose that center A is directly reduced by X; thus, X may serve as a branch point for parallel electron flow through centers A and B.     

Primary events in the photosynthetic reaction centre from Rhodopseudomonas spheroides strain R26: Triplet and oxidized states of bacteriochlorophyll and the identification of the primary electron acceptor

ESR studies at approximately 10 °K on the reaction centre complex of the photosynthetic bacterium Rhodopseudomonas spheroides (strain R26), have revealed bacteriochlorophyll triplet states and a component which has an ESR absorption centred at g = 1.82. The triplet-state bacteriochlorophyll is induced only in the light and is only detectable when the reaction-centre bacteriochlorophyll and its primary electron acceptor are reduced; the ESR triplet state signals are composed of both ESR absorption and ESR emission bands. The oxidation-reduction properties of the g = 1.82 component and its flash-induced kinetic behavior in relation to that of P870 are those expected for the primary electron acceptor in bacterial photosynthesis.     

Electron-spin resonance studies of the bound iron-sulfur centers in Photosystem I II. Correlation of P-700 triplet production with urea/ferricyanide inactivation of the iron-sulfur clusters

Photosystem I charge separation in a subchloroplast particle isolated from spinach was investigated by electron spin resonance (ESR) spectroscopy following graduated inactivation of the bound iron-sulfur centers by urea-ferricyanide treatment. Previous work demonstrated a differential decrease in iron-sulfur centers A, B and X which indicated that center X serves as a branch point for parallel electron flow through centers A and B (Golbeck, J.H. and Warden, J.T. (1982) Biochim. Biophys. Acta 681, 77–84). We now show that during inactivation the disappearance of iron-sulfur centers A, B, and X correlates with the appearance of a spin-polarized triplet ESR signal with |D| = 279·10⁻⁴ cm⁻¹ and |E| = 39·10⁻⁴ cm⁻¹. The triplet resonances titrate with a midpoint potential of +380 ± 10 mV. Illumination of the inactivated particles results in the generation of an asymmetric ESR signal with g = 2.0031 and ΔH_pp = 1.0 mT. Deconvolution of the P-700⁺ contribution to this composite resonance reveals the spectrum of the putative primary acceptor species, A₀, which is characterized by g = 2.0033 ± 0.0004 and ΔH_pp = 1.0 ± 0.2 mT. The data presented in this report do not substantiate the participation of the electron acceptor A₁ in PS I electron transport, following destruction of the iron-sulfur cluster corresponding to center X. We suggest that A₁ is closely associated with center X and that this component is decoupled from the electron-transport path upon destruction of center X. The inability to photoreduce A₁ in reaction centers lacking a functional center X may result from alteration of the reaction center tertiary structure by the urea-ferricyanide treatment or from displacement of A₁ from its binding site.     

A study of chemically induced dynamic electron polarization (CIDEP) in Photosystem I of whole algal cells at ambient temperatures

Time-resolved electron paramagnetic resonance (EPR) studies were carried out at room temperature and at 273 K on whole-cell samples of the photosynthetic algae: Anacystis nidulans and Scenedesmus obliquus, the latter being 97% deuterated from the growing medium. These photosynthetic organisms show greatly enhanced EPR signals which result from the generation of nonequilibrium spin populations, a phenomenon known as chemically induced dynamic electron polarization (CIDEP). We report magnetic-field profiles of the early transient signals of Photosystem I which are very similar to those observed at low temperatures. The results suggest that one or more early reduced electron acceptors in Photosystem I are being observed at ambient physiological temperatures.     

Electron spin polarization (CIDEP) of a primary electron acceptor in Photosystem II

Photosystem II particles prepared according to Berthold et al. (Berthold, D.A., Babcock, G.T. and Yocum. C.F. (1981) FEBS Lett. 134, 231–234) and to Ganago and Klimov (Ganago, I.B. and Klimov, V.V. (1985) Biofizika, in the press) were subjected to an iron extraction procedure and cooled in the light under reducing conditions. The samples showed a 0.9 mT wide EPR line at g = 2.0044 attributed to the reduced primary acceptor Q⁻_A. Further prolonged illumination at 15 K generated a wide, somewhat asymmetric EPR signal at g = 2.0034−2.0038 that showed strong, reversible polarization upon continuous illumination at 15 K and below. The signal is ascribed to an acceptor that becomes spin-polarized through exchange-mediated transfer of polarization as described previously for photosynthetic bacteria (Gast, P. and Hoff, A.J. (1979) Biochim. Biophys. Acta 548, 502–535). Arguments are given that the aceptor may be intermediate between the pheophytin transient acceptor and Q_A.     

Characterisation of electron acceptors A0 and A1 in cyanobacterial Photosystem I

Preparations of cyanobacterial Photosystem I were compared to those of pea Photosystem I using ESR spectroscopy. Photoreduced samples were illuminated at cryogenic temperatures with ESR spectra taken at 205 K. After illumination at 205 K and 230 K, signals appeared which correspond to the shape and position of the signals assigned to A₁ and A₀, respectively, in higher plant Photosystem I.     

The role of the membrane-bound iron-sulphur centres A and B in the photosystem I reaction centre of spinach chloroplasts.

Photosystem I particles prepared from spinach chloroplast using Triton X-100 were frozen in the dark with the bound iron-sulphur Centre A reduced. Illumination at cryogenic temperatures of such samples demonstrated the photoreduction of the second bound iron-sulphur Centre B. Due to electron spin-electron spin interaction between these two bound iron-sulphur centres, it was not possible to quantify amounts of Centre B relative to the other components of the Photosystem I reaction centre by simulating the line-shape of its EPR spectrum. However, by deleting the free radical signal I from the EPR spectra of reduced Centre A alone or both Centres A plus B reduced, it was possible to double integrate these spectra to demonstrate that Centre B is present in the Photosystem I reaction centre in amounts comparable to those of Centre A and thus also signal I (P-700) and X. Oxidation-reduction potential titrations confirmed that Centre A had Em congruent to -550 mV, Centre B had Em congruent to -585 mV. These results, and those presented for the photoreduction of Centre B, place Centre B before Centre A in the sequence of electron transport in Photosystem I particles at cryogenic temperatures. When both A and B are reduced, P-700 photooxidation is reversible at low temperature and coupled to the reduction of the component X. The change from irreversible to reversible P-700 photooxidation and the photoreduction of X showed the same potential dependence as the reduction of Centre B with Em congruent to -585 mV, substantiating the identification of X as the primary electron acceptor of Photosystem I.     

Photosynthetic electron transport and electrochromic effects at sub-zero temperatures

Spinach chloroplasts, suspended in a liquid medium containing ethyleneglycol, showed reversible absorbance changes near 700 and 518 nm due to P-700 and “P-518” in the region from ?35 to ?50 °C upon illumination. The kinetics were the same at both wavelengths, provided absorbance changes due to Photosystem II were suppressed. At both wavelengths, the decay was slowed down considerably, not only by the System I electron acceptor methyl viologen, but also by silicomolybdate. The effect of the latter compound is probably not due to the oxidation of the reduced acceptor of Photosystem I by silicomolybdate, but to the enhanced accessibility of the acceptor to some other oxidant.In the presence of both an electron donor and acceptor for System I, a strong stimulation of the extent of the light-induced absorbance increase at 518 nm was observed. The most effective donor tested was reduced N-methylphenazonium methosulphate (PMS). The light-induced difference spectrum was similar to spectra obtained earlier at room temperature, and indicated electrochromic band shifts of chlorophylls a and b and carotenoid, due to a large potential over the thylakoid membrane, caused by sustained electron transport. It was estimated that steady-state potentials of up to nearly 500 mV were obtained in this way; the potentials reversed only slowly in the dark, indicating a low conductance of the membrane. This decay was accelerated by gramicidin D. The absorbance changes were linearly proportional to the membrane potential.     

Electron and proton transfers from P-430 to ferredoxin-NADP-reductase in Chlorella cells

After blocking Photosystem II on whole Chlorella cells, we measured the absorption changes between 0°C and ?10°C.The absorption changes measured 2 μs after the beginning of a Xenon Flash are the sum of changes due to P⁺-700 and changes due to P^?-430 (after the subtraction of the carotenoid triplet change and of the electrochromic effect).The reduction of P^?-430 is not resolved by our technique. Its reoxidation presents a half-time around 1 μs at 0°C and around 2 μs at ?10°C.The reduction and protonation of ferredoxin-NADP-reductase to its neutral semi-quinoid form FNRH° present a half-time of about 3 μs at 0°C and 6 μs at ?10°C.The presence of only one photoreducible ferredoxin-NADP-reductase per Photosystem I center is confirmed. The acceptor preceding ferredoxin-NADP-reductase is not ferredoxin, but is an acceptor X' the differential extinction coefficients of which are weak or null from 420 nm to 480 nm.Tentative explanations which would reconcile these results with what was already known about ferredoxin are proposed.