The Cl effect on photosynthetic oxygen evolution: interaction of Cl with 18-kDa, 24-kDa and 33-kDa proteins

The interaction of Cl⁻ with the extrinsic proteins of 18 kDa, 24 kDa and 33 kDa in the photosynthetic oxygen-evolution complex was studied by comparing spinach photosystem II particles of different protein compositions. The 33-kDa protein decreased the Cl⁻ concentration optimum for oxygen evolution from 150 to 30 mM, and the 24-kDa protein decreased it from 30 to 10 mM. The 18-kDa protein did not change the optimum Cl⁻ concentration, but sustained oxygen evolution at Cl⁻ concentrations lower than 3 mM. The presence of the 24-kDa and 18-kDa proteins, but not each protein alone, markedly suppressed inactivation of oxygen evolution at a very low Cl⁻ concentration and its restoration by readdition of Cl⁻.     

The S-state dependence of Cl binding to plant Photosystem II

A combined single-turnover flash and ³⁵Cl NMR technique has been used to monitor S-state dependence of Cl⁻ binding to PS-II particles derived from mangrove (Avicennia marina). No detectable high-affinity binding was found to particles in the S₀ and S₁ states, but binding with an affinity comparable to that which activates O₂ evolution was found in the S₂ and S₃ states.     

The influence of anions on oxygen evolution by isolated spinach chloroplasts

A study has been made of the onset of chloride deprivation on the oxygen-evolving characteristics of isolated spinach chloroplasts. Using a modulated oxygen electrode it is found that the type of inhibition depends on the anion replacing chloride in the bathing medium. With nitrate a large increase in phase lag accompanies a relatively small inhibition which can be shown to be consistent with a decrease in the rate constant of the reaction which limits the rate of electron transport between water and Photosystem II. With sulphate there is a very small phase change but a larger inhibition which suggests that replacing chloride with sulphate in an electron-transport chain shuts off that chain. With acetate there is a moderate increase in phase lag and the largest inhibitory effect. The phase-lag increase suggests that acetate is affecting the same chloride-sensitive site as nitrate. However, the inhibition cannot be explained by this effect alone and points to the existence of a second chloride-sensitive site. Of the four forward reactions associated with the Kok model of oxygen evolution (Kok, B., Forbush, B. and McGloin, M. (1970) Photochem. Photobiol. 11, 457–475) only S1₃ → S₀ is slowed down when chloride is replaced by nitrate. This reaction is not slowed down by replacing chloride with sulphate.     

EDTA-induced release of manganese and proteins from inside-out thylakoid vesicles and the inhibition of oxygen evolution

Washing of inside-out, but not right-way-round, pea chloroplast thylakoid vesicles with 2 mM EDTA inhibits O2 evolution. Artificial electron donor/acceptor studies indicate that the site of inhibition is on the oxidising side of photosystem two (PS2), a conclusion reinforced by chlorophyll fluorescence measurements. Evidence is presented that the EDTA inhibition of O2 evolution is linked partly to the removal of one Mn atom per PS2 reaction centre and partly to the removal of extrinsic membrane proteins having apparent molecular weights between 58 and 70 kdaltons.     

Structural organization of the oxidizing side of photosystem II. Exogenous reductants reduce and destroy the Mn-complex in photosystems II membranes depleted of the 17 and 23 kDa polypeptides

Removal of 23 and 17 kDa water-soluble polypeptides from PS II membranes causes a marked decrease in oxygen-evolution activity, exposes the oxidizing side of PS II to exogenous reductants (Ghanotakis, D.F., Babcock, G.T. and Yocum, C.F. (1984) Biochim. Biophys. Acta 765, 388–398) and alters a high-affinity binding site for Ca²⁺ in the oxygen-evolving complex (Ghanotakis, D.F., Topper, J.N., Babcock, G.T. and Yocum, C.F. (1984) FEBS Lett. 170, 169–173). We have examined further the state of the functional Mn complex in PS II membranes from which the 17 and 23 kDa species have been removed by high-salt treatment. These membranes contain a structurally altered Mn complex which is sensitive to destruction by low concentrations of NH₂OH which cannot, in native PS II membranes, cause extraction of functional Mn. In addition to NH₂OH, a wide range of other small (H₂O₂, NH₂NH₂, Fe²⁺) and bulky (benzidine, hydroquinone) electron donors extract Mn (up to 80%) from the polypeptide-depleted PS II preparations. This extraction is due to reduction of the functional Mn complex since light, which would generate higher oxidation states within the Mn complex, prevents Mn release by reductants. Release of Mn by reductants does not extract the 33 kDa water-soluble protein implicated in Mn binding to the oxidizing side of PS II, although the protein can be partially or totally extracted from Mn-depleted preparations by exposure to high ionic strength or to high (0.8 M) concentrations of Tris. We view our results as evidence for a shield around the Mn complex of the oxygen-evolving complex comprised of the 33 kDa polypeptide along with the 23 and 17 kDa proteins and tightly bound Ca²⁺.     

Cytochrome distribution across chloroplast thylakoid membranes. Controlled proteolysis of inside-out and right-side-out vesicles

The transverse distribution of chloroplast cytochromes b-559 (high and low potentials), b-563 and f in pea thylakoid membranes was studied by the effects of trypsin and pronase on inside-out and right-side-out thylakoid vesicles. The high potential (HP) form of cytochrome b-559 was degraded to a low potential (LP) form most rapidly in right-side-out vesicles. In either type of vesicle there was no overall loss of the cytochrome from the membrane. This suggests that the haem group is buried in the membrane but that the cytochrome environment is most labile at the outer surface. Cytochrome b-563 was unaffected by trypsin and only slightly degraded by pronase in inverted vesicles. However, pronase caused the loss of an M_r 1000, non-haem fraction from the cytochrome f polypeptide in inside-out vesices only. The total cytochrome f content (measured spectrophotometrically and by staining polyacrylamide gels for haem associated peroxidase activity) decayed only slightly in either type of vesicle. These observations suggest that cytochrome f is, in part, exposed to the intrathylakoid lumen, whilst its haem group is retained in a more hydrophobic region.     

The effect of pH on the reduction kinetics of P-680 in tris-treated chloroplasts

The primary donor of Photosystem II (PS II), P-680, was photo-oxidized by a short flash and its rate of reduction was measured at different pH values by following the recovery of the absorption change at 820 nm in chloroplasts pretreated with a high concentration of Tris. The re-reduction is biphasic with a fast phase (dominant after the first flash) attributed to the donation by a donor, D₁, and a slow phase (usually dominant after the second flash) attributed to a back-reaction with the primary acceptor.

It is found that pH has a strong influence on the donation from D₁ (τ = 2 μs at pH 9, 44 μs at pH 4), but no influence on the back reaction (τ ≈ 200 μs). pH also influences the stability of the charge separation since the contribution of donation from D₁ at the second flash increases at lower pH, getting close to 100% at pH 4.     

Fluoride inhibition of oxygen evolution; new evidence from Cl-NMR measurements

³⁵Cl-NMR was used to investigate the nature of F⁻-induced inhibition of oxygen-evolution in thylakoids from the mangrove, Avicennia marina. These studies showed a correlation between F⁻ inhibition of oxygen evolving activity and increased bulk Cl⁻ relaxation, possibly associated with the formation of a new class of high-affinity Cl⁻-binding sites, or a change in the nature of the existing binding sites, induced by F⁻. The presence of added Cl⁻ did not alter the F⁻-induced inhibition of oxygen evolution. Increased Cl⁻ relaxation and F⁻-induced inhibition of oxygen evolution occurred at lower concentrations of F⁻ at pH 7.8 than at pH 6.3. In mangrove thylakoids. F⁻-induced inhibition of oxygen evolution does not appear to be due to competition with Cl⁻ for Cl⁻ binding sites, but instead involves some other interaction close to the oxygen-evolving complex.     

The influence of metal cations and pH on the heat sensitivity of photosynthetic oxygen evolution and chlorophyll fluorescence in spinach chloroplasts

The heat-sensitivity of photosynthetic oxygen evolution of thylakoids isolated from spinach increases by increasing the pH above neutral value. The temperature for inactivation (transition temperature) is lowered from about 45° C (pH 6.0–7.4) to 33°C (pH 8.5). Similar results are obtained with intact chloroplasts. At pH 7.0 the transition temperature of washed thylakoids decreases by lowering the salt concentration below 20 mM with monovalent cations (Li⁺, Na⁺, K⁺) and below 3–4 mM with divalent cations (Mg²⁺, Ca²⁺, Sr²⁺). Illumination decreases the heat-sensitivity of oxygen evolution in intact chloroplasts, but even increases the heat-sensitivity in uncoupled chloroplasts. In intact chloroplasts the transition temperature of the heat-induced rise in chlorophyll fluorescence yield (F_o; see Schreiber and Armond 1978) decreases from 44° C to 38° C when the pH of the suspending medium is increased from 6.5 to 8.5. At 20° C, F_o is almost insensitive to pH (6.0–8.5). At 40° C, however, F_o is constant between 6.0 and 7.0, but strongly increases by increasing the pH above neutral value. The results are discussed in terms of a close relation between electrostatic forces at the thylakoid membrane and thermal sensitivity of photosynthetic apparatus. It is suggested that the heat-sensitivity of the photosystem II complex partially depends on the ionization state of fixed groups having alkaline pK. The packed volume of thylakoids suspended in a low salt medium increases when the temperature is increased above 30° C (pH 7.0) and above 20° C (pH 8.0), respectively. This result suggests a heat-induced increase in surface charge density of the thylakoid membrane.Abbreviations HEPES N-2-hydroxyethylpiperazine-N-2-ethane sulfonic acid - MES morpholinoethane sulfonic acid - MOPS 2-N-morpholinopropane sulfonic acid - TRICIN N-[tris(hydroxymethyl)-methyl] glycine     

Spin-label studies of the lipid regions of spinach thylakoids and a detergent-derived oxygen-evolving Photosystem II preparation

We have compared the fluidity of thylakoid membranes with the membrane present in a Triton X-100-derived, oxygen-evolving Photosystem II (PS II) preparation using two different spin labels. Data obtained with 2,2,6,6-tetramethylpipiridine-N-oxyl (TEMPO) shows that the PS II preparation contains less fluid membrane than the thylakoid. The TEMPO partition parameter (f) is about 2.5-times greater for the thylakoids at 6 mg chlorophyll/ml than for the PS II preparation at the same chlorophyll concentration. Similarly, the rotational correlation time, τ, of TEMPO residing in the membrane of the PS II preparation is about 2-times longer than the τ for TEMPO in the thylakoid membrane. A spin label which partitions more completely into the bilayer, 2-heptyl-2-hexyl-5,5-dimethyloxazolidine-N-oxyl (7N14), indicates a much greater fluidity in the thylakoid membrane than the membrane of the PS II preparation. The PS II preparation appears to have a hydrocarbon phase which approaches the rigid limit of EPR detectable motion. These results are discussed in terms of possible lipid depletion in the PS II preparation and in terms of lateral heterogeneity of hydrocarbon fluidity in the thylakoid membrane caused by the lateral heterogeneity in protein components.     

Reversible alteration of nanosecond reduction of chlorophyll a+II in inside-out thylakoids correlated to inhibition and reconstitution of oxygen-evolving activity

The electron donation to Chl a⁺_II has been studied by measurement of absorbance changes at 824 nm under repetitive excitation conditions. For untreated inside-out thylakoids the electron donation was dominated by 35 and 220 ns kinetics. After salt-washing, both oxygen-evolution and nanosecond phases decreased drastically with corresponding increase in the microsecond time range. On addition of a purified 23 kDa protein, a restoration of the nanosecond phases up to 75% of the orginal level was obtained concomitant with a corresponding restoration of oxygen evolution. The results are consistent with a function of the 23 kDa protein at the oxidizing side of Photosystem II and that the nanosecond donation to Chl-a⁺_II is coupled to the natural path of electrons from water.     

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.     

EPR detection of a cryogenically photogenerated intermediate in photosynthetic oxygen evolution

In Photosystem II preparations at low temperature we were able to generate and trap an intermediate state between the S₁ and S₂ states of the Kok scheme for photosynthetic oxygen evolution. Illumination of dark-adapted, oxygen-evolving Photosystem II preparations at 140 K produces a 320-G-wide EPR signal centered near g = 4.1 when observed at 10 K. This signal is superimposed on a 5-fold larger and somewhat narrower background signal; hence, it is best observed in difference spectra. Warming of illuminated samples to 190 K in the dark results in the disappearance of the light-induced g = 4.1 feature and the appearance of the multiline EPR signal associated with the S₂ state. Low-temperature illumination of samples prepared in the S₂ state does not produce the g = 4.1 signal. Inhibition of oxygen evolution by incubation of PS II preparations in 0.8 M NaCl buffer or by the addition of 400 μM NH₂OH prevents the formation of the g = 4.1 signal. Samples in which oxygen evolution is inhibited by replacement of Cl^? with F^? exhibit the g = 4.1 signal when illuminated at 140 K, but subsequent warming to 190 K neither depletes the amplitude of this signal nor produces the multiline signal. The broad signal at g = 4.1 is typical for a $\text{S =}\text{5}\text{2}$ spin system in a rhombic environment, suggesting the involvement of non-heme Fe in photosynthetic oxygen evolution.     

External electric field effects on photosynthetic membrane vesicles. Kinetic characterization of two electrophotoluminescence phases in hypotonically swollen chloroplasts

Strong externally applied electrical field pulses are known to stimulate delayed luminescence from preilluminated blebs (hypotonically swollen vesicles originating from thylakoid membranes of broken chloroplasts) by up to 3 orders of magnitude. This phenomenon is known as electrophotoluminescence. Previous analysis showed the kinetics of the electrophotoluminescence to be biphasic, displaying a rapid (R) phase which decays towards a slower one (S) (Ellenson, J.L. and Sauer, K. (1976) Photochem. Photobiol. 23, 113–123). We demonstrate that these two components represent different processes. At low pH, a good kinetic separation is obtained between the two phases, which become distinct, with the S phase manifesting also an initial rise period. Under these conditions, it is possible to estimate separately the approximate rise times of the two phases. It is shown that the R and S components have a different dependence on the pH and on the time between the actinic flash and onset of the field. The field dependence is also different, with the S phase requiring a lower threshold field than R. From these observations, it is concluded that the R and S luminescence components are formed by different precursors. The difference in behaviour of the two phases during formation of the bleb indicates that the precursors of the R and S phases belong to different parts of the bleb. We suggest that R precursors are located in the wall of the swollen thylakoid and S precursors in the membrane formations which are attached to this wall.     

Identification of polypeptides associated with the 23 and 33 kDa proteins of photosynthetic oxygen evolution

An immunological approach was used for nearest-neighbor analyses for the 23 and 33 kDA proteins of the oxygen-evolving complex. Functional Photosystem II particles with a simple polypeptide composition were partly solubilized with detergent and incubated with monospecific antibodies against either the 23 or the 33 kDa protein. SDS-polyacrylamide gel electrophoresis revealed that the immunoprecipitates, apart from the antigenic proteins, also contained polypeptides at 24, 22 and 10 kDa. In contrast, polypeptides of the light-harvesting and Photosystem II core complexes showed very poor coprecipitation with the 23 and 33 kDa proteins. The 24, 22 and 10 kDa polypeptides were not precipitated by the antibodies if the 23 and 33 kDa proteins had been removed from the particles prior to solubilization. These observations demonstrate a close association between the 24, 22 and 10 kDa polypeptides and the 23 and 33 kDa proteins of the oxygen-evolving complex. None of these precipitated polypeptides contained any manganese. It is suggested that the 24, 22 and 10 kDa polypeptides are subunits of the oxygen-evolving complex and involved in the binding of the extrinsic 23 and 33 kDa proteins to the inner thylakoid surface.     

Manganese proteins isolated from spinach thylakoid membranes and their role in O2 evolution: II. A binuclear manganese-containing 34 kilodalton protein,a probable component of the water dehydrogenase enzyme

Extraction conditions have been found which result in the retention of managanese to the 33–34 kDa protein, first isolated as an apoprotein by Kuwabara and Murata (Kuwabara, T. and Murata, N. (1979) Biochim. Biophys Acta 581, 228–236). By maintaining an oxidizing-solution potential, with hydrophilic and lipophilic redox buffers during protein extraction of spinach grana-thylakoid membranes, the 33–34 kDa protein is observed to bind a maximum of 2 Mn/protein which are not released by extended dialysis versus buffer. This manganese is a part of the pool of 4 Mn/Photosystem II normally associated with the oxygen-evolving complex. The mechanism for retention of Mn to the protein during isolation appears to be by suppression of chemical reduction of natively bound, high-valent Mn to the labile Mn(II) oxidation state. This protein is also present in stoichiometric levels in highly active, O₂-evolving, detergent-extracted PS-II particles which contain 4–5 Mn/PS II. Conditions which result in the loss of Mn and O₂ evolution activity from functional membranes, such as incubation in 1.5 mM NH₂OH or in ascorbate plus dithionite, also release Mn from the protein. The protein exists as a monomer of 33 kDa by gel filtration and 34 kDa by gel electrophoresis, with an isoelectric point of 5.1 ± 0.1. The protein exhibits an EPR spectrum only below 12 K which extends over at least 2000 G centered at g = 2 consisting of non-uniformly separated hyperfine transitions with average splitting of 45–55 G. The magnitude of this splitting is nominally one-half the splitting observed in monomeric manganese complexes having O or N donor ligands. This is apparently due to electronic coupling of the two ⁵⁵Mn nuclei in a presumed binuclear site. Either a ferromagnetically coupled binuclear Mn₂(III,III) site or an antiferromagnetically coupled mixed-valence Mn₂(II,III) site are considered as possible oxidation states to account for the EPR spectrum. Qualitatively similar hyperfine structure splittings are observed in ferromagnetically coupled binuclear Mn complexes having even-spin ground states. The extreme temperature dependence suggests the population of low-lying excited spin states such as are present in weakly coupled dimers and higher clusters of Mn ions, or, possibly, from efficient spin relaxation such as occurs in the Mn(III) oxidation state. Either 1.5 mM NH₂OH or incubation with reducing agents abolishes the low temperature EPR signal and releases two Mn(II) ions to solution. This is consistent with the presence of Mn(III) in the isolated protein. The intrinsically unstable Mn₂(II,III) oxidation state observed in model compounds favors the assignment of the stable protein oxidation state to the Mn₂(III,III) formulation. This protein exhibits characteristics consistent with an identification with the long-sought Mn site for photosynthetic O₂ evolution. An EPR spectrum having qualitatively similar features is observable in dark-adapted intact, photosynthetic membranes (Dismukes, G.C., Abramowicz, D.A., Ferris, F.K., Mathur, P., Upadrashta, B. and Watnick, P. (1983) in The Oxygen-Evolving System of Plant Photosynthesis (Inoue, Y., ed.), pp. 145–158, Academic Press, Tokyo) and in detergent-extracted, O₂-evolving Photosystem-II particles (Abramowicz, D.A., Raab, T.K. and Dismukes, G.C. (1984) Proceedings of the Sixth International Congress on Photosynthesis (Sybesma, C., ed.), Vol. I, pp. 349–354, Martinus Nijhoff/Dr. W. Junk Publishers, The Hague, The Netherlands), thus establishing a direct link with the O₂ evolving complex.     

Photoacoustic detection of photosynthetic oxygen evolution from leaves. Quantitative analysis by phase and amplitude measurements

The photoacoustic signal from an intact leaf was analyzed as a vectorial summation of photothermal and photosynthetic oxygen-evolution contributions. A method is outlined to estimate each contribution separately. The amplitude of the oxygen-evolution component relative to that of the photothermal singnal decreases as the modulation frequency increases due to two processes which specifically damp the oxygen-evolution modulation: (1) diffusion of oxygen from the chloroplasts to the cell boundary, and (2) electron-transfer reactions occurring between the photochemical act and oxygen evolution. The effects of the two processes are well separated and are observed over different ranges of modulation frequency. Analysis of the data leads to a consistent estimation of the oxygen diffusion coefficient and also to a preliminary idea on the limiting time constant on the donor side of Photosystem II. The dependence of the photoacoustic oxygen-evolution signal on the intensity of added nonmodulated background light is used to construct the light saturation curve of (gross) Photsynthesis, with an estimation of the ratio maximal rate / maximal quantum yield. The photoacoustic method is distinguished by its sensitivity and rapidity (a single measurement takes approx. 1 s), far better than any other method to measure gross photosynthesis. The only disadvantage is in the fact that the quantum yield of oxygen evolution is determined in a relative basis only. Attempts to calibrate the photoacoustic measurements in an absolute sense are underway.     

Investigation of double turnovers in Photosystem II charge separation and oxygen evolution with excitation flashes of different duration

The characteristics of double hitting in Photosystem II charge separation and oxygen evolution in algae and chloroplasts were investigated with saturating excitation flashes of 3 μs, 300 ns and 5 ns duration. Two types of double hitting or advancement in S-states were found to occur in oxygen evolution: a non-photochemical type found even with 5 ns flashes and a photochemical type seen only with microsecond-long flashes, which have extensive tails. The non-photochemical type, occurring with a probability of about 3%, is sensitive to the physiological condition of the sample, and is only present in algae or chloroplast samples that have been freshly prepared. In chloroplasts incubated with ferricyanide, a 3-fold increase in double advancement of S-states is observed with xenon-flash illumination but not with 300 ns or 5 ns laser illumination. However, double turnovers in Photosystem II reaction center charge separation are large with xenon flash or 300 ns laser illumination but not with 5 ns laser illumination. This indicates that quite different kinetic processes are involved in double advancement in S-states for oxygen evolution and double turnovers in charge separation. Various models of the Photosystem II reaction center are discussed. Also, based on experiments with chloroplasts incubated with ferricyanide, an unique solution to the oxygen S-state distribution in the dark suggested by Thibault (Thibault, P. (1978) C.R. Acad. Sci. Paris 287, 725–728) can be rejected.     

Studies on thermoluminescence,delayed light emission and oxygen evolution from photosynthetic materials: UV effects

The effect of ultraviolet light on thermoluminescence, oxygen evolution and the slow component of delayed light has been investigated in chloroplasts and Pothos leaves. All peaks including peak V (48°C) were inhibited by UV. However, the peak at 48°C which was induced by DCMU was enhanced following UV irradiation of chloroplasts at ambient temperature (23°C) whereas peak II (-12°C) and peak III (10°C) which were also induced by DCMU were inhibited. Chloroplasts treated with DCMU and dark incubated for several minutes at ambient temperature prior to recording of glow curves have also shown enhancement of peak at 48°C. A slow component of delayed light and photosystem II activity of chloroplasts were inhibited by UV whereas photosystem I activity was marginally affected. These results corroborate involvement of photosystem II in generating thermoluminescence and slow components of delayed light in photosynthetic materials.Abbreviations DCIP Dichlorophenol Indophenol - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - DCQ 2,6 Dichloro-p-benzoquinone - DLE delayed light emission - MOPS Morpholino propane sulfonic acid - PSI Photosystem I - PS II Photosystem II - TL thermoluminescence