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1.
Michael Seibert  Jean Lavorel 《BBA》1983,723(2):160-168
Patterns of O2 evolution resulting from sequences of short flashes are reported for Photosystem (PS) II preparations isolated from spinach and containing an active, O2-evolving system. The results can be interpreted in terms of the S-state model developed to explain the process of photosynthetic water splitting in chloroplasts and algae. The PS II samples display damped, oscillating patterns of O2 evolution with a period of four flashes. Unlike chloroplasts, the flash yields of the preparations decay with increasing flash number due to the limited plastoquinone acceptor pool on the reducing side of PS II. The optimal pH for O2 evolution in this system (pH 5.5–6.5) is more acidic than in chloroplasts (pH 6.5–8.0). The O2-evolution, inactivation half-time of dark-adapted preparations was 91 min (on the rate electrode) at room temperature. Dark-inactivation half-times of 14 h were observed if the samples were aged off the electrode at room temperature. Under our conditions (experimental conditions can influence flash-sequence results), deactivation of S3 was first order with a half-time of 105 s while that of S2 was biphasic. The half-times for the first-order rapid phase were 17 s (one preflash) and 23 s (two preflashes). The longer S2 phase deactivated very slowly (the minimum half-time observed was 265 s). These results indicate that deactivation from S3 → S2 → S1, thought to be the dominant pathway in chloroplasts, is not the case for PS II preparations. Finally, it was demonstrated that the ratio of S1 to S0 can be set by previously developed techniques, that S0 is formed mostly from activated S3 (S4), and that both S0 and S1 are stable in the dark.  相似文献   

2.
J.L. Zimmermann  A.W. Rutherford 《BBA》1984,767(1):160-167
The light-induced EPR multiline signal is studied in O2-evolving PS II membranes. The following results are reported: (1) Its amplitude is shown to oscillate with a period of 4, with respect to the number of flashes given at room temperature (maxima on the first and fifth flashes). (2) Glycerol enhances the signal intensity. This effect is shown to come from changes in relaxation properties rather than an increase in spin concentration. (3) Deactivation experiments clearly indicate an association with the S2 state of the water-oxidizing enzyme. A signal at g = 4.1 with a linewidth of 360 G is also reported and it is suggested that this arises from an intermediate donor between the S states and the reaction centre. This suggestion is based on the following observations: (1) The g = 4.1 signal is formed by illumination at 200 K and not by flash excitation at room temperature, suggesting that it arises from an intermediate unstable under physiological conditions. (2) The formation of the g = 4.1 signal at 200 K does not occur in the presence of DCMU, indicating that more than one turnover is required for its maximum formation. (3) The g = 4.1 signal decreases in the dark at 220 K probably by recombination with Q?AFe. This recombination occurs before the multiline signal decreases, indicating that the g = 4.1 species is less stable than S2. (4) At short times, the decay of the g = 4.1 signal corresponds with a slight increase in the multiline S2 signal, suggesting that the loss of the g = 4.1 signal results in the disappearance of a magnetic interaction which diminishes the multiline signal intensity. (5) Tris-washed PS II membranes illuminated at 200 K do not exhibit the signal.  相似文献   

3.
Rita Barr  Frederick L. Crane 《BBA》1982,681(1):139-142
A 120 min incubation period with sulfhydryl reagents, such as p-chloromercuribenzoic acid, shows greater than 50% loss of electron-transport activity in Photosystem (PS) II of spinach chloroplasts. Since p-chloromercuriphenylsulfonic acid, a nonpenetrating sulfhydryl reagent, and 4,4′-dithiopyridine, a bifunctional sulfhydryl reagent, show greater inhibition of 3-(3,4-dichlorophenyl)-1,1-dimethylurea-insensitive silicomolybdate reduction than of dibromothymoquinone-insensitive indophenol reduction, it is postulated that two different sulfhydryl reagent-sensitive sites are involved in the PS II electron-transport chain of spinach chloroplasts.  相似文献   

4.
The quenching of Photosystem II (PS II) chlorophyll fluorescence by oxidised plastoquinone has been used in an attempt to determine their relative distribution in the partition zone and stroma-exposed thylakoid membranes. Thus, the PS II-plastoquinone interaction was determined in stacked (2.5 mM MgCl2) and largely unstacked (0.25 mM MgCl2) membranes. A method to correct for spillover or other quenching changes at the different MgCl2 concentrations, which would compete with the plastoquinone-induced quenching, was devised utilising the quinone dibromothymoquinone. This compound is demonstrated to behave as an ideal (theoretically) PS II quencher at both high and low MgCl2 concentrations, which indicates that it distributes itself homogeneously between partition zone and stroma-exposed membrane regions. In passing from the stacked to the unstacked configuration, the PS II-plastoquinone interaction decreases less than the PS II-dibromothymoquinone interaction. This is interpreted to mean that plastoquinone is present in both the partition zone and stroma-exposed membranes, with somewhat higher concentrations in the stroma-exposed membranes. Thus, plastoquinone is well placed to transport reducing equivalents from the partition zones to the stroma-exposed membranes.  相似文献   

5.
O2 uptake in spinach thylakoids was composed of ferredoxin-dependent and -independent components. The ferredoxin-independent component was largely 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) insensitive (60%). Light-dependent O2 uptake was stimulated 7-fold by 70 μM ferredoxin and both uptake and evolution (with O2 as the only electron acceptor) responded almost linearly to ferredoxin up to 40 μM. NADP+ reduction, however, was saturated by less than 20 μM ferredoxin. The affinity of O2 uptake for for O2 was highly dependent on ferredoxin concentration, with K12(O2) of less than 20 μM at 2 μM ferredoxin but greater than 60 μM O2 with 25 μM ferredoxin. O2 uptake could be suppressed up to 80% with saturating NADP+ and it approximated a competitive inhibitor of O2 uptake with a Ki of 8–15 μM. Electron transport in these thylakoids supported high rates of photophosphorylation with NADP+ (600 μmol ATP/mg Chl per h) or O2 (280 μmol/mg Chl per h) as electron acceptors, with ATP2e ratios of 1.15–1.55. Variation in ATP2e ratios with ferredoxin concentration and effects of antimycin A indicate that cyclic electron flow may also be occurring in this thylakoid system. Results are discussed with regard to photoreduction of O2 as a potential source of ATP in vivo.  相似文献   

6.
The fluorescence yield of chloroplasts reflects the redox state of the electron acceptor of the Photosystem II reaction center, with increasing yield as the acceptor is reduced. Chemical reductive titrations of fluorescence yield in chloroplasts at room temperature indicate two distinct midpoint potentials, suggesting the possibility of Photosystem II electron acceptor heterogeneity. We have carried out a potentiometric titration of the fluorescence decay kinetics in spinach chloroplasts using a continuous mode-locked dye laser with low-intensity excitation pulses and a picosecond-resolution single-photon timing system. At all potentials the fluorescence decay is best described by three exponential components. As the potential is lowered, the slow phase changes 30-fold in yield with two distinct midpoint potentials, accompanied by a modest (3-fold) increase in the lifetime. The titration curve for the slow component of the fluorescence decay of spinach chloroplasts is best characterized by two single-electron redox reactions with midpoint potentials at pH 8.0 of +119 and ?350 mV, with corresponding relative contributions to the fluorescence yield of 49 and 51%, respectively. There is little change in the fast and middle components of the fluorescence decay. We found that the oxidized form of the redox mediator 2-hydroxy-1,4-naphthoquinone preferentially quenches the fluorescence, causing an anomalous decrease in the apparent midpoint of the high-potential transition. This effect accounts for a significant difference between the midpoint potentials that we observe and some of those previously reported. The selective effect of reduction potentials on particular fluorescence decay components provides useful information about the organization and distribution of the Photosystem II electron acceptor.  相似文献   

7.
After isolated chloroplast thylakoids have been transferred to a medium which is more alkaline than their storage medium, they retain considerable amounts of unequilibrated protons for often longer than 10 min. Essentially all of these protons are released upon uncoupler addition when the thylakoids are osmotically swollen, but only a portion of them when they are in a shrunken state. Osmotic swelling also greatly accelerates the inactivation of the water-oxidizing system enzyme of Photosystem II, and its depletion of functional Cl?, at alkaline pH. Analyses of the mestable proton gradient in terms of stoichiometry, temperature dependence, and effect on fluorescent amine probes, suggest that most of the protons involved are bound and exchange readily with the bulk phases only when the thylakoids are swollen. It is concluded that, in shrunken thylakoids, the water-oxidizing enzymes are buried in special H+-sequestering domains which probably are formed by cavities in the inner surface of the thylakoid membrane. An observed cooperative action of alkaline pH and divalent cations during Cl?-extraction from Photosystem II is interpreted as revealing an involvement of both a negatively charged surface region and positively charged groups in maintaining the functional integrity of the site of water oxidization.  相似文献   

8.
Greg Smutzer  Jui H. Wang 《BBA》1984,766(1):240-244
A PS II preparation highly active in oxygen generation was prepared from the cyanophyte, Synechococcus lividus. This preparation was enriched in Hill reaction activity, manganese, cytochrome b-559, and possessed only trace amounts of cytochrome b-563. This non-phosphorylating, visually clear preparation appears to be a promising system for the detailed study of Photosystem II.  相似文献   

9.
Rita Barr  Frederick L. Crane 《BBA》1980,591(1):127-134
Two possible 3-(3,4-dichlorophenyl)-1,1-dimethylurea-insensitive sites were found in PS II of spinach chloroplasts, depending on the pH of the assay medium used. The low site (pH 6) can be inhibited by certain quinolines, such as 8-hydroxyquinoline at concentrations less than 50 μM. The high pH site (pH 8) can be inhibited by disodium cyanamide, folic acid, or 5,6-benzoquinoline at concentrations from 50 μM to 5 mM. With the exception of orthophenanthroline, which stimulates the high pH site but does not show much inhibition at low pH, all other inhibitors gave opposite effects at the pH values used, i.e., they stimulated at low pH or inhibited at high pH, or vice versa. Several mechanisms for the observed effects are discussed.  相似文献   

10.
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.  相似文献   

11.
The addition of linolenic acid to thylakoids produces various pH-dependent effects. We have demonstrated a binding site near the Photosystem (PS) II center with a pKa of 6.5: when linolenic acid is unprotonated it induces in the dark a rise of the initial fluorescence level, the latter being similar to the maximum fluorescence obtained during illumination of untreated thylakoids. The comparison of the fluorescence lifetimes in the presence and absence of linolenic acid leads us to conclude that the charge stabilisation on the primary acceptor, Q, is prevented by linolenic acid. A second binding site on the protein carrying B, the secondary acceptor of PS II, has also been demonstrated for linolenic acid. It has a 3-(3,4-dichlorophenyl)-1,1-dimethylurea-type effect both in the protonated and unprotonated forms. Finally, measurements of electrophoretic mobility of the thylakoids indicate several other sites of linolenic acid inclusion with an average pKa of 5.7. At alkaline pH the presence of unprotonated linolenic acid increases the charge density on the membrane. As a result a higher concentration of divalent cations is needed to obtain fluorescence and stacking changes than for untreated thylakoids. The presence, at acidic pH values, of the unprotonated form of linolenic acid leads to the inhibition of cation-induced fluorescence changes, probably by preventing the movement of chlorophyll-protein complexes in the membrane.  相似文献   

12.
Yeda press disruption of thylakoids in the presence of magnesium followed by aqueous polymer two-phase partitioning fractionated the total thylakoid membrane material into two distinctly different fractions. One fraction comprised approx. 60% of the material on a chlorophyll basis and contained inside-out vesicles while the other fraction (40%) contained right-side-out vesicles. The sidedness of the vesicles was determined from the direction of their light-induced proton translocation. The inside-out vesicles showed a pronounced Photosystem (PS) II enrichment as judged by their high PS II and low PS I activities. Moreover, they showed a high ratio between the PS II reaction centre chlorophyll-protein complex and the PS I reaction centre chlorophyll-protein complex (CP I). The chlorophyll ab ratio was as low as 2.3 compared to 3.2 for the starting material. In contrast, the right-side-out vesicles showed a pronounced PS I enrichment. Their chlorophyll ab ratio was 4.3–4.9. The tight stacking induced by Mg2+ allows a quantitative formation of inside-out vesicles from the appressed thylakoid regions while mainly non-appressed thylakoids turn right-side-out. The possibility of fractionating all of the thylakoid material into two sub-populations with markedly different composition with respect to PS I and PS II argues against a close physical association between the two photosystems and in favour of their spatial separation in the plane of the membrane. This fractionation procedure, which can be completed within 1 h and gives high yields of both PS II inside-out thylakoids and PS I right-side-out thylakoids, should be very useful for facilitating and improving studies on both the transverse and lateral organization of the thylakoid membrane.  相似文献   

13.
An O2-evolving Photosystem (PS) II preparation was isolated from maize by a Triton X-100 procedure (Kuwabara, T. and Murata, N. (1982) Plant Cell Physiol. 23, 533–539). A highly active O2-evolving preparation was obtained which evolved O2 at 76% the rate of fresh chloroplasts (H2O → 2,6-dichloro-p-benzoquinone) and was very sensitive to 3-(3,4-dichlorophenyl)-1,1-dimethylurea. There was no detectable PS I activity in the preparation (2,3,5,6-tetramethyl-p-phenylenediamine → methyl viologen). When analyzed by lithium dodecyl sulfate (LDS) polyacrylamide gel electrophoresis the O2-evolving preparation was shown to be highly depleted in CP I, CF1, and devoid of cytochromes f and b-563 (the absence of which was confirmed by difference spectroscopy). The preparation was enriched in the PS II reaction center polypeptides I and II, the 34 kDa polypeptide (Metz, J., Wong, J. and Bishop, N.I. (1980) FEBS Lett. 114, 61–66), the Coomassie blue-stainable 32 kDa polypeptide (Kuwabara, T. and Murata, N. (1979) Biochim. Biophys. Acta 581, 228–236), LHCP-associated polypeptides and cytochrome b-559. Polypeptides of unknown function at 40.5, 25, 24, 22, 16.6 and 14 kDa were also present in the O2-evolving preparation. Triton X-114 phase partitioning (Bricker, T.M. and Sherman, L.A. (1982) FEBS Lett. 149, 197–202) indicated that the majority of these polypeptides were intrinsic. Only the polypeptides at 32, 25, 24 and 14 kDa were extrinsic. When examined by the octylglucoside procedure of Camm and Green (Camm, E.L. and Green, B.R. (1980) Plant Physiol. 66, 428–432) the PS II O2-evolving preparation was shown to contain the chlorophyll-proteins CP 27, CP 29, CP II1, D, and CP a-1 and CP a-2. Chlorophyll-proteins associated with PS I were highly depleted. The visible absorption spectra indicated an enrichment of chlorophyll b and carotenoids in the preparation. The 77 K fluorescence emission spectrum (excitation wavelength = 435 nm) exhibits a strong F-686 with little F-695 shoulder and a broad, low-intensity F-735 emission.  相似文献   

14.
An O2-evolving Photosystem II subchloroplast preparation was obtained from spinach chloroplasts, using low concentrations of digitonin and Triton X-100. The preparation showed an O2 evolution activity equivalent to 20% of the uncoupled rate of fresh broken chloroplasts, but had no significant Photosystem-I-dependent O2 uptake activity. The preparation showed a chlorophyll ab ratio of 1.9 and a P-700chlorophyll ratio of 12400. Absorption spectra at room temperature and fluorescence emission spectra of chlorophyll at 77 K suggested a significant decrease in Photosystem I antenna chlorophylls in the O2-evolving Photosystem II preparation.  相似文献   

15.
Jane M. Bowes  Antony R. Crofts 《BBA》1981,637(3):464-472
(1) If DCMU is added to chloroplasts which have been preilluminated (0–8 flashes) the turnover of the water-splitting enzyme is limited to one further transition upon continuous illumination. (2) The intensity of millisecond delayed fluorescence measured in the presence of mediators of cyclic electron transport around Photosystem I and of DCMU added after pre-flashing is stimulated above the level in the presence of DCMU alone and varies according to the number of pre-flashes (Bowes, J.M. and Crofts, A.R. (1978) Z. Naturforsch 33c, 271–275). (3) Separate contributions of the following energetic terms to the induction kinetics and extent of millisecond delayed fluorescence under these conditions have been examined with a view to assessing their involvement in and the mechanism of the stimulation of the emission above the level in dark-adapted chloroplasts in the presence of DCMU: (a) the initial pH of the phase in equilibrium with the water-splitting enzyme; (b) the change in internal pH which occurred when Photosystem I acted as a proton pump; (c) the electrical potential difference across the membrane resulting from rapid charging of the membrane capacitance. (4) It was confirmed that delayed light was stimulated as a result of the interaction of the intrathylakoid pH (3a and b) with the equilibria of the S-states involving proton release according to the model in which this occurs on all except the transition S1 → S2; the stimulation was qualitatively proportional to the number of protons released. (5) There was no marked variation of the membrane potential as a function of the number of pre-flashes.  相似文献   

16.
6-Azido-5-decyl-2,3-dimethoxy-p-benzoquinone (6-azido-Q0C10) was found to replace the native plastoquinone at B (the second stable electron acceptor to Photosystem II (PS II)). The 6-azido-Q10C10 would accept electrons from the primary electron-accepting quinone, Q, thus allowing electron transport through PS II to the plastoquinone pool in thylakoids. The synthetic azidoquinone also competes with the PS II herbicides ioxynil and atrazine for binding. This observation strongly favors the hypothesis that PS II herbicides block electron transport by replacing the native quinone which acts as the second electron carrier on the reducing side of PS II (termed B). Covalent linkage of 6-azido-Q0C10 to its binding environment by ultraviolet irradiation greatly reduces herbicide-binding affinity but does not lead to a loss in herbicide-binding sites. We take this as evidence that covalent attachment of 6-azido-Q0C10 allows some freedom of quinone head-group movement such that the herbicides can enter the binding site. This indicates that the protein determinants which regulate quinone and herbicide binding are very closely related, but not identical. A compound somewhat related to 6-azido-Q0C10 is 2-azido-3-methoxy-5-geranyl-6-methyl-p-benzoquinone (2-azido-Q2). This compound was found to be an ineffective competitor with respect to herbicide binding. Thus, interactions with protein-binding determinants are highly dependent on the molecular structure of quinones. The 2-azido-Q2 was an inhibitor of electron flow in the intersystem portion of the chain.  相似文献   

17.
Inside-out thylakoid vesicles have been separated from right-side-out material after press disruption of chloroplast lamellae. The separation was obtained by partition in an aqueous dextran-polyethylene glycol two-phase system, a method which utilizes differences in surface properties for separation of membrane particles. The isolated thylakoid vesicles showed the following inside-out properties: (1) light-induced reversible proton extrusion into the surrounding medium when supplied with the Photosystem II electron acceptor phenyl-p-benzoquinone; (2) a pH rise in the internal phase accompanying the external proton release, (3) sensitivity to trypsin treatment different from that of thylakoid membranes of normal orientation; (4) concave EF and convex PF freeze-fracture faces.  相似文献   

18.
19.
Sándor Demeter  Imre Vass 《BBA》1984,764(1):24-32
In the glow curves of chloroplasts excited by a series of flashes at +1°C the intensity of the main thermoluminescence band appearing at +30°C (B band; B, secondary acceptor of Photosystem II) exhibits a period-4 oscillation with maxima on the 2nd and 6th flashes indicating the participation of the S3 state of the water-splitting system in the radiative charge recombination reaction. After long-term dark adaptation of chloroplasts (6 h), when the major part of the secondary acceptor pool (B pool) is oxidized, a period-2 contribution with maxima occurring at uneven flash numbers appears in the oscillation pattern. The B band can even be excited at ?160°C as well as by a single flash in which case the water-splitting system undergoes only one transition (S1 → S2). The experimental observations and computer simulation of the oscillatory patterns suggest that the B band originates from charge recombination of the S2B? and S3B? redox states. The half-time of charge recombination responsible for the B band is 48 s. When a major part of the plastoquinone pool is reduced due to prolonged excitation of the chloroplasts by continuous light, a second band (Q band; Q, primary acceptor of Photosystem II) appears in the glow curve at +10°C which overlaps with the B band. In chloroplasts excited by flashes prior to DCMU addition only the Q band can be observed showing maxima in the oscillation pattern at flash numbers 2, 6 and 10. The Q band can also be induced by flashes after DCMU addition which allows only one transition of the water-splitting system (S1 → S2). In the presence of DCMU, electrons accumulate on the primary acceptor Q, thus the Q band can be ascribed to the charge recombination of either the S2Q? or S3Q? states depending on whether the water-splitting system is in the S2 or the S3 state. The half-time of the back reaction of Q? with the donor side of PS II (S2 or S3 states) is 3 s. It was also observed that in a sequence of flashes the peak positions of the Q and B bands do not depend on the advancement of the water-splitting system from the S2 state to the S3 state. This result implies that the midpoint potential of the water-splitting system remains unmodified during the S2 → S3 transition.  相似文献   

20.
Steven M. Theg  Peter H. Homann 《BBA》1982,679(2):221-234
Studies of the association of Cl? with Photosystem (PS) II in CF1-containing thylakoid membranes revealed that photosynthetically active Cl? is retained in a Cl?-free medium unless it is sufficiently alkaline, uncoupling conditions are established and light is excluded. After treatment under such conditions, electron transport from water became dependent on added Cl? under all conditions. Quantitative measurements of 36Cl? retention in the light revealed that there were about five Cl? anions present in Cl?-sufficient chloroplasts per PS II reaction center, and one-fourth of that in Cl?-deficient samples. Uncouplers representing three different types of uncoupling mechanism were found to be effective mediators of Cl? release from thylakoids. Since the ability to collapse a proton gradient probably is the only property shared by all the tested uncouplers, a proton gradient may be involved in the retention of Cl?. As uncoupler-mediated Cl? release did not depend on preillumination of our samples, a long-lived proton gradient must exist in dark-adapted chloroplasts which may not span the whole thickness of the thylakoid membrane. It is postulated that the Cl? active in PS II reactions resides in a special membrane domain from which protons slowly equilibrate with those in the bulk solutions. Cl? is thought to be released to the bulk phases only when the pH of the membrane domain is raised above a certain threshold by the action of uncouplers. This domain may be identical to the intramembranous compartment which has been postulated to be associated with PS II (Prochaska, L.J. and Dilley, R.A., (1978) Front. Biol. Res. Energ. 1, 265–274).  相似文献   

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