Anion-dependent changes of energy transfer in chloroplasts III. Evidence for inactivation of light-triggered adenosine triphosphatase in chloroplasts by chloride

Washing chloroplasts with a high concentration of Tris-Cl^- buffercaused Cl^- dependent inhibition of photophosphorylation, light-inducedpH rise and light-triggered Mg²⁺-dependent ATPase activity.The inhibition of these activities was largely prevented bythe presence of 10^–4 M ADP or ATP during Tris washing,especially that of Mg²⁺-ATPase activity. The results were interpretedas suggesting that the inactivation of light-triggered ATPaseactivity in chloroplasts by chloride is one of the causes ofthe uncoupling of chloroplasts with Tris washing. (Received April 30, 1974; )     

Effects of manganese, calcium, dithiothreitol and bovine serum albumin on the light-reactivation of Tris-acetone-washed chloroplasts

Oxygen-evolution activity of spinach chloroplasts was investigatedby washing chloroplasts with 0.8M Tris buffer containing 20%acetone. This inactivitation was easily removed by two successivetreatments, dark- and light-reactivations. The first treatmentwas dark-reactivation step, rewashing inactivated chloroplastswith reduced DPIP (DPIP treatment). The second one was a light-reactivatedchloroplasts with incubating chloroplasts with Mn²⁺, Ca²⁺, dithiothreitoland bovine serum albumin under ilumination. Both light- and dark-reactivation treatments were required toregain oxygen-evolution activity of Tris-acetone-washed chloroplasts,which is characteristic of such chloroplasts. However, in Tris-washedchloroplasts considerable activity was recovered by dark-reactivationalone. Manganese and calcium contents of Tris-acetone-washed chloroplastswere compared with those of chloroplasts obtained by other preparations. Tris-acetone washing was presumed to inhibit the oxygen-evolutionsite of Photo-systetm II by affecting Mn, Ca and other substancesin chloroplasts. The inhibition site was estimated from a changein fluorescence yield of chlorophyll and the effect of artificialelectron donor specific for Photosystem II on NADP photoreductionactivity. (Received August 20, 1973; )     

Rates of vectorial proton transport supported by cyclic electron flow during oxygen reduction by illuminated intact chloroplasts

The light-dependent quenching of 9-aminoacridine fluorescence was used to monitor the state of the transthylakoid proton gradient in illuminated intact chloroplasts in the presence or absence of external electron acceptors. The absence of appreciable light-dependent fluorescence quenching under anaerobic conditions indicated inhibition of coupled electron transport in the absence of external electron acceptors. Oxygen relieved this inhibition. However, when DCMU inhibited excessive reduction of the plastoquinone pool in the absence of oxygen, coupled cyclic electron transport supported the formation of a transthylakoid proton gradient even under anaerobiosis. This proton gradient collapsed in the presence of oxygen. Under aerobic conditions, and when KCN inhibited ribulose bisphosphate carboxylase and ascorbate peroxidase, fluorescence quenching indicated the formation of a transthylakoid proton gradient which was larger with oxygen in the Mehler reaction as electron acceptor than with methylviologen at similar rates of linear electron transport. Apparently, cyclic electron transport occured simultaneously with linear electron transport, when oxygen was available as electron acceptor, but not when methylviologen accepted electrons from Photosystem I. The ratio of cyclic to linear electron transport could be increased by low concentrations of DCMU. This shows that even under aerobic conditions cyclic electron transport is limited in isolated intact chloroplasts by excessive reduction of electron carriers. In fact, P₇₀₀ in the reaction center of Photosystem I remained reduced in illuminated isolated chloroplasts under conditions which resulted in extensive oxidation of P₇₀₀ in leaves. This shows that regulation of Photosystem II activity is less effective in isolated chloroplasts than in leaves. Assuming that a Q-cycle supports a H⁺/e ratio of 3 during slow linear electron transport, vectorial proton transport coupled to Photosystem I-dependent cyclic electron flow could be calculated. The highest calculated rate of Photosystem I-dependent proton transport, which was not yet light-saturated, was 330 mol protons (mg chlorophyll h)^–1 in intact chloroplasts. If H⁺/e is not three but two proton transfer is not 330 but 220 mol (mg Chl H)^–1. Differences in the regulation of cyclic electron transport in isolated chloroplasts and in leaves are discussed.     

A rapid,light-induced transient in electron paramagnetic resonance signal II activated upon inhibition of photosynthetic oxygen evolution

A rapid, light-induced reversible component in Signal II is observed upon inhibition of oxygen evolution in broken spinach chloroplasts. The inhibitory treatments used include Tris washing, heat, treatment with chaotropic agents, and aging. This new Signal II component is in a 1 : 1 ratio with Signal I (P700). Its formation corresponds to a light-induced oxidation which occurs in less than 500 μs. The subsequent decay of the radical results from a reduction which occurs more rapidly as the reduction potential of the chloroplast suspension is decreased. The formation of this free radical component is complete following a single 10-μs flash, and it occurs with a quantum efficiency similar to that observed for Signal I formation. Red light is more effective than far-red light in the generation of this species, and, in preilluminated chloroplasts, 3-(3,4-dichlorophenyl)-1,1-dimethylurea blocks its formation. Inhibition studies show that the decline in oxygen evolution parallels the activation of this Signal II component.These results are interpreted in terms of a model in which two pathways, one involving water, the other involving the rapid Signal II component, compete for oxidizing equivalents generated by Photosystem II. In broken chloroplasts this Signal II pathway is deactivated and water is the principal electron donor. However, upon inhibition of oxygen evolution, the Signal II pathway is activated.     

Effect of phenolic herbicides on the oxygen-evolving side of Photosystem II. Formation of the carotenoid cation

Phenolic herbicides were added to suspensions of spinach chloroplasts or to oxygen-evolving Photosystem II membranes. Flash absorption spectroscopy at 21°C around 1000 nm reveals that these chemicals lead to a flash-induced absorption increase attributed to the radical-cation of a carotenoid. The herbicides studied can be arranged in the following order of decreasing efficiency for the reported effect: i-dinoseb, bromonitrothymol, trinitrophenol, ioxynil, dinitroorthocresol, 2,4-dinitrophenol. A similar effect was not observed with atrazine, DCMU or o-phenanthroline. For a given herbicide concentration, the amount of flash-induced carotenoid cation increases sharply when the pH is lowered below 5.5. A similar effect does not take place with other molecules which induce the formation of a carotenoid cation: tetraphenylboron, FCCP, 2-(3-chloro-4-trifluoromethyl)anilino-3,5-dinitrothiophene (ANT-2p). The previous effects are observed in both oxygen-evolving Photosystem II and in preparations in which oxygen evolution is inhibited with alkaline Tris. In untreated material, the carotenoid cation is formed with a half-time of 10–35 μs. After Tris treatment, this half-time is a little longer at low than at high pH. These results indicate the existence of a specific site where phenolic inhibitors interact in the oxygen-evolving site of Photosystem II     

Light-induced Mg2+ ATPase activity of coupling factor in intact chloroplasts

Intense illumination of isolated, intact, spinach chloroplasts triggers the well known proton-pumping Mg²⁺ ATPase activity of coupling factor, which can be assayed in subsequently lysed chloroplasts by monitoring ATP-driven quenching of 9-aminoacridine fluorescence. The light-triggered ATPase activity decays slowly in the dark and is inhibited by N,N′-dicyclohexylcarbodiimide. After osmotic lysis and washing of the chloroplasts, preillumination no longer triggers maximal proton-pumping ATPase until methylviologen and dithiothreitol are added to the medium. It is suggested that intact organelles contain soluble or loosely bound cofactors necessary for light-triggering of coupling factor ATPase. On osmotic lysis, these endogenous cofactors are diluted or inactivated and must be replaced by addition of a dithiol reagent and an electron acceptor.     

Inhibitory effect of p-nitrothiophenol in the light on the photosystem II activity of spinach chloroplasts.

The treatment of spinach chloroplasts with p-nitrothiophenol in the light at acidic and neutral pH'S caused specific inhibition of the Photosystem II activity, whereas the same treatment in the dark did not affect the activity at all. The photosystem I activity was not inhibited by p-nitrothiophenol both in the light and in the dark. The inhibition was accompanied by changes of fluorescence from chloroplasts. As observed at room temperature, the 685-nm band was lowered by the p-nitrothiophenol treatment in the light and, at liquid nitrogen temperature, the relative height of the 695-nm band to the 685-nm band increased and the 695-nm band shifted to longer wavelengths. The action spectra for these effects of p-nitrothiophenol on the activity and fluorescence showed a peak at 670 nm with a red drop at longer wavelengths. It was concluded that the light absorbed by Photosystem II is responsible for the chemical modification of chloroplasts with p-nitrothiopehnol to causing the specific inhibition of Photosystem II.     

Similarity of EPR Signal IIf rise and P-680+ decay kinetics in Tris-washed chloroplast Photosystem II preparations as a function of pH

The rise time, of Signal II_f and the decay time of P-680⁺ have been measured kinetically as a function of pH by using EPR. The Photosystem II-enriched preparations which were used as samples were derived from spinach chloroplasts, and they evolved oxygen before Tris washing. The onset kinetics of Signal II_f are in agreement, within experimental error, with the fast component of the decay of an EPR signal attributable to P-680⁺. The signal II_f rise kinetics also show good agreement with published values of the pH dependence of the decay of P-680⁺ measured optically (Conjeaud, H. and Mathis, P. (1980) Biochim. Biophys. Acta 590, 353–359). These results are consistent with a model where the species Z (or D₁) responsible for Signal II_f is the immediate electron donor to P-680⁺ in tris-washed Photosystem II fragments.     

Kinetic study of oxygen evolution parameters in Triswashed, reactivated chloroplasts.

Tris-washed chloroplasts which have lost the ability to evolve oxygen can be reactivated by the procedure of Yamashita T., Tsuji, J. and Tomita G. (1971) Plant Cell Physiol. 12, 117-126) [7] to give 100 percent of the rate of control chloroplasts in continuous illumination. Furthermore, in flashing light the reactivated chloroplasts exhibit oxygen-yield oscillations of period four that are characteristic of the control. Similar kinetic parameters for intermediate steps in the water-splitting process are observed for the two preparations. We conclude that the reactivation procedure restores the native oxygen evolution mechanism to Tris-washed chloroplasts. A relatively rapid and reversible (0.5 s decay) light-induced component of EPR Signal II is observed upon inhibition of O2 evolution by Tris washing (Babcock G. T. and Sauer, K. (1975) Biochim. Biophys. Acta 376, 315-328) [10]. Reactivated chloroplasts are similar to untreated chloroplasts in that this Signal IItransient is not observed. Manganese, which is released by Tris treatment to the interior of the thylakoid membrane in an EPR-detectable state, is returned to an EPR-undetectable state by reactivation. The reactivation procedure does not require light to restore O2 evolution and EDTA has no effect on the extent of reactivation. These results are discussed in terms of possible mechanisms for manganese incorporation into photosynthetic membranes.     

Primary and secondary electron donors in photosystem II of chloroplasts. Rates of electron transfer and location in the membrane.

Absorption changes at 820 or 515 nm after a short laser flash were studied comparatively in untreated chloroplasts and in chloroplasts in which oxygen evolution is inhibited. In chloroplasts pre-treated with Tris, the primary donor of Photosystem II (P-680) is oxidized by the flash it is re-reduced in a biphasic manner with half-times of 6 microseconds (major phase) and 22 microseconds. After the second flash, the 6 microseconds phase is nearly absent and P-680+ decays with half-times of 130 microseconds (major phase) and 22 microseconds. Exogenous electron donors (MnCl2 or reduced phenylenediamine) have no direct influence on the kinetics of P-680+. In untreated chloroplasts the 6 and 22 microseconds phases are of very small amplitude, either at the 1st, 2nd or 3rd flash given after dark-adaptation. They are observed, however, after incubation with 10 mM hydroxylamine. These results are interpreted in terms of multiple pathways for the reduction of P-680+: a rapid reduction (less than 1 microseconds) by the physiological donor D1; a slower reduction (6 and 22 microseconds) by donor D'1, operative when O2 evolution is inhibited; a back-reaction (130 microseconds) when D'1 is oxidized by the pre-illumination in inhibited chloroplasts. In Tris-treated chloroplasts the donor system to P-680+ has the capacity to deliver only one electron. The absorption change at 515 nm (electrochromic absorption shift) has been measured in parallel. It is shown that the change linked to Photosystem II activity has nearly the same magnitude in untreated chloroplasts or in chloroplasts treated with hydroxylamine or with Tris (first and subsequent flashes). Thus we conclude that all the donors (P-680, D1, D'1) are located at the internal side of the thylakoid membrane.     

Hydroxylamine,hydrazine and methylamine donate electrons to the photooxidizing side of Photosystem II in leaves inhibited in oxygen evolution due to water stress

When leaf discs are water stressed, they lose the capacity for photosynthetic oxygen evolution and variable (chlorophyll a) fluorescence. Such a loss of variable fluorescence was previously reported by Govindjee et al. (Plant Sci. Lett. 20 (1981) 191–194). The later activity is not lost if prior to the water-stress treatment the leaf is incubated with typical water analogs known to act as electron donors to Photosystem II, such as hydroxylamine and hydrazine. Methylamine also acts in the same fashion. These results indicate that one of the sites of drought damage is the oxidizing side of Photosystem II, and that electron donors can restore electron transport, at least to the plastoquinone pool, similar to their effect in Tris treatment of isolated chloroplasts.     

Light-induced Mg2+ ATPase activity of coupling factor in intact chloroplasts.

Intense illumination isolated, intact, spinach chloroplasts triggers the well known proton-pumping Mg2+ ATPase activity of coupling factor, which can be assayed in subsequently lysed chloroplasts by monitoring ATP-driven quenching of 9-aminoacridine fluorescence. The light-triggered ATPase activity decays slowing in the dark and is inhibited by N,N'-dicyclohexylcarbodiimide. After osmotic lysis and washing of the chloroplasts, preillumination no longer triggers maximal proton-pumping ATPase until methylviologen and dithiothreitol are added to the medium. It is suggested that intact organelles contain soluble or loosely bound cofactors necessary for light-triggering of coupling factor ATPase. On osmotic lysis, these endogenous cofactors are diluted or inactivated and must be replaced by addition of a dithiol reagent and an electron acceptor.     

Effect of hydrogen ion buffers on photosynthetic oxygen evolution in the blue-green alga, Agmenellum quadruplicatum.

The photosynthetic oxygen evolution capacity of Agmenelium quadruplication suspended in four hydrogen ion buffers (pH 7.4, 0.05 M) and its synthetic marine growth medium was measured with an oxygen electrode. High rates of oxygen evolution were obtained in the growth medium and N-tris(hydroxymethyl)-methylglycine (Tricine) buffer. Compared to oxygen evolution in the growth medium, rates in phosphate buffer and N-tris(hydroxymethyl)-2-aminoethanesulphonic acid (TES) buffer were sometimes reduced by up to 30% and rates in tris (hydroxymethyl) amino-methane (Tris) were consistently reduced by 50%. An incubation-rinsing procedure caused inhibition of oxygen evolution in TES, phosphate, and Tris by 50 to 100%. Oxygen evolution could be restored to cells rinsed in TES or phosphate by resuspension in growth medium or in buffer plus magnesium and calcium ions. Bezoquinone-supported oxygen evolution was not affected by rinsing with any buffer tested except Tris. Ferricyanide was photoreduced at a low rate by cells rinsed in Tes but at a high rate in TES plus magnesium and calcium ions. We interpreted our results to mean that, in Agmenellum quadruplicatum, inhibition of photosynthetic oxygen evolution by Tris occurs at the level of photosystem 2 while the effects of TES and phosphate are on electron-transport occurring after the rate-limiting reaction.     

Primary and secondary electron donors in Photosystem II of chloroplasts. Rates of electron transfer and location in the membrane

Absorption changes at 820 or 515 nm after a short laser flash were studied comparatively in untreated chloroplasts and in chloroplasts in which oxygen evolution is inhibited.In chloroplasts pre-treated with Tris, the primary donor of Photosystem II (P-680) is oxidized by the flash, as observed by an absorption increase at 820 nm. After the first flash it is re-reduced in a biphasic manner with half-times of 6 μs (major phase) and 22 μs. After the second flash, the 6 μs phase is nearly absent and P-680⁺ decays with half-times of 130 μs (major phase) and 22 μs. Exogenous electron donors (MnCl₂ or reduced phenylenediamine) have no direct influence on the kinetics of P-680⁺.In untreated chloroplasts the 6 and 22 μs phases are of very small amplitude, either at the 1st, 2nd or 3rd flash given after dark-adaptation. They are observed, however, after incubation with 10 mM hydroxylamine.These results are interpreted in terms of multiple pathways for the reduction of P-680⁺: a rapid reduction (<1 μs) by the physiological donor D₁; a slower reduction (6 and 22 μs) by donor D′₁, operative when O₂ evolution is inhibited; a back-reaction (130 μs) when D′₁ is oxidized by the pre-illumination in inhibited chloroplasts. In Tris-treated chloroplasts the donor system to P-680⁺ has the capacity to deliver only one electron.The absorption change at 515 nm (electrochromic absorption shift) has been measured in parallel. It is shown that the change linked to Photosystem II activity has nearly the same magnitude in untreated chloroplasts or in chloroplasts treated with hydroxylamine or with Tris (first and subsequent flashes). Thus we conclude that all the donors (P-680, D₁, D′₁) are located at the internal side of the thylakoid membrane.     

Reactivation of the Hill reaction of Tris-washed chloroplasts

The Hill reaction of chloroplasts was inhibited by washing themwith 0.8 M Tris buffer. This inhibition was further promotedby adding ferricyanide in the washing medium. When a reducingreagent, such as the 2,6-dichlorophenol indophenol (DCPIP)-ascorbatesystem or the hydroquinone (HQJ-ascorbate system, had been addedto the Tris buffer, Hill reaction activity was unaffected. Hill reaction activity of Tris-washed chloroplasts recoveredup to 70% of the initial level by re-washing the chloroplastswith a preparation medium containing theabove reducing reagents. Photobleaching of carotenoid and chlorophyll is characteristicof Tris-washed chloroplasts. However, reactivated chloroplastsshowed no photobleaching as in the case with intact chloroplasts. (Received April 20, 1970; )     

Kinetic study of oxygen evolution parameters in tris-washed,reactivated chloroplasts

Tris-washed chloroplasts which have lost the ability to evolve oxygen can be reactivated by the procedure of Yamashita. T., Tsuji, J. and Tomita, G. ((1971)Plant Cell Physiol. 12, 117–126) [7] to give 100% of the rate of control chloroplasts in continuous illumination. Furthermore, in flashing light the reactivated chloroplasts exhibit oxygen-yield oscillations of period four that are characteristic of the control. Similar kinetic parameters for intermediate steps in the water-splitting process are observed for the two preparations. We conclude that the reactivation procedure restores the native oxygen evolution mechanism to Tris-washed chloroplasts.A relatively rapid and reversible (0.5 s decay) light-induced component of EPR Signal II is observed upon inhibition of O₂ evolution by Tris washing (Babcock G. T. and Sauer, K. (1975) Biochim. Biophys. Acta 376, 315–328) [10]. Reactivated chloroplasts are similar to untreated chloroplasts in that this Signal II transient is not observed. Manganese, which is released by Tris treatment to the interior of the thylakoid membrane in an EPR-detectable state, is returned to an EPR-undetectable state by reactivation. The reactivation procedure does not require light to restore O₂ evolution and EDTA has no effect on the extent of reactivation. These results are discussed in terms of possible mechanisms for manganese incorporation into photosynthetic membranes.     

Inhibitory effect of p-nitrothiophenol in the light on the Photosystem II activity of spinach chloroplasts

The treatment of spinach chloroplasts with p-nitrothiophenol in the light at acidic and neutral pH's caused specific inhibition of the Photosystem II activity, whereas the same treatment in the dark did not affect the activity at all. The photosystem I activity was not inhibited by p-nitrothiophenol both in the light and in the dark. The inhibition was accompanied by changes of fluorescence from chloroplasts. As observed at room temperature, the 685-nm band was lowered by the p-nitrothiophenol treatment in the light and, at liquid nitrogen temperature, the relative height of the 695-nm band to the 685-nm band increased and the 695-nm band shifted to longer wavelengths. The action spectra for these effects of p-nitrothiophenol on the activity and fluorescence showed a peak at 670 nm with a red drop at longer wavelengths. It was concluded that the light absorbed by Photosystem II is responsible for the chemical modification of chloroplasts with p-nitrothiophenol to causing the specific inhibition of Photosystem II.     

Photoreduction of 2,6-dichlorophenolindophenol by diphenylcarbazide: a photosystem 2 reaction catalyzed by tris-washed chloroplasts and subchloroplast fragments

The use of diphenylcarbazide as an electron donor coupled to the photoreduction of 2,6-dichlorophenolindophenol by tris-washed chloroplasts or subchloroplast fragments provides a simple and sensitive assay for photosystem 2 of chloroplasts. By varying the concentration of tris buffer at pH 8.0 during an incubation period it is shown that the destruction of oxygen evolution activity is accompanied by a corresponding emergence of an ability to photooxidize diphenylcarbazide, as evidenced by absorbance changes due to diphenylcarbazide at 300 nm. The temperature-sensitive oxidation of diphenylcarbazide is inhibited by DCMU and by high ionic strengths. This activity appears to measure the primary photochemical reaction of photosystem 2.     

The effects of digitonin on photochemical activities of isolated chloroplasts

The addition of digitonin to chloroplasts stimulated the rate of oxygen evolution followed by a gradual inhibition. The effect of digitonin was dependent on the digitonin to chlorophyll ratio and on temperature and time. The initial stimulation of oxygen evolution appeared to be a result of uncoupling as digitonin did not stimulate oxygen evolution by uncoupled chloroplasts. The stimulatory effect occurred more rapidly at high digitonin to chlorophyll ratios but the extent of stimulation was low and inhibition occurred soon after addition of the detergent. The inhibition of electron flow by digitonin was due to a site of action near photosystem II which resembled the inhibition reported for tris buffer and resulted in photobleaching. However, digitonin inhibition could not be recovered by washing with reducing agents and was only partially recovered by the addition of artificial electron donors to photosystem II. Electron flow mediated by photosystem I was unaffected by the addition of digitonin but was decreased when the chloroplasts were separated by subsequent centrifuging. This suggested that digitonin solubilizes photosystem I components which remain active in the soluble form.     

The rise in chlorophyll a fluorescence yield and decay in delayed light emission in Tris-washed chloroplasts in the 6–100 μs time range after an excitation flash

Parallel measurements of the rise in chlorophyll a fluorescence yield and delayed light emission decay, after a 10 ns saturating excitation flash, have been made in tris(hydroxymethyl)aminomethane-washed chloroplasts. Various electron donor systems (Mn²⁺; ascorbate; reduced phenylenediamine and benzidine) were used in conjuction with different preillumination regimes to alter [P⁺-680], the oxidized form of the Photosystem II reaction center chlorophyll a. Conditions giving rise to high [P⁺-680] resulted in only a small rise in fluorescence yield, an inhibition of a 6 μs delayed light component, and an enhancement of a 60 μs component of delayed light emission. These results confirm the hypothesis that P⁺-680 acts as a quencher of fluorescence and that delayed light emission in the microsecond time range is due to the back reaction of P⁺-680 and Q^?. (Q is the first “stable” electron acceptor of Photosystem II.) Two preillumination flashes are required before the full effect of Tris washing is observed in the delayed light emission decay and fluorescence yield rise; this suggests that a capacity to hold two charges exists between the Tris block and P⁺-680. Tris washing has no direct effect on the movement of electrons from Z (the first electron donor to P⁺-680) to P⁺-680. Finally, Mn²⁺ donates electrons to P⁺-680 via Z.