The existence of a high photochemical turnover rate at the reaction centers of System II in Tris-washed chloroplasts

In Tris-washed chloroplasts the kinetics of the primary electron acceptor X 320 of reaction center II has been investigated by fast repetitive flash spectroscopy with a time resolution of $\text{≈ 1 μs}$. It has been found that X 320 is reduced by a flash in $\text{? 1 μs}$. The subsequent reoxidation in the dark occurs mainly by a reaction with a 100–200 μs kinetics. The light-induced difference spectrum confirms X 320 to be the reactive species. From these results it is concluded that in Tris-washed chloroplasts the reaction centers of System II are characterized by a high photochemical turnover rate mediated either via rapid direct charge recombination or via fast cyclic electron flow.     

Studies on the functional organization of Photosystem II. The effect of protein-modifying procedures and of ADRY agents on the reaction pattern of photosystem II in Tris-washed chloroplasts

The role of the protein matrix embedding the functionally active redox components of Photosystem II reaction centers has been studied by investigating the effects of procedures which modify the structure of proteins. In order to reduce the influence of the electron transport involving secondary donor and acceptor components, Triswashed chloroplasts were used which are completely deprived of their oxygen-evolving capacity. The functional activity was detected via absorption changes, reflecting at 334 and 690 or 834 nm the turnover of the primary plastoquinone acceptor, X320, and of the photochemically active chlorophyll a complex, Chl a_II, respectively, and at 520 nm the transient formation of a transmembrane electric potential gradient. Under repetitive flash excitation of Tris-washed chloroplasts it was found that: (a) The relaxation kinetics at 690 nm become significantly accelerated in the presence of external electron donors. (b) Trypsin treatment blocks to a high degree the turnover of Chl a_II and X320 unless exogenous acceptors are present, which directly oxidize X320^?, such as K₃Fe(CN)₆. (c) In the presence of K₃Fe(CN)₆ the recovery kinetics of Chl a_II and X320 are retarded markedly by trypsin, followed by a progressive decline in the extent thereof. (d) 2-(3-Chloro-4-trifluoromethyl)anilino-3,5-dinitrothiophene (ANT 2p), known to reduce the lifetime of S₂ and S₃ in normal chloroplasts, significantly accelerates the recovery of Chl a_II. 10 μs kinetics are observed which correspond with the electron-transfer rate from D₁ to Chl a⁺_II. ANT 2p simultaneously retards the decay kinetics of X320^? and of the electrochromic absorption changes. (e) The kinetic pattern of the electrochromic absorption changes is also affected by the salt content of the suspension. Under dark-adapted conditions, the 10 μs relaxation kinetics of the 834 nm absorption change due to the first flash are hardly affected by mild trypsinization of 5–10 min duration, whereas the amplitude decreases by approx. 30%. The data obtained in Tris-washed chloroplasts could consistently be interpreted as a modification of the back reaction between X320^? and Chl a⁺_II which is caused solely by a change in the reactivity of X320 due to trypsin-induced degradation of the native X320-B apoprotein. Furthermore, ADRY agents are inferred to stimulate cyclic electron flow, which leads to reduction of D⁺₁ between the flashes. A simplified scheme is discussed which describes the functional organization of the reaction center complex.     

A rapid vectorial back reaction at the reaction centers of photosystem II in tris-washed chloroplasts induced by repetitive flash excitation.

In Tris-washed chloroplasts, completely lacking the oxygen-evolving capacity, absorption changes in the range of 420--560 nm induced by repetitive flash excitation have been measured in the presence and absence of electron donors. It was found: (1) At 520 nm flash-induced absorption changes are observed, which predominantly decay via a 100--200-mus exponential kinetics corresponding to that of the back reaction between the primary electron donor and acceptor of Photosystem II (Haveman, J. and Mathis, P. (1976) Biochim. Biophys. Acta 440, 346--355; Renger, G. and Wolff, Ch. (1976) Biochim. Biophys. Acta 423, 610--614). In the presence of hydroquinone/ascorbate as donor couple the amplitude is nearly doubled and the decay becomes significantly slowed down. (2) The difference spectrum of the absorption changes obtained in the presence of hydroquinone/ascorbate, which are sensitive to ionophores, is nearly identical with that of normal chloroplasts in the range of 460--560 nm (Emrich, H.M., Junge, W. and Witt, H.T. (1969) Z. Naturforsch. 24b, 114--1146). In the absence of hydroquinone/ascorbate the difference spectrum of the absorption changes, characterized by a 100--200-mus decay kinetics, differs in the range of 460--500 nm and by a hump in the range of 530--560 nm. The hump is shown to be attributable to the socalled C550 absorption change, which reflects the turnover of the primary acceptor of Photosystem II (van Gorkom, H.J.(1976) Thesis, Leiden), while the deviations in the range of 460--500 nm are understandable as to be due to the overlapping absorption changes of chlorphyll alpha II+. The problems arising with the latter explanation are discussed. (3) The electron transfer due to the rapid turnover at Photosystem II, which can be induced by flash groups with a short dark time between the flashes, is not able to energize the ATPase and to drive photophosphorylation. On the basis of the present results it is inferred, that in Tris-washed chloroplasts under repetitive flash excitation a rapid transmembrane vectorial electron shuttle takes place between the primary acceptor (X320) and donor (Chl alpha II) of Photosystem II, which is not able to energize the photophosphorylation. Furthermore, the data are shown to confirm the localization of X320 and Chl alpha II within the thylakoid membrane at the outer and inner side, respectively.     

Internal pH of human neutrophil lysosomes

We focus this report on the relationship between signal II fast and slow during a flash sequence for Tris-washed chloroplasts at different pH-values. The pH influences both the redox state and spectral form of signal II slow in dark-adapted chloroplasts. At pH 6.0, signal II slow is oxidized and does not influence the kinetics of signal II fast equally formed on each flash. At pH 8.5, signal II slow in mainly reduced in the dark and the first flash produces signal II slow and no signal fast. Signal II fast appears on the following flashes only. Signals II fast and slow are connected to the same center and signal II fast is observed only if signal II slow is oxidized.     

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

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

Precursors to microsecond delayed luminescence in oxygenevolving and inhibited chloroplasts

We have investigated submillisecond delayed luminescence in spinach chloroplasts under a variety of conditions. In Tris-washed chloroplasts, which are inhibited on the oxidizing side of P-680, the delayed light emission in the 7–200 μs time-range decayed with biphasic behavior. In fully dark-adapted samples illuminated by a single saturating laser pulse, the fast phase of delayed luminescence followed a nearly identical pH-dependent time-course as that observed optically and by ESR for P⁺-680 reduction, thus verifying the recombination hypothesis for the origin of delayed light. The observed slower phase of delayed luminescence was also pH dependent, but unlike the fast phase, could not be ascribed to specific electron transfer events of PS II. This phase could be rationalized by a heterogeneity in the population of P-680. While kinetic parameters were found to be insensitive to changes in ionic strength, the overall luminescence intensity was quite sensitive to the electrical parameters, thus indicating the role of ionic strength and local charges in delayed luminescence modulation. A similar series of experiments was performed on untreated chloroplasts. The pH-dependent delayed luminescence behavior in both untreated chloroplasts and Tris-washed chloroplasts was similar despite significantly faster kinetics associated with the reduction of P⁺-680 by the secondary PS II electron donor, Z, in the former preparation (e.g., Van Best, J.A. and Mathis, P. (1978) Biochim. Biophys. Acta 503, 178–188). Thus, it was concluded that, in untreated samples, microsecond delayed luminescence emanates primarily from centers which are not competent in oxygen evolution. The nearly identical delayed luminescence intensity in untreated chloroplasts and in Tris-washed chloroplasts was rationalized by a model which predicts modulations in delayed luminescence yield by the exciton-quenching effect of P⁺-680. Computer simulations demonstrate the feasibility of this model. The previously documented flash oscillations in microsecond delayed luminescence intensity in untreated chloroplasts (Bowes, J.M. and Crofts, A.R. (1979) Biochim. Biophys. Acta 547, 336–346), which we readily observed, were attributed to alterations in delayed luminescence yield (in nonfunctional centers) by variations in charge density stored at the oxygen-evolving complex of functional centers. Taken together, our results emphasize the dependence of delayed luminescence kinetics upon electron-transfer kinetics and the dependence of delayed luminescence amplitude upon the photochemical parameters, the exciton yield and the emission yield.     

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.     

The reduction kinetics of chlorophyll aI as an indicator for proton uptake between the light reactions in chloroplasts.

The flash-induced oxidation kinetics of the primary acceptor of light Reaction II (X-320) and the reduction kinetics of chlorophyll aI (P-700) after far-red preillumination have been studied with high time resolution in spinach chloroplasts. 1. The kinetics of chlorophyll aI exhibits a pronounced lag phase of 2--3 ms at the onset of reduction as would be expected for the final product of consecutive reactions. Because the oxidation of the plastoquinone pool is the rate-limiting step for the electron transport between the two light reactions, the lag indicates the maximal electron transfer time over all preceding reactions after light Reaction II. 2. The observation that the lag phase decreases with decreasing pH is evidence of an electron transfer step coupled to a proton uptake reaction. 3. Protonation of X-320 after reduction in the flash is excluded because a slight increase of the decay time is found at decreasing pH values. 4. The time course of plastohydroquinone formation is deduced from the first derivative of the reduction kinetics of chlorophyll aI. This approach covers those plastohydroquinone molecules being available to the electron carriers of System I via the rate-limiting step. Direct measurements of absorbance changes would not allow to discriminate between these and functionally different plastohydroquinone molecules. 5. The derived time course of plastohydroquinone at different pH gives evidence for an additional electron transfer step with a half time of about 1 ms following the proton uptake and preceding the rate-limiting step. It is tentatively attributed to the diffusion of neutral plastohydroquinone across the hydrophobic core of the thylkaloid membrane. 6. The lower limit of the rate constant for proton uptake by an electron carrier, consistent with the lag of chlorophyll aI reduction, is estimated as greater than 10(11) M-1s-1. The value is higher than that of the fastest diffusion controlled protonations of organic molecules in solution. Possible mechanisms of linear electron transport between light Reaction II and the rate-limiting oxidation of neutral plastohydroquinone are thoroughly discussed.     

The role of reagents accelerating the deactivation reactions of water-splitting enzyme system Y (ADRY reagents) in destabilizing high-potential oxidizing equivalents generated in chloroplast Photosystem II

A class of compounds, usually referred to as ADRY reagents, destabilize intermediates in the photosynthetic water-oxidizing process. The effects of these species on the reduction kinetics of Z^?, the oxidized donor to P-680, have been monitored in Tris-washed chloroplasts by following the decay of EPR Signal IIf. In the presence of ADRY reagents (e.g., sodium picrate, carbonyl cyanide m-chlorophenylhydrazone) this process follows an exponential time course, the decay half-time of which decreases as the ADRY reagent concentration increases. From this pseudo-first-order behavior, the second-order rate constants for four commonly used ADRY reagents have been extracted. The ADRY-induced acceleration in Z^? reduction proceeds independently of conditions imposed on the acceptor side of Photosystem II and shows no synergism with exogenous electron donors. These observations are most easily rationalized in terms of a model which proposes direct reduction of Z^? by the ADRY reagent followed by regeneration of the reduced ADRY reagent in a nonspecific reaction with membrane components such as carotenoids, chlorophyll or protein. A comparison of the second-order rate constants we obtain for ADRY reagents in their reaction with Z^? in Tris-washed chloroplasts with those obtained from the literature for the ADRY- reagent induced deactivation of states S₂ and S₃ in oxygen-evolving chloroplasts reveals a close similarity between the two processes. From this observation, a general model for the action of ADRY reagents in destabilizing the high-potential oxidizing equivalents generated in Photosystem II is proposed.     

A flash photolysis ESR study of photosystem II signal IIvf, the physiological donor to P-680+.

In flash-illuminated, oxygen-evolving spinach chloroplasts and green algae, a free radical transient has been observed with spectral parameters similar to those of Signal II (g approximately 2.0045, deltaHpp approximately 19G). However, in contrast with ESR Signal II, the transient radical does not readily saturate even at microwave power levels of 200 mW. This species is formed most efficiently with "red" illumination (lambda less than 680 nm) and occurs stoichiometrically in a 1:1 ratio with P-700+. The Photosystem II transient is formed in less than 100 mus and decays via first-order kinetics with a halftime of 400-900 mus. Additionally, the t1/2 for radical decay is temperature independent between 20 and 4 degrees C; however, below 4 degrees C the transient signal exhibits Arrhenius behavior with an activation energy of approx. 10 kcal-mol-1. Inhibition of electron transport through Photosystem II by o-phenanthroline, 3-(3,4-dichlorophenyl)-1,1-dimethylurea or reduced 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone suppresses the formation of the light-induced transient. At low concentrations (0.2 mM), 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone partially inhibits the free radical formation, however, the decay kinetics are unaltered. High concentrations of 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone (1-5 mM) restore both the transient signal and electron flow through Photosystem II. These findings suggest that this "quinoidal" type ESR transient functions as the physiological donor to the oxidized reaction center chlorophyll, P-680+.     

Effects of chloride depletion on electron donation from the water-oxidizing complex to the photosystem II reaction center as measured by the microsecond rise of chlorophyll fluorescence in isolated pea chloroplasts

The role of Cl^? in the electron transfer reactions of the oxidizing side of Photosystem II (PS II) has been studied by measuring the fluorescence yield changes corresponding to the reduction of P⁺-680, the PS II reaction center chlorophyll, by the secondary PS II donor, Z. In Cl^?-depleted chloroplasts, a rapid rise in fluorescence yield was observed following the first and second flashes, but not during the third or subsequent flashes. These results indicate that there exists an additional endogenous electron donor beyond P-680 and Z in Cl^?-depleted systems. In contrast, the terminal endogenous donor on the oxidizing side of PS II in Tris-washed preparations has previously been shown to be Z, the component giving rise to EPR signals II_f and II_vf. The rate of reduction of P⁺-680 in the Cl^?-depleted chloroplasts was as rapid as that measured in uninhibited systems, within the time resolution of our instrument. Again, this is in contrast to Tris-washed preparations in which a dramatic decrease in the rate if this reaction has been previously reported. We have also carried out a preliminary study on the rate of rereduction of Z⁺ in the Cl^?-depleted system. Under steady-state conditions, the reduction half-time of Z⁺ in uninhibited systems was about 450 μs, while in the Cl^?-depleted chloroplasts, the reduction of Z⁺ was biphasic, one phase with a half-time of about 120 ms, and a slower phase with a half-time of several seconds. The appearance of the quenching state due to P⁺-680 observed following the third flash on excitation of Cl^?-depleted chloroplasts was delayed by two flashed when low concentrations of NH₂OH (20–50 μM) were included in the medium. Hydrazine at somewhat higher concentrations showed the same effect. This is taken to indicate that the reactions leading to PS II oxidation of NH₂OH or NH₂NH₂ are uninhibited by Cl^? depletion. Addition of NH₂OH at low concentrations to Tris-washed chloroplasts did not alter the pattern of the fluorescence yield, indicating that the reactions leading to the NH₂OH oxidation present in Cl^?-depleted systems are absent following Tris inhibition. The results are discussed in terms of an inhibition by Cl^? depletion of the reactions of the oxygen-evolving complex. It is suggested that no intermediary redox couple exists between the oxygen-evolving complex and Z, and that Z⁺ is reduced directly by Mn of the complex. In terms of the S-state model, Cl^? depletion appears to inhibit the advancement of the mechanism beyond S₂, but not to inhibit the transitions from S₀ to S₁, or from S₁ to S₂.     

Flash-induced absorption changes of the primary donor of photosystem II at 820 nm in chloroplasts inhibited by low pH or tris-treatment.

A comparative study is made, at 15 degrees C, of flash-induced absorption changes around 820 nm (attributed to the primary donors of Photosystems I and II) and 705 nm (Photosystem I only), in normal chloroplasts and in chloroplasts where O2 evolution was inhibited by low pH or by Tris-treatment. At pH 7.5, with untreated chloroplasts, the absorption changes around 820 nm are shown to be due to P-700 alone. Any contribution of the primary donor of Photosystem II should be in times shorter than 60 mus. When chloroplasts are inhibited at the donor side of Photosystem II by low pH, an additional absorption change at 820 nm appears with an amplitude which, at pH 4.0, is slightly higher than the signal due to oxidized P-700. This additional signal is attributed to the primary donor of Photosystem II. It decays (t 1/2 about 180 mus) mainly by back reaction with the primary acceptor and partly by reduction by another electron donor. Acid-washed chloroplasts resuspended at pH 7.5 still present the signal due to Photosystem II (t 1/2 about 120 mus). This shows that the acid inhibition of the first secondary donor of Photosystem II is irreversible. In Tris-treated chloroplasts, absorption changes at 820 nm due to the primary donor of Photosystem II are also observed, but to a lesser extent and only after some charge accumulation at the donor side. They decay with a half-time of 120 mus.     

Effects of pH on reactions on the donor side of photosystem II.

The effects of pH on the increase of fluorescence yield measured in the microsecond range, and on the microsecond delayed fluorescence have been studied in dark adapted chloroplasts as a function of flash number. (1) At pH 7, the amplitude of the fast-phase of the microsecond fluorescence yield rise oscillated as a function of flash number with period 4 and with maxima on flashes 1 and 5, and minima on flashes 3 and 7. The damped oscillations were apparent over the range between 6 and 8, although the absolute amplitude of the fast phase was diminished at the lower end of the range. At pH 4, there was no fast phase in the rise and, at pH 9, an enhanced fast-phase occurred only for the first flash. (2) The decay of microsecond delayed fluorescence was described by the sum of exponentials with half-times of 10--15 mus and 40--50 mus. Over the pH range 6- less than 8, the extrapolated initial amplitude and the proportion of the change due to the faster component showed oscillations which were opposite in phase to those observed for the prompt fluorescence yield rise; the slower component showed weaker oscillations of the same phase. At pH 4, there were no oscillations and the slow phase predominated. At pH 9, the delayed fluorescence intensity was diminished on the first flash, and high on subsequent flashes. (3) The results are interpreted in terms of a model in which protons are released during all transitions of the S-states with the exception of S1 leads to S2, and in which ther are two sites of inhibition on the donor side of the photo-system at extreme pH values. At pH 4, electron donation to P+ occurs with a half-time approx. 135 mus, either by a back reaction from Q-, or from D; electron transport is interrupted between Z1 and P. At pH 9, electron transport is inhibited between Z1 and Z2; rapid re-reduction of P+ by Z1 occurs after 1 flash, and on subsequent flashes electrons from D, an alternative donor reduce P+. The location of the positive charge on states S2 and S3 is discussed.     

The site of manganese function in photosynthetic electron transport system

The effects of Mn²⁺ on aerobic photobleaching of carotenoids, on photoreduction of 2,6-dichlorophenolindophenol (DCIP) and on fluorescence above 600 mμ of spinach chloroplasts washed with 0.8 M Tris-HC1 buffer were investigated. Carotenoids (mostly carotenes, lutein and violaxanthin) in the Tris-washed chloroplasts were irreversibly bleached by illumination with red light, while carotenoids in normal chloroplasts prepared with a low concentration of Tris-HC1 underwent no bleaching upon illumination. The photobleaching of carotenoids observed with Tris-washed chloroplasts was inhibited by Mn²⁺ (MnCl₂ or MnSO₄) as well as by some inhibitors of the Hill reaction such as dichlorophenyl-1,1-dimethylurea (DCMU), methylthio-4,6-bis-isopropylamino-s-triazine and o-phenanthroline or by reducing agents such as ascorbate plus tetramethyl-p-phenylene diamine (TMPD). DCIP photoreduction, which was deactivated by Tris, was reactivated to 50–80% of the rate for normal chloroplasts upon addition of Mn²⁺. The restored photoreduction of DCIP was inhibited by DCMU and carbonylcyanide m-chlorophenylhydrazone (CCCP). The steady-state fluorescence yield of normal chloroplasts measured at room temperature was lowered by Tris treatment, and the decreased yield was restored by adding Mn²⁺ as well as ascorbate plus TMPD. CCCP also lowered the yield; the yield was recovered by adding ascorbate plus TMPD. Determination of manganese in normal and Tris-washed chloroplasts showed that 30% of the manganese in chloroplast was removed with Tris. It was postulated that Mn²⁺ functions in the electron transport on the oxidizing side of Photosystem II at a site between water and an electron carrier (Y). CCCP as well as Tris inhibits the reduction of Y⁺ by Mn²⁺, and carotenoids are oxidized by Y⁺ which is reduced by ascorbate plus TMPD.     

Studies on the interaction between hydroxylamine and hydrazine as substrate analogues and the water-oxidizing enzyme system in isolated spinach chloroplasts

The functional interaction between the photosynthetic water-oxidizing enzyme system and the substrate analogues hydroxylamine and hydrazine has been analyzed in isolated class II chloroplasts by measuring the effect of these species on the characteristic oscillation pattern of oxygen yield induced by a flash train. The following was found. (1) At concentrations where both substances cause the pronounced two-flash phase shift (Bouges, B. (1971) Biochim. Biophys. Acta 234, 103–112) the dark equilibration is rather slow with half-times of approx. 1 min. (2) The numerical evaluation of the oscillation patterns reveals quantitative differences between hydroxylamine and hydrazine. The interaction with hydroxylamine is complex. It involves one- and two-electron processes as well as fast reaction steps during the flash sequence. The fast reactions take place only with redox states S₂ and S₃ of the water-oxidizing enzyme. Furthermore, the redox turnover in the presence of hydroxylamine leads to an S₁-state that differs markedly in its susceptibility to hydroxylamine from that of S₁ in control chloroplasts. (3) Below a threshold concentration which varies for different preparations the hydrazine effect can be quantitatively described by the assumption that after dark equilibration the agent becomes consumed irreversibly via a reaction with two oxidizing redox equivalents produced by PS II. This process is accomplished during the first two flashes. No further interaction occurs during the flash sequence, so that besides the two-flash phase shift the water-oxidizing enzyme system reveals the normal oxygen-evolution pattern. (4) Based on the analysis of the concentration dependence hydrazine is inferred to interact with the catalytic center of the water-oxidizing enzyme system via a cooperative mechanism including two binding sites. The data are discussed in terms of the kinetics of the dark interaction and its possible rate limitation. Mechanistic aspects (ligand-ligand exchange at the functional manganese cluster and transport step) are considered. Furthermore, possible mechanisms for the redox reaction of hydrazine at the catalytic site are briefly discussed.     

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; )     

Reactions between primary and secondary acceptors of photosystem II in Chlorella pyrenoidosa under anaerobic conditions as studied by chlorophyll fluorescence.

The kinetics of the fluorescence yield phi of chlorophyll a in Chlorella pyrenoidosa were studied under anaerobic conditions in the time range from 50 mus to several minutes after short (t 1/2 = 30 ns or 5 mus) saturating flashes. The fluorescence yield "in the dark" increased from phi = 1 at the beginning to phi approximately 5 in about 3 h when single flashes separated by dark intervals of about 3 min were given. After one saturating flash, phi increased to a maximum value (4-5) at 50 mus, then phi decreased to about 3 with a half time of about 10 ms and to the initial value with a half time of about 2 s. When two flashes separated by 0.2 s were given, the first phase of the decrease after the second flash occurred within 2 ms. After one flash given at high initial fluorescence yield, the 10-ms decay was followed by a 10 s increase to the initial value. After the two flashes 0.2 s apart, the rapid decay was not followed by a slow increase. These and other experiments provided additional evidence for and extend an earlier hypothesis concerning the acceptor complex of Photosystem II (Bouges-Bocquet, B. (1973) Biochim. Biophys. Acta 314, 250-256; Velthuys, B. R. and Amesz. J. (1974) Biochim. Biophys. Acta 333, 85-94): reaction center 2 contains an acceptor complex QR consisting of an electron-transferring primary acceptor molecule Q, and a secondary electron acceptor R, which can accept two electrons in succession, but transfers two electrons simultaneously to a molecule of the tertiary acceptor pool, containing plastoquinone (A). Furthermore, the kinetics indicate that 2 reactions centers of System I, excited by a short flash, cooperate directly or indirectly in oxidizing a plastohydroquinone molecule (A2-). If initially all components between photoreaction 1 and 2 are in the reduced state the following sequence of reactions occurs after a flash has oxidised A2- via System I: Q-R2- + A leads to Q-R + A2- leads to QR- + A2-. During anaerobiosis two slow reactions manifest themselves: the reduction of R (and A) within 1 s, presumably by an endogenous electron donor D1, and the reduction of Q in about 10 s when R is in the state R- and A in the state A2-. An endogenous electron donor, D2, and Q- complete in reducing the photooxidized donor complex of System II in reactions with half times of the order of 1 s.     

The reduction kinetics of chlorophyll a1 as an indicator for proton uptake between the light reactions in chloroplasts

The flash-induced oxidation kinetics of the primary acceptor of light Reaction II (X-320) and the reduction kinetics of chlorophyll a₁ (P-700) after far-red preilluination have been studied with high time resolution in spinach chloroplasts.

1. 1. The kinetics of chlorophyll a₁ exhibits a pronounced lag phase of 2–3 ms at the onset of reduction as would be expected for the final product of consecutive reactions. Because the oxidation of the plastoquinone pool is the rate-limiting step for the electron transport between the two light reactions, the lag indicates the maximal electron transfer time over all preceding reactions after light Reaction II.

2. 2. The observation that the lag phase decreases with decreasing pH is evidence of an electron transfer step coupled to a proton uptake reaction.

3. 3. Protonation of X-320 after reduction in the flash is excluded because a slight increase of the decay time is found at decreasing pH values.

4. 4. The time course of plastohydroquinone formation is deduced from the first derivative of the reduction kinetics of chlorophyll a₁. This approach covers those plastohydroquinone molecules being available to the electron carriers of System I via the rate-limiting step. Direct measurements of absorbance changes would not allow to discriminate between these and functionally different plastohydroquinone molecules.

5. 5. The derived time course of plastohydroquinone at different pH gives evidence for an additional electron transfer step with a half time of about 1 ms following the proton uptake and preceding the rate-limiting step. It is tentatively attributed to the diffusion of neutral plastohydroquinone across the hydrophobic core of the thylakoid membrane.

6. 6. The lower limit of the rate constant for proton uptake by an electron carrier, consistent with the lag of chlorophyll a₁ reduction, is estimated as > 10¹¹ M⁻¹ · s⁻¹. The value is higher than that of the fastest diffusion controlled protonations of organic molecules in solution.

Possible mechanisms of linear electron transport between light Reaction II and the rate-limiting oxidation of neutral plastohydroquinone are thoroughly discussed.