Correlation between plastoquinone reduction, field formation and proton translocation in photosynthesis

Electrochromic absorbance changes in spinach chloroplasts induced by an external electrical field

Absorbance changes induced by electrical field pulses were studied in osmotically swollen spinach chloroplasts. The results and their interpretation on the basis of the geometry and electrical properties of the material may be summarized as follows: 1. The spherical vesicles, 'blebs', formed upon dilution of a chloroplast suspension consist of only a single membrane, while part of the thylakoid system remains concentrated in a few patches on its surface. 2. When an electrical field pulse is applied, an up to 3000-fold enhanced field is built up in the membrane, with a time constant of about 20 mus. From this the specific capacitance of the bleb wall was found to be 2 microF . CM-2. 3. The electrical field in the membrane causes several absorbance changes of the photosynthetic pigments with different dependencies on the direction of polarization of the measuring light. Some of these are due to field-induced changes in orientation, in particular of chlorophyll alpha, and have a relaxation time of less than 100 mus. Most of the absorbance changes directly reflect the kinetics of the membrane potential and can be ascribed to electrochromic shifts of photosynthetic pigments, mainly of carotenoids. 4. The carotenoid absorbance changes depend quadratically on the membrane potential; an apparent saturation at high applied field strengths is ascribed to dielectric breakdown at a membrane potential of about 1 V. 5. All carotenoids in the membrane contribute to the absorbance changes induced by an externally applied field, whereas the well-known light-induced electrochromic absorbance change at 518 nm is mainly caused by a minor fraction of permanently polarized and spectrally red-shifted carotenoids. A computer simulation showed that this interpretation quantitatively explains the results and requires no unreasonable values of the various parameters involved.

The plastoquinone pool as possible hydrogen pump in photosynthesis

The function of the plastoquinone pool as a possible pump for vectorial hydrogen (H+ + e-) transport across the thylakoid membrane has been investigated in isolated spinach chloroplasts. Measurements of three different optical changes reflecting the redox reactions of the plastoquinone, the external H+ uptake and the internal H+ release led to the following conclusions: (1) A stoichiometric coupling of 1 : 1 : 1 between the external H+ uptake, the electron translocation through the plastoquinone pool and the internal H+ release (corrected for H+ release due to H2O oxidation) is valid (pHout = 8, excitation with repetitive flash groups). (2) The rate of electron release from the plastoquinone pool and the rate of proton release into the inner thylakoid space due to far-red illumination are identical over a range of a more than 10-fold variation. These results support the assumption that the protons taken up by the reduced plastoquinone pool are translocated together with the electrons through the pool from the outside to the inside of the membrane. Therefore, the plastoquinone pool might act as a pump for a vectorial hydrogen (H+ + e-) transport. The molecular mechanism is discussed. The differences between this hydrogen pump of chloroplasts and the proton pump of Halobacteria are outlined.

Studies on the proton transport at system II in trypsin-treated spinach chloroplasts

The proton transport coupled with the DCMU-insensitive oxygen evolution mediated by K3[Fe(CN)6] in trypsin-treated chloroplasts (Renger, G. (1976) FEBS Lett. 69, 225--230) has been investigated with the aid of the pH indicator bromcresol purple. It was found that (1) the proton uptake from the outer aqueous phase observed in normal chloroplasts is completely suppressed by mild trypsin treatment; (2) a rather slow proton release into the external phase is detected which is insensitive to DCMU; (3) in the presence of DCMU, the extent of the proton release depends on the incubation time with trypsin in a similar manner as the average oxygen yield per flash. The results are interpreted by the assumption, that: (i) the reduced primary electron acceptor of System II, X 320-, does not become protonated, and (ii) the external acidification is caused by a passive efflux of protons, which are released by the watersplitting enzyme system Y into the inner phase of the thylakoids. The pK value of X 320- in trypsinated chloroplasts is estimated to be below 4.5. A possible pK shift caused by a modification of the proteinaceous barrier, which earlier (Renger, G. (1976) Biochim. Biophys. Acta 440, 287--300) was postulated to cover up the primary electron acceptor X 320, is discussed. Furthermore, the watersplitting enzyme system Y is inferred to be sensitive to deletereous attack from the outer aqueous phase mainly by secondary structural effects. Trypsination does not change the direction of the proton release in system Y.

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.

Photosynthetic electron transport and electrochromic effects at sub-zero temperatures

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

Relations between the electrical potential, pH gradient, proton flux and phosphorylation in the photosynthetic membrane

The transmembrane electrical potential (deltaphi), the proton flux (H+), the rate of electron transport (e), the pH gradient (deltapH) and the rate of phosphorylation (ATP) were measured in chloroplasts of spinach. Photosynthesis was excited periodically with flashes of variable frequencies and intensities. A new method is described for determining the rate of electron transport and proton flux. Under conditions where the rate of electron transport and proton flux are not pH controlled the following correlations were found in the range 50 mV less than or equal to deltaphi less than or equal to 125 mV and 1.8 less than or equal to deltapH less than or equal to 2.7: (1) The pH gradient, deltapH, increases with H+ independently of Phout between 7-9. (2) The rate of phosphorylation, ATP, depends exponentially on deltapH (at constant deltaphi) and is independent of pHout between 7-9. (3) The rate of phosphorylation, ATP, depends also on deltaphi (at constant deltapH and at constant proton flux H+). (4) The proton flux via the ATPase pathway, Hp+, depends non-linearly on the ratio of the proton concentrations: Hp+ approximately (Hin+/Hout+)b, (b=2.3--2.6). The proton flux via the basal pathway, Hb+, depends linearly on the ratio of the proton concentrations: Hb+ approximately (Hin/Hout). (5) The ratio deltaH+/ATP (e/ATP, i.e. the ratio of the total proton flux, Hp+ + Hb+, and the rate of ATP formation, ATP, depends strongly on deltaphi and on deltapH. The ratio is deltaH+/ATP approximately 3 (e/ATP approximately 1.5) at deltapH 2.7 and deltaphi = 125 mV. (6) It is supposed that the reason for the dependence of deltaH+/ATP on deltaphi anddeltapH is the different functional dependence of the basal proton flux Hb+ and the phosphorylating proton flux Hp+ on deltapH and deltaphi. The calculation of deltaH+/ATP on the basis of this assumption is in fair agreement with the experimental values. Also the "threshold" effects can be explained in this way. (7) The ratio of deltaHp+/ATP, i.e. the ratio of the phosphorylating proton flux Hp+ and ATP, is deltaHp+/ATP APPROXIMATELY 2.4.

[Biophysical primary processes in photosynthetic membranes. Data with pulse-spectroscopical methods]

The electron transfer in the photosynthetic membrane of green plants from H2O to NADP+ is driven by two chlorophyll reaction centers in series. The electron transfer converts one part of the light energy into the form of the reducing power of NADPH. The transfer initiates an electrical field across the membrane. The electrical energy of the charged membrane is an additional state into which light energy is converted. Protolytic reactions coupled with the electron transfer lead to a proton translocation into the inner space of the thylakoid. The discharging of the ectrically energized membrane by H+ efflux is coupled with the formation of ATP.

Current-voltage studies on the thylakoid membrane in the presence of ionophores

The reversibility of the binding of ionophores to the thylakoid membrane is studied. While gramicidin binds practically irreversibly, valinomycin and nonactin bind reversibly, however, only a small fraction (about 1%) of the membrane-bound valinomycin or nonactin is active in ion transport. The current-voltage relationship is evaluated under these circumstances. We have found that it is practically linear. This together with the relationship between current and ion concentration agrees qualitatively with the results reported for bimolecular lipid membranes, which contain a large fraction of negatively charged lipids. For the ionophores, valinomycin and nonactin, the binding equilibria (K approximately equal to 10-4) and the turnover numbers (approximately equal to 3-10-4/s) are evaluated for their action on the thylakoid membrane. Possible reasons for the inactivity of the majority of membrane-bound ionophore molecules are discussed.

Slow 514 nm absorption phases and oxygen exchange transients in Ulva

1. The slow 514-nm spectral changes in Ulva were studied using bright continuous 650-nm light. Transient and steady-state absorption changes were compared with changes in net rate of O2 exchange in a system designed to measure both parameters simultaneously. 2. Time courses of the 514-nm absorption change show three phases following the onset of light: one rapid increase and two slower (larger than or equal to 1 s) transient increases. Upon cessation of the light three transient absorption phases also follow: a rapid decrease and two slower (greater than 1 s) transient increases. Parallel transient phases (but opposite in sign) were found at 480 nm. 3. The kinetics of the slow 514-nm absorption transients correlate with the characteristic induction transients in net O2 exchange. 4. Similar difference spectra and the restoration kinetics of the light-on and light -off transient phases indicate that the slow 514-nm absorption changes reflect the same component(s) and process(es). 5. The experimental results are discussed in terms of the electrochromic hypothesis for the 515-nm absorption shift. We interpret the slow 514-nm absorption changes in Ulva as a reflection of relatively slow ionic readjustments across the photosynthetic membranes.