Inhibition of the light-induced H+ release from uncoupled thylakoid membranes by N-ethylmaleimide.

The light-induced H+ release from thylakoids, which can be observed under completely uncoupled conditions, was inhibited by the SH reagent N-ethylmaleimide (NEM) and its analogs, while the conventional H+ uptake and electron transfer were not affected. The half-inhibiting concentration of NEM for the H+ release was 10 mM and 4 mM in thylakoids in the presence of nigericin and in CF1-depleted thylakoids, respectively. The inhibitory effect increased with the increase in hydrophobicity of the NEM analogs: N-methylmaleimide less than N-ethylmaleimide less than N-phenylmaleimide. It is suggested that SH groups in hydrophobic interior within the membrane are essential to the release of protons.     

The role of the chloroplast coupling factor in the inactivation of thylakoid membranes at low temperatures

Thylakoids isolated from spinach leaves ( Spinacia oleracea L. cv. Monatol) were exposed to variable low temperatures under non-freezing conditions. After incubation, changes in the activities of several photochemical reactions and physical properties of the membranes were measured at room temperature.
Cyclic photophosphorylation was strictly dependent on the temperature and the electrolyte concentration: decrease in temperature and increase in NaCl concentration enhanced membrane damage. Inactivation of photophosphorylation was accompanied by stimulation of non-cyclic electron transport, increase in proton permeability and decrease in δpH. When dicyclohexylcarbodiimide was added, the proton gradient became completely restored. The temperature- and salt-dependent breakdown of photophosporylation was closely related to the release of the chloroplast coupling factor (CF₁) from the membranes. The addition of Mg²⁺, very low concentrations of ATP or ADP, or higher concentrations of low-molecular-weight polyols prior to temperature treatment prevented thylakoid damage.
The data indicate that inactivation of photophosphorylation of thylakoids at low temperatures is determined to a considerable extent by the cold lability of the CF₁. As a consequence, it must be concluded that damage of biomembranes caused by freezing is not due solely to changes resulting from the ice formation but additionally by temperature-dependent alterations of cold-labile proteins. Moreover, the data explain the mechanism of non-colligative cryoprotection of isolated thylakoid membranes.     

Sigmoidal stimulation by solutes of light-induced proton translocation in thylakoid membranes

A sigmoidal curve was obtained for the relationship betweenthe stimulation of light-induced proton uptake and the concentrationof salts in a suspending medium for thylakoid membranes. Substitutionof sucrose for the salts also resulted in a sigmoidal curve.It changed into a hyperbolic curve with salts when the mediumalready contained sucrose. The results are discussed in relationto the structural arrangement of the thylakoid membranes bythe osmotic effect of the solutes. (Received February 10, 1975; )     

Membrane-bound coupling factor ATPase activity during light-induced chloroplast development in Euglena gracilis

Dark-grown non-dividing cells of Euglena gracilis Klebs var. bacillaris Cori were exposed to light for up to 72 h and thylakoid membrane fractions were isolated by sedimentation in sucrose step gradients at various stages of development. The membrane-bound coupling factor (CF1)-ATPase activity of these prothylakoids (0 h of light) and developing thylakoid membranes (12 to 72 h of light) was characterized by its cation specificity and sensitivity to inhibitors. The enzyme at all stages of development was activated by Mg2+ and to a lesser extent by Ca2+; Mn2+ was found to activate, as well as or better than Mg2 + at comparable concentrations. The activity of the enzyme was almost completely inhibited by dicyclohexylcarbodiimide (DCCD; 0.3 mM), but was insensitive to oligomycin, valinomycin and carbonyl cyanide P-trifluoromethoxyphenylhydrazone (FCCP). Low concentrations of NH4CI gave a slight stimulation of enzyme activity, whereas high concentrations of the uncoupler were inhibitory. The specific activity of the membrane-bound CF,-ATPase was highest in prothylakoid membranes. Specific activity decreased on a thylakoid protein or chlorophyll basis during the first 12 h of development, and achieved a steady state level by 48 h following light induction. Estimates of total CF1-ATPase activity per cell indicate that the time for major synthesis of the enzyme is between 12 and 3d h ol development. These results suggest that following an initial lag period in membrane development lasting about 12 h, there is a formation of CF1-ATPase that accompanies further thylakoid membrane development.     

The coupling factor of photophosphorylation and the electric properties of the thylakoid membrane

The rate of ATP synthesis of illuminated chloroplasts is correlated with the electric conductance of their inner membranes. In agreement with previous studies it is shown that ATP synthesis is paralleled by an increased conductance of the thylakoid membrane. This conductance together with the ability to form ATP is abolished if chloroplasts are treated with an antibody against the coupling factor CF₁. It is not influenced by the fragmented monovalent antibody. This parallels the lack of influence of the fragmented antibody on ATP synthesis in contrast to its influence on hydrolysis and exchange reactions. We conclude that there are different sites for the interaction of the coupling factor with adenine nucleotides.Extraction of the coupling factor is shown to increase the membrane conductance by more than two orders of magnitude. Reincorporation of the crude coupling factor partially restores the net conductance of the membrane (increase in resistance by a factor of 2.5), while a higher degree of restoration was observed for ATP synthesis and the proton conductivity of the membrane. We conclude that the extraction procedure opens different conductive channels in the membrane; a proton specific one, possibly associated with the binding protein for the coupling factor, plus other channels for “non-protons” which in contrast to the proton channel cannot be plugged by reincorporation of the coupling factor.     

Characteristics of light-induced H+ transport in spinach chloroplast at lower temperatures I. Relationship between H+ transport and physical changes of the microenvironment in chloroplast membranes

Light-induced H⁺ transport of spinach chloroplasts was investigatedin the temperature range from 5° to 30°C with a glasselectrode. The rate of H⁺ transport was reduced by lowering the temperature.Addition of 1 µM phenazine methosulfate (PMS) considerablystimulated the H⁺ uptake in chloroplasts. PMS was also effectivein stimulating the H⁺ efflux when the illumination was turnedoff. The latter effect became more marked at lower temperatures.These results indicate that electron transfer reactions in thechloroplast not only drive the forward process of H⁺ gradientformation, but also participate in the backward H⁺ efflux. The Arrhenius plot applied to the first-order rate constantof the H⁺ efflux showed a discontinuity at about 20°C. Nohysteresis was detected with the temperature dependence andits discontinuity in the H⁺ transport. On the other hand, theaddition of PMS abolished the discontinuity and a linear relationshipwas observed in the Arrhenius plot. Probably, temperature-dependentphysical changes in the microenvironment of the chloroplastlamellae are responsible for determining the characteristicsof the H⁺transport. (Received September 11, 1975; )     

The relationship between gastric acid secretion and gastric H+,K+-ATPase activity

The H+,K+-ATPase has been postulated to be the enzyme responsible for H+ secretion by the parietal cell. Omeprazole has been shown to be an inhibitor of acid secretion in vivo, but also in in vitro test models for acid secretion, including partly purified H+,K+-ATPase, the inhibitory action of omeprazole has been demonstrated (Wallmark, B., Jaresten, B. M., Larsson, H., Ryberg, B., Br?ndstr?m, A., and Fellenius, E. (1983) Am. J. Physiol. 245, G64-G71). It was thus possible to use this compound to demonstrate a correlation between H+,K+-ATPase activity in rat oxyntic mucosa and in vivo H+ secretion. Two results were found. (a) Increasing oral doses of omeprazole progressively inhibited acid secretion, H+,K+-ATPase activity, and phosphoenzyme formation of a microsomal fraction isolated from the inhibited rat mucosa. Furthermore, a Mg2+-stimulated ATPase activity, associated with the H+,K+-ATPase membrane fraction, was not affected by the omeprazole treatment. (b) Recovery of H+,K+-ATPase activity following complete omeprazole inhibition was correlated with the appearance of acid secretion. The results indicate a strict relationship between the activity of the gastric H+,K+-ATPase in the microsomal fraction and gastric acid secretion.     

The coupling factor of photophosphorylation and the electric properties of the thylakoid membrane.

The rate of ATP synthesis of illuminated chloroplasts is correlated with the electric conductance of their inner membranes. In agreement with previous studies it is shown that ATP synthesis is paralleled by an increased conductance of the thylakoid membrane. This conductance together with the ability to form ATP is abolished if chloroplasts are treated with an antibody against the coupling factor CF1. It is not influenced by the fragmented monovalent antibody. This parallels the lack of influence of the fragmented antibody on ATP synthesis in contrast to its influence on hydrolysis and exchange reactions. We conclude that there are different sites for the interaction of the coupling factor with adenine nucleotides. Extraction of the coupling factor is shown to increase the membrane conductance by more than two orders of magnitude. Reincorporation of the crude coupling factor partially restores the net conductance of the membrane (increase in resistance by a factor of 2.5), while a higher degree of restoration was observed for ATP synthesis and the proton conductivity of the membrane. We conclude that the extraction procedure opens different conductive channels in the membrane; a proton specific one, possibly associated with the binding protein for the coupling factor, plus other channels for "non-protons" which in contrast to the proton channel cannot be plugged by reincorporation of the coupling factor.     

Evidence for a catalytic function of the coupling factor 1 protein reconstituted with chloroplast thylakoid membranes.

The effects of tentoxin on the ATPase activities of coupling factor 1 proteins (CF1) and photophosphorylation with isolated chloroplasts and chloroplasts reconstituted with coupling factor proteins have been examined. 1. The calcium-dependent ATPase activities of coupling factors isolated from spinach, lettuce and Nicotiana otophora are completely inhibited by tentoxin. The ATPase activities of coupling factors isolated from Nicotiana tabacum and Nicotiana knightiana are not affected by tentoxin. 2. Phenazine methosulfate-catalyzed cyclic photophosphorylation with chloroplasts isolated from spinach, lettuce and N. otophora is completely inhibited by tentoxin, whereas chloroplasts isolated from N. knightiana and N. tabacum are relatively insensitive to tentoxin. 3. Spinach chloroplasts, partially depleted in CF1, can be reconstituted with coupling factors isolated from a wide variety of plants including lettuce, radish, N. tabacum, N. knightiana and N. otophora. 4. Spinach chloroplasts reconstituted with spinach, lettuce and N. otophora CF1 retain their sensitivity to tentoxin; however, when reconstituted with N. knightiana and N. tabacum coupling factor proteins, a significant fraction of the reconstituted rate remains tentoxin insensitive. These data are interpreted as evidence that coupling factors that reconstitute with spinach thylakoid membranes have both a catalytic and structural function.     

Effect of ionophores A23187 and nigericin on the light-induced redistribution of Mg2+, K+ and H+ across the thylakoid membrane.

Passive redistributions of Mg2+ and K+ ions across the thylakoid membranes, occurring in association with the light-driven electrogenic influx of hydrogen ions have been examined in suspensions of broken spinach chloroplasts under a variety of conditions. (i) In accord with results of Hind el al. (Proc. Natl. Acad. Sci. U.S. (1974) 71, 1484), it was found that at a low K/Mg concentration ratio in the medium, the K-efflux is negligibly small, whereas a substantial Mg-efflux is observed. The converse is true when the K/Mg concentration ratio in the medium is high. (ii) In the presence of A23187, which was found to cause approximately a 60% inhibition of the light-induced pH-gradient, a significant influx of Mg2+ was observed in the light at a high K/Mg concentration ratio. Conversely the Mg-influx was small in the presence of A23187 when the K/Mg concentration ratio in the medium was low. Under these conditions, the Mg-influx was considerably increased upon the addition of valinomycin. A23187 was found not to affect the K-efflux in the light. (iii) The light-induced K-influx observed in the presence of nigericin also was found to be dependent on the concentration ratio of the monovalent and divalent cation. Its magnitude increased upon an increase in the K/Mg ratio. The results are interpreted in terms of a simplified model in which the total passive efflux of cations, driven by the potential set by the electrogenic proton pump, is considered to be a constant fraction of the proton influx. According to this, an increase in the flux of an ion species, induced either by raising its concentration, or by increasing its permeability through the membrane, will cause a decrease in the flux of the other cations. The relevance of the results is discussed with respect to conclusions about the involvement and relative magnitudes of the passive K and Mg effluxes across the thylakoid membrane during energization of intact chloroplasts and chloroplasts in situ.     

Strong light-induced reorganization of pigment-protein complexes of thylakoid membranes in rye (spectroscopic study)

The supramolecular reorganization of LHCII complexes within the thylakoid membrane in Secale cereale leaves under low and high light condition was examined. Rye seedlings were germinated hydroponically in a climate chamber with a 16 h daylight photoperiod, photosynthetic photon flux density (PPFD) of 150 μmol m⁻² s⁻¹ and 24/16 °C day/night temperature. The influence of pre-illumination of the plants with high light intensity on the PSII antenna complexes was studied by comparison of the structure and function of the LHCII complexes and organization of thylakoid membranes isolated from 10-day-old plants illuminated with low (150 μmol m⁻² s⁻¹) or high (1200 μmol m⁻² s⁻¹) light intensity. Aggregated and trimeric with monomeric forms of LHCII complexes were separated from the whole thylakoid membranes using non-denaturing electrophoresis. Analyses of fluorescence emission spectra of these different LHCII forms showed that the monomer was the most effective aggregating antenna form. Moreover, photoprotection connected with LHCII aggregation was more effective upon LHCII monomers in comparison to trimer aggregation. Light stress induced specific organization of neighboring LHCII complexes, causing an increase in fluorescence yield of the long-wavelength bands (centered at 701 and 734 nm). The changes in the organization of the thylakoid membrane under light stress, observed by analysis of absorbance spectra obtained by Fourier transform infrared spectroscopy, also indicated light-induced LHCII aggregation.     

The effect of chloroplast coupling factor removal on thylakoid membrane ion permeability

Removal of coupling factor protein (CF₁) from spinach thylakoid membranes results in an enhancement of proton permeability but has no effect on chloride or potassium permeability. Anion permeability was measured by the rate of thylakoid packed volume changes. Potassium permeability was monitored by turbidity changes, packed thylakoid volume changes and ion flux studies using ⁸⁶Rb⁺ as a tracer. ⁴⁵Ca²⁺ was used to measure divalent cation fluxes. CF₁-depleted chloroplasts had an unaltered rate of Ca²⁺ uptake, but the rate of Ca²⁺ efflux appeared to be increased. Calcium efflux rates could also be increased by the addition of a proton specific uncoupler, FCCP.     

Free energy coupling between H+-generating and H+-consuming pumps. Ratio between output and input forces

The delta Gp/delta mu H ratio has been measured in mitochondria close to state 4 in the presence of various uncoupler or K+/valinomycin concentrations in media containing either 1 mM or 50 mM Pi. Care has been taken to control the factors affecting delta Gp and delta mu H which could lead to an artefactual increase of the delta Gp/delta mu H ratio above the highest accepted value for the H+/ATP stoichiometry (n = 4, synthesis + transport). In particular, to avoid overestimation of delta Gp due to inactivation of the ATPases at low delta mu H or to the presence of adenylate kinase, the static head state was approached from the side of net ATP synthesis and delta Gp was measured in a state close to static head but still maintaining a residual rate of aerobic phosphorylation. For each concentration of uncoupler or K+, the Pi concentration and/or the adenylate energy charge (EC) as a function of time have been measured as indicators of net ATP synthesis. Only the values of delta Gp measured during a decrease in Pi concentration and/or an increase in EC have been considered to be meaningful for calculations of delta Gp/delta mu H ratios. Both uncouplers and K+ transport cause a marked depression of delta mu H and a parallel depression of the rate of ATP synthesis. However the low rate of ATP synthesis taking place under conditions of low delta mu H eventually results, especially at high Pi concentrations, in a relatively large delta Gp. The delta Gp/delta mu H ratios obtained at the lower delta mu H values exceed 4 and approach 6. Although slightly higher delta Gp/delta mu H ratios are obtained with valinomycin-treated than with uncoupler-treated mitochondria, the pattern of the rise of the force ratio as delta mu H decreases is similar in both cases. An increase of the delta Gp/delta mu H ratio above 4, the maximal accepted H+/ATP stoichiometry is thermodynamically incompatible with the delocalized protonic coupling model.     

The effect of chloroplast coupling factor removal on thylakoid membrane ion permeability.

Removal of coupling factor protein (CF1) from spinach thylakoid membranes results in an enhancement of proton permeability but has no effect on chloride or potassium permeability. Anion permeability was measured by the rate of thylakoid packed volume changes. Potassium permeability was monitored by turbidity changes, packed thylakoid volume changes and ion flux studies using 86Rb+ as a tracer. 45Ca2+ was used to measure divalent cation fluxes. CF1-depleted chloroplasts had an unaltered rate of Ca2+ uptake, but the rate of Ca2+ efflux appeared to be increased. Calcium efflux rates could also be increased by the addition of a proton specific uncoupler, FCCP.     

Influence of Ca2+ on the thylakoid lumen violaxanthin de-epoxidase activity through Ca2+ gating of H+ flux at the CFo H+ channel

Part of the chloroplast photoprotection response to excess light absorption involves formation of zeaxanthin (and antheraxanthin) via the violaxanthin deepoxidase enzyme, the activity of which requires lumen acidity near or below pH 6.0. Clearly, the violaxanthin de-epoxidase activity is strongly regulated because at equivalent energization levels (including the parameters of H⁺ accumulation and ATP formation rates), there can be either low or high violaxanthin de-epoxidase enzyme activity. This work shows that the factor or factors responsible for regulating the violaxanthin deepoxidase correlate directly with those which regulate the expression of membrane-localized or delocalized proton gradient (Δ~μ_H+) energy coupling. The most clearly identified factor regulating switching between localized and delocalized energy coupling modes is Ca²⁺ binding to the lumen side of the thylakoid membrane; in particular, Ca²⁺ binding to the 8 kDA subunit III of the CF_o H⁺ channel. The activity of violaxanthin deepoxidase in pea (Pisum sativa) and spinach (Spinacea oleracea) thylakoids is shown here to be strongly correlated with conditions known from previous work to displace Ca²⁺ from the CF_o H⁺ channel and thus to modulate the extent of lumenal acidification while maintaining a fairly constant rate of ATP formation. This revised version was published online in June 2006 with corrections to the Cover Date.