Freezing of isolated thylakoid membranes in complex media

Chloroplast thylakoid membranes isolated from spinach leaves (Spinacia oleracea L. cv. Monatol) were subjected to a freeze-thaw treatment in a buffered medium containing 70 mM KCl, 30 mM NaNO₃ and 20 mM K₂SO₄ in different combinations. In the presence of the three predominant inorganic electrolytes, inactivation of photophosphorylation was mainly caused by a decrease in the capacity of the photosynthetic electron transport; release of proteins from the membranes was not manifest and light-induced H⁺ gradient and proton permeability were largely unaffected. Omission of nitrate from the medium had little effect. When either sulfate or chloride or both were omitted prior to freezing, inactivation of photophosphorylation was correlated with stimulation of the phosphorylating electron flow, marked increase in H⁺ permeability and loss of the ability of the thylakoids to accumulate protons in the light. In the absence of sulfate, uncoupling was mainly a consequence of the dissociation of chloroplast coupling factor (CF₁). Partial restoration of proton impermeability and pH gradient occurred upon the addition of N,N-dicyclohexylcarbodiimide (DCCD). When sulfate was present but chloride omitted, CF₁ remained attached to the membranes and the addition of DCCD had no effect, indicating that the increase in proton efflux was caused by a different mechanism. It is concluded that sulfate stabilizes the CF₁ and prevents its release from the membranes, but KCl is also necessary for maintaining the low permeability of the membranes to protons. The importance of complex media for investigations on isolated biomembrane systems is stressed.Abbreviations CF₁ chloroplast coupling factor - DCCD N,N-dicyclohexylcarbodiimide - Hepes 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid I=Santarius 1986 b     

Freezing of isolated thylakoid membranes in complex media. V. Inactivation and protection of electron transport reactions

When chloroplast thylakoid membranes isolated from spinach leaves (Spinacia oleracea L. cv. Monatol) were frozen in media containing the predominant inorganic electrolytes of the chloroplast stroma, linear photosynthetic electron transport became progressively inhibited. After onset of freezing, both PSII- and PSI-mediated electron flow were inactivated almost to the same extent. Prolonged storage of the membranes in the frozen state increased damage to PSII relative to PSI activity. Under these conditions, a preferential injury of the water oxidation system was not observed. In thylakoids stored at 0 °C, PSI activity remained fairly unimpaired but inactivation of PSII occurred with strongest inhibition at the oxidizing side.The addition of low-molecular-weight cryoprotectants such as glycerol, sugars, certain amino acids and carbonic acids to thylakoid suspensions prior to freezing provided almost complete preservation of PSI activity and considerable but incomplete stabilization of PSII.Abbreviations BQ 1,4-benzoquinone - Chl chlorophyll - DAD 1,4-diamino-2,3,5,6-tetramethylbenzene - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - DCPIP 2,6-dichlorophenolindophenol - DMBQ 2,5-dimethyl-p-benzoquinone - DPC 1,5-diphenylcarbazide - Hepes 4-(2-hydroxyethyl)-1-piperazineeth-anesulfonic acid - MV methylviologen - PD 1,4-diaminobenzene - SOD superoxide dismutase (EC 1.15.1.1) - TMHQ tetramethyl-p-hydroquinone - TMPD N,N,N,N-tetramethyl-1,4-diaminobenzene - Tris 2-amino-2-(hydroxymethyl)-1,3-propandiol Dedicated to Professor Dr. Wilhelm Simonis, Würzburg, on the occasion of his 80th birthday     

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.     

Mechanical freeze-thaw damage and frost hardening in leaves and isolated thylakoids from spinach. I. Mechanical freeze-thaw damage in an artificial stroma medium

Abstract Freeze-thaw damage to thylakoids in spinach leaves has been simulated in vitro, using a complex, defined artificial stroma medium. The resulting mechanical damage was quantified by measuring the loss of the marker protein plastocyanin from the thylakoid lumen, which is released as a result of membrane rupture. Loss of plastocyanin was already apparent at 0°C and became more severe at subzero temperatures. The time course of plastocyanin loss during freezing was biphasic: after an initial rapid loss, plastocyanin release was linearly dependent on incubation time. In short-term experiments a linear dependence on freezing temperature was observed. Solute diffusion into the thylakoids, leading to influx of water and eventually membrane rupture, has been observed in vitro as well as after freezing of leaves.     

Mechanical freeze-thaw damage and frost hardening in leaves and isolated thylakoids from spinach. II. Frost hardening reduces solute permeability and increases extensibility of thylakoid membranes

Abstract Thylakoids isolated from cold-acclimated spinach (Spinacia oleracea L.) leaves were more resistant against mechanical freeze-thaw injury measured as plastocyanin release, than thylakoids from non-acclimated leaves. They were more resistant against solute influx during freezing and they were able to re-expand to a larger volume in comparison to non-hardy controls. Likewise, plastocyanin was released from thylakoids of non-acclimated but not of frost-hardy leaves under conditions of mild in situ freezing stress for several days.     

Effects of prolonged freezing stress on the photosynthetic apparatus of moderately hardy leaves as assayed by chlorophyll fluorescence kinetics

Abstract Moderately frost-hardy leaves of the wintergreen broadleaf woody shrubs Pyracantha coccinea and Ligustrum ovalifolium and the winter annual herb Spinacia oleracea were subjected to extended freezing stress up to 15 d at temperatures 2–8°C above the mean lethal temperature (LT₅₀). After thawing, the fast kinetics of in vivo chlorophyll fluorescence of photosystem II (PSII) and the potential of linear photosynthetic electron transport of isolated thylakoid membranes was measured at room temperature. The lower the minimum freezing temperature and the longer the time of exposure, the greater was the suppression of the fluorescence signals of the leaves and decrease of the electron transport capacity of the thylakoid membranes. The pattern of inactivation of PSII -mediated electron flow, i.e. inhibition of photoreaction to photochemistry and/or electron donation to the photochemical reaction, during long-term freezing at temperatures somewhat above the LT₅₀ of the leaves was similar to that observed earlier after relatively brief exposure of leaves and isolated thylakoid membranes to more severe freezing stress. As injury occurred during freezing in complete darkness, it is likely that prolonged winter stress under natural environmental conditions causes changes in the photosynthetic apparatus of moderately hardy leaves which are not due to photoinhibition.     

Freezing of isolated thylakoid membranes in complex media: I. The effect of potassium and sodium chloride,nitrate, and sulfate

Thylakoid membranes isolated from spinach leaves (Spinacia oleracea L. cv. Monatol) were subjected to a freeze-thaw cycle in the presence of a buffered medium containing sorbitol as a cryoprotectant and various combinations of potassium and sodium chloride, nitrate, and sulfate. Above a certain total salt concentration, an increase in the concentration of a single electrolyte, or of potassium plus sodium salts with identical anions, always led to a decrease in photophosphorylation activity. A similar effect was obtained with combinations of nitrate plus chloride with identical cations and of KNO₃ plus NaCl. By contrast, in the presence of suitable combinations of NaNO₃ plus KCl, NaNO₃ plus sulfates, and chlorides plus sulfates, inactivation of photophosphorylation was diminished, sometimes dramatically, at initial molarities of nitrate or chloride which alone caused partial or complete membrane damage. When NaNO₃, KCl, and potassium or sodium sulfate were simultaneously present during freezing, thylakoids were affected very little over a wide range of concentration. Diminution or prevention of inactivation of photophosphorylation by suitable combinations of two or more cryotoxic inorganic salts can be explained by postulating that the different solutes act on different sites and that each reduces the concentration of the others by colligative action, together with specific effects of the various electrolytes on individual membrane sites.     

Synthetic quinones influencing herbicide binding and Photosystem II electron transport. The effects of triazine-resistance on quinone binding properties in thylakoid membranes

We have analyzed the binding of synthetic quinones and herbicides which inhibit electron transport at the acceptor side of Photosystem II (PS II) of the photosynthetic electron-transport chain in thylakoid membranes. These data show that quinones and PS II-directed herbicides compete for binding to a common binding environment within a PS II region which functions as the Q⁻ / PQ oxidoreductase. We observed that (1) synthetic quinones cause a parallel inhibition of electron transport and [¹⁴C]herbicide displacement, and (2) herbicide binding is affected both by the fully oxidized and fully reduced form of a quinone. Quinone function and inhibitor binding were also investigated in thylakoids isolated from triazine-resistant weed biotypes. We conclude the following. (1) The affinity of the secondary accepting quinone, B, is decreased in resistant thylakoids. (2) The observation that the equilibrium concentration of reduced Q after transferring one electron to the acceptor side of PS II is increased in resistant as compared to susceptible chloroplasts may be explained both by a decrease in the affinity of PQ for the herbicide / quinone binding environment, and by a decrease of the midpont redox potential of the B / B⁻ couple. (3) The binding environment regulating quinone and herbicide affinity may be divided roughly into two domains; we suggest that the domain regulating quinone head-group binding is little changed in resistant membranes, whereas the domain-regulating quinone side-group binding (and atrazine) is altered. This results in increased inhibitory activity of tetrachloro-p-benzoquinone and phenolic herbicides, which are hypothesized to utilize the quinone head-group domain. The two domains appear to be spatially overlapping because efficient atrazine displacement by tetrachloro-p-benzoquinone is observed.     

Differential changes in the electron transport properties of thylakoid membranes during aging of attached and detached leaves, and of isolated chloroplasts

Abstract. Aging of chloroplasts both in vivo and in vitro causes a considerable loss in the 2,6-dichlorophenol indophenol (DCPIP)-Hill reaction with water as electron donor. The loss can be reduced by exogenous electron donors like diphenyl carbazide (DPC). suggestive of aging-induced damage of the oxygen evolving system. Aging also brings about a considerable loss in methylviologen (MV) reduction mediated by Photosystem I (PS I) of chloroplasts with an ascorbate-DCPIP couple as the electron donating system.
The loss in the electron transport ability of the plastids is faster during in vitro compared to in vivo aging of the chloroplasts.
Light protects the photo-electron transport ability of chloroplasts during aging of intact leaves in contrast to its action during aging of the isolated organelles.     

Cysteine, γ-glutamyl-cysteine and glutathione contents of spinach leaves as affected by darkness and application of excess sulfur. II. Glutathione accumulation in detached leaves exposed to H2S in the absence of light is stimulated by the supply of glycine to the petiole

When illuminated leaf discs and detached leaves of spinach ( Spinacia oleracea L. cv. Estivato) were exposed to 0.4 and 0.25 μl 1^-1 H₂S, respectively, pool sizes of cysteine and glutathione increased. In the dark, apart from these compounds, the level of γ-glutamyl-cysteine also increased. Incubation of leaf discs with 1.0 m M buthionine sulfoximine (BSO) resulted in the accumulation of cysteine only, both in the light and in darkness. When glycine was supplied to the petioles of detached leaves exposed to H₂S in the dark, the accumulation of glutathione was stimulated, while γ-glutamyl-cysteine accumulation was prevented completely. Glycolate and glyoxylate, precursors of glycine in the glycolate pathway, had nearly the same effect as glycine. Although other amino acids were apparently taken up equally well as glycine when supplied to the petiole, they were much less effective, or not effective at all, in restoring glutathione synthesis in the dark. These results provide evidence, that H₂S-induced glutathione accumulation in spinach leaves in the dark is limited by the availability of glycine, giving rise to the accumulation of the metabolic precursor γ-glutamyl-cysteine.     

Manganese proteins isolated from spinach thylakoid membranes and their role in O2 evolution: II. A binuclear manganese-containing 34 kilodalton protein,a probable component of the water dehydrogenase enzyme

Extraction conditions have been found which result in the retention of managanese to the 33–34 kDa protein, first isolated as an apoprotein by Kuwabara and Murata (Kuwabara, T. and Murata, N. (1979) Biochim. Biophys Acta 581, 228–236). By maintaining an oxidizing-solution potential, with hydrophilic and lipophilic redox buffers during protein extraction of spinach grana-thylakoid membranes, the 33–34 kDa protein is observed to bind a maximum of 2 Mn/protein which are not released by extended dialysis versus buffer. This manganese is a part of the pool of 4 Mn/Photosystem II normally associated with the oxygen-evolving complex. The mechanism for retention of Mn to the protein during isolation appears to be by suppression of chemical reduction of natively bound, high-valent Mn to the labile Mn(II) oxidation state. This protein is also present in stoichiometric levels in highly active, O₂-evolving, detergent-extracted PS-II particles which contain 4–5 Mn/PS II. Conditions which result in the loss of Mn and O₂ evolution activity from functional membranes, such as incubation in 1.5 mM NH₂OH or in ascorbate plus dithionite, also release Mn from the protein. The protein exists as a monomer of 33 kDa by gel filtration and 34 kDa by gel electrophoresis, with an isoelectric point of 5.1 ± 0.1. The protein exhibits an EPR spectrum only below 12 K which extends over at least 2000 G centered at g = 2 consisting of non-uniformly separated hyperfine transitions with average splitting of 45–55 G. The magnitude of this splitting is nominally one-half the splitting observed in monomeric manganese complexes having O or N donor ligands. This is apparently due to electronic coupling of the two ⁵⁵Mn nuclei in a presumed binuclear site. Either a ferromagnetically coupled binuclear Mn₂(III,III) site or an antiferromagnetically coupled mixed-valence Mn₂(II,III) site are considered as possible oxidation states to account for the EPR spectrum. Qualitatively similar hyperfine structure splittings are observed in ferromagnetically coupled binuclear Mn complexes having even-spin ground states. The extreme temperature dependence suggests the population of low-lying excited spin states such as are present in weakly coupled dimers and higher clusters of Mn ions, or, possibly, from efficient spin relaxation such as occurs in the Mn(III) oxidation state. Either 1.5 mM NH₂OH or incubation with reducing agents abolishes the low temperature EPR signal and releases two Mn(II) ions to solution. This is consistent with the presence of Mn(III) in the isolated protein. The intrinsically unstable Mn₂(II,III) oxidation state observed in model compounds favors the assignment of the stable protein oxidation state to the Mn₂(III,III) formulation. This protein exhibits characteristics consistent with an identification with the long-sought Mn site for photosynthetic O₂ evolution. An EPR spectrum having qualitatively similar features is observable in dark-adapted intact, photosynthetic membranes (Dismukes, G.C., Abramowicz, D.A., Ferris, F.K., Mathur, P., Upadrashta, B. and Watnick, P. (1983) in The Oxygen-Evolving System of Plant Photosynthesis (Inoue, Y., ed.), pp. 145–158, Academic Press, Tokyo) and in detergent-extracted, O₂-evolving Photosystem-II particles (Abramowicz, D.A., Raab, T.K. and Dismukes, G.C. (1984) Proceedings of the Sixth International Congress on Photosynthesis (Sybesma, C., ed.), Vol. I, pp. 349–354, Martinus Nijhoff/Dr. W. Junk Publishers, The Hague, The Netherlands), thus establishing a direct link with the O₂ evolving complex.     

Mitochondrial hyperpolarization during chronic complex I inhibition is sustained by low activity of complex II,III, IV and V

The mitochondrial oxidative phosphorylation (OXPHOS) system consists of four electron transport chain (ETC) complexes (CI–CIV) and the F_oF₁-ATP synthase (CV), which sustain ATP generation via chemiosmotic coupling. The latter requires an inward-directed proton-motive force (PMF) across the mitochondrial inner membrane (MIM) consisting of a proton (ΔpH) and electrical charge (Δψ) gradient. CI actively participates in sustaining these gradients via trans-MIM proton pumping. Enigmatically, at the cellular level genetic or inhibitor-induced CI dysfunction has been associated with Δψ depolarization or hyperpolarization. The cellular mechanism of the latter is still incompletely understood. Here we demonstrate that chronic (24 h) CI inhibition in HEK293 cells induces a proton-based Δψ hyperpolarization in HEK293 cells without triggering reverse-mode action of CV or the adenine nucleotide translocase (ANT). Hyperpolarization was associated with low levels of CII-driven O₂ consumption and prevented by co-inhibition of CII, CIII or CIV activity. In contrast, chronic CIII inhibition triggered CV reverse-mode action and induced Δψ depolarization. CI- and CIII-inhibition similarly reduced free matrix ATP levels and increased the cell's dependence on extracellular glucose to maintain cytosolic free ATP. Our findings support a model in which Δψ hyperpolarization in CI-inhibited cells results from low activity of CII, CIII and CIV, combined with reduced forward action of CV and ANT.