Effects of freezing on the structure of chloroplast membranes

Electron spin resonance (ESR) spectra of stearic acid spin labels incorporated into spinach thylakoids can be used to monitor membrane changes during freezing. Changes in the ESR parameters can be directly correlated to the extent of functional freeze damage. Freeze-induced changes in the ESR parameters strongly depend on the osmotic conditions of the incubation medium. Similar changes as on freezing can be observed by transferring thylakoids from an isotonic to a hypotonic medium, i.e., by swelling osmotically flattened thylakoids. This and computer simulations of spin label ESR spectra, which allow for variation of vesicle shape, lead to the conclusion that freeze-induced ESR spectral changes are due to swelling of the thylakoids. Indeed, van't Hoff plots of thylakoid packed volume indicate a freeze-induced increase in the apparent number of osmotically active molecules within the intrathylakoid lumen. During freezing, salt and/or sugar leak into the lumen. Simultaneously, proton channels are irreversibly opened. As the structural alterations obtained upon freezing are not accompanied by a change in bulk fluidity, these data are interpreted in terms of a local action of cryotoxic agents on critical microstructures, possibly at the rims of the thylakoid membranes.     

Structural reorganization of thylakoid systems in response to heat treatment

The structural reorganization of pea thylakoid systems in response to osmotic shock in a wide range of temperatures (36–70°C) was studied. At temperatures 40–46°C, the configuration of thylakoid systems changed from a flattened to a nearly round, whereas thylakoids themselves remained compressed. The percentage of thylakoids stacked into grana at 44°C decreased from 71 % in the control to 40 % in experimental samples, reaching 59 % at 48°C. At 44°C and above, thylakoid systems ceased to respond to the osmotic shock by disordering, in contrast to what happened at lower temperatures (36–43°C) and in the control, and retained the configuration inherent in thylakoid systems at these temperatures. At 50°C and above, the packing of thylakoids in grana systems changed, and thylakoids formed extended strands of pseudograna. Simultaneously, single thylakoids formed a network of anastomoses through local fusions. At temperatures of 60–70°C, thylakoid systems appeared as spherical clusters of membrane vesicles with different degree of separation.This revised version was published online in March 2005 with corrections to the page numbers.     

Effect of Light and Chilling Temperatures on Chilling-sensitive and Chilling-resistant Plants. Pretreatment of Cucumber and Spinach Thylakoids in Vivo and in Vitro

The effects of chilling temperatures, in light or dark, on the isolated thylakoids and leaf discs of cucumber (Cucumis sativa L. “Marketer”) and spinach (Spinacia oleracea L. “Bloomsdale”) were studied. The pretreatment of isolated thylakoids and leaf discs at 4 C in the dark did not affect the phenazine methosulfate-dependent phosphorylation, proton uptake, osmotic response to sucrose, Ca²⁺-dependent ATPase activity, or chlorophyll content. Exposure of cucumber cotyledon discs and isolated thylakoids of cucumber and spinach to 4 C in light resulted in a rapid inactivation of the thylakoids. The sequence of activities or components lost during inactivation (starting with the most sensitive) are: phenazine methosulfate-dependent cyclic phosphorylation, proton uptake, osmotic response to sucrose, Ca²⁺-dependent ATPase activity, and chlorophyll. The rate of loss of proton uptake, osmotic response to sucrose, Ca²⁺-dependent ATPase activity and chlorophyll is similar for isolated cucumber and spinach thylakoids, whereas spinach thylakoids are more resistant to the loss of phenazine methosulfate-dependent phosphorylation. The thylakoids of spinach leaf discs were unaffected by exposure to 4 C in light. The results question whether the extreme resistance of spinach thylakoids treated in vivo is solely a function of the chloroplast thylakoid membranes and establish the validity of using in vitro results to make inferences about cucumber thylakoids treated in vivo at 4 C in light.     

Carbonic Anhydrase Activities in Pea Thylakoids

Pea thylakoids with high carbonic anhydrase (CA) activity (average rates of 5000 µmol H⁺ (mg Chl)^–1 h^–1 at pH 7.0) were prepared. Western blot analysis using antibodies raised against the soluble stromal -CA from spinach clearly showed that this activity is not a result of contamination of the thylakoids with the stromal CA but is derived from a thylakoid membrane-associated CA. Increase of the CA activity after partial membrane disintegration by detergent treatment, freezing or sonication implies the location of the CA in the thylakoid interior. Salt treatment of thylakoids demonstrated that while one part of the initial enzyme activity is easily soluble, the rest of it appears to be tightly associated with the membrane. CA activity being measured as HCO₃ ^– dehydration (dehydrase activity) in Photosystem II particles (BBY) was variable and usually low. The highest and most reproducible activities (approximately 2000 µmol H⁺ (mg Chl)^–1 h^–1) were observed in the presence of detergents (Triton X-100 or n-octyl--D-glucopyranoside) in low concentrations. The dehydrase CA activity of BBY particles was more sensitive to the lipophilic CA inhibitor, ethoxyzolamide, than to the hydrophilic CA inhibitor, acetazolamide. CA activity was detected in PS II core complexes with average rate of 13,000 µmol H⁺ (mg Chl)^–1 h^–1 which was comparable to CA activity in BBY particles normalized on a PS II reaction center basis.This revised version was published online in October 2005 with corrections to the Cover Date.     

Changes in the structure and the functional state of thylakoids under the conditions of osmotic shock

The effect of osmotic shock on the ultrastructure and functions of C-class pea chloroplasts has been examined. When incubated in a non-sucrose medium for 30 s or more, thylakoids were found to pass to a stable deformed state. This state was characterized by an altered orientation of thylakoids to each other with the lumen thickness remaining the same as in the normal state. Experiments with shorter incubation periods (10–20 s) revealed a swelling of thylakoids, which probably represented an intermediate stage. The deformation of the thylakoid system was accompanied by a decrease in the non-cyclic ATP synthesis but by an increase in the rate of cyclic photophosphorylation. Besides, the deformed thylakoids demonstrated an acceleration of the basal electron transport, as well a rise in the light-induced H⁺ and imidazol uptake. The data obtained are discussed in the light of membrane interactions fixing the configuration of a thylakoid.     

Changes in some thylakoid membrane proteins and pigments upon desiccation of the resurrection plant Haberlea rhodopensis

The changes in some proteins involved in the light reactions of photosynthesis of the resurrection plant Haberlea rhodopensis were examined in connection with desiccation. Fully hydrated (control) and completely desiccated plants (relative water content (RWC) 6.5%) were used for thylakoid preparations. The chlorophyll (Chl) a to Chl b ratios of thylakoids isolated from control and desiccated leaves were very similar, which was also confirmed by measuring their absorption spectra. HPLC analysis revealed that β-carotene content was only slightly enhanced in desiccated leaves compared with the control, but the zeaxanthin level was strongly increased. Desiccation of H. rhodopensis to an air-dried state at very low light irradiance led to a little decrease in the level of D1, D2, PsbS and PsaA/B proteins in thylakoids, but a relative increase in LHC polypeptides. To further elucidate whether the composition of the protein complexes of the thylakoid membranes had changed, we performed a separation of solubilized thylakoids on sucrose density gradients. In contrast to spinach, Haberlea thylakoids appeared to be much more resistant to the same solubilization procedure, i.e. complexes were not separated completely and complexes of higher density were found. However, the fractions analyzed provided clear evidence for a move of part of the antenna complexes from PSII to PSI when plants became desiccated. This move was also confirmed by low temperature emission spectra of thylakoids.Overall, the photosynthetic proteins remained comparatively stable in dried Haberlea leaves when plants were desiccated under conditions similar to their natural habitat. Low light during desiccation was enough to induce a rise in the xanthophyll zeaxanthin and β-carotene. Together with the extensive leaf shrinkage and some leaf folding, increased zeaxanthin content and the observed shift in antenna proteins from PSII to PSI during desiccation of Haberlea contributed to the integrity of the photosynthetic apparatus, which is important for rapid recovery after rehydration.     

Low temperature development of winter rye leaves alters the detergent solubilization of thylakoid membranes

Thylakoids isolated from leaves of winter rye (Secale cereale L. cv Puma) grown at either 20 or 5°C were extracted with the nonionic detergents Triton X-100 and octyl glucoside. Less total chlorophyll was extracted from 5°C thylakoids by these detergents under all conditions, including pretreatment with cations. Thylakoids from either 20 or 5°C leaves were solubilized in 0.7% Triton X-100 and centrifuged on sucrose gradients to purify the light harvesting complex (LHCII). Greater yields of LHCII were obtained by cation precipitation of particles derived from 20°C thylakoids than from 5°C thylakoids. When 20 and 5°C thylakoids were phosphorylated and completely solubilized in sodium dodecyl sulfate, no differences were observed in the ³²Pi-labeling characteristics of the membrane polypeptides. However, when phosphorylated thylakoids were extracted with octyl glucoside, extraction of LHCII associated with the 5°C thylakoids was markedly reduced in comparison with the extraction of LHCII from 20°C membranes. Since 20 and 5°C thylakoids exhibited significant differences in the Chl content and Chl a/b ratios of membrane fractions produced after solubilization with either Triton X-100 or octyl glucoside, and since few differences between the proteins of the two membranes could be observed following complete denaturation in sodium dodecyl sulfate, we conclude that the integral structure of the thylakoid membrane is affected during rye leaf development at low temperature.     

Effects of High Temperature Exposure of Spinach Intact Plants and Isolated Thylakoids on Light-Harvesting Complex 2 Protein Phosphorylation

After a 6 min exposure of isolated thylakoids to 43 °C, the extent of phosphorylation of light-harvesting complex of photosystem 2 (LHC2) was higher than in control thylakoids kept at 25 °C. Similarly, the exposure of intact spinach plants to 43 °C in dark for 11 h induced higher extent of thylakoid LHC2 phosphorylation than in control plants kept at 25 °C. The induced ability of LHC2 for enhanced phosphorylation may enable better energy distribution in favour of photosystem 1.     

Quality control of Photosystem II under light stress – turnover of aggregates of the D1 protein in vivo

When photodamaged under excessive light, the D1 protein is digested and removed from Photosystem (PS) II to facilitate turnover of the protein. In vitro studies have shown that part of the photodamaged D1 protein forms aggregates with surrounding polypeptides before being digested by a protease(s) in the stroma [Yamamoto Y (2001) Plant Cell Physiol 42: 121–128]. The aim of this study was to examine whether light-induced aggregation of the D1 protein also occurs in vivo. The following results were obtained: (1) PS II activity in spinach leaves was significantly inhibited by weak illumination (light intensity, 20–100 μE m⁻² s⁻¹), as monitored by chlorophyll fluorescence Fv/Fm, when the leaves were kept at higher temperatures (35–40 °C); (2) aggregation of the D1 protein, as well as cleavage of the protein, was detected in thylakoids isolated from spinach leaves that had been subjected to heat/light stress; (3) aggregates of the D1 protein disappeared after incubation of the leaves at 25 °C in the dark or under illumination with weak light. Since it is dependent on the presence of oxygen, aggregation of the D1 protein is probably induced by reactive oxygen species produced in thylakoids upon illumination at elevated temperatures. Consistent with this notion, singlet oxygen production in thylakoid samples under illumination was shown to be stimulated significantly at higher temperatures.     

The functional sites of chlorophylls in D1 and D2 subunits of Photosystem II identified by pulsed EPR

The functional site of Chl_Z, an auxiliary electron donor to P680⁺, was determined by pulsed ELDOR applied to a radical pair of Y_D^• and Chlz⁺ in oriented PS II membranes from spinach. The radical-radical distance was determined to be 29.5 Å and its direction was 50° from the membrane normal, indicating that a chlorophyll on the D2 protein is responsible for the EPR Chlz⁺ signal. Spin polarized ESEEM (Electronin Spin Echo Envelop Modulation) of a ³Chl and Q_A⁻ radical pair induced by a laser flash was observed in reaction center D1D2Cytb₅₅₉ complex, in which Q_A was functionally reconstituted with DBMIB and reduced chemically. Q_A⁻ESEEM showed a characteristic oscillating time profile due to dipolar coupling with ³Chl. By fitting with the dipolar interaction parameters, the distance between ³Chl and Q_A⁻ was determined to be 25.9 Å, indicating that the accessory chlorophyll on the D1 protein is responsible for the ³Chl signal.     

Differential effect of NaCl and polyethylene glycol on the ultrastructure of chloroplasts in rice seedlings

Ionic and osmotic effects of salinity on the ultrastructure of chloroplasts in salt-treated rice seedlings were investigated. After rice seedlings were grown in hydroponic culture for three weeks, they were treated with NaCl and polyethylene glycol (PEG) 4000 both at a water potential of -1.0 MPa for 3 days. The most notable difference in ultrastructural change between NaCl and PEG treatment was observed in the damage in chloroplast membranes. NaCl induced swelling of thylakoids and caused only a slight destruction of the chloroplast envelope. PEG caused severe destruction of the chloroplast envelope compared with NaCl, however thylakoids did not swell. Our observations suggested that in salt-treated rice plants, the ionic effects induced swelling of thylakoids and the osmotic effects caused the destruction of chloroplast envelope.     

The activation and inactivation of the Dunaliella salina chloroplast coupling factor 1 (CF1) in vivo and in situ

Preillumination of intact cells of the eukaryotic, halotolerant, cell-wall-less green alga Dunaliella salina induces a dark ATPase activity the magnitude of which is about 3–5-fold higher than the ATPase activity observed in dark-adapted cells. The light-induced activity arises from the activation and stabilization in vivo of chloroplast coupling factor 1 (CF₁). This activity, 150–300 μmol ATP hydrolyzed/mg Chl per h, rapidly decays (with a half-time of about 6 min at room temperature) in intact cells but only slowly decays (with a half-time of about 45 min at room temperature) if the cells are lysed by osmotic shock immediately after illumination. The activated form of the ATPase in lysed cells is inhibited if the membranes are treated with ferri- but not ferrocyanide, suggesting that the stabilization of the activated form of CF₁ is due to the reduction of the enzyme in vivo in the light.     

Ferredoxin Cross-Links to a 22 kD Subunit of Photosystem I

We have used a cross-linking approach to study the interaction of ferredoxin (Fd) with photosystem I (PSI). The cross-linking reagent N-ethyl-3-(3-dimethylaminopropyl) carbodiimide was found to cross-link spinach Fd to a 22 kilodalton subunit of PSI in both isolated spinach (Spinacia oleracea) PSI complexes and spinach thylakoid membranes. The product had an apparent molecular weight of 38 kilodaltons on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and was identified as a cross-linked product using specific antibodies to Fd and the 22 kilodalton subunit. In both a native PSI complex (200 Chl/P700) and a PSI core complex (100 Chl/P700), a second cross-linked product at 36 kilodaltons was seen. The latter cross-reacted with an antibody to Fd but did not cross-react with antibodies directed against the 24.3, 22, 19, 17.3 or 8.5 kilodalton, or psaC subunits of PSI. Its composition remains to be determined. In thylakoids only the 38 kilodalton product was observed along with a cross-linked complex of Fd and Fd:NADP⁺ reductase.     

A chlorophyll b-less mutant of Chlamydomonas reinhardii lacking in the light-harvesting chlorophyll complex but not in its apoproteins

The mutant pg 113, derived from Chlamydomonas reinhardii, arg₂⁻ mt⁺ (parent strain), completely lacks chlorophyll (Chl) b but is still able to grow under autotrophic conditions. The light-harvesting Chl complex (LHCP) is absent. This is shown (a) by the lack of the corresponding signal in the CD spectrum of thylakoids and (b) by the absence of the band of the LHCP after electrophoresis of partially solubilized thylakoid membranes on lithium dodecyl sulfate polyacrylamide gels. All the other chlorophyll-protein complexes are present. In spite of the absence of the LHCP, all the polypeptide components of this complex are present in the mutant in the same ratios as in the parent strain, although in slightly reduced amounts. The LHC apoproteins are synthesized, processed and transported into the thylakoid membrane of the mutant. Moreover, the phosphorylation of thylakoid membrane polypeptides, which is related to the regulation of the energy distribution between Photosystem I and II, is the same in the mutant and in the parent strain, indicating that phosphorylation is not dependent on the presence of Chl b. Electron micrographs of thin sections of whole cells show that there are stacked regions of thylakoids in both the mutant and the parent strain chloroplasts. However, in the mutant, stacks are located near the chloroplast envelope, while long stretches or sometimes circles of unstacked membranes are found in the interior, mostly around the pyrenoid.     

Hydrogenation of geranylgeraniol : two pathways exist in spinach chloroplasts

The reduction of geranylgeranylpyrophosphate to phytylpyrophosphate in spinach chloroplasts is described for the first time. The reductase is localized in the chloroplast envelope. By contrast, the reduction of the geranylgeranyl moiety in Chl synthesis is catalyzed in the thylakoids (via Chl synthetase). NADPH functions as electron donor in both reactions. Chl synthetase is firmly bound to the thylakoid membranes, and very little activity is found in the stroma fraction. Chl synthetase in chloroplasts can use the pyrophosphate ester of either phytol, geranylgeraniol, or farnesol, phytylpyrophosphate being the preferred substrate. Exogenous Chlide exhibits no influence on Chl synthesis by chloroplast subfractions.     

Electron microscopic structure and oxygen evolution activity of thylakoids from Avicennia marina prepared under different osmotic and ionic conditions

Abstract Stacking of thylakoid membranes in vitro was assessed using electron microscopy. Grana stacks of spinach thylakoids formed when 5 mol m^?3 MgCl₂ was present, but no stacking of thylakoids from the mangrove Avicennia marina occurred in the presence of 10 mol m^?3? MgCl₂. Isolation of mangrove thylakoids with a high osmotic strength medium did not induce grana formation if the medium consisted only of sorbitol or glycinebetaine. Addition of cations to the high osmotic strength medium did induce some loose-grana formation, with divalent cations being more effective than monovalent cations. Glycinebetaine was a better osmoticum than sorbitol for grana formation provided divalent cations had been added. Oxygen evolution activity of the preparations was influenced by the amount of membrane stacking, with the preparations with the greatest amount of stacked membrane having the highest activity. Isolation with sorbitol or glycinebetaine based media did not alter this pattern, nor did assay in sorbitol or glycinebetaine. Mangrove thylakoids have a requirement for both a high osmotic strength and divalent cations for grana formation in vitro which may be related to the low water potential of the plant environment in vivo.     

Dual character of lipid composition of the envelope membrane of spinach chloroplasts

The envelope membrane was isolated from intact spinach chloroplastsby gentle osmotic treatment in a medium containing appropriateamounts of cations to prevent dissociation and fragmentationof the thylakoids. This treatment allowed us to separate effectivelythe envelope membranes from the thylakoids with one-step (0.6M/0.9 M) sucrose density gradient centrifugation. The envelope membrane contained both glyceroglycolipids andglycerophospholipids, as does the thylakoid membrane. Therewere, however, notable differences in the relative amounts oflipid components between these two membranes. The major glyceroglycolipidin the envelope membrane was digalactosyl diglyceride, whereasmonogalactosyl diglyceride was the major one in the thylakoid.The envelope membrane was characterized by a high content ofglycerophospholipids, as much as three-fold that in the thylakoidmembrane. Phosphatidyl choline, which is known to be minor inthe thylakoids and abundant in the microsomal and mitochondrialmembranes, was a major component, accounting for 50% of thetotal glycerophospholipids. The dual character of lipid compositionof the envelope membrane is discussed in terms of its chemicaland structural connection to the other intracellular membranesystems. (Received May 26, 1975; )     

Desiccation‐induced alterations in surface topography of thylakoids from resurrection plant Haberlea rhodopensis studied by atomic force microscopy,electrokinetic and optical measurements

With their ability to survive complete desiccation, resurrection plants are a suitable model system for studying the mechanisms of drought tolerance. In the present study, we investigated desiccation‐induced alterations in surface topography of thylakoids isolated from well‐hydrated, moderately dehydrated, severely desiccated and rehydrated Haberlea rhodopensis plants by means of atomic force microscopy (AFM), electrokinetic and optical measurements. According to our knowledge, so far, there were no reports on the characterization of surface topography and polydispersity of thylakoid membranes from resurrection plants using AFM and dynamic light scattering. To study the physicochemical properties of thylakoids from well‐hydrated H. rhodopensis plants, we used spinach thylakoids for comparison as a classical model from higher plants. The thylakoids from well‐hydrated H. rhodopensis had a grainy surface, significantly different from the well‐structured spinach thylakoids with distinct grana and lamella, they had twice smaller cross‐sectional area and were 1.5 times less voluminous than that of spinach. Significant differences in their physicochemical properties were observed. The dehydration and subsequent rehydration of plants affected the size, shape, morphology, roughness and therefore the structure of the studied thylakoids. Drought resulted in significant enhancement of negative charges on the outer surface of thylakoid membranes which correlated with the increased roughness of thylakoid surface. This enhancement in surface charge density could be due to the partial unstacking of thylakoids exposing more negatively charged groups from protein complexes on the membrane surface that prevent from possible aggregation upon drought stress.     

Multiple sources of carbonic anhydrase activity in pea thylakoids: soluble and membrane-bound forms

Carbonic anhydrase (CA) activity of pea thylakoids, thylakoid membranes enriched with photosystem I (PSI-membranes), or photosystem II (PSII-membranes) as well as both supernatant and pellet after precipitation of thylakoids treated with detergent Triton X-100 were studied. CA activity of thylakoids in the presence of varying concentrations of Triton X-100 had two maxima, at Triton/chlorophyll (triton/Chl) ratios of 0.3 and 1.0. CA activities of PSI-membranes and PSII-membranes had only one maximum each, at Triton/Chl ratio 0.3 or 1.0, respectively. Two CAs with characteristics of the membrane-bound proteins and one CA with characteristics of the soluble proteins were found in the medium after thylakoids were incubated with Triton. One of the first two CAs had mobility in PAAG after native electrophoresis the same as that of CA residing in PSI-membranes, and the other CA had mobility the same as the mobility of CA residing in PSII-membranes, but the latter was different from CA situated in PSII core-complex (Ignatova et al. 2006 Biochemistry (Moscow) 71:525–532). The properties of the “soluble” CA removed from thylakoids were different from the properties of the known soluble CAs of plant cell: apparent molecular mass was about 262 kD and it was three orders more sensitive to the specific CA inhibitor, ethoxyzolamide, than soluble stromal CA. The data are discussed as indicating the presence of, at least, four CAs in pea thylakoids.     

Differences in the way potassium chloride and sucrose solutions effect osmotic potential of significance to stomata aperture modulation

Guard cell solution osmotic potential changes resulting in the opening and closing of stomata apertures follow an initial influx of potassium ions, their substitution with sucrose molecules and the subsequent reduction of the latter. To provide an insight into the osmotic mechanism of the changes, the new equation for calculating osmotic pressure, which equates the difference between the energy of pure water across a semi-permeable membrane interface with that of solution water, was used to compare the osmotic properties of KCl and sucrose. For sucrose solutions, the effect of the sucrose molecules in increasing the spacing of the solution water was mainly responsible for osmotic potential; this contrasted with K⁺ + Cl^? ions where their spacing effect was only a little higher to that of water held to those ions. At solute concentrations giving an osmotic potential level of ?3.0 MPa near that of turgid guard cells, the spacing effect on the potential of the unattached solution water molecules caused by sucrose, but in its theoretical absence, was estimated as ?2.203 MPa compared with ?1.431 MPa for KCl. In contrast, the potential attributed to water molecules firmly held to the K⁺ + Cl^? ions was ?1.212 MPa versus zero for sucrose. The potential to keep the sucrose molecules in solution was ?0.797 MPa compared with ?0.357 MPa for KCl. The findings illustrate that the way KCl effects osmotic pressure is very different to that of sucrose. It is concluded that stomata aperture modulation is closely linked to the osmotic properties of its guard cell solution solutes.