Homogeneous catalytic hydrogenation of lipids in the photosynthetic membrane: Effects on membrane structure and photosynthetic activity

We have carried out a series of experiments in which the lipid composition of the photosynthetic membrane has been altered by the homogeneous catalytic hydrogenation of the unsaturated fatty acid residues of membrane lipids. The modified membrane was investigated by electron microscopy, electron-spin resonance and fluorescence polarization methods. Alteration in the functional characteristics of the hydrogenated membrane was monitored by the measurement of photophosphorylation and electron-transport activities. The following results were found. (a) Saturation of 10% of the fatty acyl double bonds induced a definite decrease in the dimension of both thylakoids and loculi. Microdensitometry showed that these structural changes arose from a thickening of the single membranes with a simultaneous decrease in the spacing between membranes. These changes might be accounted for by the alignment of the hydrocarbon chains of saturated lipids and the increased hydrophobicity of the membranes. (b) The orientational pattern of chlorophyll-a molecules was not altered by saturating up to 50% of fatty acyl double bonds in membrane lipids, indicating that the energy-transfer processes amongst the chlorophyll molecules remained functional after hydrogenation. (c) Saturation of double bonds of lipids inhibited whole electron transport prior to the inhibition of Photosystem II and Photosystem I activity, which may suggest that the unsaturation level of fatty acids plays a crucial role by ensuring the lateral mobility of plastoquinone between Photosystem II and Photosystem I.     

Modulation of chloroplast membrane lipids by homogeneous catalytic hydrogenation

A method is reported for the modification of lipids in situ in chloroplast membrane by which a homogeneous, water-soluble catalyst Pd(QS)2 (QS, sulphonated alizarine; C14H6O7NaS) is incorporated into the thylakoids of isolated chloroplast. The catalyst itself did not affect the photosynthetic activity but caused an extensive loss of unsaturated fatty acids in the presence of hydrogen gas. The polyunsaturated fatty acids were hydrogenated at a faster rate than the monoenoic acids. During hydrogenation the orientational ordering of membrane lipids, as measured with the C-12 positional isomer of spin-labelled stearic acid, displayed a slight increase in agreement with the alterations in membrane composition. Progressive saturation of double bonds of lipids primarily inhibits electron transport between the photosystems followed by the inhibition of electron flow around photosystem II. Photosystem I electron transport was not inhibited even by 50% fatty acid hydrogenation. We suggest that using Pd(QS)2 catalyst for thylakoid hydrogenation offers an excellent technique to study the role of various unsaturated fatty acids in the regulation of membrane fluidity and photosynthetic processes.     

The fluidity of chloroplast thylakoid membranes and their constituent lipids: A comparative study by ESR

Comparative measurements were made of the fluidity of chloroplast thylakoids, total membrane lipids and polar lipids utilizing the order parameter and motion of spin labels.No significant differences were found in the fluidity of membranes or total membrane lipids from a wild type and a mutant barley (Hordeum vulgare chlorina f₂ mutant) which lacks chlorophyll $\text{b}$ and a 25 000 dalton thylakoid polypeptide. Redistribution of intrinsic, exoplasmic face (EF) membrane particles by unstacking thylakoid membranes in low salt medium also had no effect on membrane fluidity. However, heating of isolated thylakoids decreased membrane fluidity.The fluidity of vesicles composed of membrane lipids is much greater than that of the corresponding membranes. Fluidity of the membranes, however, increased during greening indicating that the rigidity of the membranes, compared with that of total membrane lipids, is not caused by chlorophyll or its associated peptides. It is concluded that the restriction of motion in the acyl chains in the thylakoids is not caused by chlorophyll or the major intrinsic polypeptide but by some other protein components.     

The modulation of membrane fluidity by hydrogenation processes. III. The hydrogenation of biomembranes of spinach chloroplasts and a study of the effect of this on photosynthetic electron transport

A method is reported for the in situ modification of the lipids of isolated spinach chloroplast membranes. The technique is based on a direct hydrogenation of the lipid double bonds in the presence of the catalyst, chlorotris(triphenylphosphine)rhodium (I). The pattern of hydrogenation achieved suggests that the catalyst distributes amongst all of the membranes. The polyunsaturated lipids within the membranes are hydrogenated at a faster rate and at an earlier stage than are the monoenoic lipids.Whilst addition of the catalyst to the chloroplast causes an initial 10–20% decrease in Hill activity, saturation of up to 40% of the double bonds present can be accomplished without causing further significant alterations in photosynthetic electron transport processes or marked morphological changes of the chloroplast structure as observed in the electron microscope.     

The modulation of membrane fluidity by hydrogenation processes. III. The hydrogenation of biomembranes of spinach chloroplasts and a study of the effect of this on photosynthetic electron transport.

A method is reported for the in situ modification of the lipids of isolated spinach chloroplast membranes. The technique is based on a direct hydrogenation of the lipid double bonds in the presence of the catalyst, chlorotris(triphenylphosphine)rhodium (I). The pattern of hydrogenation achieved suggests that the catalyst distributes amongst all of the membranes. The polyunsaturated lipids within the membranes are hydrogenated at a faster rate and at an earlier stage than are the monoenoic lipids. Whilst addition of the catalyst to the chloroplast causes an initial 10--20% decrease in Hill activity, saturation of up to 40% of the double bonds present can be accomplished without causing further significant alterations in photosynthetic electron transport processes or marked morphological changes of the chloroplast structure as observed in the electron microscope.     

Membrane lipids in heat injury of spinach chloroplasts

Heat treatment of intact leaves and of isolated thylakoid membranes from spinach (Spinacia oleracea L. cvs. Monatol and Montako) caused inactivation of photochemical processes such as electron transport through photosystem II and photophos-phorylation. Membrane lipid analysis demonstrated that heat-induced damage to thylakoids is not caused by chemical alterations in the lipids such as oxidation of unsaturated fatty acids, or release of free fatty acids due to hydrolysis of lipids. Partial extraction of lipids from isolated chloroplast membranes before and after thermal inactivation do not point to drastic changes in the binding relations of the lipids within the membranes. However, it cannot be excluded that during high temperature treatment changes in lipid-lipid interactions and/or delocalization of specific lipids within the thylakoids might be responsible for the disorganization of the functional integrity of the membranes. Since thermostability of chloroplast membranes is decreased when they are exposed to free unsaturated fatty acids, small amounts of membrane lipids which become hydrolyzed during extended heat treatment may partly contribute to primary heat damage.     

Lipid unsaturation determines the interaction of AFP type I with model membranes during thermotropic phase transitions

We have previously shown that antifreeze protein (AFP) type I from winter flounder interacts with the acyl chains of lipids in model membranes containing a mixture of dimyristoylphosphatidylcholine (DMPC) and the plant thylakoid lipid digalactosyldiacylglycerol (DGDG), most likely through hydrophobic interactions. By contrast, in studies with pure phospholipid membranes, no such interaction was seen. DGDG is a highly unsaturated lipid, which renders these studies quite different from the previous studies of AFP-membrane interaction where the lipids were saturated or trans-unsaturated. Therefore, it seemed possible that either the digalactose headgroups or the unsaturated DGDG acyl chains, or both, may be important for interactions of membranes with AFP type I. To distinguish between these possibilities, we catalytically hydrogenated the DGDG to obtain a galactolipid with completely saturated fatty acyl chains. The results with the hydrogenated DGDG were strikingly different from those obtained previously with the unsaturated DGDG; the clear binding of AFPs to the bilayer appeared to be lost. Nevertheless, the temperature-dependent folding of AFP type I was inhibited in the presence of liposomes containing either the unsaturated or the hydrogenated DGDG. The results indicate that the liposomes and protein still interact, even following hydrogenation of the acyl chains, perhaps at the membrane-solution interface.     

The influence of carotenoids on the oxidative stability and phase behaviour of plant polar lipids

Carotenoids and total neutral lipids from thylakoids of Nerium oleander were evaluated as antioxidants in liposomes prepared from soybean polar lipids. The extent of lipid oxidation was assessed from the formation of malondialdehyde and conjugated dienes after exposure of the liposomes to free radicals generated by ⁶⁰Co gamma radiolysis. The carotenoids incorporated into the bilayers were isolated from clones of oleander grown at 20° or 45°, growth conditions which are known to result in a difference in the thermal properties of the membrane lipids. The effect of carotenoids on the temperature of the phase transition of thylakoid polar lipids was also examined. The results showed that, in comparison with the effectiveness of a reference antioxidant, α-tocopherol, the carotenoids and total neutral lipids from thylakoids of oleander did not protect the soybean polar lipids from oxidation, nor did they influence the temperature of the phase transition of thylakoid polar lipids.     

Differential thermal effects on the energy distribution between photosystem II and photosystem I in thylakoid membranes of a psychrophilic and a mesophilic alga

Sensitivity of the photosynthetic thylakoid membranes to thermal stress was investigated in the psychrophilic Antarctic alga Chlamydomonas subcaudata. C. subcaudata thylakoids exhibited an elevated heat sensitivity as indicated by a temperature-induced rise in F_o fluorescence in comparison with the mesophilic species, Chlamydomonas reinhardtii. This was accompanied by a loss of structural stability of the photosystem (PS) II core complex and functional changes at the level of PSI in C. reinhardtii, but not in C. subcaudata. Lastly, C. subcaudata exhibited an increase in unsaturated fatty acid content of membrane lipids in combination with unique fatty acid species. The relationship between lipid unsaturation and the functioning of the photosynthetic apparatus under elevated temperatures is discussed.     

Effect of Temperature on Growth of Bacillus sp. T-4, a Thermophilic Acidophilic Bacterium

The lipid distribution and function in the thylakoid membranes from a thermophilic cyanobacterium, Mastigocladus laminosus, were investigated. The thylakoid membranes were treated with digitonin and separated on a DEAE-cellulose column into fractions enriched in photosystem I or II complex. Lipid analyses showed a specific distribution of anionic lipids among the fractions. A mild delipidation of the membranes with cholate indicates that monogalactosyl diacylglycerol (MGDG) and sulfoquinovosyl diacylglycerol (SQDG) are released rapidly, while the major parts of digalactosyl diacylglycerol (DGDG) and phosphatidylglycerol (PG) are tightly associated with membranes, suggesting a different distribution between the two groups of lipids. Measurements of fluorescence of delipidated and reconstituted thylakoids showed the contribution of lipids to energy transfer. MGDG enhanced all the original fluorescence of thylakoids, while acidic PG and SQDG stimulated fluorescence of photosystem I and antena chlorophyll-protein complexes. DGDG was less effective under the conditions tested.     

LIPID MODIFICATIONS RELATED TO ENCYSTMENT AND EXCYSTMENT OF CRYPTOMONAS RUFESCENS SKUJA (CRYPTOPHYCEAE)1

The lipids of Cryptomonas rufescens (Skuja) cells have been analyzed. Quantitative changes of polar and neutral lipids were observed during cell encystment, induced by cultures in a nitrogen-deficient medium. During encystment, thylakoids disappeared while unsaturated galactolipids, characteristics of chloroplast membranes, decreased and neutral lipids accumulated in the cytoplasm. When excystment was induced, the reversal of the phenomenon was observed while thylakoids containing galactolipids were formed.     

A Comparison of the Effects of Chilling on Thylakoid Electron Transfer in Pea (Pisum sativum L.) and Cucumber (Cucumis sativus L.)

Experiments comparing the photosynthetic responses of a chilling-resistant species (Pisum sativum L. cv Alaska) and a chilling-sensitive species (Cucumis sativus L. cv Ashley) have shown that cucumber photosynthesis is adversely affected by chilling temperatures in the light, while pea photosynthesis is not inhibited by chilling in the light. To further investigate the site of the differential response of these two species to chilling stress, thylakoid membranes were isolated under various conditions and rates of photosynthetic electron transfer were determined. Preliminary experiments revealed that the integrity of cucumber thylakoids from 25°C-grown plants was affected by the isolation temperature; cucumber thylakoids isolated at 5°C in 400 millimolar NaCl were uncoupled, while thylakoids isolated at room temperature in 400 millimolar NaCl were coupled, as determined by addition of gramicidin. The concentration of NaCl in the homogenization buffer was found to be a critical factor in the uncoupling of cucumber thylakoids at 5°C. In contrast, pea thylakoid membranes were not influenced by isolation temperatures or NaCl concentrations. In a second set of experiments, thylakoid membranes were isolated from pea and cucumber plants at successive intervals during a whole-plant light period chilling stress (5°C). During wholeplant chilling, thylakoids isolated from cucumber plants chilled in the light were uncoupled even when the membranes were isolated at warm temperatures. Pea thylakoids were not uncoupled by the whole-plant chilling treatment. The difference in integrity of thylakoid membrane coupling following chilling in the light demonstrates a fundamental difference in photosynthetic function between these two species that may have some bearing on why pea is a chilling-resistant plant and cucumber is a chilling-sensitive plant.     

Structure of photosynthetic membranes of Euglena using X-ray diffraction

Novel X-ray diffraction results of membranes from chloroplasts of Euglena are presented, together with freeze-etch images obtained concurrently. Conditions were found for sharp lamellar reflections corresponding to ordered stacking of thylakoids. The periodicity measured by diffraction agrees well with that observed by microscopy. Intensities of diffraction were analysed in order to calculate the electron density distributions across the membranes. Some arguments in favour of the preferred phases of the reflection are given. The distributions indicate firstly the presence of 25 Å-wide regions where the hydrocarbon chains of the membrane lipids are concentrated. This result is discussed in terms of structural models for the chloroplast membrane. Comparison with results of freeze-etching indicates where in the density distribution are the regons inside and outside the membrane sacs. Secondly, the density distributions show maxima on the outside of the membranes only, corresponding possibly to an asymmetrical distribution of lipids.     

Polyunsaturated fatty acyl residues of galactolipids are involved in the control of bilayer/non-bilayer lipid transitions in higher plant chloroplasts

Total polar lipid extracts of chloroplasts isolated from broad beans (Vicia faba) tend to form non-bilayer structures when dispersed in dilute salt solutions. Monoglactosyldiacylglycerol is shown to play a dominant role in this process. The tendency of this lipid to form non-bilayer structures when dispersed alone in water was found to depend upon the degree of unsaturation of its associated fatty acyl chains. Highly unsaturated lipids (average number of double bonds per lipid molecule greater than about 5.0) form inverted hexagonal (Hex_II) structures in water at 20°C, whilst more saturated lipids (average number of double bonds per lipid molecule less than about 4.5) form lamellar sheets. Wide-angle X-ray diffraction and differential scanning calorimetry measurements indicate that these lamellae consist of gel-phase lipid that can adopt either of two structures depending on the thermal history of the sample. Freeze-fracture studies performed on total polar lipid extracts that have been hydrogenated using Adams' catalyst, and reconstituted extracts in which monogalactosyldiacylglycerol has been selectively hydrogenated, show that the degree of unsaturation of this lipid is a key factor in determining whether or not non-bilayer structures are formed in such extracts. Increasing the extent of saturation of the acyl residues of monogalactosyldiacylglycerol reduces the tendency to form non-bilayer structures. Similar effects are observed on lowering the temperature of the dispersions. Fluorescence polarisation measurements using 1,6-diphenyl-1,3,5-hexatriene indicate that the disappearance of non-bilayer structures is accompanied by a marked decrease in the fluidity of the lipid matrix. The possible significance of these observations is discussed in terms of the thermal adaptation and chilling sensitivity of plant membranes.     

Non-vesicular and vesicular lipid trafficking involving plastids

In plants, newly synthesized fatty acids are either directly incorporated into glycerolipids in the plastid or exported and assembled into lipids at the endoplasmic reticulum (ER). ER-derived glycerolipids serve as building blocks for extraplastidic membranes. Alternatively, they can return to the plastid where their diacylglycerol backbone is incorporated into the glycerolipids of the photosynthetic membranes, the thylakoids. Thylakoid lipids are assembled at the plastid envelope membranes and are transferred to the thylakoids. Under phosphate-limited growth conditions, galactolipids are exported from the outer plastid envelope membranes to extraplastidic membranes. Proteins, such as TRIGALACTOSYLDIACYLGLYCEROL1 (TGD1) or VESICLE-INDUCING PROTEIN IN PLASTIDS1 (VIPP1), which are involved in different aspects of plastid lipid trafficking phenomena have recently been identified and mechanistic models that are based on the analysis of these components have begun to emerge.     

Chloroplast membrane damage during freezing: the lipid phase

In order to study the effect of freeze damage to chloroplast membranes microviscosity of spinach thylakoids was probed by stearic acid spin labels. Changes in ESR parameters have been determined either as a function of temperature or during freezing at ?15 °C as a function of time. An empirical parameter $\text{h}{}_{\mathrm{+}}\text{h}{}_0$ (ratio of height of a low field line component h₊ over height of the central line h₀) proved to be very sensitive to minute changes in membrane structure.In cryoprotected chloroplast membranes Arrhenius plot breaks indicative of phase changes are observed at +15 and ?10 °C. Breaks in the Arrhenius plots were not observed in vesicles prepared from chloroplast lipids by sonication. Instead, a melting zone was indicated below ?30 °C.Freeze damage of thylakoids during storage at ?15 °C is reflected in an increase of $\text{h}{}_{\mathrm{+}}\text{h}{}_0$ and a decrease in central line width W₀. At +20 °C, differences between the ESR parameters of active as compared to freeze-damaged membranes could be detected, if the osmolarity of the suspending medium exceeded 200 mosm. The observed changes in line shapes are interpreted as an increase in mobility and/or orientation of the lipids following the swelling of thylakoids. They do not indicate a disorganization of the lipid phase. Sedimentation experiments indicated that the freeze-damaged swollen membranes still exhibited osmotic responses. It is suggested that freezing which is known to dissociate proteins from the membranes altered the charge distribution of the membranes leading first to membrane swelling and finally, by the opening of hydrophilic channels, to membrane collapse.     

Frost hardening and photosynthetic performance of Scots pine (Pinus sylvestris L.). II. Seasonal changes in the fluidity of thylakoid membranes

The fluidity of chloroplast thylakoid membranes of frost-tolerant and frost-sensitive needles of␣three- to four-year-old Scots pine (Pinus sylvestris L.) trees, of liposomes produced from the lipids of the thylakoids of these needles, and of liposomes containing varying amounts of light-harvesting complex (LHC) II protein was investigated by means of electron paramagnetic resonance (EPR) measurements using spin-labelled fatty acids as probes. Broadening of the EPR-resonance signals of 16-doxyl stearic acid in chloroplast membranes of frost-sensitive needles and changes in the amplitudes of the peaks were observed upon a decrease in temperature from +30 °C to −10 °C, indicating a drastic loss in rotational mobility. The lipid molecules of the thylakoid membranes of frost-tolerant needles exhibited greater mobility. Moderate frost resistance could be induced in Scots pine needles by short-day treatment (Vogg et al., 1997, Planta, this issue), and growth of the trees under short-day illumination (9 h) resulted in a higher mobility of the chloroplast membrane lipids than did growth under long-day conditions (16 h). The EPR spectrum of thylakoids from frost-tolerant needles at −10 °C was typical of a spin label in highly fluid surroundings. However, an additional peak in the low-field range appeared in the subzero temperature range for the chloroplast membranes of frost-sensitive needles, which represents spin-label molecules in a motionally restricted surrounding. The EPR spectra of thylakoids and of liposomes of thylakoid lipids from frost-hardy needles were identical at +30 °C and −10 °C. The corresponding spectra from frost-sensitive plants revealed an additional peak for the thylakoids, but not for the pure liposomes. Hence, the domains with restricted mobility could be attributed to protein-lipid interactions in the membranes. Broadening of the spectrum and the appearance of an additional peak was observed with liposomes of pure distearoyl phosphatidyl glycerol modified to contain increasing amounts of LHC II. These results are discussed with respect to a loss of chlorophyll and chlorophyll-binding proteins in thylakoids of Scots pine needles under winter conditions. Received: 3 March 1997 / Accepted: 16 July 1997     

BIOGENESIS OF CHLOROPLAST MEMBRANES : V. A Radioautographic Study of Membrane Growth in a Mutant of Chlamydomonas reinhardi y-1

The development of photosynthetic lamellae during greening of dark-grown Chlamydomonas y-1 cells was investigated by radioautography. Acetate-³H was used as a marker for membrane lipids. In short pulse-labeling experiments, about 50–60% of the radioactivity incorporated was found in the lipid fraction and about 25–50% in starch granules present in the chloroplast of these algae. The relative specificity of acetate-³H used as a marker for membranes was artificially increased through quantitative removal of the starch granules from fixed cells by amylase treatment. Analysis of turnover coefficients of different membrane constituents and of the contribution of turnover and net synthesis to the total label incorporated in pulse experiments indicated that the incorporation of acetate into specific lipids was mainly due to net synthesis. The distribution of radioactivity in the different lipid constituents at the end of a short pulse and after 30- and 60-min chases indicated that transacylation is minimal and may be disregarded as a possible cause of randomization of the label. Statistical analysis of radioautographic grain distribution and measurements of different structural parameters indicate that (a) the chloroplast volume and surface remain constant during the process, whereas the growth of the photosynthetic lamellae parallels the increase in chlorophyll; (b) the lamellae do not develop from the chloroplast envelope or from the tubular system of the pyrenoid; (c) all the lamellae grow by incorporation of new material within preexisting structures; (d) different types of lamellae grow at different rates. The pyrenoid tubular system develops faster than the thylakoids, and single thylakoids develop about twice as fast as those which are paired or fused to grana. It is concluded that growth of the membranes occurs by a mechanism of random intussusception of molecular complexes within different types of preexisting membranes.     

Lipidome of the reef-building coral Acropora cerealis: Changes under thermal stress

Coral bleaching is caused by complete or partial loss of coral endosymbionts in response to increased sea surface temperature and solar radiation. A thermal stress leads to formation of reactive oxygen species resulting in a disturbance of coral cell membranes. Lipids are an essential component of cell membranes. The lipidome of the hard coral Acropora cerealis and its alteration under thermal stress were studied. The features of A. cerealis lipids were trace amounts of monoalkyldiacylglycerols, a high content of triacylglycerols with 18:3 and 22:6 fatty acids and а high content of ceramide aminoethylphosphonate. A short-term exposure of coral fragments at 33 °C caused significant changes in lipids. Among the storage lipids, the content of triacylglycerols decreased after 12-h exposure. Among the structural lipids, contents of ethanolamine-, choline-, and inositolglycerophospholipids decreased; the most pronounced changes were observed in the composition of phosphatidylethanolamine and phosphatidylinositol after 24-h exposure.     

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.