Lateral mobility of phospholipid molecules in thin liquid films

The Fluorescence Recovery After Photobleaching (FRAP) method was applied to measure the lateral mobility of the fluorescent lipid analog, dioctadecylindocarbocyanine perchlorate (Dil-C18), in microscopic thin liquid films (Foam Films (FFs)). The foam film structures were comprised of two phosphatidylcholine monolayers adsorbed at air/water interfaces which sandwiched a thin liquid core. Lateral diffusion of the DiI molecules in the plane of the monolayers was determined as a function of the thickness of the thin liquid core of the film between the FF monolayers. The results obtained indicated that the diffusion coefficient was strongly dependent both on the distance between the FF monolayers in the range 4 nm to 85 nm (corresponding to the FF thickness) and on the film type. The applicability of the FRAP method for studying the molecular mobility in phospholipid FFs was demonstrated. Considerable differences in the surface diffusion coefficient of Dil were observed, ranging between 2 × 10^–8 cm²/s and 22 × 10^–8 cm²/s in so called yellow, gray, common black and Newton black FFs. The effect of the presence of polyethylene glycol (PEG-400) in the liquid core of lecithin FFs on surface diffusion was also studied. The surface diffusion results from the FF studies were compared with data from black lipid membranes (BLMs). These structures are related in thickness terms but the molecular orientation in FFs is the reverse of that in BLMs. Correspondence to: Z. Lalchev     

The interaction of meso-tetraphenylporphyrin with phospholipid monolayers

In this article, we investigate the interaction of meso-tetraphenylporphyrin (TPP) with phospholipid monolayers. Pure TPP molecules form films at the air-water interface with large extension of aggregation, which is confirmed by UV-vis spectra of transferred monolayers. For mixed films of TPP with dipalmitoyl phosphatidyl choline (DPPC) or dipalmitoyl phosphatidyl glycerol (DPPG), on the other hand, aggregation is only significant at high surface pressures or high concentrations of TPP (above 0.1 molar ratio). This was observed via Brewster angle microscopy (BAM) for the Langmuir films and UV-vis spectroscopy for transferred layers onto solid substrates. TPP indeed causes the DPPC and DPPG monolayers to expand, especially at the liquid-expanded to liquid-condensed phase transition for DPPC. The effects from TPP cannot be explained using purely geometrical considerations, as the area per TPP molecule obtained from the isotherms is at least twice the expected value from the literature. Therefore, interaction between TPP and DPPC or DPPG should be cooperative, so that more phospholipid molecules are affected than just the first neighbors to a TPP molecule.     

Miscibility of DPPC and DPPA in monolayers at the air/water interface

Monolayers of mixtures of 1,2-dipalmitoylphosphatidylcholine (DPPC) as the substrate and 1,2-dipalmitoylphosphatidic acid (DPPA) as the product of the hydrolysis reaction catalyzed by phospholipase D (PLD) were investigated in the presence of Ca2+. The miscibility behavior and the microstructure of mixed domains have been studied by grazing incidence X-ray diffraction (GIXD), Brewster angle microscopy and film balance measurements. The phase diagram reveals partial miscibility on both sides and a wide miscibility gap, which becomes narrower at high pressure. At low pressure, the segregation of condensed DPPA-rich domains in a fluid-like DPPC matrix was detected already at small DPPA concentrations and their structure was determined. A small amount of DPPC mixed into the segregated DPPA domains induces the transformation from rectangular to an oblique unit cell and increases the tilt angle in the condensed domains. At high pressure, two types of condensed phase domains were found: DPPC-rich and DPPA-rich. A drastic reduction of the tilt angle in the DPPC-rich domains with increasing amount of DPPA was observed. The decrease of the tilt angle must be connected with a change of the head group conformation of DPPC in such mixed domains.     

Model study of interactions of high-molecular dextran sulfate with lipid monolayers and foam films

The interaction of high-molecular dextran sulfate (DS-5000) with dimyristoylphosphatidylcholine (DMPC) monolayers and foam films (FF) at the air–water interface in the presence of Ca²⁺ and Na⁺ ions was studied. DS-5000 was added in monolayer films (MF) and in FF as monomer molecules and in liposomal form. When added in liposomal form in FF, DS-5000 decreased the stability of DMPC common black films (CBF), and no formation of Newton black films (NBF) was observed. However, when included as monomer molecules in FF, DS-5000 caused film thinning, and drastically decreased the expansion rate of the black spots and transition of thick films to NBF, thus avoiding formation of CBF. The above effects were observed in both gel and liquid-crystalline phase states of DMPC in the presence of Ca²⁺ ions only, and not in the presence of Na⁺ ions. We postulate that the interaction of DMPC with DS-5000 in the plane of FF is mediated by Ca²⁺ bridges and results in dehydration of the DMPC polar heads. The interaction between DMPC and DS-5000 in monolayers resulted in slower adsorption and spreading of DMPC molecules at the interface, lower monolayer surface pressure, and penetration of DS-5000 molecules to DMPC monolayers when surface lipid density was higher than 50 Ų per DMPC molecule. The applicability of the FF model for studying the interactions of phospholipids with polysaccharides at interfaces surrounded by bulk solution, and for modeling such interactions in biological systems, e.g. LDL adhesion to the arterial walls, aggregation and fusion of liposomes, etc., is discussed.     

Phase diagram of mixed monolayers of stearic acid and dimyristoylphosphatidylcholine. Effect of the acid ionization

The aim of this work is to study the phase diagram of mixed monolayers composed of dimyristoylphosphatidylcholine (DMPC) and stearic acid (SA) at different ionic strength and bulk pH of the aqueous subphase. In this way, the effect of ionization of SA on the interaction and thus on phase separation with the DMPC matrix can be analyzed. To this purpose, we first determined the ionization state of pure SA monolayers as a function of the bulk subphase pH. The SA monolayers are nearly fully ionized at pH 10 and essentially neutral at pH 4 and the mixture of DMPC and SA was studied at those two pHs. We found that the DMPC-enriched phase admits more SA if the SA monolayer is in a liquid-expanded state, which is highly related to the acid ionization state, and thus to the bulk pH and ionic strength. At pH 4 the molecules hardly mix while at pH 10 the mixed monolayer with DMPC can admit between 30 and 100% of SA (depending on the lateral pressure) before phase separation is established. The addition of calcium ions to the subphase has a condensing effect on SA monolayers at all pHs and the solubility of SA in the DMPC matrix does not depend on the bulk pH in these conditions. The observed phase diagrams are independent on the manner in which the state of the mixed film is reached and may thus be considered states of apparent equilibrium.     

Effects of the propeptide of group X secreted phospholipase A2 on substrate specificity and interfacial activity on phospholipid monolayers

Group X secreted phospholipase A₂ (GX sPLA₂) plays important physiological roles in the gastrointestinal tract, in immune and sperm cells and is involved in several types of inflammatory diseases. It is secreted either as a mature enzyme or as a mixture of proenzyme (with a basic 11 amino acid propeptide) and mature enzyme. The role of the propeptide in the repression of sPLA₂ activity has been studied extensively using liposomes and micelles as model interfaces. These substrates are however not always suitable for detecting some fine tuning of lipolytic enzymes. In the present study, the monolayer technique is used to compare PLA₂ activity of recombinant mouse GX sPLA₂ (mGX) and its pro-form (PromGX) on monomolecular films of dilauroyl-phosphatidyl-ethanolamine (DLPE), -choline (DLPC) and -glycerol (DLPG). The PLA₂ activity and substrate specificity of mGX (PE ≈ PG > PC) were found to be surface pressure-dependent. mGX displayed a high activity on DLPE and DLPG but not on DLPC monolayers up to surface pressures corresponding to the lateral pressure of biological membranes (30–35 mN/m). Overall, the propeptide impaired the enzyme activity, particularly on DLPE whatever the surface pressure. However some conditions could be found where the propeptide had little effects on the repression of PLA₂ activity. In particular, both PromGX and mGX had similar activities on DLPG at a surface pressure of 30 mN/m. These findings show that PromGX can be potentially active depending on the presentation of the substrate (i.e., lipid packing) and one cannot exclude such an activity in a physiological context. A structural model of PromGX was built to investigate how the propeptide controls the activity of GX sPLA₂. This model shows that the propeptide is located within the interfacial binding site (i-face) and could disrupt both the interfacial binding of the enzyme and the access to the active site by steric hindrance.     

Ganglioside GD3 and GD3-lactone mediated regulation of the intermolecular organization in mixed monolayers with dipalmitoylphosphatidylcholine

The interactions of dpPC with ganglioside GD3 and two lactones, GD3LacI or GD3LacII, in lipid monolayers occur with reduced, unaltered, or increased molecular area and surface potential/molecule, respectively. dpPC is fully miscible with GD3 and GD3LacI but films with GD3LacII show immiscibility above 75 mol% lactone. At low proportions of GD3 in mixtures with dpPC, GD3 undergoes condensation and depolarization; dpPC is depolarized and its molecular area is reduced above 50 mol% GD3. GD3LacI forms ideally mixed films with dpPC. Mixtures of dpPC with GD3LacII at mole fractions below 0.3 show increased mean molecular area and surface potential/molecule mostly due to lactone alterations. Between mole fractions of 0.3 and 0.75 the surface parameters of dpPC are altered, and above these proportions both lipids are immiscible. Defined variations of molecular properties induced by ganglioside lactonization are selectively transduced to changes of the intermolecular organization and surface electrostatics in mixed interfaces with dpPC. Thus, changes in the relative proportions of a ganglioside and its lactone forms may act as sensitive biotransducers for membrane-mediated cellular functions, without the need for metabolically altering the concentration of gangliosides.     

Location and orientation of Triclosan in phospholipid model membranes

Triclosan is a hydrophobic antibacterial agent used in dermatological preparations and oral hygiene products. Although the molecular mechanism of action of this molecule has been attributed to inhibition of fatty acid biosynthesis, earlier work in our laboratories strongly suggested that the antibacterial action of Triclosan is mediated at least partly through its membranotropic effects. In order to assess its location in phospholipid membranes, high-resolution magic-angle spinning natural abundance ¹³C NMR of Triclosan embedded within egg yolk lecithin model membranes has been used to obtain ¹³C spin–lattice relaxation times for both Triclosan and lecithin carbon atoms in the presence of Gd³⁺ ions. The results indicate that Triclosan is localized in the upper region of the phospholipid membrane, its hydroxyl group residing in the vicinity of the C=O/C2 carbon atoms of the acyl chain of the phospholipid, and the rest of the Triclosan molecule is probably aligned in a nearly perpendicular orientation with respect to the phospholipid molecule. Intercalation of Triclosan into bacterial cell membranes likely compromises the functional integrity of those membranes, thereby accounting for at least some of this compounds antibacterial effects.Abbreviations COLOC correlation by long-range coupling - EYL egg yolk lecithin - HETCOR heteronuclear chemical-shift correlation - MAS magic-angle spinning - MLV multilamellar vesicles     

Comparison of the interaction of tomatine with mixed monolayers containing phospholipid, egg sphingomyelin, and sterols

The interaction of the glycoalkaloid tomatine with monolayers of a phospholipid (dimyristoylphosphatidylcholine, DMPC), and sphingolipid (egg sphingomyelin), and cholesterol is compared. Using measurements of the surface pressure response as a function of the subphase concentration of tomatine, interfacial binding constants are estimated for mixed monolayers of DMPC and cholesterol and for those of egg sphingomyelin and cholesterol of mole ratio 7:3. The binding constants obtained suggest a stronger interaction of tomatine with DMPC and cholesterol mixed monolayers, reflecting easier displacement of cholesterol from its interaction with DMPC than from its interaction with egg sphingomyelin. Mixtures of tomatine and cholesterol are found to spread directly at the water-air interface and form stable monolayers, suggesting that cholesterol holds tomatine at the interface despite the absence of observed monolayer behavior for tomatine alone. The interaction of tomatine with DMPC and cholesterol monolayers is found to exhibit a pH dependence in agreement with previously reported results for its interaction with liposomes; in particular, the interaction is much less at pH 5 than at pH 7 or pH 9. It is found that while tomatine interacts strongly with monolayers containing sitosterol, it does not interact with monolayers containing sitosterol glucoside. The response of monolayers of varying composition of DMPC and cholesterol to tomatine is also examined. Brewster angle microscopy (BAM) reveals further evidence for formation of suspected islands of tomatine + cholesterol complexes upon interaction with mixed monolayers of lipid and sterol.     

Interaction of amphiphilic chlorin-based photosensitizers with 1,2-dipalmitoyl-sn-glycero-3-phosphocholine monolayers

The drawbacks of the presently used photosensitizers include their relatively low selectivity toward cancer cells, and long-lasting accumulation in healthy tissues. Our recent results indicate that conjugating a photosensitizer with folic acid both enhances the active uptake by cells, and decreases the accumulation in healthy tissue. Here, the interaction between 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) monolayers used as model membranes, and three different photosensitizers were studied; the derivatives were the non-conjugated meta-tetrahydroxyphenylchlorin (m-THPC, CHL1) and tris(3-hydroxyphenyl)-4-carboxyphenylchlorin (CHL2), as well as a folic acid-conjugated m-THPC-like molecule (CHL3). The results obtained indicate that the folate moiety present in the conjugated derivative CHL3 is involved in the interaction with the phospholipid polar heads. This interaction may be responsible for a better miscibility of CHL3 with the DPPC films compared to CHL1 and CHL2, while elimination of CHL3 from the tissue may be due rather to specific, biological processes and not to its polarity.     

Surface activity and interaction of StarD7 with phospholipid monolayers

StarD7 protein forms stable Gibbs and Langmuir monolayers at the air-buffer interface showing marked surface activity. The latter is enhanced by penetration into phospholipid films at an initial surface pressure above the protein’s own equilibrium adsorption surface pressure to a lipid-free interface. The protein-phospholipid stabilizing interactions at the interface depend on the lipid, with preference for phosphatidylserine, cholesterol, and phosphatidylglycerol, and the increases of lateral surface pressure generated are comparable to those of other membrane-active proteins. The surface activity of StarD7 is strong enough to thermodynamically drive and retain StarD7 at the lipid membrane interface where it may undergo lipid-dependent reorganization as indicated by changes of surface pressure and electrostatics.     

Direct measurement of interaction forces in free thin liquid films stabilized with phosphatidylcholine

Microscopic foam films from suspensions of small unilamellar dimyristoylphosphatidylcholine (DMPC) vesicles have been obtained. The film formation is facilitated at temperatures above the gel-liquid crystalline transition of DMPC. A detailed study of the dependence of equilibrium thickness of DMPC foam films on electrolyte concentration at constant capillary pressure and a direct measurement of the disjoining pressure isotherm has been carried out. Formation of thick equilibrium horizontal microscopic films stabilized with DMPC at low external pressures and low electrolyte concentrations was found and interpreted as being due to the existence of long-range electrostatic interactions in these films. A diffuse electric layer potential of 36 mV has been calculated. The DMPC films have been compared to films obtained from non-ionic surfactant solutions where the long range electrostatic repulsion is explained as being due to specific adsorption of OH^– at the film interfaces. However, unlike the results obtained for surfactant films, in this study formation of common black films and thinning of the DMPC Newton film with pressure have been observed. Offprint requests to: D. Exerowa     

Phase coexistence in films composed of DLPC and DPPC: A comparison between different model membrane systems

For the biophysical study of membranes, a variety of model systems have been used to measure the different parameters and to extract general principles concerning processes that may occur in cellular membranes. However, there are very few reports in which the results obtained with the different models have been compared. In this investigation, we quantitatively compared the phase coexistence in Langmuir monolayers, freestanding bilayers and supported films composed of a lipid mixture of DLPC and DPPC. Two-phase segregation was observed in most of the systems for a wide range of lipid proportions using fluorescence microscopy. The lipid composition of the coexisting phases was determined and the distribution coefficient of the fluorescent probe in each phase was quantified, in order to explore their thermodynamic properties. The comparison between systems was carried out at 30 mN/m, since it is accepted that at this or higher lateral pressures, the mean molecular area in bilayers is equivalent to that observed in monolayers. Our study showed that while Langmuir monolayers and giant unilamellar vesicles had a similar phase behavior, supported films showed a different composition of the phases with the distribution coefficient of the fluorescent probe being close to unity. Our results suggest that, in supported membranes, the presence of the rigid substrate may have led to a stiffening of the liquid-expanded phase due to a loss in the degrees of freedom of the lipids as a consequence of the proximity of the solid material.     

Influence of mixed electrolytes on the adsorption of lysozyme,PEG, and PEGylated lysozyme on a hydrophobic interaction chromatography resin

In a recent work (Werner A and Hasse H in J Chromatogr A 2013;1315:135) the influence of mixed electrolytes on the adsorption of the macromolecules lysozyme, PEG and di‐PEGylated lysozyme on a hydrophobic resin has been studied, but only at one overall ionic strength (3000 mM). The present work, therefore, extends these studies to other ionic strengths (2400 and 2700 mM), and explores the application of a model to predict the entire data set. The adsorbent is Toyopearl PPG‐600M. The solvent is a 25 mM aqueous sodium phosphate buffer at pH 7.0. The studied salts are sodium chloride, sodium sulfate, ammonium chloride and ammonium sulfate. Pure salts as well as binary and ternary mixtures of these salts with varying ratios of the amounts of the salts are studied at 25 °C. The loading of the adsorbent increases with increasing salt concentration for all macromolecules. Synergetic effects of the mixed electrolytes are observed. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 33:1104–1115, 2017     

Interactions of hemin, antimalarial drugs and hemin-antimalarial complexes with phospholipid monolayers

Hemin, antimalarial drugs and complexes formed between them, have demonstrable effects on biological membranes. Using the phospholipid monolayer model, we show that hemin intercalates into the membrane and increases its surface pressure, depending on the lipid composition and the initial surface pressure: negative surface charges and particularly looser compaction of the phospholipids reduce the effect of hemin. With increasing surface pressure hemin tends to intercalate as a monomer, and the half-saturation concentration of its effect increases exponentially. The antimalarial monovalent drugs quinine and mefloquine, but not chloroquine, also penetrate into the membrane and expand it. All three drugs markedly increase the effect of hemin, but chloroquine reduces the effect in monolayers composed of unsaturated phospholipids. The drugs' effect is mostly due to an increase in the maximal surface pressure and suggests a complexation of hemin and drug within the membrane phase. Preformed hemin-drug complexes decrease the half-saturation concentration of the effect and suggest that the complexes adsorb to the membrane, releasing the hemin through an apolar continuum into the phospholipid phase. The implications of the results to the membrane toxicity mechanism proposed for the molecular mode of action of antimalarial drugs are discussed.     

Interaction of natural polyamines and dimethylsilyl analogues with a phospholipid monolayer: a study by Brewster angle microscopy and PM-IRRAS

This work presents an analysis of the physicochemical interactions of natural and dimethylsilyl polyamines with an anionic deuterated phospholipid monolayer, d(62)DPPG (dipalmitoyl phosphatidyl glycerol), at the air-water interface. It was motivated by previous studies, which suggested an antitumour strategy based on the accumulation of derivatives such as bis(7-amino-4-azaheptyl) dimethylsilyl (azhepSi), in order to diminish the concentration of natural polyamines (spermine and putrescine) whose metabolism is strongly activated in tumour cells. Our results, obtained by the surface-pressure technique, Brewster angle microscopy (BAM) and polarization modulation infrared reflection absorption spectroscopy (PM-IRRAS), support the idea of an interaction between the polar head groups of d(62)DPPG and amino groups followed by an adsorption of polyamines up to the carbonyl group. Moreover, an insertion of the dimethylsilyl group up to the alkyl chains occurs with azhepSi, in agreement with the observation that the cohesion of the alkyl chain is lower in this case, as compared with the effect of natural polyamines.     

The structure and phase behaviour of alpha-tocopherol-rich domains in 1-palmitoyl-2-oleoyl-phosphatidylethanolamine

The effect of alpha-tocopherol on the structure and thermotropic phase behaviour of 1-palmitoyl-2-oleoyl-phosphatidylethanolamine dispersed in excess water was examined by synchrotron X-ray diffraction and differential scanning calorimetry. Small- and wide-angle X-ray scattering intensity profiles were recorded from mixed dispersions containing up to 20 mol% alpha-tocopherol during temperature scans over the range 10-75 degrees C. These showed that a domain enriched in alpha-tocopherol phase separated from pure phospholipid in the mixture. This domain tends to have inverted hexagonal structure which coexists with phospholipid bilayers depleted of alpha-tocopherol. The scattering intensity and dimensions of the phase are dependent on the temperature and proportion of alpha-tocopherol in the mixture. Phase separations were also manifest in calorimetric scans of the mixed dispersions evidenced from the appearance of multiple peaks at temperatures corresponding to transitions observed in the X-ray scattering experiments. The effect of alpha-tocopherol in the range 0-20 mol% on the phase behaviour and structure of the phospholipid as observed from the X-ray scattering and calorimetric results have been used to construct a partial phase diagram of the mixture in the temperature range 10-75 degrees C. This shows that alpha-tocopherol has a marked tendency to partition from bilayers of the phospholipid to form an enriched domain in which the phospholipid assumes a hexagonal-II structure.     

Interaction of gentamicin with phosphatidylserine/phosphatidylcholine mixtures in adsorption monolayers and thin liquid films: morphology and thermodynamic properties

Gentamicin possesses strong adverse actions like oto and nephrotoxicity. The latter is a result of strong gentamicin–acid phospholipid interactions, resulting in cell fusion, fission, etc., ions as calcium interact with gentamicin and effectively deter its toxicity. In this work, the interactions of gentamicin and Ca²⁺ with phosphatidylserine/phosphatidylcholine (PS/PC) mixtures of different ratio are experimentally characterized. Special attention is paid to bridge thermodynamic and morphological properties of adsorption monolayers and thin liquid films (TLFs) composed of these lipid mixtures. Our results show that gentamicin decreases the stability of common black TLFs formed of pure PS coupled with suppression of lipid surface adsorption to the monolayers at the air–water interface; also, gentamicin reveals effects of lowering of lipid spreading on the interface and significant loss of material during monolayer cycling, increase of condensed phase, and organization of dense net-like domain monolayer texture. Gentamicin addition results in opposite effects for films formed of DPPC/PS (95:5) mixture. It increases the stability of Newton black TLFs formed by DPPC/PS correlated with faster and stronger surface adsorption and better surface spreading; also, gentamicin lowers the amount of condensed phase and organization of domains of smaller size. We also showed that Ca²⁺ itself decreases the stability of common black TLFs formed of PS accompanied with weaker surface adsorption, formation of higher amounts of condensed phase and organization of domains. In our experiments, Ca²⁺ softens, even deters, the effects of gentamicin on both PS and DPPC/PS films.     

Interactions of inorganic mercury with phospholipid micelles and model membranes. A31P-NMR study

The binding of inorganic mercury Hg(II) to phospholipid headgroups has been investigated by phosphorus-31 nuclear magnetic resonance of phosphatidylethanolamine (PE), phosphatidylserine (PS) and phosphatidylcholine (PC) in water micellar and multilamellar phases. HgCl₂ triggers the aggregation of phospholipid micelles, leading to a lipid-mercury precipitate that is no longer detectable by high-resolution³¹P-NMR. The remaining signal area corresponds to micelles in the soluble fraction and is a non-linear function of the initial mercury-to-lipid molar ratio. Kinetics of micelle aggregation are exponential for the first 15 min and show a plateau tendency after 120 min. Apparent Hg(H) affinities for phospholipid headgroups are in the order: PE > PS > PC. The same binding specificity is observed when HgCl₂ is added to (1:1) mixtures of different micelles (PE + PC; PS + PC). However, mercury binding to mixed micelles prepared with two lipids (PE/PC or PS/PC) induces the aggregation of both lipids. Hg(II) also leads to a³¹P-NMR chemical shift anisotropy decrease of PC, PS and mixed (1:1) PE/PC multilamellar vesicles and markedly broadens PS spectra. This indicates that HgCl₂ binding forces phospholipid headgroups to reorient and that the concomitant network formation leads to a slowing down of PS membrane collective motions. Formation of a gel-like lamellar phase characterized by a broad NMR linewidth is also observed upon HgCl₂ binding to PE samples both in fluid (L) or hexagonal (H_II) phases. The PE hexagonal phase is no longer detected in the presence of HgCl₂. Mixed PE/PC dispersions remain in the fluid phase upon mercury addition, indicating that no phase separation occurs. Addition of excess NaCl leads to the appearance of the non-reactive species HgCl _inf4 ^sup2– and induces the reversal of all the above effects.Abbreviations A(t) time-dependence of peak area - A₄₀ peak area at t=40 min - 1/ rate of peak area decrease - isotropic chemical shift - isotropic chemical shift change - chemical shift anisotropy - DPPC dipalmitoylphosphatidylcholine - Hg(II) inorganic mercury - NMR nuclear magnetic resonance - pCl –log [Cl^–] - PC phosphatidylcholine - PE phosphatidylethanolamine - PL phospholipid - PS phosphatidylserine - R_i mercury-to-lipid molar ratio - MLV multilamellar vesicles - SUV small unilamellar vesicles     

Effects of preconditioning on electrolyte leakasge and lipid composition in black spruce (Picea mariand) stressed with polyethylene giycol

Black spruce ( Picea mariana Mill. B. S. P.) rooted cuttings were grown in solution culture and preconditioned by osmotically stressing plants with polyethylene glycol. After relief from preconditioning stress, water relations, membrane leakiness, and the composition of lipids and fatty acids were compared in preconditioned and control, unconditioned plants. Both groups of plants were subsequently subjected to a severe osmotic stress with polyethylene glycol and examined again. Osmotic stress decreased shoot water potentials and increased the leakage of electrolytes from shoots of stressed, compared with unstressed, plants. However, both unstressed and stressed preconditioned plants leaked less electrolytes compared with unconditioned plants. Changes in sterol, phospholipid and glycolipid composition were observed in preconditioned unstressed and stressed plants. Sterol and phospholipid levels de clined as a result of stress, and preconditioning resulted in a decline in sterol: phospholipid ratios in plants.