Farnesol and geranylgeraniol modulate the structural properties of phosphatidylethanolamine model membranes

The biological activity of farnesol (FN) and geranylgeraniol (GG) and their isoprenyl groups is related to membrane-associated processes. We have studied the interactions of FN and GG with 1,2-dielaidoyl-sn-glycero-3-phosphoethanolamine (DEPE) membranes using DSC and X-ray diffraction. Storage of samples at low temperature for a long time favors a multidomain system formed by a lamellar crystalline (Lc) phase and isoprenoids (ISPs) aggregates. We demonstrate that ISPs alter the thermotropic behavior of DEPE, thereby promoting a H_II growth in a lamellar Lc phase with a reduced degree of hydration. The H_II phase occurs with the same repeat distance (d_HII=5.4 nm) as the Lc phase and upon heating it expands considerably (δd/δT≈0.22 nm/°C). The dimensional stabilization of this H_II phase coincides with the transition temperature of the Lc to L_α phase. Thereafter, the system DEPE/ISP will progress by increasing the nonlamellar-forming propensity and reaching a single H_II phase at high temperature. The cooling scan followed a similar structural path, except that the system went into a stable gel phase L_β with a repeat distance, d_Lβ=6.5 nm, in co-existence with a H_II phase. The formation of ISP microdomains in model PE membranes substantiates the importance of the isoprenyl group in the binding of isoprenylated proteins to membranes and in lipid–lipid interactions through modulation of the membrane structure.     

Structural and dynamical surface properties of phosphatidylethanolamine containing membranes

The hydration of solid dimyristoylphosphatidylethanolamine (DMPE) produces a negligible shift in the asymmetric stretching frequency of the phosphate groups in contrast to dimyristoylphosphatidylcholine (DMPC). This suggests that the hydration of DMPE is not a consequence of the disruption of the solid lattice of the phosphate groups as occurs in DMPC. The strong lateral interactions between NH₃ and PO₂⁻ groups present in the solid PEs remain when the lipids are fully hydrated and seem to be a limiting factor for the hydration of the phosphate group hindering the reorientation of the polar heads. The lower mobility is reflected in a higher energy to translocate the phosphoethanolamine (P-N) dipoles in an electrical field. This energy is decreased in the presence of increasing ratios of PCs of saturated chains in phosphoethanolamine monolayer. The association of PC and PE in the membrane affecting the reorientation of the P-N groups is dependent of the chain-chain interaction. The dipole potentials of PCs and PEs mixtures show different behaviors according to the saturation of the acyl chain. This was correlated with the area in monolayers and the hydration of the P-N groups. In spite of the low hydration, DMPE is still able to adsorb fully hydrated proteins, although in a lower rate than DMPC at the same surface pressure. This indicates that PE interfaces posses an excess of surface free energy to drive protein interaction. The relation of this free energy with the low water content is discussed.     

Effects of oleic acid and its congeners,elaidic and stearic acids,on the structural properties of phosphatidylethanolamine membranes

Fatty acid derivatives are abundant in biological membranes, mainly as components of phospholipids and cholesterol esters. Their presence, free or bound to phospholipids, modulates the lipid membrane behavior. The present study shows the differential influence of the C-18 fatty acids (FAs), oleic, elaidic, and stearic acids on the structural properties of phosphatidylethanolamine (PE). X-ray diffraction of PE-FA systems demonstrated that oleic acid (OA) produced important concentration-dependent alterations of the lipid membrane structure: it induced reductions of up to 20-23 degrees C in the lamellar-to-hexagonal transition temperature of 1-palmitoyl-2-oleoyl PE and dielaidoyl PE and regulated the dimensions of the hexagonal lattice. In contrast, elaidic and stearic acids did not markedly alter the phospholipid mesomorphism. The above effects were attributed to the different "molecular shape" of OA (with a kink at the middle of the molecule) with respect to their congeners, elaidic and stearic acids. The effects of free fatty acids (FFAs) on membrane structure are relevant for several reasons: i) some biological membranes contain very high levels of FFAs. ii) Mediterranean diets with high OA intake have been shown to exert protective effects against tumoral and hypertensive pathologies. iii) FFA derivatives have been developed as antitumoral and antihypertensive drugs.     

Acid- and calcium-induced structural changes in phosphatidylethanolamine membranes stabilized by cholesteryl hemisuccinate

The membrane stabilization effect of cholesteryl hemisuccinate (CHEMS) and the sensitivity of the CHEMS-phosphatidylethanolamine membranes to protons and calcium ions were studied by differential scanning calorimetry, freeze-fracture electron microscopy, and 31P NMR. (1) At neutral pH, the addition of 8 mol % CHEMS to transesterified egg phosphatidylethanolamine (TPE) raised the lamellar-hexagonal transition temperature of TPE by 11 degrees C. Stable bilayer vesicles were formed when the incorporated CHEMS exceeded 20 mol %. (2) At a pH below 5.5, the protonation of CHEMS enhanced the formation of the hexagonal phase (HII) of TPE. At 25 mol % CHEMS the bilayer-hexagonal transition temperature was lowered by 30 degrees C at pH 4.5. (3) The endothermic acid-induced hexagonal hexagonal transition of TPE-CHEMS was suppressed at 35 mol % CHEMS. However, 31P NMR and electron microscopy indicated that a lamellar-hexagonal transition still occurred at this composition. (4) The main transition of TPE was not affected by the protonation of the incorporated CHEMS, indicating that no macroscopic phase separation occurred in TPE-CHEMS mixtures at low pH. (5) In contrast to the HII-promoting effect of H+, the neutralization of the negative charge on TPE-CHEMS by Ca2+ resulted in aggregates that remained in the lamellar structure even at the hexagonal transition temperature of TPE. It is suggested that calcium might form a complex between CHEMS in apposed bilayers. These results are related to the possible biological function of acidic cholesterol esters in biomembranes.     

A product of ozonolysis of cholesterol alters the biophysical properties of phosphatidylethanolamine membranes

There is evidence that some products of the reaction of ozone with cholesterol contribute to atherosclerosis. One of these compounds is 3beta-hydroxy-5-oxo-5,6-secocholestan-6-al. We have synthesized this compound and have demonstrated that it reacts with phosphatidylethanolamine to form a Schiff base. The 3beta-hydroxy-5-oxo-5,6-secocholestan-6-al also affects the physical properties of phosphatidylethanolamines. We show by both DSC and X-ray diffraction that it increases the negative curvature of the membrane. In addition, 3beta-hydroxy-5-oxo-5,6-secocholestan-6-al causes the lamellar phase to become disorganized, resulting in the loss of lamellar periodicity. The chemical and physical interactions of 3beta-hydroxy-5-oxo-5,6-secocholestan-6-al with phosphatidylethanolamines may contribute to damaging effects of this lipid on cell membranes, resulting in pathology.     

The hypotensive drug 2-hydroxyoleic acid modifies the structural properties of model membranes

We studied the interactions of the hypotensive drug, 2-hydroxyoleic acid (2OHOA), with model membranes using the techniques of DSC, 31P NMR and X-ray diffraction. We demonstrate that 2OHOA alters the thermotropic behaviour of 1,2-dielaidoyl-sn-glycero-3-phosphoethanolamine (DEPE), thereby promoting the formation of hexagonal phases (H(II)), despite stabilizing the lamellar phase (Lalpha). The lattice parameters of lamellar and non-lamellar structures were not altered by the presence of 2OHOA. The molecular bases underlying the alterations in membrane structure provoked by 2OHOA were analysed by comparing the effects produced by 2OHOA with the closely related fatty acids (FAs), oleic acid (OA) and elaidic acid (EA). The capacity of C-18 FAs to induce H(II)-phase formation followed the order OA > 2OHOA > EA. Furthermore, while 2OHOA stabilized the Lalpha phase, OA destabilized it. The net negative charge of 2OHOA at physiological pH (approximately 7.4) influenced its effect on membrane structure. By analysing the molecular architecture of 2OHOA in DEPE monolayers, interactions between the carboxylate groups of 2OHOA and the amine groups of DEPE were observed, as well as between the 2-hydroxyl group of the FA and the carbonyl oxygen of the phospholipid acyl chain. These structural characteristics provoked an increase in the P-to-N and P-to-P distances of neighbouring phospholipid headgroups in the presence of 2OHOA, with respect to those observed with OA and EA. The higher headgroup area at the lipid-water interface in presence of 2OHOA could account for the differential effect of this drug on the phase behaviour of DEPE membranes.     

Rapid transbilayer movement of phosphatidylcholine in unsaturated phosphatidylethanolamine containing model membranes

Aqueous dispersions of egg phosphatidylethanolamine/18 : 1_c, 18 : 1_c-phosphatidylcholine/cholesterol/18 : 1_c, 18 : 1_c-phosphatidic acid (50 : 16 : 30 : 4) undergo a temperature-dependent transition from extended bilayers to structures characterized by isotropic ³¹P-NMR signals and visualized by freeze-fracturing as lipidic particles associated with the bilayer. This transition is accompanied by a 3-fold increase in the phosphatidylcholine pool which can be exchanged by phospholipid exchange protein demonstrating a direct relation between the occurrence of non-bilayer lipid structures and an increased transbilayer movement of phosphatidylcholine.     

The hypotensive drug 2-hydroxyoleic acid modifies the structural properties of model membranes

We studied the interactions of the hypotensive drug, 2-hydroxyoleic acid (2OHOA), with model membranes using the techniques of DSC, ³¹P NMR and X-ray diffraction. We demonstrate that 2OHOA alters the thermotropic behaviour of 1,2-dielaidoyl-sn-glycero-3-phosphoethanolamine (DEPE), thereby promoting the formation of hexagonal phases (H_II), despite stabilizing the lamellar phase (L_α). The lattice parameters of lamellar and non-lamellar structures were not altered by the presence of 2OHOA. The molecular bases underlying the alterations in membrane structure provoked by 2OHOA were analysed by comparing the effects produced by 2OHOA with the closely related fatty acids (FAs), oleic acid (OA) and elaidic acid (EA). The capacity of C-18 FAs to induce H_II-phase formation followed the order OA>2OHOA>EA. Furthermore, while 2OHOA stabilized the L_α phase, OA destabilized it. The net negative charge of 2OHOA at physiological pH (～7.4) influenced its effect on membrane structure. By analysing the molecular architecture of 2OHOA in DEPE monolayers, interactions between the carboxylate groups of 2OHOA and the amine groups of DEPE were observed, as well as between the 2-hydroxyl group of the FA and the carbonyl oxygen of the phospholipid acyl chain. These structural characteristics provoked an increase in the P-to-N and P-to-P distances of neighbouring phospholipid headgroups in the presence of 2OHOA, with respect to those observed with OA and EA. The higher headgroup area at the lipid–water interface in presence of 2OHOA could account for the differential effect of this drug on the phase behaviour of DEPE membranes.     

Effects of 2-hydroxyoleic acid on the structural properties of biological and model plasma membranes

Genetic hypertension is associated with alterations in lipid metabolism, membrane lipid composition and membrane-protein function. 2-Hydroxyoleic acid (2OHOA) is a new antihypertensive molecule that regulates the structure of model membranes and their interaction with certain peripheral signalling proteins in vitro. While the effect of 2OHOA on elevated blood pressure is thought to arise through its influence on signalling proteins, its effects on membrane lipid composition remain to be assessed. 2OHOA administration altered the lipid membrane composition of hypertensive and normotensive rat plasma membranes, and increased the fluidity of reconstituted liver membranes from hypertensive rats. In spontaneously hypertensive rats (SHR), treatment with 2OHOA increased the cholesterol and sphingomyelin content while decreasing that of phosphatidylserine-phosphatidylinositol lipids. In addition, monounsaturated fatty acid levels increased as well as the propensity of reconstituted membranes to form H_II-phases. These data suggest that 2OHOA regulates lipid metabolism that is altered in hypertensive animals, and that it affects the structural properties of liver plasma membranes in SHR. These changes in the structural properties of the plasma membrane may modulate the activity of signalling proteins that associate with the cell membrane such as the Gαq/11 protein and hence, signal transduction.     

Effects of 2-hydroxyoleic acid on the structural properties of biological and model plasma membranes

Genetic hypertension is associated with alterations in lipid metabolism, membrane lipid composition and membrane-protein function. 2-Hydroxyoleic acid (2OHOA) is a new antihypertensive molecule that regulates the structure of model membranes and their interaction with certain peripheral signalling proteins in vitro. While the effect of 2OHOA on elevated blood pressure is thought to arise through its influence on signalling proteins, its effects on membrane lipid composition remain to be assessed. 2OHOA administration altered the lipid membrane composition of hypertensive and normotensive rat plasma membranes, and increased the fluidity of reconstituted liver membranes from hypertensive rats. In spontaneously hypertensive rats (SHR), treatment with 2OHOA increased the cholesterol and sphingomyelin content while decreasing that of phosphatidylserine-phosphatidylinositol lipids. In addition, monounsaturated fatty acid levels increased as well as the propensity of reconstituted membranes to form HII-phases. These data suggest that 2OHOA regulates lipid metabolism that is altered in hypertensive animals, and that it affects the structural properties of liver plasma membranes in SHR. These changes in the structural properties of the plasma membrane may modulate the activity of signalling proteins that associate with the cell membrane such as the Galphaq/11 protein and hence, signal transduction.     

Importance of phosphatidylethanolamine for the interaction of apocytochrome c with model membranes containing phosphatidylserine

The effect of phosphatidylethanolamine (PE) on the binding of apocytochrome c to model membranes was examined. When 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) of the standard vesicles composed of 80% of this lipid and 20% of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoserine (POPS) was gradually replaced with upward of 50% of 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine (POPE), the binding increased appreciably. Ca(2+), causing the phase separation of PS, also brought about increased binding of apocytochrome c in the PC/PS system, underlining the importance of PS properties in membranes for the protein binding. The resonance energy transfer between Trp-59 in apocytochrome c and pyrene-PS incorporated into bilayers showed that the replacement of PC with PE increased the extent of apocytochrome c penetration into membranes by a PE concentration-dependent manner. However, in the absence of PS, PE had no apparent effect on these functions of apocytochrome c, suggesting that PE-induced change(s) of acidic membrane properties is important to the association of apocytochrome c with vesicles. From the observations that the excimer to monomer fluorescence ratio of pyrene-PS increased and the fluorescence of NBD-PS was quenched with increasing concentration of PE, it was deduced that PE caused PS-enriched domains in PC/PE/PS membranes. The colocalization of pyrene-PS with BODIPY-PS by PE further supported the possibility. We suggest that PE-induced formation of PS-enriched domains acts as binding sites for apocytochrome c in membranes.     

Ubiquitination of phosphatidylethanolamine in organellar membranes

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Hemagglutinin fusion peptide mutants in model membranes: structural properties, membrane physical properties, and PEG-mediated fusion

While the importance of viral fusion peptides (e.g., hemagglutinin (HA) and gp41) in virus-cell membrane fusion is established, it is unclear how these peptides enhance membrane fusion, especially at low peptide/lipid ratios for which the peptides are not lytic. We assayed wild-type HA fusion peptide and two mutants, G1E and G13L, for their effects on the bilayer structure of 1,2-dioleoyl-3-sn-phosphatidylcholine/1,2-dioleoyl-3-sn-phosphatidylethanolamine/Sphingomyelin/Cholesterol (35:30:15:20) membranes, their structures in the lipid bilayer, and their effects on membrane fusion. All peptides bound to highly curved vesicles, but fusion was triggered only in the presence of poly(ethylene glycol). At low (1:200) peptide/lipid ratios, wild-type peptide enhanced remarkably the extent of content mixing and leakage along with the rate constants for these processes, and significantly enhanced the bilayer interior packing and filled the membrane free volume. The mutants caused no change in contents mixing or interior packing. Circular dichroism, polarized-attenuated total-internal-reflection Fourier-transform infrared spectroscopy measurements, and membrane perturbation measurements all conform to the inverted-V model for the structure of wild-type HA peptide. Similar measurements suggest that the G13L mutant adopts a less helical conformation in which the N-terminus moves closer to the bilayer interface, thus disrupting the V-structure. The G1E peptide barely perturbs the bilayer and may locate slightly above the interface. Fusion measurements suggest that the wild-type peptide promotes conversion of the stalk to an expanded trans-membrane contact intermediate through its ability to occupy hydrophobic space in a trans-membrane contact structure. While wild-type peptide increases the rate of initial intermediate and final pore formation, our results do not speak to the mechanisms for these effects, but they do leave open the possibility that it stabilizes the transition states for these events.     

Distribution of phosphatidylethanolamine arachidonic acid in platelet membranes

Arachidonic acid (20:4) and other fatty acids and aldehydes in phosphatidylethanolamine (PE) present on the platelet surface was determined. Surface-exposed PE was isolated by using 2,4,6-trinitrobenzenesulfonate, a nonpenetrating probe (Schick, P.K., Kurica, K.B. and Chacko, G.K. (1976) J. Clin. Invest. 57, 1221–1226). PE contains 50% total platelet arachidonic acid. Approx. 16% platelet PE is present on the platelet surface. The study showed that the fatty acid and aldehyde composition of PE on the platelet surface is virtually identical to that in PE present inside the platelet. Therefore, 8 nmol arachidonic acid are present in PE in the outer layer of the plasma membrane in 10⁹ platelets.     

Solvation properties of raft-like model membranes

Dimethyl sulfoxide (DMSO) is a universal water-soluble solvent widely used in many biotechnological and medical applications, such as cells cryopreservation, and for the treatment of different human diseases (e.g. amyloidosis). Despite the great number of reported studies, the effects of DMSO on the physico-chemical properties of biological membranes are poorly understood. Often, these studies are limited to model membranes composed of phosphatidylcholines (PCs) and cholesterol (Chol). In this work, we explored the effect of DMSO on liposomes composed of the natural egg sphingomyelin (ESM) and Chol as raft-like model membranes.With a multi-technique approach we probe the structure and the thermal stability of ESM/Chol bilayer at different Chol mole fractions. In particular, we investigate the ESM-solvent interactions to clarify the role of DMSO in perturbing the solvating conditions of lipid vesicles and show that the addition of DMSO increases the thermal stability of vesicles. An increase of transition temperature, a decrease of both enthalpy and entropy as well as a decrease of the cooperativity of the gel to liquid phase transition are observed at 0.1 DMSO mole fraction. Fluorescence experiments with the probe Laurdan and FTIR spectra strongly indicate that DMSO exerts a dehydration effect on the membrane. Besides, FTIR measurements with tungsten hexacarbonyl, in combination with fluorescence data of the probe NBD-PE, indicate that DMSO promotes the formation of a highly packed membrane by reducing the thickness of the membrane.     

Correlation between acetylcholine receptor function and structural properties of membranes

Protein-lipid interactions were studied by using Torpedo californica acetylcholine receptor (AChR) as a model system by reconstituting purified AChR into membranes containing various synthetic lipids and native lipids. AChR function was determined by measuring two activities at 4 degrees C: (1) low to high agonist affinity-state transition of AChR in the presence of an agonist (carbamylcholine) in either membrane fragments or sealed vesicles and (2) ion-gating activity of AChR-containing vesicles in response to carbamylcholine. Sixteen samples were examined, each containing different lipid compositions including phosphatidylcholine, cholesterol, phosphatidic acid, phosphatidylethanolamine, asolectin, neutral lipid depleted asolectin, native lipids, and cholesterol-depleted native lipids. Phosphatidylcholines with different configurations of fatty acyl chains were used. The dynamic structures of these membranes were probed by incorporating spin-labeled fatty acid into AChR-containing vesicles and measuring the order parameters. It was found that both aspects of AChR function were highly dependent on the lipid environment even though carbamylcholine binding itself was not affected. An appropriate membrane fluidity was necessarily required to allow the interconversion between the low and high affinity states of AChR. An optimal fluidity hypothesis is proposed to account for the conformational transition properties of membrane proteins. In addition, the conformational change was only a necessary, but not sufficient, condition for the AChR-mediated ion flux activity. Among membranes in which AChR manifested the affinity-state transition, only those containing both cholesterol and negatively charged phospholipids (such as phosphatidic acid) retained the ion-gating activity.     

Fusion of Sindbis virus with model membranes containing phosphatidylethanolamine: implications for protein-induced membrane fusion

The pH-induced fusion of Sindbis virus with model lipid membranes containing phosphatidylethanolamine has been studied using a quantitative fluorescence technique. The headgroup and acyl chain domains of the lipids have been altered systematically to determine their effect on fusion. Unsaturated phosphatidylethanolamines (PE) have been found to promote fusion, either by themselves, or in combination with phosphatidylcholines (PC). Cholesterol added to a mixture of unsaturated PE and PC was also shown to increase the extent of viral fusion. The results of these studies have been interpreted in terms of a tentative model for the molecular aspects of the target membrane which are necessary for viral fusion. In this model, the target membrane must have a sufficiently-sized domain containing poorly hydrated lipids which are capable of existing in a non-bilayer arrangement.     

The effects of 7-dehydrocholesterol on the structural properties of membranes

Smith-Lemli-Opitz syndrome, a congenital and developmental malformation disease, is typified by abnormal accumulation of 7-dehydrocholesterol (7DHC), the immediate precursor of cholesterol (CHOL), and depletion thereof. Knowledge of the effect of 7DHC on the biological membrane is, however, still fragmentary. In this study, large-scale atomistic molecular dynamics simulations, employing two distinct force fields, have been conducted to elucidate differences in the structural properties of a hydrated dimyristoylphosphatidylcholine bilayer due to CHOL and 7DHC. The present series of results indicate that CHOL and 7DHC possess virtually the same ability to condense and order membranes. Furthermore, the condensing and ordering effects are shown to be strengthened at increasing sterol concentrations.