Lipid miscibility and size increase of vesicles composed of two phosphatidylcholines

Lateral heterogeneity and domain formation in cellular membranes

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Review article describing recent experimental and theoretical membrane lateral heterogeneity research.

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Describes the static and dynamic physical concepts behind domain formation in model membranes.

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Describes coarse-grained, phenomenological approaches that result in phases associated with lipid lateral heterogeneity.

As early as the development of the fluid mosaic model for cellular membranes, researchers began observing the telltale signs of lateral heterogeneity. Over the decades this has led to the development of the lipid raft hypothesis and the ensuing controversy that has unfolded, as a result. Here, we review the physical concepts behind domain formation in lipid membranes, both of their structural and dynamic origins. This, then leads into a discussion of coarse-grained, phenomenological approaches that describe the wide range of phases associated with lipid lateral heterogeneity. We use these physical concepts to describe the interaction between raft-lipid species, such as long-chain saturated lipids, sphingomyelin, and cholesterol, and non-raft forming lipids, such as those with short acyl chains or unsaturated fatty acids. While debate has persisted on the biological relevance of lipid domains, recent research, described here, continues to identify biological roles for rafts and new experimental approaches have revealed the existence of lipid domains in living systems. Given the recent progress on both the biological and structural aspects of raft formation, the research area of membrane lateral heterogeneity will not only expand, but will continue to produce exciting results.

Reconstruction of integrin activation

Integrins are integral membrane proteins that mediate cell-matrix and cell-cell adhesion. They are important for vascular development and hematopoiesis, immune and inflammatory responses, and hemostasis. Integrins are also signaling receptors that can transmit information bidirectionally across plasma membranes. Research in the past 2 decades has made progress in unraveling the mechanisms of integrin signaling and brings the field to the moment of attempting synthetic reconstruction of the signaling pathways in vitro. Reconstruction of biologic processes provides stringent tests of our understanding of the process, as evidenced by studies of other biologic machines, such as ATP synthase, lactose permease, and G-protein-coupled receptors. Here, we review recent progress in reconstructing integrin signaling and the insights that we have gained through these experiments.

Optical-trapping Raman microscopy detection of single unilamellar lipid vesicles

Raman spectra of individual unilamellar phospholipid vesicles ( approximately 0.6 microm in size) have been acquired by optical-trapping confocal Raman microscopy over the 900-3200-cm(-)(1) region. Raman scattering from the phospholipid bilayer of a single, trapped liposome could be detected, along with molecular species trapped within the vesicle. The Raman spectra of vesicles prepared from four different phosphatidylcholine lipids, 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC), 1,2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC), 1,2-dilauroyl-sn-glycero-3-phosphocholine (DLPC), and 1,2-dioleoyl-sn-glycero-3-phosphocholine (DOPC), could be readily distinguished by evaluating differences in the skeletal C-C and C-H stretching modes of the acyl hydrocarbon tails. These differences correlate with changes in lipid organization for different gel to liquid-crystal transition temperatures (T(m)): 41, 24, 7, and -20 degrees C for DPPC, DMPC, DLPC, and DOPC, respectively. The spectra could be acquired on the same trapped vesicle for several hours, which allowed the permeability of the bilayer to be investigated by monitoring the leakage of perchlorate anions from the vesicle. Vesicles prepared from pure DPPC or DOPC, with gel to liquid-crystal transition temperatures well above and well below room temperature, exhibited no detectable anion transfer. DLPC and DMPC vesicles permitted rapid ion transfer across the bilayer. The lengths of hydrocarbon tails were shorter in these two lipids, which could indicate that shorter chains lower the hydrophobic barrier of a membrane to ion transport. While the DMPC chains were longer than DLPC with a correspondingly higher T(m), the temperature of the experiment corresponds to the T(m) of DMPC, and domain boundaries between gel and liquid-crystal phases could contribute to high membrane permeability.

An index of lipid phase diagrams

There is a growing awareness of the utility of lipid phase behavior data in studies of membrane-related phenomena. Such miscibility information is commonly reported in the form of temperature-composition (T-C) phase diagrams. The current index is a conduit to the relevant literature. It lists lipid phase diagrams, their components and conditions of measurement, and complete bibliographic information. The main focus of the index is on lipids of membrane origin where water is the dispersing medium. However, it also includes records on acylglycerols, fatty acids, cationic lipids, and detergent-containing systems. The miscibility of synthetic and natural lipids with other lipids, with water, and with biomolecules (proteins, nucleic acids, carbohydrates, etc.) and non-biological materials (drugs, anesthetics, organic solvents, etc.) is within the purview of the index. There are 2188 phase diagram records in the index, the bulk (81%) of which refers to binary (two-component) T-C phase diagrams. The remainder is made up of more complex (ternary, quaternary) systems, pressure-T phase diagrams, and other more exotic miscibility studies. The index covers the period from 1965 through to July, 2001.

Temperature- and pH-controlled fusion between complex lipid membranes. Examples with the diacylphosphatidylcholine/fatty acid mixed liposomes

The fusion capability of complex lipid bilayers and its pH as well as temperature sensitivity have been studied by optical and spectroscopic means. The aggregation and fusion efficiency of such lipid membranes can be optimized by controlling the phase characteristics of the individual membrane components. For a practically relevant illustration, the stoichiometric 1:2 (mol/mol) mixtures of phosphatidylcholines and fatty acids are used. Perhaps the most interesting liposomes of this kind, which are made of dipalmitoylphosphatidylcholine/elaidic acid (DPPC/ELA-COOH (1:2)), undergo a chain-melting phase transition between 42 degrees C and 48 degrees C, depending on the bulk pH value. The highest chain-melting phase transition temperatures are measured with the fully protonated fatty acids at pH < or = 5.5 and involve a change into the non-bilayer high-temperature state. Upon increasing pH, this transition reverts into an ordinary gel-to-fluid lamellar phase change and occurs at 42 degrees C, by and large. Simultaneously, the rate and the efficacy of fusion between the PC/FA and PC/FA- mixed vesicles decreases. The fusion efficacy of the PC/FA(-) mixed liposomes at pH > or = pK(FA) approximately 7.5 is practically negligible. This is largely due to the increased interbilayer repulsion and to the relatively high water-solubility of the deprotonated fatty acid molecules at high pH. While the pH-variability chiefly affects the efficacy of the intermembrane aggregation, the vesicle fusion itself is more sensitive to temperature variations. It is more likely that the temperature dependence of the intramembrane defect density is chiefly responsible for this. Optimal conditions for the fusion between DPPC/ELA-COOH (1:2) mixed vesicles are thus 3.5 < or = pH < or = 5.5 (6.3) (aggregation maximum) and T > or = 41.5 degrees C = Tm(DPPC) (defect density and fusion maximum). Under such conditions the average size of PC/FA (1:2) mixed vesicles in a 1 mM suspension increases by a factor of 10 over a period of 10 min. Interbilayer fusion can also be catalyzed by the mechanically induced local membrane defects. Freshly made liposomes thus always fuse more avidly than aged vesicles. This permits estimates of the kinetics of membrane defects annihilation based on the measured temporal dependence of the maximum fusion-rate. From such studies, a quasi-exponential decay on the time scale of 1.2 h is found for the thermolabile fusogenic DPPC/ELA-COOH liposomes.

pH-dependent lipid packing, membrane permeability and fusion in phosphatidylcholine vesicles

We have studied the rate of membrane fusion, the lipid dynamics and order and the membrane permeability of phosphatidylcholine vesicles as a function of pH. Acidification induced very different effects depending on the state of the bilayer. In liquid-crystalline bilayers, acidification decreased the rate of membrane fusion, the acyl chain motion and disorder and the rate of K+ release, whereas in solid bilayers acidification increased the rate of membrane fusion, the lipid acyl chain disorder and the rate of K+ release. These pH-dependent modifications are interpreted in terms of conformational and/or packing changes of the phosphatidylcholine head group in the membrane. In solid bilayers, these changes are not easily accommodated by the rigid structure, and the resulting stress leads to an unstable bilayer.

Isothermal lipid phase transitions

In liotropic lipid systems phase transitions can be induced isothermally by changing the solvent concentration or composition; alternatively, lipid composition can be modified by (bio)chemical means. The probability for isothermal phase transitions increases with the decreasing transition entropy; it is proportional to the magnitude of the transition temperature shift caused by transformation-inducing system variation. Manipulations causing large thermodynamic effects, such as lipid (de)hydration, binding of protons or divalent ions and macromolecular adsorption, but also close bilayer approach are, therefore, likely to cause structural lipid change(s) at a constant temperature. Net lipid charges enhance the membrane susceptibility to salt-induced isothermal phase transitions; a large proportion of this effect is due to the bilayer dehydration, however, rather than being a consequence of the decreased Coulombic electrostatic interactions. Membrane propensity for isothermal phase transitions, consequently, always increases with the hydrophilicity of the lipid heads, as well as with the desaturation and shortening of the lipid chains. Upon a phase change at a constant temperature, some of the interfacially bound solutes (e.g. protons or calcium) are released in the solution. Membrane permeability and fusogenicity simultaneously increase. In mixed systems, isothermal phase transitions, moreover, may result in lateral phase separation. All this opens up ways for the involvement of isothermal phase transitions in the regulation of biological processes.

The different influences of ether and ester phospholipids on the conformation of gramicidin A. A molecular modelling study

With AMBER (assisted model building with energy refinement) molecular modelling techniques, the interactions between lipids which differ in the type of chain linkage (e.g., ether or ester) and gramicidin were approximated. It was found, theoretically, that replacement of the ester function in dipalmitoylphosphatidylcholine (DPPC) by an ether moiety induces a shift in the rotameric distribution of the Trp-15 side-chain in gramicidin A. Concomitantly, the channel entrance is contracted by approx. 0.4 A. The perturbation can be related to the strong hydrogen-bond formed between the lipid carbonyl group and the indole proton of the Trp-15 residue of gramicidin. In the ether lipid-gramicidin assembly a weaker H-bond is formed between Trp-15 and the phosphate moiety. To obtain a first indication of the influence of the strength of this H-bond on gramicidin A, a preliminary experimental study was set up. The transport properties of gramicidin A were studied using efflux measurements through vesicle walls containing ether and ester lipids, respectively. A change in the permeability of gramicidin A was found when ether lipids were added to a bilayer composed of the ester lipid dioleoylphosphatidylcholine (DOPC).

Lipid peroxidation and phospholipase A2 activity in liposomes composed of unsaturated phospholipids: a structural basis for enzyme activation

The effect of lipid peroxidation on membrane structure and phospholipase A2 activity was studied using liposomes composed of bovine liver phosphatidylcholine (PC) and phosphatidylethanolamine (PE). The phospholipids were mixed at set ratios and sonicated to yield small unilamellar vesicles. The liposome preparations were subjected to lipid peroxidation as induced by cumene hydroperoxide and hematin. Under these conditions, a sharp increase in lipid peroxidation was noted over a 30 min incubation period and was accompanied by loss of polyunsaturated fatty acids (PUFA). Liposomes enriched in PE were most extensively peroxidized with a preferred oxidation of this phospholipid. The extent of PC oxidation was also greater in liposomes containing the largest proportions of PE. Analysis of liposome anisotropy, via steady-state fluorescence polarization of diphenylhexatriene indicated that progressive increases in either PE content or the level of lipid peroxidation increased the apparent microviscosity of the vesicles. Moreover, lipid peroxidation increased anisotropy more effectively than variations in the ratios of PE vs. PC. Thus, peroxidation of 5-10% of the phospholipids produced the same anisotropy increase as a 20% increase in the ratio of PE vs. PC. Analysis of vesicle turbidity suggested that fusion was also more readily achieved through lipid peroxidation. When liposomes were incubated with 0.4 U/ml of snake venom phospholipase A2, a direct correlation was found between the degree of lipid peroxidation and the extent of phospholipid hydrolysis. The more unsaturated phospholipid, PE, was most extensively hydrolyzed following peroxidation. Increasing the proportion of PE also resulted in more extensive phospholipid hydrolysis. These findings indicate that lipid peroxidation produces a general increase in membrane viscosity which is associated with vesicle instability and enhanced phospholipase A2 attack. A structural basis for membrane phospholipase A2 activation as a consequence of lipid peroxidation is discussed in light of these findings.

Interaction of the fluorescent probe N-(lissamine Rhodamine B sulfonyl)dipalmitoylphosphatidylethanolamine with phosphatidylcholine bilayers

The surface density of the fluorescent probe N-(lissamine Rhodamine B sulfonyl)dipalmitoylphosphatidylcholine is the same in the two lipid leaflets of phosphatidylcholine bilayers containing the probe. In the liquid-crystalline state, the probe molecules aggregate above a threshold amount, approximately 0.2 mol/mol phospholipids. Above this threshold value, the surface density of the free probe molecules is constant, and all probe molecules added are incorporated in the aggregated form. The aggregation of the probe increases by approximately 20% when the medium pH is lowered to 4. In the gel state, the probe aggregation is higher than that in the liquid-crystalline state, and the free probe molecules distribute unevenly in the bilayer surface. Even though the results obtained in our model system cannot be directly extrapolated to all model systems, we point out that care is to be taken in the use of the probe. In fact, only in membranes in the liquid-crystalline state in which the amount of probe molecules to phospholipid molecules is lower than 1:7 the fluorescence response of the probe is independent of the pH changes and of the molecular aggregation.

Lipid interaction of diphtheria toxin and mutants with altered fragment B. 1. Liposome aggregation and fusion

The interaction of diphtheria toxin and its cross-reacting mutants crm 45,228 and 1001 with small unilamellar vesicles has been followed by a turbidity assay, electron microscopy, fluorescence energy transfer and membrane permeability. All toxins at pH lower than 6 induce the aggregation and fusion of liposomes containing negatively charged phospholipids; crm 45 and crm 1001 are less potent than diphtheria toxin. Isolated diphtheria toxin fragment B is very effective while isolated fragment A is ineffective. Liposome fusion induced by the toxins at low pH occurs without release of the internal content implying that fusion does not involve vesicle breakage and resealing. The pH dependence of the membrane interaction of diphtheria toxin monitored by turbidity is in close agreement with that monitored by fluorescence energy transfer. It shows that diphtheria toxin can alter the lipid bilayer structure in the pH interval 5-6. This pH range occurs in endosomes and suggests that histidyl and carboxyl residues are likely to be involved in the conformational change of diphtheria toxin triggered by acidic pH.