Reconstitution of lipoproteins. II. Lipid-protein interaction between dimyristoyl-lecithin and dimyristoyl-lecithin:cholesterol vesicles and purified apolipoprotein C-I and C-III2 studied by isomeric spin-labelled lecithins

The reconstitution of purified apolipoprotein C-I and C-III2 with sn-3-dimyristoyl-lecithin and sn-3-dimyristoyl-lecithin:cholesterol (10:1) vesicles was studied by electron spin resonance spectroscopy using isomeric 5'-, 12'-, and 16'-(N-oxyl-4",4"-dimethyloxazolidine)stearoyl spin-labelled lecithin probes. Results obtained from the temperature-induced changes of lipoprotein recombinants showed the hydrophilic nature of the lipid-protein interactions. The temperature-induced phospholipid phase transition, as measured by 5'-(N-oxyl-4",4"-dimethyloxazolidine)stearoyl spin-labelled lecithin probe in recombinants containing apoprotein C-1 or apoprotein C-iii2, is very broad and has a small cooperative unit indicative of extensive lipid-protein interactions occurring at the head group region of the phospholipid bilayer. When 12"- and 16'-(N-oxyl-4",4"-dimethyloxazolidine)stearoyl spin-labelled lecithins are used as probes in the same system, similar sharper and more cooperative lipid phase changes are detected. These results indicate a surface location for both apoprotein C-I and apoprotein C-III2 with respect to the phospholipid bilayer in lipoprotein recombinants with and without cholesterol.     

Selective enzymatic radioactive and spin labelling of phospholipids in biological membranes: application to study of temperature-induced changes of microsomal phosphatidylinositols and mitochondrial polyglycerophosphatides.

A new method for the covalent radioactive and spin labelling of lipids within isolated biological membranes has been described in detail and applied to studies of temperature-induced changes of microsomal and mitochondrial membranes. The method is based on the enzymatic use of radioactive substrates carrying covalently bound doxyl derivatives of stearic acid in the biosynthesis of phospholipids in isolated membranes. Radioactive-and spin-labelled lipids bound to the microsomal and mitochondrial membranes were then used as internal probes in monitoring temperature-induced changes of these membranes. Since the analysis of isolated radioactive-and spin-labelled lipids revealed the exact composition of membrane-bound labelled lipids, specific temperature-induced changes were correlated with specific lipids of examined membranes. Phosphatidylinositol of microsomal membranes and polyglycerophosphatides (phosphatidyl-glycerol and cardiolipin) of mitochondrial and inner mitochondrial membranes were found to be involved in the apparent formation of lipid clusters at around 20-30 degrees C. Cardiolipin was found to be involved in the fluidization of inner mitochondrial membranes. These findings are discussed in view of the present state of knowledge of the organization of lipids in biological membranes.     

Permeability properties of liposomes prepared from dipalmitoyllecithin, dimyristoyllecithin, egg lecithin, rat liver lecithin and beef brain sphingomyelin

Liposomes have been prepared from dipalmitoyllecithin, dimyristoyllecithin, egg lecithin, rat liver lecithin and beef brain sphingomyelin.Permeability properties of liposomes thus prepared were studied toward glucose. The glucose permeability of liposomes with saturated lecithins (dipalmitoyllecithin and dimyristoyllecithin) and sphingomyelin appears to be more strongly temperature dependent than that of liposomes with lecithin containing unsaturated fatty acyl chains (egg and rat liver lecithins). The permeability of glucose through vesicles of dipalmitoyllecithin or dimyristoyllecithin was enhanced drastically at their transition temperatures, while the incorporation of about 25 mole% of egg lecithin into liposomes of saturated lecithins suppressed the enhanced permeation rates of glucose above the transition temperatures.The incorporation of small amounts of cholesterol enhanced the temperature-dependent permeability of glucose through the bilayer of saturated lecithins or sphingomyelin. This tendency was best shown in the case of dipalmitoyl-lecithin, in which 20 mole% of cholesterol had the most stimulating effect on the temperature-dependent permeability. The introduction of more than 33 mole% of cholesterol showed, however, reduced effects on the temperature-dependent permeability through liposomes with saturated lecithins or sphingomyelin. It was also shown that cholesterol had a much larger effect on the regulation of the temperature-dependent permeability of liposomes prepared with saturated lecithins or sphingomyelin than on that of liposomes prepared with phospholipids containing unsaturated fatty acids.     

Topological distribution of bovine serum albumin in multilamellar and unilamellar liposomes

The topological distribution of bovine serum albumin (BSA) in multilamellar vesicles (MLV) and unilamellar vesicles (ULV) composed of 1,2-dimyristoyl-sn-glycero-3-phosphorylcholine (DML)/cholesterol (molar ratio, 3:1) was studied by ESR using hydrophobic spin-labelled lecithins and hydrophilic Tempocholine. A spin-labelled BSA was also prepared, characterized and used as a probe. Results with hydrophobic spin-labelled lecithin probes showed no significant phospholipid-albumin interaction, indicating the virtual absence of albumin from the phospholipid bilayer of MLV and ULV. Reduction with L-ascorbic acid showed that MLV contained about 50% and ULV 90% of spin-labelled albumin on the surface. The distribution of Tempocholine in MLV and ULV was similar to that of entrapped BSA. These findings were confirmed by results using liposomes treated with nickel which broadened the ESR spectra of probes on the surface of vesicles. This study and our previous work suggest that the immunoadjuvant effect of liposomes can be mediated by surface antigens and can be maximized by preferential surface distribution as in ULV-associated BSA.     

Surface potential and the interaction of weakly acidic uncouplers of oxidative phosphorylation with liposomes and mitochondria.

The pH dependence of the binding of weakly acidic uncouplers of oxidative phosphorylation to rat-liver mitochondria and liposomes is mainly determined by the pKa of the uncoupler molecule. The absorption and fluorescene excitation spectra of the anionic form of weakly acidic uncouplers of oxidative phosphorylation are red-shifted upon interaction with liposomal or mitochondrial membranes. The affinity for the liposomes, as deduced from the red shift, is independent of the degree of saturation of the fatty acid chains of different lecithins. The intensity of the spectra at one pH value is strongly dependent upon the surface charge of the liposomes. With positively charged liposomes the results obtained can be almost quantitatively explained with the Gouy-Chapman theory, but with negatively charged ones deviations are observed. At a particular pH, the divalent ion Ca-2+ stongly influences the intensity of the spectra in the presence of negatively charged liposomes, but has no effect with neutral liposomes. With mitochondrial membranes an effect of Ca-2+ similar to that with negatively charged liposomes is observed. Depletion of the phospholipids of the mitochondria and subsequent restoration of the mitochrondrial membrane with lecithin, strongly diminishes this effect, but restoration with negatively charged phospholipids does not influence it. From these observations it is concluded that the anionic form of the uncoupler molecule when bound to mitochondria is located within the partly negatively charged phospholiped moiety of the membrane, with its anionic group pointing to the aqueous solution.     

Temperature-induced changes of spin-labelled radioactive lipids in isolated guinea pig liver microsomal membranes before and in mitochondrial membranes after their translocation.

Lipids of isolated guinea pig liver microsomal membranes were labelled biosynthetically with isomeric doxyl stearic acid and temperature-induced changes of these membranes were studied by electron spin resonance. A noticeable discontinuity was detected at 10--12 degree C with 12- or 16-doxyl stearic acid containing membrane lipids which was attributed to the spin-labelled lipid--microsomal membrane protein interactions since no such discontinuity was detected in liposomes prepared from total lipid extracts of microsomal membranes. When microsomal membranes containing radioactive isomeric spin-labelled lipids were incubated with unlabelled mitochondria, reisolated mitochondrial membranes contained translocated radioactive isomeric spin-labelled lipids. Temperature-induced changes in these membranes showed no discontinuity with either isomeric doxyl stearic acid derivative, establishing a difference in the environment of translocated lipids in the membrane donor compared with that in the membrane acceptor. Microsomal membranes recovered from translocation experiments showed the same behaviour as the original membranes and exhibited the same discontinuity at 10--12 degree C, establishing that the translocation incubation itself did not alter the spin-labelled lipid interaction within these membranes. Studies of the loss of paramagnetism of spin-labelled lipids in microsomal membranes before and in mitochondrial membranes after their translocation showed a significant difference and suggested that both the outer and the inner mitochondrial membranes might have been involved.     

Surface potential and the interaction of weakly acidic uncouplers of oxidative phosphorylation with liposomes and mitochondria

The pH dependence of the binding of weakly acidic uncouplers of oxidative phosphorylation to rat-liver mitochondria and liposomes is mainly determined by the pK_a of the uncoupler molecule.

The absorption and fluorescence excitation spectra of the anionic form of weakly acidic uncouplers of oxidative phosphorylation are red-shifted upon interaction with liposomal or mitochondrial membranes. The affinity for the liposomes, as deduced from the red shift, is independent of the degree of saturation of the fatty acid chains of different lecithins. The intensity of the spectra at one pH value is strongly dependent upon the surface charge of the liposomes. With positively charged liposomes the results obtained can be almost quantitatively explained with the Gouy-Chapman theory, but with negatively charged ones deviations are observed. At a particular pH, the divalent ion Ca²⁺ strongly influences the intensity of the spectra in the presence of negatively charged liposomes, but has no effect with neutral liposomes.

With mitochondrial membranes an effect of Ca²⁺ similar to that with negatively charged liposomes is observed. Depletion of the phospholipids of the mitochondria and subsequent restoration of the mitochondrial membrane with lecithin, strongly diminishes this effect, but restoration with negatively charged phospholipids does not influence it.

From these observations it is concluded that the anionic form of the uncoupler molecule when bound to mitochondria is located within the partly negatively charged phospholipid moiety of the membrane, with its anionic group pointing to the aqueous solution.     

Functional properties of the acetylcholine receptor incorporated in model lipid membranes. Differential effects of chain length and head group of phospholipids on receptor affinity states and receptor-mediated ion translocation

Torpedo acetylcholine receptor was reconstituted into liposomes of pure synthetic lipids in order to study the influence of the lipid environment on affinity state transitions and the ion translocation function of the receptor. A critical concentration of 30 to 40% of cholesteryl hemisuccinate was necessary in liposomes made of cholesteryl hemisuccinate and dimyristoyl phosphatidylcholine to mimic the kinetics of agonist-induced state transitions observed in native membranes. With increasing chain length of the saturated lecithins, a marked increase in carbamylcholine dissociation constants was observed. Substitution by other dimyristoyl phospholipids for dimyristoyl phosphatidylcholine had the same, though quantitatively less pronounced effects. Introduction of unsaturation in the acyl chains reverted the effect of increasing chain length. Unsaturated phosphatidylethanolamines in combination with 28-35 mol% of cholesteryl hemisuccinate was the best lipid mixture for reconstitution of the receptor-gating function. When phosphatidylethanolamine was replaced totally or partially by other phospholipids with the same or different acyl chain composition, a marked decrease of ion transport was apparent, even when similar vesicle size, receptor incorporation, and agonist-induced affinity transitions were obtained. Therefore, the maintenance of the affinity state transitions of the reconstituted receptor is a necessary but not sufficient condition for the manifestation of the ion-gating receptor activity. On the other hand, the more unsaturated the acyl chains of phosphatidylethanolamine are, the higher the response that was observed, suggesting that a critical lipid packing is essential for the ion translocation function of the receptor.     

Study of the effect of tegalide and bithionol on biological membranes using fluorescent probes

Fluorescent probes were used to study structural changes in different membranes affected by gamma-radiation, protonophores and radioprotective agents, tegalide and bithionol. The preparations of the defined concentrations decreased the microviscosity of membranes, lowered the peaks and changed the temperature of phase transitions in liposomes from dipalmitoyl lecithin, and induced the output of Ca2+ from mitochondria. The effects depended on the radiation dose, the structure, concentration and lipophilicity of the preparation; protonophores produced a specific effect.     

Interaction of rat liver 3-D-(-)-hydroxybutyrate aopdehydrogenase with phospholipids

The interaction of phospholipids with pure, catalytically inactive rat liver 3-d-(—)-CoA hydroxybutyrate apodehydrogenase (apoHBD) was examined, (a) A relationship could be established between density of packing of phospholipid molecules at the interface and apoHBD activation, namely, the larger the area per polar head, the higher the lipid molar efficiency. In this context, codispersion of lecithins with phospholipids that were inactive or scarcely active per se, such as phosphatidylethanolamine and lysophosphatidylcholine (miristoyl; Iysod₁₄) increased the activating efficiency of lecithins, (b) ApoHBD formed tightly bound, catalytically active complexes with lecithin liposomes and micelles (diC₁₀ + lysoC₁₄; cetylphosphorylcholine), but a phospholipid-water interface was not essential for HBD activity since a molecular dispersion of diheptanoyl lecithin (diC₇) activated apoHBD to a limited extent. ApoHBD formed loosely bound, catalytically inactive complexes with multilayer vesicles, but HBD activity could be restored by sonication or by adding liposome to those complexes. Unlike liposomes and micelles, apoHBD interaction with multilayer vesicles did not involve a hydrophobic contribution, which was apparently necessary for apoHBD activation, (c) LysoC₁₄, did₁₀ + lysoC₁₄, and cetylphosphorylcholine micelles activated apoHBD but diC₇ micelles inhibited the HBD activity of the apoHBD-diC₇ (monomer) complex. The inhibition decreased when the medium ionic strength was increased. Liposomes and diCi₁₀ + lysoC₁₄ micelles activated and stabilized apoHBD much more efficiently than pure lysoC₁₄ or cetylphosphorylcholine micelles, (d) The mode of aggregation of the activating phospholipid strongly affected the kinetics of the HBD reaction. With liposomes the reaction showed an initial lag (or induction) period whose duration varied over a range of 3 to 15 min, depending on the activating phospholipid; with diC₇ monomers and micelles the kinetics was linear throughout, while with multilayer vesicles the lag was virtually infinite since HBD activity was insignificant, (e) Energies of activation for apoHBD-diC₁₄ complexes, either below or above the lecithin gel-to-liquid crystalline transition temperature were not significantly different, in accordance with apoHBD interaction with the proximal end of the hydrocarbon chains, that is, the less subject to phase transitions. With a diC₁₄-substituted mitochondrial preparation, however, no HBD activity was detected below 24 °C (near the gel-to-liquid crystalline transition temperature of diC₁₄), thus indicating that, in the inner membrane, apoHBD interacts with the whole length of the fatty acyl chain and, consequently, is sensitive to phase transition.     

A spin probe study of the influence of cholesterol on motion and orientation of phospholipids in oriented multibilayers and vesicles

Spin probes have been used to study at the molecular level the influence of cholesterol on bilayers of egg lecithin and dipalmitoyl lecithin. Distinct differences between the two lecithin systems were revealed. Increasing amounts of cholesterol result in extension of the fatty acid chains and decreased amplitude of motion of the long axes of the fatty acids in egg lecithin. In dipalmitoyl lecithin cholesterol causes an increase in the mobility and amplitude of motion of the fatty acid side chains, presumably due to alteration of the molecular interactions between phospholipids by relaxing the close packing of these molecules. These data provide an explanation for the condensing and fluidizing effects of cholesterol in water-containing phases and monolayers of egg lecithin and dipalmitoyl lecithin, respectively, and for the permeability behavior of egg lecithin and dipalmitoyl lecithin liposomes in the presence and absence of cholesterol. Differences are revealed between the spin bilayer environments in hydrated phospholipid films and vesicles.     

Studies on fluorescence polarization of 1-acyl-2-cis- or trans-parinaroyl sn-3-glycerophosphorylcholines in model systems and microsomal membranes

Fluorescent lecithin probes containing cis- or trans-parinaric acid (PnA) at the 2-position cis-parinaroylphosphatidylcholine (cis-PnPC) and trans-parinaroyl phosphatidylcholine (trans-PnPC)) showed similar behavior to that of the free cis- or trans-parinaric acids (cis-PnA or trans-PnA) in bilayer vesicles of synthetic saturated lecithins. Transition temperatures detected by cis-PnPc were about 1°C lower than those observed with trans-PnPc. In mixed lecithin vesicles, the trans-PnPc probe monitored a higher temperature melting component than did the cis-probe. Both probes were readily incorporated into microsomal membranes and into sonicated vesicles prepared from the microsomal phospholipids. With either cis- or trans-PnPc no change in polarization ratio was observed for microsomal membranes between 40°C and 0°C but this ratio increased with decreasing temperature between 0°C and ?5°C. However, vesicles of extracted phospholipids showed a continuous increase in polarization ratio with decreasing temperature between 20°C and ?15°C with trans-PnPc and bewteen 5°C and ?15°C with cis-PnPc. These results suggest that the two lecithin probes monitor different environments in the membranes and phospholipid vesicles prepared from them.     

An EPR spin probe study of liposomes from sunflower and soybean phospholipids

Comparative properties of lecithin-based liposomes prepared from the mixed phospholipids of sunflower seeds, soybean and egg yolk were investigated by electron paramagnetic resonance (EPR) spectroscopy. For these investigations, stable nitroxide radicals, 1-oxyl-2,2,6,6-tetramethylpiperidin-4-yl 5,7-dimethyladamantane-1-carboxylate (DMAC-TEMPO), 5-doxylstearic acid (5-DSA) and 16-doxylstearic acid (16-DSA) were used as spin probes. Binding of the spin probes to the liposome membranes resulted in a substantial increase of the apparent rotational diffusion correlation times. The EPR spectra of the incorporated nitroxides underwent temperature-dependent changes. For every spin probe, values of apparent enthalpy and entropy of activation were calculated from the temperature dependence of rotational diffusion correlation times via Arrhenius equation. In case of DMAC-TEMPO, the data point to differences between the phospholipid bilayer of liposomes derived from sunflower and soy lecithin, and some similarity between the sunflower and egg yolk liposomes. Anisotropic hyperfine interaction constants of DMAC-TEMPO and 16-DSA included in the liposomes have been analyzed and attributed to different micropolarity of the surroundings of the spin probes. The kinetics of EPR signal decay of DMAC-TEMPO in the presence of 2,2′-azobis(2-amidinopropane) suggest the better stability of the sunflower liposomes to lipid peroxidation as compared to the liposomes prepared from soy lecithin.     

Spin-labelled vacuolar-ATPase inhibitors in lipid membranes

Two spin-labelled derivatives of the 5-(2-indolyl)-2,4-pentadienoyl class of inhibitors of the vacuolar ATPase have been synthesised and their EPR properties characterised in phospholipid membranes. One spin-labelled inhibitor is the amide derivative of pentadienic acid and 4-amino-TEMPO (INDOL6), and the other is the 3-hydroxymethyl-PROXYL ester (INDOL5). The response of the EPR spectra to the chain-melting transition of dimyristoyl phosphatidylcholine (DMPC) bilayers demonstrates that both derivatives incorporate in phospholipid membranes. The axially anisotropic EPR spectra of INDOL6 in fluid DMPC membranes indicate that the indolyl-pentadienoyl inhibitors intercalate between the lipid chains, in the membrane. INDOL5, designed to possess additional internal segmental mobility, exhibits more nearly isotropic motion of the spin-label moiety in fluid membranes than does INDOL6. The EPR characteristics of INDOL5 are therefore well suited to detecting specific ligand-protein interactions. Progressive saturation EPR experiments with polar and hydrophobic relaxation agents (aqueous Ni2+ and oxygen) show that the nitroxide group is buried in the membrane, with the indole moiety providing the anchor at the membrane polar-apolar interface. Rates of spin-label reduction by externally added ascorbate confirm this assignment. These two spin-labelled derivatives provide complementary EPR probes of the lipid environment (INDOL6), and of ligand-protein interactions (INDOL5), for this class of V-ATPase inhibitor.     

NMR study of the interactions of polymyxin B, gramicidin S, and valinomycin with dimyristoyllecithin bilayers

The interactions of three polypeptide antibiotics (polymyxin B, gramicidin S, and valinomycin) with artificial lecithin membranes were studied by nuclear magnetic resonance (NMR). Combination of 31P and 2H NMR allowed observation of perturbations of the bilayer membrane structure induced by each of the antibiotics in the regions of the polar headgroups and acyl side chains of the phospholipids. The comparative study of the effects of these membrane-active antibiotics and the lipid bilayer structure demonstrated distinct types of antibiotic-membrane interactions in each case. Thus, the results showed the absence of interaction of polymyxin B with the dimyristoyllecithin membranes. In contrast, gramicidin S exhibited strong interaction with the lipid above the gel to liquid-crystalline phase transition temperature: disordering of the acyl side chains was evident. Increasing the concentration of gramicidin S led to disintegration of the bilayer membrane structure. At a molar ratio of 1:16 of gramicidin S to lecithin, the results are consistent with coexistence of gel and liquid-crystalline phases of the phospholipids near the phase transition temperature. Valinomycin decreased the phase transition temperature of the lipids and increased the order parameters of the lipid side chains. Such behavior is consistent with penetration of the valinomycin molecule into the interior of the lipid bilayers.     

Chemistry and biology of N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-labeled lipids: fluorescent probes of biological and model membranes

Lipids that are covalently labeled with the 7-nitrobenz-2-oxa-1,3-diazol-4-yl (NBD) group are widely used as fluorescent analogues of native lipids in model and biological membranes to study a variety of processes. The fluorescent NBD group may be attached either to the polar or the apolar regions of a wide variety of lipid molecules. Synthetic routes for preparing the lipids, and spectroscopic and ionization properties of these probes are reviewed in this report. The orientation of various NBD-labeled lipids in membranes, as indicated by the location of the NBD group, is also discussed. The NBD group is uncharged at neutral pH in membranes, but loops up to the surface if attached to acyl chains of phospholipids. These lipids find applications in a variety of membrane-related studies which include membrane fusion, lipid motion and dynamics, organization of lipids and proteins in membranes, intracellular lipid transfer, and bilayer to hexagonal phase transition in liposomes. Use of NBD-labeled lipids as analogues of natural lipids is critically evaluated.     

Study of the interaction between the organophosphorus insecticide GA-41 and model membranes using NMR-spectroscopy

Interaction between organophosphorous insecticide GA-41 and liposomes formed from lecithin and multilamellar dispersion from lecithin and cardiolipin mixture (molar ratio is 7:3) has been studied by 1H- and 31P-NMR spectroscopy. The results obtained showed that while interacting with model membranes the GA-41 molecules intercalate into the range of hydrocarbon chains of phospholipids. At certain concentration of GA-41 its molecules induce the formation of some defects on bilayer structure, leading to permeability for Pr3+ ions.     

Acyl chain unsaturation modulates distribution of lecithin molecular species between mixed micelles and vesicles in model bile. Implications for particle structure and metastable cholesterol solubilities.

We determined the distribution of lecithin molecular species between vesicles and mixed micelles in cholesterol super-saturated model biles (molar taurocholate-lecithin-cholesterol ratio 67:23:10, 3 g/dl, 0.15 M NaCl, pH approximately 6-7) that contained equimolar synthetic lecithin mixtures or egg yolk or soybean lecithins. After apparent equilibration (48 h), biles were fractionated by Superose 6 gel filtration chromatography at 20 degrees C, and lecithin molecular species in the vesicle and mixed micellar fractions were quantified as benzoyl diacylglycerides by high performance liquid chromatography. With binary lecithin mixtures, vesicles were enriched with lecithins containing the most saturated sn-1 or sn-2 chains by as much as 2.4-fold whereas mixed micelles were enriched in the more unsaturated lecithins. Vesicles isolated from model biles composed of egg yolk (primarily sn-1 16:0 and 18:0 acyl chains) or soy bean (mixed saturated and unsaturated sn-1 acyl chains) lecithins were selectively enriched (6.5-76%) in lecithins with saturated sn-1 acyl chains whereas mixed micelles were enriched with lecithins composed of either sn-1 18:1, 18:2, and 18:3 unsaturated or sn-2 20:4, 22:4, and 22:6 polyunsaturated chains. Gel filtration, lipid analysis, and quasielastic light scattering revealed that apparent micellar cholesterol solubilities and metastable vesicle cholesterol/lecithin molar ratios were as much as 60% and 100% higher, respectively, in biles composed of unsaturated lecithins. Acyl chain packing constraints imposed by distinctly different particle geometries most likely explain the asymmetric distribution of lecithin molecular species between vesicles and mixed micelles in model bile as well as the variations in apparent micellar cholesterol solubilities and vesicle cholesterol/lecithin molar ratios.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies of structural modifications induced by gamma-irradiation in distearoylphosphatidylcholine liposomes

An investigation of the structural and thermodynamical modifications induced by gamma-irradiation in model membranes is reported. Differential scanning calorimetry and X-ray diffraction were used to study the different phases and associated transitions of distearoylphosphatidylcholine multilamellar liposomes after 60Co gamma-irradiation. Changes were observed in the shape of the calorimetric peaks and in the corresponding phase transition temperatures. In particular a shoulder was observed at about 20 kGy. The three phases characteristic of lecithins with identical acyl chains were detected also for the highest radiation dose. The formation of lysolecithin and stearic acid upon phospholipid degradation was observed. The lysolecithin concentration increases as a function of irradiation dose, until a saturation value is reached at 40 kGy. These results correlate quite well with those obtained for interlayer and interchain distances and for the width of the main phase transition calorimetric peak. At the highest dose (approximately equal to 80 kGy) cross-linked adjacent radicals and other molecular species are also formed. Appreciable differences, and some similarities, in the behaviour of DSPC and DPPC liposomes under gamma-irradiation were observed.     

Chiroptical properties of lecithin reverse micelles and organogels

The ultraviolet absorbance and circular dichroism (CD) spectra of lecithin reverse micelles and gels were investigated in order to establish whether the formation of these noncovalent macromolecular aggregates, which was induced by the addition of water to solutions of lecithin in organic solvents, was accompanied by specific spectroscopic changes. Systems containing the synthetic short-chain lecithins, 1,2-hexanoyl-, 1,2-diheptanoyl-, 1,2-dioctanoyl-, and 1,2-dinonaoyl-sn-glycero-3-phosphatidylcholines were used as models for the long-chain lecithins, soybean phosphatidylcholine and palmitoyl-oleoyl-phosphatidylcholine. All the molecules studied had asymmetric centres, formed reverse micelles under appropriate conditions, and, while both the long-chain lecithins also formed gels, none of the short-chain molecules did. As well as having CD spectra that were simpler to interpret, spectroscopic observations on solutions of the short-chain lecithins could be carried out over a large water content range. The ester chromophore of these compounds was shown to be highly sensitive to variation in both the solvent environment and the temperature, and components of both direct solvent effects and conformational change upon the addition of water were detected in the spectra. The spectra of the longer chain lecithins were complicated by the presence of double bonds although, here again, it was found that significant changes occurred as the water content increased, as monitored by the ester chromophore. However, no specific effect that could be ascribed to gelation alone was detected. The overall picture that emerged was that the ester chromophore of anhydrous micelles gave rise to a specific negative band in the CD spectrum (λ_max ≈ 210 nm) whereas a positive CD signal (λ_max ≈ 233 nm) was associated with the same chromophore in filled (i.e., hydrated) micelles. The two signals correspond to two different conformational states of the lecithin molecule, the hydrated state being not only more conformationally restricted but also providing a less polar environment for the ester groups, while the addition of water to the system shifts the conformational equilibrium. These observations have been interpreted as showing that only a limited range of lecithin conformation is compatible with the formation of the micellar structure and that it is this constraint, together with those introduced by the overall geometry of the aggregated state, that gives rise to the changes observed in the CD spectrum.