Formation of unilamellar liposomes from total polar lipid extracts of methanogens.

Unilamellar liposomes were formed by controlled detergent dialysis of mixed micelles consisting of acetone-insoluble total polar lipids extracted from various methanogens and the detergent n-octyl-beta-D-glucopyranoside. The final liposome populations were studied by dynamic light scattering and electron microscopy. Unilamellar liposomes with mean diameters smaller than 100 nm were obtained with lipid extracts of Methanococcus voltae, Methanosarcina mazei, Methanosaeta concilii, and Methanococcus jannaschii (grown at 50 degrees C), whereas larger (greater than 100-nm) unilamellar liposomes were obtained with lipid extracts of M. jannaschii grown at 65 degrees C. These liposomes were shown to be closed intact vesicles capable of retaining entrapped [14C]sucrose for extended periods of time. With the exception of Methanospirillum hungatei liposomes, all size distributions of the different liposome populations were fairly homogeneous.     

Interaction of mitochondrial aspartate aminotransferase with negatively charged lecithin liposomes.

Several kinds of hydrophilic proteins were examined to determine their interaction with artificial liposomes. Mitochondrial aspartate aminotransferase (m-GOT) [EC 2.6.1.1], as well as cytochrome c, was found to interact strongly with negatively charged liposomes. In each case, an appreciable amount of the protein bound to liposomes remained unreleased after raising the salt concentration in the medium. The m-GOT tightly bound to the liposomes was also found to become latent in its enzymatic activity, and could be reversibly activated by solubilization of the liposomes with detergent. This is also the case for cytochrome c, which ceases to be reducible by external reductant, such as dithionite. Furthermore, the tightly bound m-GOT was not susceptible to the proteolytic action of trypsin, or that of Nagarse. From these observations it can be inferred that these basic proteins interact with acidic liposomes not only electrostatically but also hydrophobically. This kind of hydrophobic interaction was not observed in the combination of positively charged liposomes and acidic proteins, including s-GOT. Mitochondrial GOT was shown to be bound to isolated intact mitochondrial, but the bound enzyme was fully active, in contrast to the case of acidic liposomes. The hydrophobic interaction of water-soluble protein with liposomes is discussed in connection with the penetration of matrix enzyme through mitochondrial membranes.     

A small hydrophobic domain that localizes human erythrocyte acetylcholinesterase in liposomal membranes is cleaved by papain digestion

A small hydrophobic domain in isolated human erythrocyte acetylcholinesterase is responsible for the interaction of this enzyme with detergent micelles and the aggregation of the enzyme on removal of detergent. Papain has been shown to cleave this hydrophobic domain and to generate a fully active hydrophilic enzyme that shows no tendency to interact with detergents or to aggregate [Dutta-Choudhury, T.A., & Rosenberry, T.L. (1984) J. Biol. Chem. 259, 5653-5660]. We report here that the intact enzyme could be reconstituted into phospholipid liposomes while the papain-disaggregated enzyme showed no capacity for reconstitution. More than 80% of the enzyme reconstituted into small liposomes could be released by papain digestion as the hydrophilic form. Papain was less effective in releasing the enzyme from large liposomes that were probably multilamellar. In a novel application of affinity chromatography on acridinium resin, enzyme reconstituted into small liposomes in the presence of excess phospholipid was purified to a level of 1 enzyme molecule per 4000 phospholipid molecules, a ratio expected if each enzyme molecule was associated with a small, unilamellar liposome. Subunits in the hydrophilic enzyme form released from reconstituted liposomes by papain digestion showed a mass decrease of about 2 kilodaltons relative to the intact subunits according to acrylamide gel electrophoresis in sodium dodecyl sulfate, a difference similar to that observed previously following papain digestion of the soluble enzyme aggregates. The data were consistent with the hypothesis that the same hydrophobic domain in the enzyme is responsible for the interaction of the enzyme with detergent micelles, the aggregation of the enzyme in the absence of detergent, and the incorporation of the enzyme into reconstituted phospholipid membranes.     

Core/shell nanofibers with embedded liposomes as a drug delivery system

The broader application of liposomes in regenerative medicine is hampered by their short half-life and inefficient retention at the site of application. These disadvantages could be significantly reduced by their combination with nanofibers. We produced 2 different nanofiber-liposome systems in the present study, that is, liposomes blended within nanofibers and core/shell nanofibers with embedded liposomes. Herein, we demonstrate that blend electrospinning does not conserve intact liposomes. In contrast, coaxial electrospinning enables the incorporation of liposomes into nanofibers. We report polyvinyl alcohol-core/poly-ε-caprolactone-shell nanofibers with embedded liposomes and show that they preserve the enzymatic activity of encapsulated horseradish peroxidase. The potential of this system was also demonstrated by the enhancement of mesenchymal stem cell proliferation. In conclusion, intact liposomes incorporated into nanofibers by coaxial electrospinning are very promising as a drug delivery system.     

Binding of a nonionic detergent to membranes: flip-flop rate and location on the bilayer

The kinetic aspects of amphiphile interaction with intact membranes (unilamellar and multilamellar liposomes, sarcoplasmic reticulum vesicles) were studied, with the nonionic detergent octa(ethylene glycol) dodecyl monoether (C12E8) as a prototype. C12E8 was bound to these membranes noncooperatively and with a maximum of 0.6-0.8 mol per mole of phospholipid, before the onset of solubilization. Binding was not affected by ultrasonication to expose internal binding sites on the inner leaflet. All detergent could be removed from the membranes by treatment with hydrophobic beads. Furthermore, bound detergent, also from the inside of multilayered liposomes, comprising 10-20 bilayers, was quickly released by dilution of the membranes, followed by gel filtration. The time course of these processes was investigated with a rapid-filtration apparatus, using glass fiber filters to deposit membrane material. Both detergent binding and removal could be described by a monoexponential process with a half-time of approximately 350 ms for all types of membranes. Binding of detergent enhanced the intrinsic fluorescence of sarcoplasmic reticulum vesicles. This occurred in less than 100 ms, probably as the result of direct interaction of C12E8 with Ca2+-ATPase at a few binding sites. The data show that flip-flop of C12E8 across lipid membranes is a rapid process that cannot account for incomplete detergent removal in reconstitution experiments [Ueno, M., Tanford, C., & Reynolds, J. A. (1984) Biochemistry 23, 3070-3076]. It is also suggested that other nonionized amphiphiles, including those with an anesthetic action, rapidly gain access to membrane proteins on the inside of the cell, even when used at low, clinical doses.     

Solubilization and reconstitution of vesicular stomatitis virus envelope using octylglucoside.

Reconstituted vesicular stomatitis virus envelopes or virosomes are formed by detergent removal from solubilized intact virus. We have monitored the solubilization process of the intact vesicular stomatitis virus by the nonionic surfactant octylglucoside at various initial virus concentrations by employing turbidity measurements. This allowed us to determine the phase boundaries between the membrane and the mixed micelles domains. We have also characterized the lipid and protein content of the solubilized material and of the reconstituted envelope. Both G and M proteins and all of the lipids of the envelope were extracted by octylglucoside and recovered in the reconstituted envelope. Fusion activity of the virosomes tested either on Vero cells or on liposomes showed kinetics and pH dependence similar to those of the intact virus.     

Reaction System for Violaxanthin De-Epoxidase with PSII Membranes

PSII membranes were used as a substrate for violaxanthin de-epoxidase(VDE) that had been solubilized from spinach thylakoids by sonication.Inclusion of Tween 20 in the assay mixture was essential, althoughthe detergent apparently inhibited the activity in the conventionalassay with purified violaxanthin and lipid as substrate. Themaximum enhancing effect of the detergent was observed nearits critical micellar concentration. It is likely that the monomerof the detergent helped VDE react with the substrate in themembranes. Dependence of the activity on the substrate concentrationsuggested that VDE functions at least at two sites in the membranes,probably on both their lumenal and stromal surfaces. The abilityof the enzyme to function on the stromal surface in in vitroassays was demonstrated by using intact thylakoids as the substrate.Under such conditions where the endogenous VDE was functioningin the lumen, the exogenously added VDE converted an-theraxanthinto zeaxanthin in the absence of Tween 20. This result suggeststhat, in the reaction with PSII membranes, the detergent wasrequired for VDE to react with violaxanthin but not with antheraxanthin.Otherwise, the detergent was necessary for the reaction on thelumenal surface. (Received September 5, 1997; Accepted October 19, 1997)     

Structural changes induced by Triton X-100 on sonicated phosphatidylcholine liposomes

Solubilization of sonicated unilamellar vesicles by Triton X-100 is a complex process. Solubilization starts at low detergent concentrations, as compared to the case of large vesicles, and is accompanied by the simultaneous rapid formation of large multilamellar liposomes. Measurements of lipid and detergent distribution indicate that, at a 1:1 lipid:detergent mole ratio, about one-third of the lipid, with most of the detergent, is solubilized in the form of mixed micelles. The remaining two-thirds are in the form of multilamellar liposomes, virtually free of detergent. Higher detergent concentrations also bring about the solubilization of these liposomes.     

Efficient Encapsulation of Plasmid DNA in Anionic Liposomes by a Freeze/Thaw-Extrusion Procedure

Abstract

In this study we investigated whether intact plasmid DNA can be efficiently encapsulated in anionic liposomes prepared by freeze/thaw and extrusion techniques. There is controversy about this method of DNA encapsulation, especially as to whether DNA remains intact and retains its biological activity during extrusion. A solution containing supercoiled plasmid pCMVβ (7164 base pairs) was added to dry lipid films, and after freezing and thawing, the suspension was extruded through a filter with 0.2 μm pores. About 20% of the DNA became encapsulated, as evidenced by protection from degradation by endonuclease added externally. Plasmid isolated from the liposomes was structurally intact, and had essentially the same transfection activity as untreated DNA. These results show that plasmid DNA can be reliably and efficiently encapsulated in anionic liposomes by freeze/thaw and extrusion.     

Incorporation of human liver and placental alkaline phosphatases into liposomes and membranes is via phosphatidylinositol

As assessed by incorporation into liposomes and by adsorption to octyl-Sepharose, the integrity of the membrane anchor for the purified tetrameric forms of alkaline phosphatase from human liver and placenta was intact. Any treatment that resulted in a dimeric enzyme precluded incorporation and adsorption. An intact anchor also allowed incorporation into red cell ghosts. The addition of hydrophobic proteins inhibited incorporation into liposomes to varying degrees. Alkaline phosphatase was 100% releasable from liposomes and red cell ghosts by a phospholipase C specific for phosphatidylinositol. There was no appreciable difference in the rates of release of placental and liver alkaline phosphatases, although both were approximately 250 x slower in liposomes and 100 x slower in red cell ghosts than the enzyme's release from a suspension of cultured osteosarcoma cells. Both enzymes were released by phosphatidylinositol phospholipase C as dimers and would not reincorporate or adsorb to octyl-Sepharose. However, the enzyme incorporated, resolubilized by Triton X-100, and cleansed of the detergent by butanol treatment was tetrameric by gradient gel electrophoresis, was hydrophobic, and could reincorporate into fresh liposomes. A monoclonal antibody to liver alkaline phosphatase inhibited the enzyme's incorporation into liposomes, and abolished its release from liposomes and its conversion to dimers by phosphatidylinositol phospholipase C.     

Ectoplasmic insertion of a glycosylphosphatidylinositol-anchored protein in glycosphingolipid- and cholesterol-containing phosphatidylcholine vesicles.

Glycosylphosphatidylinositol (glycosyl-PtdIns)-anchored proteins are proposed to be clustered in membrane microdomains enriched in cholesterol and glycosphingolipids (GlySphs). We have prepared biomimetic membranes in order to study the possible phenomena of surface aggregation of these membrane components. Phosphatidylcholine liposomes were treated by octylglucoside to insert a glycosyl-PtdIns-protein, alkaline phosphatase (ALP), some cholesterol, and a GlySph, the lactocerebroside. The association of these compounds was shown by centrifugation on a density gradient. The presence of ALP on the surface of the vesicles was shown by the action of a phospholipase, and the presence of the lactocerebroside was shown by the use of a galactose-specific tetravalent lectin. Our data show that total alkaline phosphatase and half to total lactocerebroside were ectoplasmically inserted in the vesicles membrane. In addition, we observed that the presence of small amounts of ALP in the liposomes led to significant changes in membrane stability with regard to detergent, as shown by the changes in the solubilization process monitored by turbidimetry. Furthermore, we have built an original method to study the cohesion of the vesicles membrane, in which some magnesium ions were trapped in the luminal space of the liposomes during several days. The ALP is magnesium-dependent for its catalytic activity and was inhibited after incubation of ALP-containing liposomes in a magnesium-free buffer. The ALP activity was restored by the addition of detergent to the liposomes, due to the release of the luminal magnesium ions. Surface aggregation phenomena will now be investigated by atomic force microscopy.     

Incorporation of mannose 6-phosphate receptors into liposomes. Receptor topography and binding of alpha-mannosidase.

A receptor that binds the lysosomal enzyme alpha-mannosidase via mannose 6-phosphate moieties (mannose 6-phosphate receptor) was purified from Swarm-rat chondrosarcoma and bovine liver microsomal membranes. Receptor-reconstituted liposomes were prepared by dialysis of taurodeoxycholate-dispersed lipids with purified mannose 6-phosphate receptor. Liposomes appeared by electron microscopy as 60-120 nm unilamellar vesicles. Receptor-reconstituted liposomes retained the ability to bind alpha-mannosidase specifically. Binding was saturable with an apparent Kd of 1 nM and was competitively inhibited by mannose 6-phosphate (Ki 2mM). Liposomes containing entrapped 125I-bovine serum albumin were used to demonstrate that treatment with 0.045% taurodeoxycholate rendered liposomes permeable to macromolecules without solubilizing the membrane. Receptor orientation in the liposome membrane was established by measuring binding of ligand to intact and detergent-treated liposomes. Unlike coated vesicles, which contain cryptic mannose 6-phosphate receptors [Campbell, Fine, Squicciarini & Rome (1983) J. Biol. Chem. 258, 2526-2533], treatment of liposomes with detergent revealed no additional cryptic binding sites. In addition, treatment of liposomes with 0.75% trypsin abolished total receptor binding activity. The results suggest that the receptor is inserted with its binding site facing the outside of the liposome.     

Studies on the methodology of the carboxyfluorescein assay and on the mechanism of liposome stabilization by red blood cells in vitro

The stability of small unilamellar liposomes was investigated in human blood, in vitro. Using the carboxyfluorescein technique, interaction between the dye, the detergent Triton X-100, and an as yet unidentified component of human serum grossly interferes with the experiment and necessitates the use of other detergents, preferably sodium deoxycholate. Separation of liposomes and blood cells by centrifugation induces a small leakage from the liposomes and can lead to an underestimation of the real liposome stability. Upon incubation with whole blood, intact liposomes are absorbed nonspecifically to erythrocytes and internalized by leukocytes, the extent and kinetics of the former process being insenstive to the presence of metabolic inhibitors. The stability of liposomes is significantly enhanced in whole blood or in serum containing washed erythrocytes. Similarly, liposome stability in serum could be augmented be presaturating the serum lipoproteins with excess phospholipid. Our work adds support to previous notions that stable liposomes with high affinities for certain blood-cell components might be developed as suitable carrier systems for drug targetting in pathological disorders within the blood stream.     

Liposomal formulations of protein proteinase inhibitors: Preparation and specific activity

Possibility of encapsulation of water-soluble proteins into multilayer liposomes of soybean zwitterionic phospholipid mixtures (phosphatidylcholine (PC) and phosphatidylethanolamine (PE)) was investigated. The influence of the PC/PE ratio (w/w) on efficiency of incorporation of the Bowman-Birk soybean proteinase inhibitor (BBI) and aprotinin (BPTI) into liposomes was studied. Protein encapsulation did not affect liposome sizes. Confocal laser scanning microscopy demonstrated that proteins were located in the central part of the spherical particle and also between bilayers. The study of biological (antitrypsin and antichymotrypsin) activity demonstrated partial spatial shielding of active sites of proteins entrapped in liposomes. The effect of an ionic detergent on the activity of the encapsulated BBI and BPTI is consistent with this hypothesis and suggests that this shielding is reversible. Stability of liposomes was examined using three various media modeling gastrointestinal fluids (gastric and intestinal juices and fluids). Data obtained indicate that the prepared liposomes seem to be promising formulations for BBI and BPTI delivery.     

Functional reconstitution of the partially purified aspartate-glutamate carrier from mitochondria

The aspartate/glutamate carrier from beef heart mitochondria has been solubilized with detergent. The transport protein was partially purified by chromatography on hydroxyapatite in the presence of dodecyl octaoxyethylene ether and high concentrations of ammonium acetate. During purification, the aspartate/glutamate carrier was identified by functional reconstitution into egg yolk phospholipid liposomes. After hydroxyapatite chromatography the protein is 30 fold enriched in aspartate/glutamate transport activity but still contains ADP/ATP-carrier and phosphate carrier. The reconstituted activity is specific for exchange of L-aspartate and L-glutamate and is similar to intact mitochondria with respect to substrate affinity and inhibitor sensitivity.     

Mechanisms of membrane protein insertion into liposomes during reconstitution procedures involving the use of detergents. 2. Incorporation of the light-driven proton pump bacteriorhodopsin

A method has been developed for identifying the step in a detergent-mediated reconstitution procedure at which an integral membrane protein can be associated with phospholipids to give functional proteoliposomes. Large liposomes prepared by reverse-phase evaporation were treated with various amounts of the detergents Triton X-100, octyl glucoside, or sodium cholate as described in the preceding paper [Paternostre, M.-T., Roux, M., & Rigaud, J. L. (1988) Biochemistry (preceding paper in this issue)]. At each step of the solubilization process, we added bacteriorhodopsin, the light-driven proton pump from Halobacterium halobium. The protein-phospholipid detergent mixtures were then subjected to SM2 Bio-Beads treatments to remove the detergent, and the resulting vesicles were analyzed with respect to protein insertion and orientation in the membrane by freeze-fracture electron microscopy, sucrose density gradients, and proton pumping measurements. The nature of the detergent used for reconstitution proved to be important for determining the mechanism of protein insertion. With sodium cholate, proteoliposomes were formed only from ternary phospholipid-protein-detergent micelles. With octyl glucoside, besides proteoliposome formation from ternary mixed micelles, direct incorporation of bacteriorhodopsin into preformed liposomes destabilized by saturating levels of this detergent was observed and gave proteoliposomes with optimal proton pumping activity. With Triton X-100, protein insertion into destabilized liposomes was also observed but involved a transfer of the protein initially present in phospholipid-Triton X-100-protein micelles into Triton X-100 saturated liposomes. Our results further demonstrated that protein orientation in the resulting proteoliposomes was critically dependent upon the mechanism by which the protein was incorporated.     

Ultrastructure of reconstituted membranes containing the muscarinic receptor

In this paper the demonstration is made that membrane vesicles (liposomes) containing the muscarinic receptor can be formed by polyethylene glycol (PEG) precipitation of detergent extracts of bovine atrial membranes. The incorporation of the muscarinic receptor in these vesicles may be related to the restoration of the heterogeneity and nucleotide modulation of muscarinic agonist binding by PEG precipitation of atrial detergent extracts, previously reported. Vesicles are also formed when detergent solubilized asolectin lipids, alone or in combination with membrane detergent extracts, are precipitated by PEG. The structure of the vesicles seems depend on their lipid and protein composition and the procedure employed for the removal of the dispersing medium. These results indicate that PEG precipitation could be used for the reconstitution of the muscarinic receptor into the liposomes of exogenous lipids.Special Issue dedicated to Prof. Eduardo De Robertis.     

Improved purification for thermophilic F1F0 ATP synthase using n-dodecyl beta-D-maltoside

Here we report a fast, simple purification for thermophilic F1F0 ATP synthase (TF1F0) that utilizes a cocktail of stabilizing reagents and the detergent n-dodecyl beta-D-maltoside to yield enzyme with an ATPase activity of 41 micromol/min/mg, 2.5-fold higher than that previously reported. ATPase activity was 80% inhibited by the F0-reactive reagent dicyclohexylcarbodiimide, indicating that F1-F0 interactions were largely intact. To measure ATP-driven proton pumping activity, purified TF1F0 was incorporated into liposomes, and the ATP-induced change in internal pH was measured using the fluorescent probe pyranine. In the presence of valinomycin, a maximum ATP-driven deltapH of 0.8 units was obtained. To measure ATP synthesis activity, TF1F0 was incorporated into liposomes with the light-dependent proton pump bacteriorhodopsin. Proteoliposomes were illuminated to generate an electrochemical gradient, after which ADP and inorganic phosphate were added to initiate ATP synthesis. A steady state ATP synthesis activity of 490 nmol/min/mg was achieved after an initial approximately 30-min lag phase.     

Functional reconstitution of influenza virus envelopes.

We have examined several procedures for the reconstitution of influenza virus envelopes, based on detergent removal from solubilized viral membranes. With octylglucoside, no functionally active virosomes are formed, irrespective of the rate of detergent removal: in the final preparation the viral spike proteins appear predominantly as rosettes. Protein incorporation in reconstituted vesicles is improved when a method based on reverse-phase evaporation of octylglucoside-solubilized viral membranes in an ether/water system is employed. However, the resulting vesicles do not fuse with biological membranes, but exhibit only a non-physiological fusion reaction with negatively charged liposomes. Functional reconstitution of viral envelopes is achieved after solubilization with octaethyleneglycol mono(n-dodecyl)ether (C12E8), and subsequent detergent removal with Bio-Beads SM-2. The spike protein molecules are quantitatively incorporated in a single population of virosomes of uniform buoyant density and appear on both sides of the membrane. The virosomes display hemagglutination activity and a strictly pH-dependent hemolytic activity. The virosomes fuse with erythrocyte ghosts, as revealed by a fluorescence resonance energy transfer assay. The rate and the pH dependence of fusion are essentially the same as those of the intact virus. The virosomes also fuse with cultured cells, either at the level of the endosomal membrane or directly with the cellular plasma membrane upon a brief exposure to low pH.     

Reconstitution of Na+/K+-ATPase into phosphatidylcholine vesicles by dialysis of nonionic alkyl maltoside detergents

The reconstitution of Na+/K+-ATPase from outer medulla of rabbit kidney into large unilamellar liposomes was achieved through detergent removal by dialysis of mixed micellar solutions of synthetic dioleoyl phosphatidylcholine/octyl glucoside and Na+/K+-ATPase/decyl maltoside or decenyl maltoside. Tight, transport-active liposomes were formed when the lipid and the enzyme were solubilized separately in the nonionic detergents and mixed immediately before starting the dialysis. The two maltoside detergents with different structures of the hydrophobic part of the molecule proved to be well suited for the solubilization of Na+/K+-ATPase with high retention of enzyme activity; the inactivation of enzyme being evidently slower with the unsaturated decenyl maltoside. The diameters of the proteoliposomes, 110 and 170 nm, respectively, were also dependent on the structure of the maltoside detergent, the saturated decyl maltoside producing the bigger liposomes. After freeze-fracture, both preparations exhibited intramembranous particles as structural indicators of successful reconstitution. The electrogenic activity of the reconstituted enzyme was determined by fluorescence measurements with Oxonol VI and by tracer-flux measurements with 22Na+.