Formation of unilamellar lipid vesicles of controllable dimensions by detergent dialysis.

Vesicles are formed by solubilizing mixtures of phosphatidylcholine and cholesterol with sodium cholate and removing the detergent by rapid (hollow fiber) dialysis [e.g., Goldin, S. M. (1977) J. Biol. Chem. 252, 5630--5642]. Characterization of the vesicle size distribution by agarose gel filtration, and determination of the intravesicular aqueous compartment, demonstrates that the vesicles are relatively homogeneous in size and are primarily unilamellar. The mean diameter of the vesicles can be varied from 340 to 1280 A by varying the conditions under which they are formed; increasing the mole fraction of cholesterol and lowering the pH of the dialysate tend to produce larger vesicles. The gentle detergent treatment required for vesicle formation and the ability to control vesicle size distribution reproducibly may make this method particularly useful in studies of reconstitution of membrane proteins and in use of vesicles as vehicles for delivery of materials to living cells.     

Plasmid condensation induced by cationic compounds: hydrophilic polylysine and amphiphilic cationic lipid

The construction of an efficient carrier for genetic material is a major research objective that needs to be achieved before gene therapy can become a viable pharmacological approach. Artificial aggregates containing nucleic acids are one of the options for the systemic delivery of genetic information. The diversity of functions the aggregate is expected to fulfill necessitates its complex architecture. In order to obtain a complex supramolecular aggregate, formed from elements that are themselves complex molecules, appropriate procedures based on the detailed understanding of processes at the molecular level are required. In this study, we investigated how the various properties of cationic compounds affect nucleic acid condensation. The combination of two condensing agents, differing in their affinity towards water, when mixed with plasmids, resulted in aggregates which are resistant to enzymatic digestion and which form particles with well-defined size distributions. Such uniform and well-defined complexes may subsequently be further modified in order to obtain a fully functional genetic material carrier.     

Gene transfection into HeLa cells by vesicles containing cationic peptide lipid

Lipid vesicles are potentially useful as microcapsules for drug and/or gene delivery. We developed cationic lipid vesicles consisting mainly of sorbitan monooleate (Span 80) and cationic peptide lipid (CPL), and evaluated the CPL vesicles as gene transfection vectors. The optimum CPL concentration for gene transfection into HeLa cells was found to be 20 wt % of total lipid, and such CPL vesicles did not exhibit significant cytotoxicity. Co-culture of Poly-L-lysine and plasmids prior to making CPL vesicle-plasmid complexes was effective. Lipofection using LipofectAMINE was suppressed in 10% serum-supplemented medium. The transfection efficiency of 20 wt % CPL vesicles, however, was not affected by serum in the medium when plasmids were treated with poly-L-lysine.     

Effective detergent/lipid ratios in the solubilization of phosphatidylcholine vesicles by Triton X-100.

Effective detergent:lipid ratios (i.e. molar ratios in the mixed aggregates, vesicles or micelles) have been estimated for the solubilization of phosphatidylcholine vesicles by Triton X-100. Effective molar ratios are given for both the onset and the completion of bilayer solubilization; small unilamellar, large unilamellar and multilamellar vesicles have been used. Effective detergent:lipid ratios are independent of phospholipid concentration, and their use allows a deeper understanding of membrane-surfactant interactions.     

Rapid transmembrane movement of phosphatidylcholine in small unilamellar lipid vesicles formed by detergent removal

Small unilamellar phosphatidylcholine vesicles, formed by solubilizing phosphatidylcholine with sodium cholate and removing the detergent by gel filtration, have been studied in their interaction with phospholipid exchange protein. The exchange of phosphatidylcholine between the vesicles and erythrocyte ghosts was greatly stimulated by the phosphatidylcholine-specific exchange protein from bovine liver. It was found that 95% of the phosphatidylcholine was readily available for exchange within 3 h at 37°C. In similar vesicles prepared by sonication only 70% of the phosphatidylcholine was rapidly exchangeable. Our results indicate that the transmembrane movement of phosphatidylcholine across the bilayer of vesicles prepared by the cholate technique is a relatively fast process. The results are discussed with respect to the presence of trace amounts of lipid-associated cholate which may facilitate the transbilayer exchange of phosphatidylcholine.     

Interaction of an amine oxide detergent with lecithin vesicles as studied by nuclear magnetic resonance

The interaction of an amine oxide detergent with single bilayer lecithin vesicles was investigated with proton and phosphorus magnetic resonance. The addition of the detergent micelles to vesicles suspensions leads to rapid detergent incorporation into the vesicle bilayer, resulting in a heterogenous vesicle population. Initially, some vesicles take up the equivalent of one detergent micelle, whereas others contain no detergent. Subsequently, the detergent is distributed between the vesicles by vesicle-vesicle collisions. This can be followed by the change in the Pr3+-shifted spectral positions of the detergent and lecithin head groups with time. From the intensity of the head-group signals, it can be concluded that after about 20 h the detergent is almost equally distributed between the outer and inner vesicle membrane monolayers. Vesicles obtained by cosonication of the detergent and lecithin take up metal ions. This ion permeability depends on the vesicle concentration and can be attributed to vesicle-vesicle or vesicle-mixed micelle collisions. Egg lecithin vesicles are stable against the detergent up to molar ratios of detergent to lecithin of 0.2--0.3. At larger ratios mixed micells and multibilayers are formed. Measurements of proton spin-lattice relaxation times confirmed that the internal architecture of the vesicle bilayer is almost unaffected by the incorporated detergent.     

Interactions of mammalian cells with lipid dispersions containing novel metabolizable cationic amphiphiles

Several novel cationic amphiphiles, based on a hydrophobic cholesteryl or dioleoylglyceryl moiety, have been prepared whose hydrophobic and cationic portions are linked by ester bonds to facilitate efficient degradation in animal cells. Dispersions combining such cationic species with phosphatidylethanolamine (PE), certain structural analogues of PE or diacylglycerol can mediate efficient transfer of both nonexchangeable lipid probes and the DNA plasmid pSV2cat into cultured mammalian (CV-1 and 3T3) cells. The abilities of different types of cationic lipid dispersions to mediate transfection of mammalian cells with pSV2cat could not be directly correlated with their abilities to coalesce with other membranes, as assessed by their ability to intermix lipids efficiently with large unilamellar phosphatidylcholine/phosphatidylserine vesicles in the presence or absence of DNA. The cytotoxicities toward CV-1 cells of dispersions combining PE with most of the degradable cationic amphiphiles studied here compare favorably with those reported previously for similar dispersions containing other types of cationic amphiphiles. Fluorescent analogues of two of the diacylglycerol-based cationic amphiphiles examined in this study are shown to be readily degraded after incorporation into CV-1 cells from PE/cationic lipid dispersions.     

The biological activity of bacteriophage DNA, prepared by the cationic detergent dilution technique

The preparation of phage lambda DNA infecting E. coli K 12 with cationic detergent is described. This DNA infects E. coli spheroblasts with the same efficiency as DNA prepared by phenol methods.     

Interactions of diphtheria toxin with lipid vesicles: determinants of ion channel formation

Lipid vesicles have been utilized to study the interactions of diphtheria toxin (DT) with membranes. The assay for DT ion channel formation was fluorescence-detected membrane potential depolarization of vesicles in which valinomycin-induced potassium diffusion gradients had been generated. The following requirements for ion channel formation have been identified: (1) acid pH (less than 5); (2) trans-negative membrane potentials (35-fold increase in channel-forming activity from -6 mV to -59 mV); and (3) negatively charged phospholipid headgroups (about 100-fold more activity using vesicles formed from asolectin compared to soybean phosphatidylcholine). Concentration dependence plots of toxin activity showed a linear response with logarithmic slopes of nearly one for each lipid composition. These results show a close parallel to those obtained previously with planar lipid bilayers and thus provide guidelines for conditions which facilitate functional insertion of the toxin into vesicles.     

Oligonucleotide delivery by a cationic derivative of the polyene antibiotic amphotericin B. II: study of the interactions of the oligonucleotide/cationic vector complexes with lipid monolayers and lipid unilamellar vesicles

We report a study of the behavior of oligodeoxyribonucleotide (ODN)/amphotericin B3-(N'-dimethylamino)propylamide (AMA) complexes, in the presence of lipid monolayers and large unilamellar vesicles. This study follows the recent discovery of the capacity of AMA, as a new cationic vector, to enhance ODN cellular uptake and efficacy. It aims at investigating the internalization mode of a nucleic acid by AMA. A first study at the air-water interface of AMA and AMA/ODN by surface pressure measurement shows that only free AMA would adsorb at the air-water interface. Second, in the presence of zwitterionic phospholipid- and sterol-containing mixture, ODN-AMA interactions in solution would be higher than lipid-AMA interactions at the interface. In monolayer or with large unilamellar vesicles, AMA monomers adsorb mainly at the phospholipid interface. These results favor a crossing mechanism through AMA channel formation, despite the size of ODN.     

DNA condensation by high-affinity interaction with avidin

Avidin, the basic biotin-binding glycoprotein from chicken egg white, is known to interact with DNA, whereas streptavidin, its neutral non-glycosylated bacterial analog, does not. In the present study we investigated the DNA-binding properties of avidin. Its affinity for DNA in the presence and absence of biotin was compared with that of other positively charged molecules, namely the protein lysozyme, the cationic polymers polylysine and polyarginine and an avidin derivative with higher isoelectric point (pI approximately 11) in which most of the lysine residues were converted to homoarginines. Gel-shift assays, transmission electron microscopy and dynamic light scattering experiments demonstrated an unexpectedly strong interaction between avidin and DNA. The most pronounced gel-shift retardation occurred with the avidin-biotin complex, followed by avidin alone and then guanidylated avidin. Furthermore, ultrastructural and light-scattering studies showed that avidin assembles on the DNA molecule in an organized manner. The assembly leads to the formation of nanoparticles that are about 50-100 nm in size (DNA approximately 5 kb) and have a rod-like or toroidal shape. In these particles the DNA is highly condensed and one avidin is bound to each 18 +/- 4 DNA base pairs. The complexes are very stable even at high dilution ([DNA] =10 pM) and are not disrupted in the presence of buffers or salt (up to 200 mM NaCl). The other positively charged molecules also condense DNA and form particles with a globular shape. However, in this case, these particles disassemble by dilution or in the presence of low salt concentration. The results indicate that the interaction of avidin with DNA may also occur under physiological conditions, further enhanced by the presence of biotin. This DNA-binding property of avidin may thus shed light on a potentially new physiological role for the protein in its natural environment.     

Glycophorin-enriched vesicles obtained by a selective extraction of human erythrocyte membranes with a non-ionic detergent.

A method is described for isolating glycophorin-enriched vesicles from human erythrocytes by extracting membranes that were incubated for 30 min at 37 degrees C at pH 4.5 and washed at low and high ionic strength with the nonionic detergent Triton X-100. The extracts were 11.8 +/- 2.4 fold enriched in glycophorin and contained 325 +/- 69 microgram sialic acid/mg protein, which represented 61 +/- 16% of the total sialic acid. Upon removal of Triton X-100 one third of the total glycophorin forms glycophorin-enriched vesicles with coextracted, endogenous lipids as shown sedimintation, dextran-density gradient centrifugation, and electron microscopy. Addition of exogenous lipids increased the fraction of glycophorin-enriched vesicles up to 87%. The incorporation of glycophorin in the membrane was shown by hemagglutination inhibition assays using anti-M sera and by the accessibility of glycophorin to trypsin. Freeze-fractured vesicles did not reveal intramembranous particles. The selectivity of the extraction procedure is not simply due to chemical constraints introduced by disulfide cross-linkage of protein component 3, because only 20% of this protein undergo disulfide cross-linking. The selective extraction of glycophorin implies that glycophorin is segregated from protein component 3 and thus from intramembranous particles when erythrocyte membranes have been incubated at pH 4.5. This segregation may precede aggregation of intramembranous particles.     

The photoinduced isomerization of bilirubin in cationic detergent solutions.

When bilirubin IX alpha in solution in a buffered aqueous cationic detergent near neutral pH is irradiated with visible light, a rapid equilibrium with bilirubin III alpha and XIII alpha is set up. Little isomerization can be detected under comparable conditions in anionic or neutral detergents. The rapid disproportionation of bilirubin monoglucuronide into unconjugated bilirubin and bilirubin diglucuronide also takes place on irradiation in a solution of a cationic detergent.     

Interactions of an antimicrobial peptide, tachyplesin I, with lipid membranes.

Tachyplesin I, isolated from the acid extracts of hemocytes of Tachypleus tridentatus, is a cyclic broad-spectrum antimicrobial peptide forming a rigid, antiparallel beta-sheet because of two intramolecular S-S linkages. The strong binding of the peptide to lipopolysaccharides cannot explain the susceptibilities of gram positive bacteria and fungi to the peptide. We found that tachyplesin I caused a rapid K+ efflux from Escherichia coli cells, concomitant with a reduced cell viability. This result suggests that the peptide-induced permeability enhancement of the bacterial membranes may be a plausible action mechanism. Thus, we studied the interactions of tachyplesin I with various large unilamellar vesicles (LUVs) to reveal the molecular machinery of the antimicrobial activity. Tachyplesin I induced the leakage of calcein, a trapped fluorescent marker, from LUVs of acidic phospholipids, especially phosphatidylglycerol (PG), but not from phosphatidylcholine LUVs. A detailed analysis found that the affinity of the peptide to the PG membranes is very strong and that the binding of one peptide molecule to approx. 200 lipid molecules leads to a significant leakage. The location of tachyplesin I in membranes was estimated by use of the Trp-2 fluorescence of the peptide. The presence of PG LUVs caused a blue shift of the maximum wavelength, an increase in the quantum yield, and a complete protection from fluorescence quenching by an aqueous quencher, acrylamide. Moreover, the degree of fluorescence quenching of the Trp residue by n-doxylstearates was in the order n = 5 greater than 7 greater than 12 approximately equal to 16. These results show that the Trp residue of tachyplesin I seems to locate in a hydrophobic environment near the surface of the PG bilayers.     

Cellular uptake of cationic lipid/DNA complexes by cultured myoblasts and myotubes

Several cationic lipids which are highly efficient for delivering genes in vitro do not increase gene delivery in vivo after an intramuscular injection. In order to elucidate the origin of this phenomenon, we have studied the cellular uptake and intracellular fate of cationic lipid/DNA complexes in vitro on myogenic mouse cells (myoblasts and myotubes) of the C2 cell line and of primary cultures. We used a cationic lipid with a spermine head group and its fluorescent analog, and a fluorescent plasmid obtained by nick-translation. In myoblasts, transgene expression was obtained and lipoplexes were internalized in cytoplasmic vesicles. In myotubes, no transgene expression could be detected and we observed an absence of lipoplex internalization. The in vitro uptake of cationic lipid was inversely correlated with the degree of fusion of C2 cell myotubes cultures.     

Fusion of negatively charged phospholipid vesicles by insulin. Relationship with lipid fluidity

We have studied, by fluorescence methods, the association of insulin to liposomes, the modification of lipid fluidity, and the fusion of vesicles induced by insulin. All parameters showed a similar dependence on pH and ionic strength of the medium and on negative charges in liposomes. The influence of temperature indicated that the association of insulin to liposomes per se was not sufficient to produce a decrease in lipid fluidity and fusion of liposomes. The modification of lipid fluidity induced by insulin in biological membranes is discussed as a possible general event in the action of the hormone.     

DNA condensation with polyamines I. Spectroscopic studies

The addition of polyamines with three or four positive charges to very dilute solutions of phage T7 DNA leads to a co-operative condensation. The reaction is very rapid and the DNA remains in the B-form as characterized by circular dichroism. The particles which are formed are roughly the size of a phage particle when they are prepared for electron microscopy. This aspect is discussed more completely in the accompanying paper (Chattoraj et al., 1978).Most of the experiments were performed at low ionic strength (roughly 0.002 m) with the triamine, spermidine. The reaction also occurs in 0.15 m-sodium chloride but here the experiments are accompanied by slow irreversible effects which are evidently due to aggregation since they are accompanied by a commensurate increase in turbidity. Consequently, most of the experiments have been done under the reversible low ionic strength conditions.Neither Mg²⁺ nor the diamine putrescine produce the reaction at concentrations similar to those found in bacterial cells. The tetramer spermine, on the other hand, which is not found in bacterial cells, is a very strong condensation agent in the μm region. The spermidine analog, bis-(3-aminopropyl)amine is very similar in behavior to spermidine.The role which polyamines might play in the condensation of DNA in phage heads is discussed.