The function of tight junctions in maintaining differences in lipid composition between the apical and the basolateral cell surface domains of MDCK cells.

Tight junctions in epithelial cells have been postulated to act as barriers inhibiting lateral diffusion of lipids and proteins between the apical and basolateral plasma membrane domains. To study the fence function of the tight junction in more detail, we have fused liposomes containing the fluorescent phospholipid N-Rh-PE into the apical plasma membrane of MDCK cells. Liposome fusion was induced by low pH and mediated by the influenza virus hemagglutinin, which was expressed on the apical cell surface after viral infection. Redistribution of N-Rh-PE to the basolateral surface, monitored at 0 degree C by fluorescence microscopy, appeared to be dependent on the transbilayer orientation of the fluorescent lipids in the plasma membrane. Asymmetric liposomes containing over 85% of the N-Rh-PE in the external bilayer leaflet, as shown by a phospholipase A2 assay, were generated by octyl beta-D-glucoside dialysis. When these asymmetric liposomes were fused with the apical plasma membrane, fluorescent lipid did not move to the basolateral side. Symmetric liposomes which contained the marker in both leaflets were obtained by freeze-thawing asymmetric liposomes or by reverse-phase evaporation. Upon fusion of these with the apical membrane, redistribution to the basolateral membrane occurred immediately. Redistribution could be observed with asymmetric liposomes only when the tight junctions were opened by incubation in a Ca2+-free medium. During the normal experimental manipulations the tight junctions remained intact since a high trans-epithelial electrical resistance was maintained over the cell monolayer. We conclude that the tight junction acts as a diffusion barrier for the fluorescent phospholipid N-Rh-PE in the exoplasmic leaflet of the plasma membrane but not in the cytoplasmic leaflet.     

A role for scavenger receptor B-I in selective transfer of rhodamine-PE from liposomes to cells

We investigated the potential role of scavenger receptor B-I (SR-BI) in the selective removal of liposomal markers from blood by hepatocytes. Liposomes were labeled with [(3)H]cholesteryloleyl-ether ([(3)H]COE), 1,2-di[1-(14)C]palmitoyl-phosphatidylcholine ([(14)C]PC), and N-(lissamine rhodamine-B sulfonyl)-phosphatidylethanolamine (N-Rh-PE). The radiolabels were eliminated at identical rates from plasma, while N-Rh-PE was cleared twice as fast. Involvement of SR-BI in the selective removal of N-Rh-PE from liposomes was studied in transfected Chinese hamster ovary cells over-expressing SR-BI. Uptake of N-Rh-PE from liposomes containing phosphatidylserine was higher than [(3)H]COE, and was further enhanced by apolipoprotein A-I, confirming involvement of SR-BI in the selective uptake of liposomal N-Rh-PE by cells.     

A non-exchangeable fluorescent phospholipid analog as a membrane traffic marker of the endocytic pathway

The fluorescent phospholipid analog N-(lissamine rhodamine B sulfonyl)phosphatidylethanolamine (N-Rh-PE) was inserted into the plasma membrane of Baby hamster kidney cells at low temperature (2 degrees C). The mobility characteristics of the analog--as revealed by fluorescence photobleaching recovery--were very similar to those of membrane-inserted 1-acyl-2[6-[N-(7-nitro-2,1,3-benzoxadiazol-4-yl) amino]caproyl] phosphatidylcholine (C6-NBD-PC). Upon warming to 37 degrees C, followed by a 1-h incubation, all N-Rh-PE was located intracellularly. By contrast, after the same time interval, approximately 10% of the cell-associated PC-derivative was found intracellularly. Furthermore, the analogs moved to different intracellular sites, as N-Rh-PE associates with perinuclear and peri-Golgi structures, whereas C6-NBD-PC appears mainly in the Golgi complex. Colocalization with organelle-specific probes and Percoll gradient analysis identified the N-Rh-PE-labeled structures as lysosomes. Temperature and energy-dependent experiments supported the endocytic pathway as the mechanism of N-Rh-PE internalization. The mechanism of N-Rh-PE internalization appears to differ from that of C6-NBD-PC. In conjunction with a difference in the efficiency of removal of the lipid derivatives from the plasma membrane, the results suggest that N-Rh-PE is selectively internalized, implying that sorting of the lipid analogs already occurs at the level of the plasma membrane. The distinct difference in physical appearance of the probes after membrane insertion, i.e., N-Rh-PE being present as small clusters and C6-NBD-PC as monomers, could explain the selective sorting and internalization of N-Rh-PE. The results demonstrate that N-Rh-PE may serve as a useful marker for studying membrane traffic during endocytosis.     

Membrane fusion between liposomes composed of acidic phospholipids and neutral phospholipids induced by melittin: a differential scanning calorimetric study

Melittin-induced membrane fusion between neutral and acidic phospholipids was examined in liposome systems with a high-sensitivity differential scanning calorimeter. Membrane fusion could be detected by calorimetric measurement by observing thermograms of mixed liposomal lipids. The roles of hydrophobic and electrostatic interactions were investigated in membrane fusion induced by melittin. Melittin, a bee venom peptide, is composed of a hydrophobic region including hydrophobic amino acids and a positively charged region including basic amino acids. When phosphatidylcholine liposomes were prepared in the presence of melittin, reductions in the phase transition enthalpies were observed in the following order; dimyristoylphosphatidylcholine (DMPC) > dipalmitoylphosphatidylcholine (DPPC) > distearoylphosphatidylcholine (DSPC) > dielaidoylphosphatidylcholine (DEPC). The plase transition enthalpy of an acidic phospholipid, dipalmitoylphosphatidylserine (DPPS), was raised by melittin at low concentrations, then reduced at higher concentrations. DPPC liposomes prepared in melittin solution were fused with DPPS liposomes when the liposomal dispersions were mixed and incubated. Similar fusion was observed between dipalmitoylphosphatidylcholine and dimyristoylphosphatidic acid (DMPA) liposomes. These results indicate that a peptide including hydrophobic and basic regions can mediate membrane fusion between neutral and acidic liposomes by hydrophobic and electrostatic interactions.     

Membrane fusion by proline-rich Rz1 lipoprotein, the bacteriophage lambda Rz1 gene product.

The fusogenic properties of Rz1, the proline-rich lipoprotein that is the bacteriophage lambda Rz1 gene product, were studied. Light scattering was used to monitor Rz1-induced aggregation of artificial neutral (dipalmitoylphosphatidylcholine/cholesterol) and negatively charged (dipalmitoylphosphatidylcholine/cholesterol/dioleoylphosphatidylserin e) liposomes. Fluorescence assays [the resonance energy transfer between N-(7-nitro-2,1,3-benzoxadiazol-4-yl)phosphatidylethanolamine and N-(lissamine rhodamine B sulfonyl)dihexadecanol-sn-glycero-3-phosphoethanolamine lipid fluorescent probes, as well as fluorescent complex formation between terbium ions and dipicolinic acid encapsulated in two liposome populations and calcein fluorescence] were used to monitor Rz1-induced lipid mixing, contents mixing and leakage of neutral and negatively charged liposomes. The results demonstrated that Rz1 caused adhesion of neutral and negatively charged liposomes with concomitant lipid mixing; membrane distortion, leading to the fusion of liposomes and hence their internal content mixing; and local destruction of the membrane accompanied by leakage of the liposome contents. The use of artificial membranes showed that Rz1 induced the fusion of membranes devoid of any proteins. This might mean that the proline stretch of Rz1 allowed interaction with membrane lipids. It is suggested that Rz1-induced liposome fusion was mediated primarily by the generation of local perturbation in the bilayer lipid membrane and to a lesser extent by electrostatic forces.     

Low pH-induced fusion of liposomes with membrane vesicles derived from Bacillus subtilis

We have investigated the pH-dependent interaction between large unilamellar phospholipid vesicles (liposomes) and membrane vesicles derived from Bacillus subtilis, utilizing a fluorescent assay based on resonance energy transfer (RET) (Struck, D. K., Hoekstra, D., and Pagano, R. E. (1981) Biochemistry 20, 4093-4099). Efficient interaction occurs only with negatively charged liposomes, containing cardiolipin or phosphatidylserine, as revealed by the dilution of the RET probes from the liposomal bilayer into the bacterial membrane. The initial rate of fluorophore dilution increases steeply with decreasing pH. The interaction involves a process of membrane fusion, as indicated by the proportional transfer of cholesteryl-[1-14C]oleate, 14C-labeled egg PC, and the RET probes from the liposomes to the bacterial vesicles, the formation of interaction products with an intermediate buoyant density, and the appearance of colloidal gold, initially encapsulated in the liposomes, in the internal volume of fused structures as revealed by thin-section electron microscopy. Treatment of B. subtilis vesicles with trypsin strongly inhibits the fusion reaction, indicating the protein dependence of the process. Vesicles derived from Streptococcus cremoris or from the inner membrane of Escherichia coli also show low pH-dependent fusion with liposomes. The fusion process described in this paper may well be of considerable importance to studies on the mechanisms of membrane fusion and to studies on the structure and function of bacterial membranes. In addition, the fusion reaction could be utilized to deliver foreign substances into bacterial protoplasts.     

Processing of different liposome markers after in vitro uptake of immunoglobulin-coated liposomes by rat liver macrophages

We compared the metabolic fate of [³H]cholesteryl[¹⁴C]oleate, [³H]cholesteryl hexadecylether, ¹²⁵I-labeled bovine serum albumin and [³H]inulin as constituents of large immunoglobulin-coupled unilamellar lipid vesicles following their internalization by rat liver macrophages (Kupffer cells) in monolayer culture. Under serum-free conditions, the cholesteryl oleate that is taken up is hydrolyzed, for the greater part, within 2 h. This occurs in the lysosomal compartment as judged by the inhibitory effect of the lysosomotropic agents monensin and chloroquin. After hydrolysis, the cholesterol moiety is accommodated in the cellular pool of free cholesterol and the oleate is reutilized for the synthesis mainly of phospholipids and, to a lesser extent of triacylglycerols. During incubation in plasma, however, substantial proportions of both the cholesterol and the oleate are shed from the cells, predominantly in the unesterified form. When the liposomes are labeled with the cholesteryl ester analog [³H]cholesteryl hexadecylether only a very small fraction of the label is released from the cells, even in the presence of plasma. Similar to the label remaining associated with the cells, the released label is identified in that case as unchanged cholesteryl ether. The liposomal aqueous phase marker ¹²⁵I-labeled bovine serum albumin is also readily degraded intralysosomally and the radioactive label is rapidly released from the cells in a trichloroacetic acid-soluble form. Also, as much as 20% of the aqueous phase marker [³H]inulin that becomes cell-associated during a 2-h incubation with inulin-containing liposomes, is released from the cells during a subsequent 4-h incubation period in medium or rat plasma. The usefulness of the various liposomal labels as parameters of liposome uptake and intracellular processing is discussed.     

Poly(aspartic acid)-dependent fusion of liposomes bearing the quaternary ammonium detergent [[[(1,1,3,3-tetramethylbutyl)cresoxy]ethoxy]ethyl] dimethylbenzylammonium hydroxide

Addition of the quaternary ammonium detergent [[[(1,1,3,3-tetramethylbutyl)cresoxy]ethoxy]ethyl] dimethylbenzylammonium hydroxide (DEBDA[OH]) and the fluorescent probes N-(7-nitro-2-1,3-benzoxadiazol-4-yl)phosphatidylethanolamine and N-(lissamine rhodamine B sulfonyl)phosphatidylethanolamine (N-NBD-PE and N-Rh-PE, respectively) to liposomes composed of phosphatidylcholine (PC) and cholesterol (chol) resulted in the formation of fluorescently labeled liposomes bearing DEBDA[OH]. Incubation of the anionic polymer poly(aspartic acid) (PASP) with such liposomes resulted in strong agglutination, indicating an association between the negatively charged PASP and the positively charged liposome-associated DEBDA[OH]. Addition of PASP to a mixture of fluorescently labeled and nonlabeled liposomes, both carrying DEBDA[OH], resulted in a significant increase in the extent of fluorescence, namely, fluorescence dequenching. The degree of the fluorescence dequenching was dependent upon the ratio between the nonfluorescent and the fluorescent liposomes, upon the temperature of incubation, and upon the amount of DEBDA[OH] which was associated with the liposomes. Electron microscopic observations revealed that large liposomes were formed upon incubation of liposomes bearing DEBDA[OH] with PASP. The results of the present work strongly indicate that the fluorescence dequenching observed is due to a process of PASP-induced liposome-liposome fusion.     

Low-pH-Dependent Fusion of Sindbis Virus with Receptor-Free Cholesterol- and Sphingolipid-Containing Liposomes

There is controversy as to whether the cell entry mechanism of Sindbis virus (SIN) involves direct fusion of the viral envelope with the plasma membrane at neutral pH or uptake by receptor-mediated endocytosis and subsequent low-pH-induced fusion from within acidic endosomes. Here, we studied the membrane fusion activity of SIN in a liposomal model system. Fusion was followed fluorometrically by monitoring the dilution of pyrene-labeled lipids from biosynthetically labeled virus into unlabeled liposomes or from labeled liposomes into unlabeled virus. Fusion was also assessed on the basis of degradation of the viral core protein by trypsin encapsulated in the liposomes. SIN fused efficiently with receptor-free liposomes, consisting of phospholipids and cholesterol, indicating that receptor interaction is not a mechanistic requirement for fusion of the virus. Fusion was optimal at pH 5.0, with a threshold at pH 6.0, and undetectable at neutral pH, supporting a cell entry mechanism of SIN involving fusion from within acidic endosomes. Under optimal conditions, 60 to 85% of the virus fused, depending on the assay used, corresponding to all of the virus bound to the liposomes as assessed in a direct binding assay. Preincubation of the virus alone at pH 5.0 resulted in a rapid loss of fusion capacity. Fusion of SIN required the presence of both cholesterol and sphingolipid in the target liposomes, cholesterol being primarily involved in low-pH-induced virus-liposome binding and the sphingolipid catalyzing the fusion process itself. Under low-pH conditions, the E2/E1 heterodimeric envelope glycoprotein of the virus dissociated, with formation of a trypsin-resistant E1 homotrimer, which kinetically preceded the fusion reaction, thus suggesting that the E1 trimer represents the fusion-active conformation of the viral spike.     

Fusion of Newcastle disease virus with liposomes: role of the lipid composition of liposomes

We demonstrate here that fusion occurs between the membrane of the Newcastle disease virus (NDV) and liposomes. Fluorescence dequenching studies (using Rhodamine-bearing viral envelopes) revealed the mixing of the lipids constituting the viral and liposomal membrane. The digestion of internal viral proteins by trypsin-containing liposomes indicated the mixing of the internal aqueous compartments. This last assay is independent of exchange of lipids between liposomal and viral membrane in the absence of fusion. Investigation of the effects of liposomal composition indicated that the presence of phosphatidylethanolamine and gangliosides are essential to optimize fusion. The fact that the Newcastle disease virus membrane can fuse with liposome also confirms that fusion must be determined by the viral proteins and could be mostly independent of the nature or presence of the host proteins.     

Plasma membrane-mediated leakage of liposomes induced by interaction with murine thymocytic leukemia cells

The interaction of liposomes with BW 5147 murine thymocytic leukemia cells was studied using fluorescent probes (entrapped carboxyfluorescein and fluorescent phosphatidylethanolamine) in conjunction with a Ficoll-Paque discontinous gradient system for rapid separation of liposomes from cells. Reversible liposomal binding to discrete sites on the BW cell surface was found to represent the major form of interaction; uptake of intact liposomal contents by a process such as liposome-BW cell membrane fusion was found to apparently represent a minor pathway of interaction (2%). Liposomal lysis was found to be associated with the process of liposomal binding (perhaps as a result of the binding itself). Lysis was followed by release of the entrapped carboxyfluorescein into the media and its subsequent uptake by the cells. This lysis was shown to be dependent upon discrete membrane-associated sites that have some of the properties of proteins. The results of these studies suggest that liposomal binding to the cells, subsequent lysis of the liposomes and cellular uptake of their contents should be seriously considered in all studies of liposome-cell interactions as an alternate mode of interaction to the four modes (fusion, endocytosis, adsorption and lipid exchange) previously emphasized in the literature.     

Fusion of Sendai virions with phosphatidylcholine-cholesterol liposomes reflects the viral activity required for fusion with biological membranes

Sendai virus envelopes were reconstituted after solubilization of intact virions with either Triton X-100 or octylglucoside. Envelopes obtained from Triton X-100, but not from octylglucoside solubilized virions, were hemolytic and promoted cell-cell fusion. Fluorescence dequenching studies [using N-4-nitrobenzo-2-oxa-1,3-diazole phosphatidylethanolamine-bearing viral envelopes] revealed that both preparations fused with negatively charged phospholipids. Fusion with phosphatidylcholine (PC)/cholesterol (chol) liposomes was promoted only by the hemolytic viral envelopes. Fluorescence dequenching studies, using intact virions bearing octadecylrhodamine B chloride, revealed that intact virions fused with PC/chol as well as with negatively charged phospholipids. Only fusion with PC/chol liposomes was inhibited by phenylmethylsulfonyl fluoride and dithiothreitol, reagents which are known to block the viral ability to fuse with biological membranes.     

Preparation of connexin43‐integrated giant Liposomes by a baculovirus expression–liposome fusion method

Connexin‐43 (Cx43) containing giant liposomes (GL) were prepared by a baculovirus expression–liposome fusion method. Recombinant budded viruses expressing Cx43 were prepared and then fused with GLs containing DOPG/DOPC at pH 4.5. Connexon formation on the GL membrane was observed by transmission electron microscope. Hydrophilic fluorescent dye transfers were observed through a Cx43‐mediated pathway not only between Sf9 (Spodoptera frugiperda) cells with Cx43 but also from giant Cx43 liposomes to Cx43‐expressing U2OS cells (human osteosarcoma cell). The functional connexin‐containing liposome is expected to be useful for cellular cytosolic delivery systems. The original orientation and function of Cx43 was maintained after integration into the liposomes. The liposome fusion method will create new opportunities as a tool for analysis of channel membrane proteins. Biotechnol. Bioeng. 2010;107: 836–843. © 2010 Wiley Periodicals, Inc.     

Assembly of clathrin molecules on liposome membranes: a possible event necessary for induction of membrane fusion

Below pH6, clathrin induces fusion of liposomes containing phosphatidylserine (PS) [Maezawa et al. (1989) Biochemistry 28, 1422-1428]. Under similar conditions clathrin forms self-aggregates, suggesting that the associated form of clathrin may be involved in the fusion process. For examination of this possibility, the extent of fluorescence energy transfer from N-(p-(2-benzimidazolyl)phenyl)maleimide (BIPM)-labeled clathrin to N-(7-dimethyl-amino-4-methyl-3-coumarinyl)maleimide (DACM)-labeled clathrin in the presence of liposomes and the number of binding sites for clathrin in one liposome were examined in the pH region inducing membrane fusion. A high degree of transfer was observed, and the area on the membrane surface occupied by a clathrin molecule was estimated to be much less than that expected from its size, indicating that clathrin binds to the liposome membrane as an associated form, which may be essential for induction of membrane fusion.     

Fusion of influenza hemagglutinin-expressing fibroblasts with glycophorin-bearing liposomes: role of hemagglutinin surface density

Influenza virus gains access to the cytoplasm of its host cell by means of a fusion event between viral and host cell membrane. Fusion is mediated by the envelope glycoprotein hemagglutinin (HA) and is triggered by low pH. To learn how many hemagglutinin trimers are necessary to cause membrane fusion, we have used two NIH 3T3 fibroblast cell lines that express HA protein at different surface densities. On the basis of quantitations of the number of HA trimers per cell and the relative surface areas of the two cell lines, the HAb-2 cells have a 1.9-fold higher plasma membrane surface density than the GP4F cells. The membrane lateral diffusion coefficient and the mobile fraction for HA is the same for both cell lines. A Scatchard analysis of the binding of glycophorin-bearing liposomes to the cells showed 1700 binding sites for the GP4F cells and 3750 binding sites for the HAb-2 cells, with effectively the same liposome-cell binding constant, about 7 x 10(10) M-1. Binding was specific for glycophorin on the liposomes and HA expressed on the cells. A competition experiment employing toxin-containing and empty liposomes allowed us to quantitate the number of liposomes that fused per cell, which was a small constant fraction of the number of bound liposomes. For the HAb-2 cells, about 1 in every 70 bound liposomes fused and for the GP4F cells about 1 in every 300 bound liposomes fused. Hence, the HAb-2 cells showed 4.4 times more fusion per bound liposome, even though the surface density of HA was only 1.9 times greater. We conclude the following: (i) One HA trimer is not sufficient to induce fusion. (ii) The HA bound to glycophorin is not the HA that induces fusion. That is, even though each HA has a binding and a fusion function, those functions are not performed by the same HA trimer.     

Free fatty acid enhancement of cation-induced fusion of liposomes: synergism with synexin and other promoters of vesicle aggregation

The effect of free fatty acids on the cation-induced fusion of large unilamellar vesicles (liposomes) was investigated by using fluorescent assays which monitor the mixing of aqueous contents of liposomes. Overall fusion was modeled as a two-step process involving aggregation of vesicles followed by actual fusion. Different experimental conditions were used which favored either aggregation or fusion as the rate-limiting step in the overall process. When phosphatidylserine liposomes were induced to fuse by 4 mM Ca2+ plus 5 mM Mg2+, preincubation with arachidonic acid showed a dramatically increased overall rate of fusion compared to the same liposomes not treated with fatty acid. When fusion was induced by 3 mM Ca2+, arachidonic acid had little effect. These results were interpreted in terms of the action of arachidonic acid only at the fusion step per se and not the aggregation step. Therefore, the enhancement of the overall fusion rate would be observed solely under conditions where the actual fusion of liposomes was rate limiting (Ca/Mg) rather than the aggregation of liposomes (Ca alone). When other liposome systems were tested, the effect of arachidonic acid was observed only under fusion rate-limiting conditions. Arachidonic acid was found to act synergistically with promoters of liposomal aggregation, such as Mg2+, spermine, and synexin, to enhance the overall rate of liposome fusion, as would be expected from action at separate kinetic steps. The dependence of the fusion rates on arachidonic acid concentration demonstrated an apparently cooperative effect. The structure of the fatty acid is of critical importance in determining its effects, as shown by the fact that 16-doxylstearic acid always increased the rate of fusion while 5-doxylstearic acid always decreased the rate of fusion under all conditions tested. A number of different fatty acids, including oleic acid, elaidic acid, 16-doxylstearic acid, myristic acid, and stearic acid, were effective at increasing the fusion rate to varying extents. In general, unsaturated fatty acids were more effective than saturated ones, either due to partitioning into the membrane or because of structural requirements for promotion of fusion.     

Interactions of the low molecular weight group of surfactant-associated proteins (SP 5-18) with pulmonary surfactant lipids

The interaction of the low molecular weight group of surfactant-associated proteins, SP 5-18, with the major phospholipids of pulmonary surfactant was studied by fluorescence measurements of liposomal permeability and fusion, morphological studies, and surface activity measurements. The ability of SP 5-18 to increase the permeability of large unilamellar lipid vesicles was enhanced by the presence of negatively charged phospholipid. The permeability of these vesicles increased as the protein concentration was raised and the pH was lowered. SP 5-18 also induced leakage from liposomes made both from a synthetic surfactant lipid mixture and from lipids separated from SP 5-18 during its purification from canine sources. When SP 5-18 was added to egg phosphatidylglycerol liposomes, the population of liposomes which became permeable leaked all encapsulated contents, while the remaining liposomes did not leak at all. The extent of leakage was higher in the presence of 3 mM calcium. SP 5-18 also induced lipid mixing between two populations of egg phosphatidylglycerol liposomes in the presence of 3 mM calcium, as monitored by resonance energy transfer between two different fluorescent lipid probes, N-(7-nitro-2,1,3-benzoxadiazol-4-yl)phosphatidylethanolamine and N-(lissamine rhodamine B sulfonyl)phosphatidylethanolamine. Negative-staining electron microscopy showed that the addition of SP 5-18 and 3 mM calcium produced vesicles twice the size of control egg phosphatidylglycerol liposomes. In addition, surface balance measurements revealed that the adsorption of liposomal lipids to an air/water interface was enhanced by the presence of SP 5-18, negatively charged phospholipids, and 3 mM calcium. These observations suggest a similar lipid dependence for the interactions observed in the fluorescence and adsorption experiments.     

Temperature-sensitive poly(N-(2-hydroxypropyl)methacrylamide mono/dilactate)-coated liposomes for triggered contents release

We prepared thermosensitive poly( N-(2-hydroxypropyl)methacrylamide mono/dilactate) (pHPMA mono/dilactate) polymer and studied temperature-triggered contents release from polymer-coated liposomes. HPMA mono/dilactate polymer was synthesized with a cholesterol anchor suitable for incorporation in the liposomal bilayers and with a cloud point (CP) temperature of the polymer slightly above normal body temperature (42 degrees C). Dynamic light scattering (DLS) measurements showed that whereas the size of noncoated liposomes remained stable upon raising the temperature from 25 to 46 degrees C, polymer-coated liposomes aggregated around 43 degrees C. Also, noncoated liposomes loaded with calcein showed hardly any leakage of the fluorescent marker when heated to 46 degrees C. However, polymer-coated liposomes showed a high degree of temperature-triggered calcein release above the CP of the polymer. Likely, liposome aggregation and bilayer destabilization are triggered because of the precipitation of the thermosensitive polymer above its CP onto the liposomal bilayers, followed by permeabilization of the liposomal membrane. This study demonstrates that liposomes surface-modified with HPMA mono/dilactate copolymer are attractive systems for achieving temperature-triggered contents release.     

Phospholipase A(2)-catalyzed membrane leakage studied by immobilized liposome chromatography with online fluorescent detection

Unilamellar liposomes composed of phosphatidylcholine with an entrapped self-quenching fluorescent dye, calcein, were immobilized in chromatographic gel beads by avidin-biotin binding. Bee venom phospholipase A(2) (PLA(2)) was applied in a small amount onto the immobilized liposome column. The release of calcein from the immobilized liposomes resulting from the catalyzed hydrolysis of the phospholipids was detected online by immobilized liposome chromatography (ILC) using a flow fluorescent detector. The PLA(2)-catalyzed membrane leakage of the immobilized liposomes as studied with ILC was found to be affected by the gel pore size used for immobilization, by liposome size, and as expected by the concentration of calcium, but was unaffected by the flow rate of ILC. The largest PLA(2)-induced calcein release from the liposome column was detected on large unilamellar liposomes immobilized on TSK G6000PW or Sephacryl S-1000 gel in the presence of 1 mM Ca(2+) in the aqueous mobile phase. Comparison with the PLA(2)-catalyzed membrane leakage in free liposome suspensions, we conclude that the fluorescent leakage from liposomes hydrolyzed by PLA(2) can be rapidly and sensitively detected by ILC runs using large amount of immobilized liposomes with entrapped fluorescent dye.     

The role of calcium in fusion of artificial vesicles.

Small phospholipid vesicles (liposomes) fuse upon calcium addition as demonstrated by electron microscopy, light absorbance increases, and mixing of original liposome contents within the boundaries of the fused liposome. The integrity of the fusion event is demonstrated by a novel assay based on the luminescence of firefly extract when mixed with ATP. Subsequent addition of valinomycin or the calcium ionophore A23187 leads to further fusion as shown by electron microscopy, light microscopy, and additional absorbance increase. Concomitant with this second absorbance increase is an increase in the amount of calcium that associates with the liposomes. This increased calcium association is more than can be accounted for by equilibration of 5 mM Ca2+ across the membrane and must indicate exposure of extra calcium binding sites. Binding of calcium to the inner side of the membrane may catalyze the second stage of liposome fusion.