Sterols and sphingolipids strongly affect the growth of fusion pores induced by the hemagglutinin of influenza virus.

Cells expressing the hemagglutinin (HA) of influenza virus were fused to planar phospholipid bilayer membranes to evaluate the effects of sterols and sphingolipids in the target bilayer membranes on properties of fusion pores. Typically, in the absence of sterol, flickering pores are observed, followed by a successful pore (i.e., a pore that fully opens). The incorporation of cholesterol into the lipid bilayer had a marked effect: it greatly decreased the number of flickers, and the first pore formed was usually successful. Similar effects were produced by the sterols epicholesterol and 5beta-cholestanol. In contrast, the sterols cholesteryl acetate, coprostanol, and stanolone did not affect pore flickering, and a successful pore was observed to follow the typical number of flickers. 5alpha-cholestanol gave intermediate results. From these results, it follows that the 3-OH of cholesterol is essential to reduce flickering, but it does not matter if the 3-OH is in an alpha or beta configuration. The double bond is also not critical for the actions of cholesterol nor is the fact that it is a flat molecule. The sphingolipids sphingomyelin, lactosyl cerebroside, and glucosyl cerebroside tended to inhibit full pore enlargement, prolonging the stage of pore flickering. If a sphingolipid and a sterol that strongly interact were both included in the planar membrane, the pattern of flickering was the same as if neither had been included in the bilayer. However, if a sphingolipid and sterol that do not interact with each other were included in the bilayer, the reduced flickering characteristic of the sterol was observed.

Hemifusion between cells expressing hemagglutinin of influenza virus and planar membranes can precede the formation of fusion pores that subsequently fully enlarge.

The chronological relation between the establishment of lipid continuity and fusion pore formation has been investigated for fusion of cells expressing hemagglutinin (HA) of influenza virus to planar bilayer membranes. Self-quenching concentrations of lipid dye were placed in the planar membrane to monitor lipid mixing, and time-resolved admittance measurements were used to measure fusion pores. For rhodamine-PE, fusion pores always occurred before a detectable amount of dye moved into an HA-expressing cell. However, with DiI in the planar membrane, the relationship was reversed: the spread of dye preceded formation of small pores. In other words, by using DiI as probe, hemifusion was clearly observed to occur before pore formation. For hemifused cells, a small pore could form and subsequently fully enlarge. In contrast, for cells that express a glycosylphosphatidylinositol-anchored ectodomain of HA, hemifusion occurred, but no fully enlarged pores were observed. Therefore, the transmembrane domain of HA is required for the formation of fully enlarging pores. Thus, with the planar bilayer membranes as target, hemifusion can precede pore formation, and the occurrence of lipid dye spread does not preclude formation of pores that can enlarge fully.

Effects of spontaneous bilayer curvature on influenza virus-mediated fusion pores.

Cells expressing the hemagglutinin protein of influenza virus were fused to planar bilayer membranes containing the fluorescent lipid probes octadecylrhodamine (R18) or indocarbocyanine (DiI) to investigate whether spontaneous curvature of each monolayer of a target membrane affects the growth of fusion pores. R18 and DiI lowered the transition temperatures for formation of an inverted hexagonal phase, indicating that these probes facilitate the formation of negative curvature structures. The probes are known to translocate from one monolayer of a bilayer membrane to the other in a voltage-dependent manner. The spontaneous curvature of the cis monolayer (facing the cells) or the trans monolayer could therefore be made more negative through control of the polarity of voltage across the planar membrane. Electrical admittance measurements showed that the open times of flickering fusion pores were shorter when probes were in trans monolayers and longer when in cis monolayers compared with times when probe was symmetrically distributed. Open times were the same for probe symmetrically distributed as when probes were not present. Thus, open times were a function of the asymmetry of the spontaneous curvature between the trans and cis monolayers. Enriching the cis monolayer with a negative curvature probe reduced the probability that a small pore would fully enlarge, whereas enriching the trans monolayer promoted enlargement. Lysophosphatidylcholine has positive spontaneous curvature and does not translocate. When lysophosphatidylcholine was placed in trans leaflets of planar membranes, closing of fusion pores was rare. The effects of the negative and positive spontaneous curvature probes do not support the hypothesis that a flickering pore closes from an open state within a hemifusion diaphragm (essentially a "flat" structure). Rather, such effects support the hypothesis that the membrane surrounding the open pore forms a three-dimensional hourglass shape from which the pore flickers shut.

Saccharide-assisted delivery of cytotoxic liposomes to human malignant cells.

The overexpression of lectins by malignant cells was applied for in vitro targeting of liposomes equipped with a saccharide vector and loaded in the lipid phase with a lipid derivative of anticancer agent sarcolysine. The lectin specificity of human leukemia HL-60 and human lung adenocarcinoma ACL cells was revealed by tests with fluorescein-labeled sugar probes. With the help of fluorescent lipid dye it was shown that active saccharide ligands increased the level of the vectored liposome binding to malignant cells by 50-80% as compared to liposomes without vector or with inactive one. The degree of liposome/cell membrane fusion was monitored fluorometrically and was shown to be complete and independent of the vectors. The targeted drug-loaded liposomes had the cytotoxic activity 2-4 times higher as compared to the vector-free ones.

New fluorescent lysolipids: preparation and selective labeling of inner liposome leaflet.

Two new fluorescent lysophosphatidylcholine probes have been synthesized for use as a donor-acceptor pair in fluorescence resonance energy transfer (FRET): 9-anthrylvinyl (LAPC) as donor and 3-perylenoyl (LPPC) as acceptor. The partition coefficients between membrane and aqueous phases were 8.3 x 10(5) and 10.5 x 10(5) for LAPC and LPPC, respectively. The inner leaflets of unilamellar lipid vesicles were labeled with these probes to assess conservation of membrane sidedness after membrane fusion. After medium-sized unilamellar vesicles (MUV) were prepared with a probe in both leaflets, probe in the outer leaflet was removed by repeatedly washing with an excess of unlabeled giant unilamellar vesicles (GUV). MUV and GUV were separated by centrifugation. The probes did not flip-flop across bilayers at 25 degrees C for at least 12 h. MUV containing the ganglioside GT1b were labeled with the LAPC/LPPC pair in the inner leaflet and incubated for 30 min at neutral pH with influenza virus. Fusion was triggered by acidification to pH 5.0 and was monitored by an increase in donor fluorescence in a FRET assay. When the inner leaflets of MUV were labeled by LAPC only, its fluorescence did not change after fusion. However, the fluorescence decreased by 60% when the LAPC was removed from the outer leaflets of the fused membranes by repeated washings with GUV. We conclude that the lipids of the inner and outer leaflets of the fused MUV/virus complexes intermixed.

Selective labeling of the inner liposome leaflet by fluorescent lipid probes, and studies of liposome fusion with influenza virus.

The inner leaflet of unilamellar lipid vesicles was labeled with fluorescent lysophosphatidylcholines. The probes make a donor-acceptor pair in resonance energy transfer (RET), being labeled with 9-anthrylvinyl (L-APC, donor) and 3-perylenoyl (L-PPC, acceptor) fluorophores. They migrate rapidly between bilayers through the water phase: tau 1/2 of equilibration is approximately 5 min at 37 degrees C. The probe(s) can be removed from the outer leaflet of uniformly labeled medium-size unilamellar vesicles (MUV) by repeated washings with excess unlabeled large unilamellar vesicles (LUV) (separation by centrifugation). The probes flip-flop across bilayers rather slowly. MUV containing the ganglioside GT1b and labeled with the L-APC/L-PPC pair in the inner leaflet were fused with an equal amount of influenza virus; the process was monitored by an increase of the donor fluorescence in RET assay. If inner MUV leaflet was labeled with the anthrylvinyl probe only, the probe fluorescence decreased by half when the probe was removed from the outer leaflets of the fused membranes. This shows that the lipids of the inner and outer leaflets of the MUV randomize in the process of fusion.