Use of a dialyzable short-chain phospholipid for efficient solubilization and reconstitution of influenza virus envelopes

Virosomes are reconstituted viral envelopes that can serve as vaccines and as vehicles for cellular delivery of various macromolecules. To further advance the use of virosomes, we developed a novel dialysis procedure for the reconstitution of influenza virus membranes that is easily applicable to industrial production and compatible with encapsulation of a variety of compounds. This procedure relies on the use of 1,2-dicaproyl-sn-glycero-3-phosphocholine (DCPC) as a solubilizing agent. DCPC is a short-chain lecithin with detergent-like properties and with a critical micelle concentration of 14 mM. DCPC effectively dissolved the influenza virus membranes after which the nucleocapsids could be removed by ultracentrifugation. The solubilized membrane components were reconstituted either by removal of DCPC by dialysis or by a procedure involving initial dilution of the solubilized membrane components followed by dialysis. Both protocols resulted in removal of 99.9% of DCPC and simultaneous formation of virosomes. Analysis of the virosome preparations by equilibrium sucrose density gradient centrifugation revealed co-migration of phospholipid and protein for virosomes produced by either method. Moreover, both virosome preparations showed morphological and fusogenic characteristics similar to native influenza virus. Size, homogeneity and spike density of the virosomes varied with the two different reconstitution procedures employed. The recovery of viral membrane proteins and phospholipids in the virosomes was found to be higher for the dilution/dialysis procedure than for the simple dialysis protocol. This novel procedure for the production of virosomes is straightforward and robust and allows further exploitation of virosomes as vaccines or as drug delivery vehicles not only in academia, but also in industrial settings.     

Cellular gene transfer mediated by influenza virosomes with encapsulated plasmid DNA

Reconstituted influenza virosomes (virus membrane envelopes) have been used previously to deliver pDNA (plasmid DNA) bound to their external surface to a variety of target cells. Although high transfection efficiencies can be obtained with these complexes in vitro, the virosome-associated DNA is readily accessible to nucleases and could therefore be prone to rapid degradation under in vivo conditions. In the present study, we show a new method for the production of DNA-virosomes resulting in complete protection of the DNA from nucleases. This method relies on the use of the short-chain phospholipid DCPC (dicaproylphosphatidylcholine) for solubilization of the viral membrane. The solubilized viral membrane components are mixed with pDNA and cationic lipid. Reconstitution of the viral envelopes and simultaneous encapsulation of pDNA is achieved by removal of the DCPC from the mixture through dialysis. Analysis by linear sucrose density-gradient centrifugation revealed that protein, phospholipid and pDNA physically associated to particles, which appeared as vesicles with spike proteins inserted in their membranes when analysed by electron microscopy. The DNA-virosomes retained the membrane fusion properties of the native influenza virus. The virosome-associated pDNA was completely protected from degradation by nucleases, providing evidence for the DNA being highly condensed and encapsulated in the lumen of the virosomes. DNA-virosomes, containing reporter gene constructs, transfected a variety of cell lines, with efficiencies approaching 90%. Transfection was completely dependent on the fusogenic properties of the viral spike protein haemagglutinin. Thus, DNA-virosomes prepared by the new procedure are highly efficient vehicles for DNA delivery, offering the advantage of complete DNA protection, which is especially important for future in vivo applications.     

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.     

Targeting influenza virosomes to ovarian carcinoma cells.

Reconstituted influenza virus envelopes (virosomes) containing the viral hemagglutinin (HA) have attracted attention as delivery vesicles for cytosolic drug delivery as they possess membrane fusion activity. Here, we show that influenza virosomes can be targeted towards ovarian carcinoma cells (OVCAR-3) with preservation of fusion activity. This was achieved by incorporating poly(ethylene glycol) (PEG)-derivatized lipids into the virosome membrane. This PEG layer serves as shield to prevent interaction of HA with ubiquitous sialic acid residues and as spatial anchor for antibody attachment. Coupling of Fab' fragments of mAb 323/A3 (anti-epithelial glycoprotein-2) to the distal ends of PEG lipids resulted in specific binding of virosomes to OVCAR-3 cells. These antibody-redirected virosomes fused with membranes of OVCAR-3 cells in a pH-dependent fashion.     

Virosomes in vaccine development: induction of cytotoxic T lymphocyte activity with virosome-encapsulated protein antigens

Virosomes are reconstituted viral envelopes which lack the genetic material but retain the cell entry and membrane fusion characteristics of the virus they are derived from. Thus, influenza virosomes are taken up by cells via receptor-mediated endocytosis, which directs the particles to the endosomal cell compartment. Subsequently, the virosomal membrane fuses with the endosomal membrane induced by the mildly acidic pH within the endosomes. This fusion process establishes continuity between the lumen of the virosome and the cell cytosol. Upon interaction of virosomes with antigen-presenting cells (APCs), protein antigens encapsulated within virosomes will be delivered to the cell cytosol, and thus, into the MHC class I presentation pathway. Indeed, virosome-mediated delivery of antigens in vivo results in efficient priming of a class I MHC-restricted cytotoxic T lymphocyte (CTL) response.     

VIROSOMES IN VACCINE DEVELOPMENT: INDUCTION OF CYTOTOXIC T LYMPHOCYTE ACTIVITY WITH VIROSOME-ENCAPSULATED PROTEIN ANTIGENS

ABSTRACT

Virosomes are reconstituted viral envelopes which lack the genetic material but retain the cell entry and membrane fusion characteristics of the virus they are derived from. Thus, influenza virosomes are taken up by cells via receptor-mediated endocytosis, which directs the particles to the endosomal cell compartment. Subsequently, the virosomal membrane fuses with the endosomal membrane induced by the mildly acidic pH within the endosomes. This fusion process establishes continuity between the lumen of the virosome and the cell cytosol. Upon interaction of virosomes with antigen-presenting cells (APCs), protein antigens encapsulated within virosomes will be delivered to the cell cytosol, and thus, into the MHC class I presentation pathway. Indeed, virosome-mediated delivery of antigens in vivo results in efficient priming of a class I MHC-restricted cytotoxic T lymphocyte (CTL) response.     

Preservation of influenza virosome structure and function during freeze-drying and storage

Virosomes derived from influenza virus are reconstituted viral envelopes, which retain the receptor-binding and cell entry properties of the native virus, but lack the viral genetic material. These virosomes are of interest because of their potential use as vaccines or cellular delivery systems. However, in aqueous dispersion influenza virosomes have a relatively poor stability. Although freeze-drying of the virosomes could improve their stability, a lyoprotectant is required to preserve the structure and function of the virosomes during the lyophilization process as well as during subsequent storage of the dry powder formulation. In this study, inulin, a medium-chain oligosaccharide, was identified as an effective stabilizer of influenza virosomes. When inulin was added to an aqueous virosomal dispersion, the vesicular structure of the virosomes, with spike proteins protruding from the virosomal surface, as well as their membrane fusion activity were completely preserved during freeze-drying. When the freeze-drying process was performed from dispersions lacking a lyoprotectant, both structure and fusogenic properties of the virosomes were lost. Moreover, it was shown that the immunogenicity of inulin-stabilized virosomes was preserved. For example, dry powder formulations of virosomes retained HA potency for at least 12 weeks at 20 degrees C. Virosomes with encapsulated pDNA encoding for the eGFP reporter gene were also found to be stabilized by inulin. The fusion capacity and the transfection efficacy (determined in BHK-21 cells) could be preserved for 12 weeks during storage at 4 degrees C. It is concluded that freeze-drying in the presence of inulin as a lyoprotectant completely preserves the structure and function of influenza virosomes.     

Preservation of Influenza Virosome Structure and Function During Freeze-Drying and Storage

Virosomes derived from influenza virus are reconstituted viral envelopes, which retain the receptor-binding and cell entry properties of the native virus, but lack the viral genetic material. These virosomes are of interest because of their potential use as vaccines or cellular delivery systems. However, in aqueous dispersion influenza virosomes have a relatively poor stability. Although freeze-drying of the virosomes could improve their stability, a lyoprotectant is required to preserve the structure and function of the virosomes during the lyophilization process as well as during subsequent storage of the dry powder formulation. In this study, inulin, a medium-chain oligosaccharide, was identified as an effective stabilizer of influenza virosomes. When inulin was added to an aqueous virosomal dispersion, the vesicular structure of the virosomes, with spike proteins protruding from the virosomal surface, as well as their membrane fusion activity were completely preserved during freeze-drying. When the freeze-drying process was performed from dispersions lacking a lyoprotectant, both structure and fusogenic properties of the virosomes were lost. Moreover, it was shown that the immunogenicity of inulin-stabilized virosomes was preserved. For example, dry powder formulations of virosomes retained HA potency for at least 12 weeks at 20°C. Virosomes with encapsulated pDNA encoding for the eGFP reporter gene were also found to be stabilized by inulin. The fusion capacity and the transfection efficacy (determined in BHK-21 cells) could be preserved for 12 weeks during storage at 4°C. It is concluded that freeze-drying in the presence of inulin as a lyoprotectant completely preserves the structure and function of influenza virosomes.     

Delivery of Foreign Substances to Cells Mediated by Fusion-Active Reconstituted Influenza Virus Envelopes (Virosomes)

Abstract

This paper presents a survey of the properties and applications of reconstituted influenza virus envelopes (virosomes). Influenza virosomes can be reconstituted from the original viral membrane lipids and spike glycoproteins, after solubilization of intact virus with octaethyleneglycol monododecyl ether (C₁₂E₈) and removal of this detergent with a hydrophobic resin (BioBeads SM-2). These virosomes are functionally active, i.e their membrane fusion activity closely mimics the well-defined low-pH-dependent membrane fusion activity of the intact virus, which is solely mediated by the viral hemagglutinin (HA). By virtue of their fusion activity, virosomes represent a powerful carrier system for cellular delivery of foreign substances, encapsulated in their aqueous interior or co-reconstituted in their membranes. Delivery of an encapsulated, water-soluble, compound is illustrated with data on the toxin gelonin. Protein synthesis in BHK-21 cells in culture is efficiently inhibited when gelonin-containing virosomes fuse from within endosomes, after internalization via receptor-mediated endocytosis, or are induced to fuse with the plasma membrane by a transient lowering of the pH in the medium. The results indicate that delivery is quite efficient; as much as 6 × 10³ molecules of gelonin can readily be delivered to the cytoplasm of a single cell by fusion with gelonin-containing virosomes.     

Reconstitution and fusogenic properties of Sendai virus envelopes

Sendai virus membranes were reconstituted by detergent dialysis, using the non-ionic detergents Triton X-100 and octyl glucoside. Membrane reassembly was determined by measuring the surface-density-dependent efficiency of resonance energy transfer between two fluorescent phospholipid analogues, which were co-reconstituted with the viral envelopes. The functional incorporation of the viral proteins was established by monitoring the ability of the reconstitution products to fuse with erythrocyte membranes, utilizing assays based on either resonance energy transfer or on relief of fluorescence selfquenching. The persistent adherence of residual Triton X-100 with the reconstituted membrane was revealed by an artificial detergent-effect on the resonance energy transfer efficiency and the occurrence of hemolysis of human erythrocytes under conditions where fusion does not occur. Properly reconstituted Sendai virus envelopes were obtained with octyl glucoside. The fusion activity of the viral envelopes was dependent on the initial concentration of octyl glucoside used to disrupt the virus and the rate of detergent removal. Rapid removal of detergent by dialysis against large volumes of dialysis buffer (ratio 1:850) or by gel filtration produced reconstituted membranes capable of inducing hemagglutination but significant fusion activity was not detected. By decreasing the volume ratio of dialysate versus dialysis buffer to 1:250 or 1:25, fusogenic viral envelopes were obtained. The initial fusion kinetics of the reconstituted viral membrane and the parent virus were different in that both the onset and the initial rate of fusion of the reconstituted membranes were faster, whereas the extents to which both particles eventually fused with the target membrane were similar. The differences in the initial fusion kinetics lead us to suggest that the details of the fusion mechanism between Sendai virus and the target membrane involve factors other than the mere presence of glycoproteins F and HN in the viral bilayer. Finally, the results also indicate that determination of the viral fusion activity in a direct manner, rather than by an indirect assay, such as hemolysis, is imperative for a proper evaluation of the functional properties retained upon viral reconstitution.     

A novel chimeric influenza virosome containing <Emphasis Type="Italic">Vesicular stomatitis</Emphasis> G protein as a more efficient gene delivery system

Objectives

To enhance the efficiency of influenza virosome-mediated gene delivery by engineering this virosome.

Results

A novel chimeric influenza virosome was constructed containing the glycoprotein of Vesicular stomatitis virus (VSV-G), along with its own hemagglutinin protein. To optimize the transfection efficiency of both chimeric and influenza cationic virosomes, HEK cells were transfected with plasmid DNA and virosomes and the transfection efficiency was assessed by FACS analysis. The chimeric virosome was significantly more efficient in mediating transfection for all amounts of DNA and virosomes compared to the influenza virosome.

Conclusions

Chimeric influenza virosome, including VSV-G, is superior to the conventional influenza virosome for gene delivery.

     

Reconstitution of liver endoplasmic reticulum membranes from solubilized proteins and lipids by removal of detergent]

A method for membrane reconstitution from cholate-solubilized microsomal proteins and lipids by a removal of the detergent on a column with charcoal has been developed. A comparative study showed that the membranes reconstituted by a dialysis or absorption do not differ from each other in terms of membrane proteins incorporation into lipid vesicles and cytochrome P-450 reconversion into cytochrome P-450. A possibility of biomembrane reconstitution from membrane proteins and lipids solubilized by a non-ionic detergent Triton X-100 was shown. A removal of the detergent results in a formation of membranes, which are chemically close to the original ones but ultrastructurally very different from the latter. On the other hand, absorption or dialysis of cholate-solubilized proteins and lipids results in reconstituted membranes with asymmetrically arranged intramembrane particles located on the hydrophobic surfaces of the membrane halves. The number and size of these particles are similar to those of the original microsomal membranes.     

pH-dependent fusion of reconstituted vesicular stomatitis virus envelopes with Vero cells. Measurement by dequenching of fluorescence

Reconstituted vesicular stomatitis virus (VSV) envelopes were formed by solubilization of the viral envelope with Triton X-100 followed by removal of detergent by direct addition of SM2 biobeads. We provide direct demonstration of fusion of reconstituted VSV with cells using fluorescent lipid and aqueous probes incorporated into the VSV virosomes during reconstitution. We show a direct comparison of the kinetics and pH profile of fusion with cells between reconstituted VSV and fluorescently labeled intact virus. With this preparation it is now possible to gain additional information about the role of cooperativity in viral protein-mediated fusion, and to permit construction of efficient vehicles for delivery of drugs and other materials into cells.     

Influenza virosomes: a flu jab for malaria?

The major attractions of vaccines based on viral carriers (vectors) include their immunogenicity without adjuvant and the relative simplicity of their associated production processes in comparison with recombinant protein-based approaches. Two influenza virosomal vaccines - for influenza and hepatitis A - are registered for human use, and the virosome platform is being evaluated as the carrier for a Plasmodium falciparum vaccine that targets both the exo-erythrocytic and erythrocytic stages. Although safe and immunogenic, the first such virosome-based malaria vaccine showed no protection in a Phase IIa clinical trial. Nevertheless, the established safety profile of virosomes and their flexibility with regard to antigen delivery - allowing for antibody induction via the conjugation of peptides and T-cell induction via encapsulation - indicate that they warrant further exploration.     

Critical factors for liposome-incorporated tumour-associated antigens to induce protective tumour immunity to SL2 lymphoma cells in mice

Physical and immunogenic properties of reconstituted membranes designed for the presentation of tumour-associated antigens (TAA) to the immune system are described. Proteins and lipids of crude membranes of SL2 murine lymphosarcoma cells were partially solubilized with octylglucoside. Reconstituted membranes, consisting mainly of unilamellar vesicles with a diameter of 0.03–0.15 μm, were formed by detergent removal and were purified by floatation in a discontinuous sucrose gradient to remove non-lipid-bound protein. Subcutaneous immunization of syngeneic mice with reconstituted membranes or with purified reconstituted membranes induced protection against an intraperitoneal challenge with 10³ viable SL2 cells. Reconstituted membranes were more immunogenic than crude membranes in immunoprotection experiments when compared on the basis of protein dose. Detergent removal was required to obtain an immunogenic presentation form of SL2 membrane antigens and to avoid toxicity associated with the detergent. Reconstitution of SL2 membranes in the presence of exogenous phospholipid slightly increased the fraction of protein that associated with the reconstituted membranes. However, the immunogenicity of the solubilized membrane TAA was not significantly affected by the presence of exogenous phospholipid. The reconstitution procedure described may be useful in identifying membrane factors required for the induction of immune responses against TAA. The versatility of the system may be employed to develop safe alternatives for whole-cell vaccines.     

Lipid composition of virosomes modulates their fusion efficiency with cryopreserved bull sperm cells

Virosomes derived from different fusogenic enveloped viruses have been generated for potential application in gene targeting to sperm cells. Comparative characterization of reconstitution products revealed that virosomes derived from influenza viruses are superior to those generated from Sendai viruses, with respect to the fusion rates with cryopreserved bull sperm cells and to sperm cell vitality after fusion. Modulation of the lipid composition during virosome reconstitution affects fusion sites on target sperms and allows optimization of the fusion rate and sperm cell vitality. A fluorescence-based microscopic fusion assay combined with a vital cell stain revealed that about 90% of sperm cells fused with influenza virosomes containing exogenous cholesterol, sphingomyelin, phosphatidylcholine, and phosphatidylethanolamine. About 85% of the fused sperm cells remained vital. Such optimized influenza-derived virosomes provide the basis for ongoing experiments, which aim at eventually generating biologically active transgenic sperms.     

Cellular Delivery of siRNA Mediated by Fusion-Active Virosomes

RNA interference is expected to have considerable potential for the development of novel specific therapeutic strategies. However, successful application of RNA interference in vivo will depend on the availability of efficient delivery systems for the introduction of small-interfering RNA (siRNA) into the appropriate target cells. This paper focuses on the use of reconstituted viral envelopes (“virosomes”), derived from influenza virus, as a carrier system for cellular delivery of siRNA. Complexed to cationic lipid, siRNA molecules could be efficiently encapsulated in influenza virosomes. Delivery to cultured cells was assessed on the basis of flow cytometry analysis using fluorescently labeled siRNA. Virosome-encapsulated siRNA directed against Green Fluorescent Protein (GFP) inhibited GFP fluorescence in cells transfected with a plasmid encoding GFP or in cells constitutively expressing GFP. Delivery of siRNA was dependent on the low-pH-induced membrane fusion activity of the virosomal hemagglutinin, supporting the notion that virosomes introduce their encapsulated siRNA into the cell cytosol through fusion of the virosomal membrane with the limiting membrane of cellular endosomes, after internalization of the virosomes by receptor-mediated endocytosis. It is concluded that virosomes represent a promising carrier system for cellular delivery of siRNA in vitro as well as in vivo.     

Cellular delivery of siRNA mediated by fusion-active virosomes

RNA interference is expected to have considerable potential for the development of novel specific therapeutic strategies. However, successful application of RNA interference in vivo will depend on the availability of efficient delivery systems for the introduction of small-interfering RNA (siRNA) into the appropriate target cells. This paper focuses on the use of reconstituted viral envelopes ("virosomes"), derived from influenza virus, as a carrier system for cellular delivery of siRNA. Complexed to cationic lipid, siRNA molecules could be efficiently encapsulated in influenza virosomes. Delivery to cultured cells was assessed on the basis of flow cytometry analysis using fluorescently labeled siRNA. Virosome-encapsulated siRNA directed against Green Fluorescent Protein (GFP) inhibited GFP fluorescence in cells transfected with a plasmid encoding GFP or in cells constitutively expressing GFP. Delivery of siRNA was dependent on the low-pH-induced membrane fusion activity of the virosomal hemagglutinin, supporting the notion that virosomes introduce their encapsulated siRNA into the cell cytosol through fusion of the virosomal membrane with the limiting membrane of cellular endosomes, after internalization of the virosomes by receptor-mediated endocytosis. It is concluded that virosomes represent a promising carrier system for cellular delivery of siRNA in vitro as well as in vivo.     

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.     

Functional reconstitution of the integral membrane proteins of influenza virus into phospholipid liposomes

The integral membrane proteins of influenza virus, a hemagglutinin and a neuraminidase, have been incorporated into liposomes composed of either phosphatidylcholine or a mixture of phosphatidylcholine and phosphatidylethanolamine (2:1 w/w) using detergent dialysis. The virus spike glycoproteins for reconstitution were selectively solubilized by using cetyltrimethylammonium bromide to leave a "core particle", which lacked a lipid bilayer but possessed quaternary structure as observed by electron microscopy. The viral spike proteins were combined with exogenous phospholipid in excess sodium cholate followed by exhaustive dialysis for 150 h. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that only the viral glycoproteins were associated with all the complexes formed. The level of sodium cholate remaining after dialysis was shown to be reduced to less than 1 molecule per 80 protein molecules. Viral proteins reconstituted into dimyristoylphosphatidylcholine liposomes were shown to have retained hemagglutination, low-pH-dependent hemolysis, and neuraminidase activities and were associated with a lipid bilayer in two types of complexes with average lipid to protein mole ratios after sucrose density gradient purification of either 590:1 or 970:1. The bilayer vesicles formed were of similar sizes and were shown by negative-stain electron microscopy to be 150-300 nm in diameter with well-defined spikes on their surface. Reconstituted liposomes of dimyristoylphosphatidylcholine were found to be unstable with respect to their trapped volume and therefore were unsuitable for fusion studies, unlike complexes formed with phosphatidylcholine or a mixture of phosphatidylcholine/phosphatidylethanolamine derived from hen eggs.(ABSTRACT TRUNCATED AT 250 WORDS)