Phosphatidylinositol may serve as the hydrophobic anchor for immobilization of proteins on liposome surface

Multifunctional, stimuli-sensitive nanoparticulate systems for drug delivery

The use of nanoparticulate pharmaceutical drug delivery systems (NDDSs) to enhance the in vivo effectiveness of drugs is now well established. The development of multifunctional and stimulus-sensitive NDDSs is an active area of current research. Such NDDSs can have long circulation times, target the site of the disease and enhance the intracellular delivery of a drug. This type of NDDS can also respond to local stimuli that are characteristic of the pathological site by, for example, releasing an entrapped drug or shedding a protective coating, thus facilitating the interaction between drug-loaded nanocarriers and target cells or tissues. In addition, imaging contrast moieties can be attached to these carriers to track their real-time biodistribution and accumulation in target cells or tissues. Here, I highlight recent developments with multifunctional and stimuli-sensitive NDDSs and their therapeutic potential for diseases including cancer, cardiovascular diseases and infectious diseases.

Current methods for attaching targeting ligands to liposomes and nanoparticles

Liposomes and nanoparticles have emerged as versatile carrier systems for delivering active molecules in the organism. These colloidal particles have demonstrated enhanced efficacy compared to conventional drugs. However, the design of liposomes and nanoparticles with a prolonged circulation time and ability to deliver active compounds specifically to target sites remains an ongoing research goal. One interesting way to achieve active targeting is to attach ligands, such as monoclonal antibodies or peptides, to the carrier. These surface-bound ligands recognize and bind specifically to target cells. To this end, various techniques have been described, including covalent and noncovalent approaches. Both in vitro and in vivo studies have proved the efficacy of the concept of active targeting. The present review summarizes the most common coupling techniques developed for binding homing moieties to the surface of liposomes and nanoparticles. Various coupling methods, covalent and noncovalent, will be reviewed, with emphasis on the major differences between the coupling reactions, on their advantages and drawbacks, on the coupling efficiency obtained, and on the importance of combining active targeting with long-circulating particles.

Development of a membrane strip immunosensor utilizing ruthenium as an electro-chemiluminescent signal generator

A photometric immunosensor that can be used for on-site diagnosis has been constructed. The sensor system was assembled by partially superimposing a nitrocellulose membrane strip (the lower) containing an immobilized antigen on the surface with a glass fiber membrane strip (the upper) including two electrodes on the opposite surfaces. To amplify the signal, we introduced a liposome, containing ruthenium molecules trapped in the core, chemically coupled to an antibody specific to the analyte (e.g. Legionella antigen). In the presence of the analyte, immune complexes were formed by antigen-antibody reactions upon addition of the immuno-liposome into a sample. This mixture was then absorbed by the capillary action from the bottom of the membrane strip. The liposome particles in the complexes were carried by a medium through the antigen pad without interaction, while free immuno-liposome was trapped by immune reactions on the pad surfaces. The aqueous medium influx into the glass pad dissolved a detergent pre-located within the compartment and the liposome rupture thereby released ruthenium molecules into the solution. The molecules were oxidized on the electrode surfaces and produced an electro-chemiluminescence (ECL) in proportion to the analyte concentration. The signal generation based on ECL resulted in an exponential dose-response pattern and the analyte detection limit of 2 ng/ml was approximately 10-fold more sensitive than that obtained from a conventional system.

Affinity liposomes in vivo: factors influencing target accumulation

To make universal and efficient liposome-based drug carriers, liposomes should be able to recognize and bind other targets beyond their natural targets, the cells of the reticuloendothial system. To make liposomes targeted, numerous methods to couple active substances, primarily, monoclonal antibodies, to the liposome surface have been developed. Resulting immunoliposomes (or affinity liposomes) demonstrate good targeting to cells and organs both in vitro and in vivo. However, the short circulation time of immunoliposomes prevented them from accumulating in targets with diminished blood flow or low antigen concentration. Long-circulating liposomes were prepared by coupling soluble and flexible polymers, such as polyethylene glycol, to the liposome surface. The mechanism of liposome steric protection with flexible polymers is based on the formation of dense "conformational cloud' by a grafted polymer over the liposome surface, and might be analyzed in terms of a statistical model of polymer solutions. By co-immobilization of specific antibodies and protecting polymers on the liposome surface, liposomes can be prepared combining both targetability and prolonged circulation in vivo. A biological model (experimental myocardial infarction in rabbit) was used to estimate the relative importance of different factors (liposome size and coating with protective polymer and/or specific antibody) for effective accumulation of liposomes in the target. Statistical analysis demonstrated that different types of liposomes have to be used in order to reach maximum absolute delivery of liposomes to the target, or maximum target-to-non-target ratio (relative delivery). Therefore, different liposomes should be used as carriers of diagnostic and therapeutic agents.

The use of streptavidin-biotin interaction for preparation of reagents for complement-dependent liposome immunoassay of proteins: detection of latrotoxin

We have developed liposome sensitization by a protein, latrotoxin (LT), using immobilization of biotinylated LT via streptavidin with biotinylated phosphatidylethanolamine contained in liposomes. The use of such liposomes in the complement-dependent homogeneous liposome immune lysis assay (LILA) has allowed us to detect in the test sample as little as 2 micrograms/ml of polyclonal and 50-100 ng/ml of monoclonal IgG and IgM antibodies to LT. LT concentration in solution was determined by inhibition of immune lysis by free LT. The sensitivity of the LT assay varied from 1 x 10(-9) to 5-50 x 10(-9) M when antiserum (polyclonal antibodies) and monoclonal antibodies to LT were correspondingly used. The results show that a streptavidin-biotin spacer can be used to immobilize protein antigens on liposomes for a subsequent application in LILA. The suggested technique greatly simplifies the sensitization procedure and extends the applicability of the LILA.

Synthetic lipid-anchored receptors based on the binding site of a monoclonal antibody

Highly specific ligand receptor interactions generally characterize molecular recognition at cell surfaces and other biological systems. In this study we simulate a membrane receptor by fusing a monoclonal antibody fragment to a phospholipid. A sulfhydryl group in the hinge region of a monoclonal antibody fragment, was covalently linked to derivatives of phosphatidylethanolamines and phosphatidylserine via three different hydrophilic spacer arms. We investigated and characterized these lipid-anchored Fab-fragments which we have named 'Fab-lipids' in liposomal and monolayer systems. Methods for the monomolecular assembling of such films at the air/water interface and techniques used for their manipulation are outlined. We describe two possibilities for building a monomolecular receptor layer, consisting of two-dimensional pattern of oriented Fab-fragments with their artificial hydrophobic anchor embedded in a lipid matrix. In the first method a monomolecular film at the air/water interface was allowed to form from a vesicular suspension and driven into a phase separation, resulting in protein rich domains embedded in a protein depleted phase. This film was transferred onto a solid support in such a way that the established pattern was preserved. Alternatively, a recognition pattern was formed by directly cross-linking the Fab-fragments to preformed planar membranes composed of the reactive spacer-lipids and an inert matrix lipid. Specificity as well as contrast of the binding activity of the receptor layers were qualified using micro-fluorimetry.

Lectin-bearing liposomes: differential binding to normal and to transformed mouse fibroblasts

The binding of covalent conjugates of concanavalin A (Con A) or wheat germ agglutinin (WGA) and liposomes (lectin-liposomes) to the surface of normal and transformed mouse fibroblasts was studied. Quantitation of the binding was performed by means of microfluorometry and radioactive lipid label counting using both sparse and dense cell cultures. It was found that 2.5-3 times more lectin-conjugated liposomes are bound to L or SV3T3 cells than to the mouse embryo fibroblasts and 3T3 cells in a broad concentration range. The binding of Con A- and WGA-liposomes was inhibited up to 70% in the presence of the corresponding carbohydrate inhibitors. A decreased binding of lectin-liposomes to cells was also observed when cells were pretreated with the free lectin. Trypsinization of the cells resulted in an increase in the Con A-liposomes binding to normal fibroblasts. When free fluorescent Con A or WGA was used in binding studies no profound differences in the binding of lectin to normal or transformed cells were detected. The relation of the lectin-liposome/cell to cell/cell interactions is discussed.

Protein immobilization on the surface of liposomes via carbodiimide activation in the presence of N-hydroxysulfosuccinimide

A method of the covalent immobilization of proteins on the surface of liposomes, containing 10% (by mol) of N-glutaryl phosphatidylethanolamine, is described. Carboxylic groups of liposomal N-glutaryl phosphatidylethanolamine were activated in the presence of water-soluble carbodiimide and N-hydroxysulfosuccinimide and reacted subsequently with protein amino groups. The liposome-protein conjugates formed contained up to 5 x 10(-4) mol protein/mol lipid. Lectins (RCA1 and WGA) upon immobilization on liposomes retained saccharide specificity and the ability to agglutinate red blood cells. The immobilization of mouse monoclonal IgG in a ratio of 3.5 x 10(-4) mol IgG/mol lipid was achieved. The liposome activation in the absence of N-hydroxysulfosuccinimide resulted in a 2-fold decrease of protein coupling yields.

The role of multivalency in antibody mediated liposome targeting

We have investigated the role of multivalency in immunoliposome binding to cells displaying different amounts of surface antigen using liposomes with increasing numbers of palmitoyl anti-H2Kk antibodies incorporated into the bilayer. RDM-4 lymphoma cells were treated with proteinase k to generate a series of cells with various amounts of H2Kk antigen. Percent binding of immunoliposomes was related to the number of antigens displayed by the RDM-4 cell. Increasing liposome binding was observed with increasing number of antibody molecules per liposome. However, the ratio of binding of the high-antigen-density cells to that of the low-antigen-density cells was higher with immunoliposomes of lower antibody density than the ones with higher antibody density. This result suggests that for better discrimination between cells differing in antigen density, liposomes with lower numbers of antibody molecules per liposome may be more useful as a discriminatory tool for cells with a low level antigen expression than liposomes with greater antibody densities.

The development and application of protein-liposome conjugation techniques

Numerous techniques have been developed over the past 10 years for the conjugation of proteins to liposomes. Early procedures involved coupling with reagents such as glutaraldehyde or EDCI. Subsequently, more sophisticated approaches involving selective bifunctional coupling agents have been developed. These later procedures are also much more efficient for coupling in aqueous media. The techniques of coupling have become more rigorous because investigators have recognized the inherent problems of producing, purifying and characterizing protein conjugated liposomes. Protein-liposome coupling techniques were developed mainly for targeted drug delivery. The attachment of specific antibodies to the surface of the liposomes makes them able to bind to cells and to subsequently be internalised by the cells. Protein conjugated liposomes have also been used for various immunochemical and diagnostic purposes. These include the binding of labelled liposomes to cells and the agglutination of cells or latex particles by protein conjugated liposomes.

Evaluation of quantitative parameters of the interaction of antibody-bearing liposomes with target antigens

The model system for the analysis of targeted liposomes is proposed--the layer of protein antigen adsorbed on polystyrene wells. Antibodies were treated with palmitoyl chloride and liposomes were produced by the cholate dialysis method in the presence of the modified protein (7 X 10(-4) mol protein/mol lipid). Affinity of antibody-bearing liposomes to the antigen on the surface of Multiwell plates was studied, and apparent dissociation constant value was estimated: KD was in the range 1.5 to 5 X 10(-9) M liposomes. Sequential transfers of liposomes in antigen-coated plates revealed that the high-affinity fraction of liposomes is adsorbed first. The bound fraction has 1.7-times-higher protein content. For effective in vivo targeting it would be necessary to have high-affinity liposomes and a high concentration of the target antigen.

Binding of antibodies in liposomes to extracellular matrix antigens

We have incorporated antibodies against fibronectin or laminin into liposomes and studied their interaction with insoluble forms of these antigens. The antibodies, after modification by palmitoylchloride, were incorporated into the lipid bilayer by the cholate dialysis method. The antibodies in the liposomes recognized their specific antigen with little reaction to the alternative attachment protein or to albumin (less than 2%). The binding of antibody-containing liposomes to insoluble antigen was inhibited by soluble antibodies to the respective antigens but not by antibodies to other antigens. The affinity constant of the liposome-antibody complex with the antigen was estimated at 1-10 X 10(-9) M liposomes. Thus, antibodies in liposomes retain their reactivity and specificity, and the reaction constant is comparable to that observed for immune complexes.

Immobilization of alpha-chymotrypsin on sucrose stearate--palmitate containing liposomes

Stable liposomes have been prepared from lipid mixture containing sucrose stearate-palmitate. 1.2 X 10(-4) mol of model enzyme alpha-chymotrypsin per mol of lipid have been coupled to prepared liposomes activated by periodate oxidation of sucrose units.

Incorporation of acylated wheat germ agglutinin into liposomes

Purified wheat germ agglutinin (WGA) was derivatized with palmitic acid at an average stoichiometry of one fatty acid per dinner. Palmitoyl WGA was readily incorporated into liposomes with a cholate-dialysis method. Liposome-bound WGA caused agglutination of red blood cells at a concentration eight-fold lower than that of the native lectin. Furthermore, enhanced binding of liposome-bound WGA to mouse spleen cells was also observed. Potential applications of the liposome-bound lectin are discussed.

A comparative study on the effectiveness of various procedures for attachment of two proteins (L-asparaginase and horse radish peroxidase) to the surface of liposomes

Five different ways of association of proteins with the surfaces of liposomes were compared. L-asparaginase (L-asp.) and horse radish peroxidase (HRP) were used as proteins since these show a large difference in their numbers of amino groups. Liposomal association was performed by way of: 1) non-specific coating of empty liposomes; 2) incorporation after 'hydrophobisation' with palmitoylchloride; 3) as 2 with dodecanoic acid; 4) coupling to phosphatidylinositol (PI) already incorporated in the liposomal membrane; and 5) as 4 with phosphatidylethanolamine (PE). The relative effectiveness of the different procedures for coupling of the proteins to liposomes as determined by the enzyme activities of intact liposomes shows a large variation, dependent on both the method used and the protein.