A. A. Rakhnyanskaya

Polyelectrolyte-coated liposomes: stabilization of the interfacial complexes.

Anionic liposomes, composed of egg lecithin (EL) or dipalmitoylphosphatidylcholine (DPPC) with 20 mol% of cardiolipin (CL(2-)), were mixed with cationic polymers, poly(4-vinylpyridine) fully quaternized with ethyl bromide (P2) or poly-L-lysine (PL). Polymer/liposome binding studies were carried out using electrophoretic mobility (EPM), fluorescence, and conductometry as the main analytical tools. Binding was also examined in the presence of added salt and polyacrylic acid (PAA). The following generalizations arose from the experiments: (a) Binding of P2 and PL to small EL/CL(2-) liposomes (60-80 nm in diameter) is electrostatic in nature and completely reversed by addition of salt or PAA. (b) Binding can be enhanced by hydrophobization of the polymer with cetyl groups. (c) Binding can also be enhanced by changing the phase state of the lipid bilayer from liquid to solid (i.e. going from EL to DPPC) or by increasing the size of the liposomes (i.e. going from 60-80 to 300 nm). By far the most promising systems, from the point of view of constructing polyelectrolyte multilayers on liposome cores without disruption of liposome integrity, involve small, liquid, anionic liposomes coated initially with polycations carrying pendant alkyl groups.

MODULATION OF INTERACTION OF POLYCATIONS WITH NEGATIVE UNILAMELLAR LIPID VESICLES

Interactions of small unilamellar negative vesicles composed of diphosphatidylglycerol (cardiolipin, CL2−), 20 mol%, and phosphatidylcholine (egg yolk lecithin, EL), 80 mol%, with various cationic polymers (CP) derived from poly(4-vinylpyridine) (PVP) were studied in water and water–salt solutions by means of photon correlation spectroscopy, microelectrophoresis, conductometry, and fluorescence techniques. The linear charge density and hydrophilic lipophilic balance of CPs were varied by quaternization of PVP with various amounts of different alkyl bromides (ethyl-(2), heptyl-(7), dodecyl-(12), cetyl-(16)). Substantial differences were observed in the behavior of exhaustingly N-ethylated PVP (CP2) and PVP N-ethylated to 50 mol% (CP2(50)) or 30 mol% (CP2(30)). All of them adsorb to the CL2−/EL vesicle membrane, neutralizing the surface negative charge and causing aggregation of the vesicles. However, CP2, a polycation with a maximum linear charge density, strongly enhances transfer of the negative lipid ions from the inner to outer bilayer leaflet, while CP2(50) and CP2(30) do not. Adsorbed CP2 does not disturb integrity of the vesicle membrane and can be completely removed from the surface of aggregated vesicles by adding a simple salt (NaCl) or a negative linear polyelectrolyte (polyacrylic acid (PAA) sodium salt). Such removal is followed by release of the original vesicles. In contrast to that, adsorbed CP2(50) or CP2(30) produce some leak through the lipid bilayer and cannot be completely desorbed either by increasing ionic strength or adding an excess of PAA. The probable reason of these differences is discussed. PVP partially N-alkylated with dodecyl or cetyl bromides (3 mol%) and then completely N-ethylated (CP2,12 and CP2,16), also having a maximum linear charge density, adsorbs to the negative vesicle surface as a result of both electrostatic binding and hydrophobic interaction. Bulky hydrocarbon pendant groups incorporate into the inner bilayer compartment. Similarly to CP2(50) and CP2(30), CP2,12 and CP2,16 cannot be removed from the surface either by adding the simple salt, or an excess of PAA. However, in contrast to CP2(50) and CP2(30), the polycations with the bulky hydrocarbon pendant groups do not cause any leak through the vesicle membrane. Finally, we have succeeded to prepare the ternary vesicles also composed of 20 mol% of CL2−, but partially replacing EL for polyoxyethylene 20 cetyl ether (Brij 58) (up to 30 mol%). The CL2−/EL/Brij vesicle carries a hydrophilic corona formed by polyoxyethylene chains exposed into water, while hydrophobic cetyl radicals are incorporated in the lipid bilayer. The CL2−/EL/Brij vesicles adsorb all studied CPs similar to the binary CL2−/EL vesicles. This means that polyoxyethylene corona is permeable for polycationic species restricting neither electrostatic binding nor incorporation of bulky hydrocarbon groups of CP2,16 into the membrane. However, the corona effectively stabilizes the CP-vesicle complexes against aggregation when the membrane surface is neutralized.

Interfacial nanofabrication strategies in development of new functional nanomaterials and planar supramolecular nanostructures for nanoelectronics and nanotechnology

Clusters, nanoparticles, nanowires, long molecules as nanotubes and polynucleotides, and functional supramolecular nanostructures are currently considered as potential building blocks for nanotechnology and nanoelectronic devices and circuits, and development and introduction of new methods to control effectively their structure, composition and nanoscale organization are necessary. Here we describe a number of new nanofabrication methods which are based on the monolayer techniques, biomimetic principles, interfacial reactions and interactions. The methods allowed to produce new stable reproducible planar one-dimensional and two-dimensional arrays of ligand-stabilized nanoclusters and nanoparticles on solid substrates, ultrathin polymeric nanoscale-ordered mono- and multilayer quasi-crystalline and nanocomposite films, planar polymeric complex films with integrated DNA and inorganic building blocks as semiconductor and iron oxide nanoparticle quasi-linear arrays and nanowires. Transmission electron microscopy, STM and AFM techniques were used to characterize the fabricated nanostructures. Effects related to discrete electron tunneling were observed in the monolayers of nanoclusters and small gold nanoparticles at room temperature using STM.

Biomembrane sensitivity to structural changes in bound polymers.

Anionic liposomes containing a 4:1 molar ratio of neutral to anionic phospholipids were treated with an excess of five zwitterionic polymers differing only in the spacer length separating their cationic and anionic moieties. Although the polymers do not disrupt the structural integrity of the liposomes, they can induce spacer-dependent molecular rearrangements within the liposomes. Thus, the following were observed: spacer length = 1, no binding to the liposomes; spacer length = 2, adsorption to the liposomes, but no molecular rearrangement; spacer length = 3, lateral lipid segregation but little or no flip-flop; spacer length = 4 or 5, lateral lipid segregation and flip-flop. These diverse behaviors are relevant to the use of biomedical formulations where polyelectrolytes play a role.

Activity of an Enzyme Immobilized on Polyelectrolyte Multilayers

The immobilization of α-chymotrypsin on the surface of boron silicate glass microspheres is conducted via the technique of multilayer adsorption of polyelectrolytes. It is shown that the enzyme is adsorbed on both positively and negatively charged surfaces and its activity is partially preserved relative to that in solution. The activity of the enzyme depends on the number of polyectrolyte layers preliminarily adsorbed on glass microspheres and on the charge of the surface. The activity of α-chymotrypsin adsorbed on the negatively charged surface is four times higher than the activity of this enzyme adsorbed on a positively charged surface.

Use of a polycation spacer for noncovalent immobilization of albumin on thermally modified virus particles

The noncovalent immobilization of the protein bovine serum albumin on the surface of spherical nanoparticles 330 ± 60 nm in diameter is described. These nanoparticles are prepared by the thermal treatment of tobacco mosaic virus and are preliminarily covered with a layer of the cationic polymer poly(N-ethyl-4-vinylpyridinium bromide). The electrostatic adsorption of the polycation on the surface of negatively charged spherical nanoparticles (on average 1.2 × 104 macromolecules per particle) is accompanied by recharging of the surface; as a result, the negatively charged protein bovine serum albumin can be adsorbed on it in an amount of 1.7 × 104 molecules per particle. The modification of spherical nanoparticles with the polycation and protein does not cause the aggregation of particles. The spherical-nanoparticle-polycation-protein ternary complex demonstrates increased stability in salt solutions relative to the spherical-nanoparticle-polycation binary complex. Because of the simplicity of the method used to modify the surface of spherical nanoparticles, it shows promise for preparation of functionally active complexes.

Proteins immobilization on the surface of modified plant viral particles coated with hydrophobic polycations

Two hydrophobic cations based on poly-N-ethyl-vinylpyridine were used to produce biologically active complexes. The complexes obtained from tobacco mosaic virus (TMV) spherical particles (SPs), hydrophobic polycation, and a model protein were stable and did not aggregate in solution, particularly at high ionic strengths. The nucleic acid-free SPs were generated by thermal remodeling of the TMV (helical rod-shaped plant virus). The model protein preserved its antigenic activity in the ternary complex (SP–polycation–protein). Immobilization of proteins on the surface of SPs coated with hydrophobic cation is a promising approach to designing biologically active complexes used in bionanotechnologies.

Polymer migration among phospholipid liposomes.

Complexation of phospholipid lipsomes with a cationic polymer, poly(N-ethyl-4-vinylpyridinium bromide) (PEVP), and subsequent interliposomal migration of the adsorbed macromolecules, have been investigated. Liposomes of two different charge types were examined: (a) a liposomal system, with an overall charge near zero, consisting of zwitterionic phosphatidylcholine (egg lecithin, EL) with added doubly anionic phospholipid, cardiolipin (CL(2-)), and cationic dihexadecyldimethylammonium bromide (HMAB(+)), in a CL(2-)/HMAB(+) charge-to-charge ratio of 1:1; (b) an anionic liposomal system composed of an EL/CL(2-) mixture plus polyoxyethylene monocetyl ether (Brij 58). Both three-component systems were designed specifically to preclude liposomal aggregation upon electrostatic association with the PEVP, a phenomenon that had complicated analysis of data from several two-component liposomes. PEVP macromolecules were found from fluorescence experiments to migrate among the charge-neutral EL/CL(2-)/HMAB(+) liposomes. In the case of anionic EL/CL(2-)/Brij liposomes, a combination of fluorescence and laser microelectrophoresis methods showed that PEVP macromolecules travel from liposome to liposome while being electrostatically associated with anionic lipids.

Metal ion adsorption to Langmuir-Blodgett films monitored by the optical waveguide technique

Abstract We applied optical waveguide methods to monitor the metal ion adsorption to ultrathin organic films. As a metal ion-sensitive material we used a polymer with azacrown ether sidegroups which are highly selective to Cu 2+ cation complexation. Ultrathin films of this material were prepared by applying the Langmuir-Blodgett technique. When exposing such a multilayer structure to an aqueous Cu 2+ ion solution, the effective index of the propagating waveguide mode increases, indicating that the ions are complexed to the molecules of the ultrathin film structure. The prepared layered structure was sensitive to solutions with a concentration down to c ≈ 3 × 10 −7 M; the response time was in the range of τ = 20–30 min.

Physicochemical and biological properties of polyampholytes: Quaternized derivatives of poly(4-vinylpyridine)

The modification of poly(4-vinylpyridine) with ω-bromocarboxylic acids and alkyl bromides yields three types of polyampholytes: polyampholytes containing both cationic and anionic groups in each monomer unit (polybetaines), polyampholytes containing betaine and cationic units, and polyampholytes containing betaine units and side cetyl radicals. Their complex formation with liposomes formed from zwitterionic (electroneutral) phosphatidylcholine and anionic diphosphatidylglycerol (cardiolipin) is investigated. The method for fixation of polymers on the liposomal membrane and the stability of the formed complexes are determined by the chemical structure of macromolecules. For the most part, polyelectrolytes are electrostatically adsorbed on the membrane and are fully removed from it with an increase in the salt concentration in the surrounding solution. An exception is the polybetaine obtained through the modification of poly(4-vinylpyridine) with ω-bromobutyric acid, which irreversibly binds to liposomes probably owing to the incorporation of macromolecular fragments into the hydrophobic part of the lipid bilayer. The insertion of side cetyl radicals into polybetaine molecules stabilizes their complexes with liposomes in the presence of salts. The cytotoxicity of the synthesized polyampholytes is one to two orders of magnitude lower than that of a cationic polymer with the same degree of polymerization.