Complexes of surfactants with oppositely charged polymers at surfaces and in bulk.

Addition of surfactants to aqueous solutions of polyelectrolytes carrying an opposite charge causes the spontaneous formation of complexes in the bulk phase in certain concentration ranges. Under some conditions, compact monodisperse multichain complexes are obtained in the bulk. The size of these complexes depends on the mixing procedure and it can be varied in a controlled way from nanometers up to micrometers. The complexes exhibit microstructures analogous to those of the precipitates formed at higher concentrations. In other cases, however, the bulk complexes are large, soft and polydisperse. In most cases, the dispersions are only kinetically stable and exhibit pronounced non-equilibrium features. Association at air-water interfaces readily occurs, even at very small concentrations. When the surfactant concentration is small, the surface complexes are usually made of a surfactant monolayer to which the polymer binds and adsorbs in a flat-like configuration. However, under some conditions, thicker layers can be found, with bulk complexes sticking to the surface. The association at solid-water interfaces is more complex and depends on the specific interactions between surfactants, polymers and the surface. However, the behaviour can be understood if distinctions between hydrophilic surfaces and hydrophobic surfaces are made. Note that the behaviour at air-water interfaces is closer to that of hydrophobic than that of hydrophilic solid surfaces. The relation between bulk and surface complexation will be discussed in this review. The emphasis will be given to the results obtained by the teams of the EC-funded Marie Curie RTN "SOCON".

Bottle-brush polymers: adsorption at surfaces and interactions with surfactants.

Solution and adsorption properties of both charged and uncharged bottle-brush polymers have been investigated. The solution conformation and interactions in solution have been investigated by small-angle scattering techniques. The association of the bottle-brush polymers with anionic surfactants has also been studied. Surfactant binding isotherm measurements, NMR, surface tension measurements, as well as SAXS, SANS and light scattering techniques were utilized for understanding the association behaviour in bulk solutions. The adsorption of the bottle-brush polymers onto oppositely charged surfaces has been explored using a battery of techniques, including reflectometry, ellipsometry, quartz crystal microbalance, and neutron reflectivity. The combination of these techniques allowed determination of adsorbed mass, layer thickness, water content, and structural changes occurring during layer formation. The adsorption onto mica was found to be very different to that on silica, and an explanation for this was sought by employing a lattice mean-field theory. The model was able to reproduce a number of salient experimental features characterizing the adsorption of the bottle-brush polymers over a wide range of compositions, spanning from uncharged bottle-brushes to linear polyelectrolytes. This allowed us to shed light on the importance of electrostatic surface properties and non-electrostatic surface-polymer affinity for the adsorption. The interactions between bottle-brush polymers and anionic surfactants in adsorbed layers have also been elucidated using ellipsometry, neutron reflectivity and surface force measurements.

Polymer-functionalized nanoparticles: from stealth viruses to biocompatible quantum dots.

In this article, we focus on nanoparticles that have been functionalized by polymers. We draw our examples from nanoparticle systems that have found biomedical and therapeutic applications. Our aim is to highlight the physical principles that might explain why these systems have been found to be successful in biomedical applications and to highlight other physical properties that might lead to new applications. We consider viruses, gold nanoparticles, magnetic nanoparticles and quantum dots, focussing attention on the ways in which functionalization by polymers has been used to alter the physical characteristics of the particular nanoparticle to improve its function as a possible therapy. In the case of viral vectors, polymer functionalization tunes the biocompatibility, suppressing the binding of antibodies and conferring the nanoparticle with stealth properties. By contrast, the inorganic nanoparticles comprise materials in a form that is not normally encountered in the human body, and polymer functionalization is necessary to ensure biocompatibility.

Effect of end-group sticking energy on the properties of polymer brushes: comparing experiment and theory.

Using surface force balance measurements we have established that polystyrene chains bearing three zwitterionic groups have a higher end-group sticking energy than equivalent chains bearing a single zwitterionic group. In a good solvent, polystyrene chains end-functionalized with three zwitterionic groups form brushes of a higher surface coverage than those bearing a single zwitterion. The increase in surface coverage is slow compared with the initial formation of the brush. Measurements of the refractive index allow us to directly quantify the variation of surface coverage, permitting comparison with models for the kinetics of brush formation based on scaling theory and an analytical self-consistent field. We find qualitative support for associating the kinetic barrier with the energy required for an incoming chain to stretch as it penetrates the existing brush.

Development of computational and graphical tools for analysis of movement and flexibility in large molecules.

We developed a computer program for the calculation and display of the difference distance matrices (DDMs) of macromolecules that has the ability to compare multiple structures simultaneously. To demonstrate its use, a data set of atoms for superimposition of the HIV-1 reverse transcriptase enzyme was defined using the coordinates for the 21 available crystal structures of this enzyme and its complexes. The DDM technique for superimposition data set generation allows selection of atoms that are invariant in all structures, is free from user bias, and represents the most accurate and precise method of producing such subsets. Comparison of this technique was made against other published methods of generating superimposition data sets, and it was found that significant differences in magnitude and trends of atom movements are observed depending on which data set was used.

Docking experiments in the flexible non-nucleoside inhibitor binding pocket of HIV-1 reverse transcriptase.

Docking experiments were undertaken using a number of published crystal structures of HIV-1 reverse transcriptase complexes with various non-nucleoside inhibitors. The docking method was validated by successfully docking each ligand, in the conformation found in the crystal structure of the complex with the enzyme, back into its binding pocket in the right orientation and position. Each ligand was then subjected to conformational searching and a database of unique low-energy conformations of all ligands established. Docking this database into each of the reverse transcriptase binding pockets showed that all inhibitors could be fitted into each different pocket, without alteration of the pocket geometry. This contradicts findings from earlier docking investigations and implies that the conformation of the binding pocket in each different complex is conserved sufficiently to allow particular uniform ligand binding modes. The inhibitor conformations selected by this docking process are mostly the same as the one the ligand adopts in its own pocket and the selected conformations and orientations exhibit an impressive degree of similarity in the arrangement of their steric and electronic features. A correlation has also been observed between inhibitor flexibility and tightness of fit into the pockets with the more flexible inhibitors achieving a tighter fit and thus fewer favourable orientations upon docking.

Structural alterations of alpha-crystallin during its chaperone action.

The small heat-shock protein, alpha-crystallin, has chaperone ability whereby it stabilises proteins under stress conditions. In this study, alterations in the structure of alpha-crystallin during its interaction with a variety of substrate proteins (insulin, alpha-lactalbumin, ovotransferrin and serum albumin) under stress conditions have been examined using visible absorption, 31P-NMR and 1H-NMR and fluorescence spectroscopy. The fluorescence and 31P-NMR data imply that during the chaperone action of alpha-crystallin under reducing conditions, there is a slight increase in hydrophilicity of its N-terminal region and an alteration in flexibility of its C-terminal region, but overall, alpha-crystallin does not undergo a gross structural change. The fluorescence data suggest that substrate proteins interact with alpha-crystallin in a molten globule or intermediately folded state. The same conclusion is made from 1H-NMR spectroscopic monitoring of the interaction of alpha-crystallin with substrate proteins, e.g. the insulin B chain. The stoichiometry of interaction between alpha-crystallin and the various substrate proteins reveals that steric factors are important in determining the efficiency of interaction between the two proteins, i.e. on a molar subunit basis, alpha-crystallin is a more efficient chaperone protein with smaller substrate proteins. Comparison is also made between the high-molecular-mass (HMM) complexes formed between alpha-crystallin and ovotransferrin when reduced and heat stressed. Under heating conditions, fluorescence spectroscopy indicates that the HMM complex has a greater exposure of hydrophobicity to solution than that formed by reduction. Furthermore, in interacting with heated ovotransferrin, the C-terminal extension of the alphaB-crystallin subunit preferentially loses its flexibility suggesting that it is involved in stabilising bound ovotransferrin. By contrast, this extension is only partially reduced in flexibility in the HMM complex formed after reduction of ovotransferrin. The functional role of the C-terminal extensions in the chaperone action and the overall quaternary structure of alpha-crystallin is discussed.

A quantitative investigation of the transannular amine-ketone (N...C=O) interaction in medium-sized heterocycles.

The transannular N...C=O interaction in several medium-sized heterocycles has been investigated by force-field methods. Conformational searching has been performed at the molecular mechanics level using different methods and the conformers so generated have been reoptimized at RHF/6-31G(d). For selected conformers, N...C distances are reported, together with transannular bond orders and atomic charges. Good agreement with available X-ray crystallographic data is obtained for the transannular bond distance in cryptopine. Changes in the partial atomic charges derived from the electrostatic potential provide good support for the donor-acceptor model of transannular interactions. Partial charges derived with other methods do not give satisfactory results. Some force fields do not reproduce the transannular interaction very well. This is demonstrated and rationalized, and modifications are suggested and tested for these force fields with good results when comparing diagnostic geometric features with X-ray data.

Glutathione S-transferase in human hepatocellular carcinoma.

Qualitative and quantitative changes in glutathione S-transferase (GSH-T) were studied in human hepatocellular carcinoma. GSH-T specific activity (mumoles per min per mg protein) was variably reduced in hepatocellular carcinoma. Similar changes were seen in "cationic" GSH-T (ligandin) concentration determined by radioimmunoassay. Immunohistochemical studies with antihuman liver ligandin suggest that positive staining was more frequently found in well-differentiated tumors. The relative activities of "cationic," "neutral," and "anionic" transferases (pI greater than 7.5) activity ranged from virtually absent to near normal values. "Neutral" (pI 6 to 6.5) and "anionic" (pI less than 5.4) species were present more often in tumors than in normal liver. In two cases, normal liver tissue and tumor were obtained from the same patient. In one, only quantitative differences were present, while in the other "cationic" and "neutral" GSH-Ts were present in the normal liver tissue while both "cationic" and "anionic" species were found in the tumor. Our studies indicate that qualitative as well as quantitative changes of GSH-T occur in human hepatocellular carcinoma.

Glutathione S-transferase in human organs.

Glutathione S-transferase (GSH-T) distribution has been investigated in human tissues. The relative contribution of each species to total enzyme activity of the various tissues has been compared. "Cationic" (pI greater than 7.5) "neutral" (pI 6-6.5) and "anionic" (pI less than 5.4) species of GSH-T were separated by isoelectric focusing. "Cationic" GSH-Ts (ligandin) quantitated by radioimmunoassay were present in all tissues studied. Highest concentrations were in liver, kidney, duodenum, testis and adrenal. "Neutral" and "anionic" GSH-Ts were not present in every tissue or in every specimen of some tissues studied. Marked inter-organ and inter-individual variation in the relative concentration of the 3 GSH-T species may explain individual and organ susceptibility to drugs and toxins and underlines the need for future studies to examine individual enzymes rather than total activity.