Tonya L. Kuhl

Modulation of interaction forces between bilayers exposing short-chained ethylene oxide headgroups

The use of liposomes as drug delivery systems has been limited by their rapid clearance from circulation by the mononuclear phagocyte system. Recent studies have found that circulation times can be greatly enhanced by incorporating a small amount of modified lipids whose headgroups are derivatized with a bulky water soluble polymeric chain of poly ethylene oxide. We report here a systematic study using the Surface Forces Apparatus to measure directly the interactions between two phosphatidyl ethanolamine lipid bilayers, exposing this polymeric headgroup at different concentrations in the bilayer. We found that the force becomes repulsive at all separations and that the thickness of the steric barrier could be controlled easily by adjusting the concentration of the modified lipids. Equilibrium force profiles were measured that were reversible and largely insensitive to changes in electrolyte concentration and temperature. The results have enabled the Dolan and Edwards theory for the steric forces of low coverage polymer surfaces and the Alexander de Gennes theory for high coverage surfaces to be tested, and both were found to apply. We conclude that these simple theories can be used to model the interactions of surprisingly short segments and, hence, apply to such systems as lipids with bulky headgroups and liposomes containing a sterically stabilizing polymer.

Packing of Ganglioside-Phospholipid Monolayers: An X-Ray Diffraction and Reflectivity Study

Using synchrotron grazing-incidence x-ray diffraction (GIXD) and reflectivity, the in-plane and out-of-plane structure of mixed ganglioside-phospholipid monolayers was investigated at the air-water interface. Mixed monolayers of 0, 5, 10, 20, and 100 mol% ganglioside GM(1) and the phospholipid dipalmitoylphosphatidylethanolamine (DPPE) were studied in the solid phase at 23 degrees C and a surface pressure of 45 mN/m. At these concentrations and conditions the two components do not phase-separate and no evidence for domain formation was observed. X-ray scattering measurements reveal that GM(1) is accommodated within the host DPPE monolayer and does not distort the hexagonal in-plane unit cell or out-of-plane two-dimensional (2-D) packing compared with a pure DPPE monolayer. The oligosaccharide headgroups were found to extend normally from the monolayer surface, and the incorporation of these glycolipids into DPPE monolayers did not affect hydrocarbon tail packing (fluidization or condensation of the hydrocarbon region). This is in contrast to previous investigations of lipopolymer-lipid mixtures, where the packing structure of phospholipid monolayers was greatly altered by the inclusion of lipids bearing hydrophilic polymer groups. Indeed, the lack of packing disruptions by the oligosaccharide groups indicates that protein-GM(1) interactions, including binding, insertion, chain fluidization, and domain formation (lipid rafts), can be studied in 2-D monolayers using scattering techniques.

Synchrotron X-Ray Study of Lung Surfactant-Specific Protein SP-B in Lipid Monolayers

This work reports the first x-ray scattering measurements to determine the effects of SP-B(1-25), the N-terminus peptide of lung surfactant-specific protein SP-B, on the structure of palmitic acid (PA) monolayers. In-plane diffraction shows that the peptide fluidizes a portion of the monolayer but does not affect the packing of the residual ordered phase. This implies that the peptide resides in the disordered phase, and that the ordered phase is essentially pure lipid, in agreement with fluorescence microscopy studies. X-ray reflectivity shows that the peptide is oriented in the lipid monolayer at an angle of approximately 56 degrees relative to the interface normal, with one end protruding past the hydrophilic region into the fluid subphase and the other end embedded in the hydrophobic region of the monolayer. The quantitative insights afforded by this study lead to a better understanding of the lipid/protein interactions found in lung surfactant systems.

A Neutron Reflectivity Study of Polymer-Modified Phospholipid Monolayers at the Solid-Solution Interface: Polyethylene Glycol-Lipids on Silane-Modified Substrates

The structure of polymer-decorated phospholipid monolayers at the solid-solution interface was investigated using neutron reflectometry. The monolayers were composed of distearoylphosphatidylethanolamine (DSPE) matrixed with varying amounts of DSPE-PEG (DSPE with polyethylene glycol covalently grafted to its headgroup). Mixed lipid monolayers were Langmuir-Blodgett deposited onto hydrophobic quartz or silicon substrates, previously hydrophobized by chemically grafting a robust monolayer of octadecyltrichlorosilane (OTS). We show that this method results in homogeneous and continuous phospholipid monolayers on the silanated substrates and determine that the grafted PEG chains extend away from the monolayers into the solvent phase as a function of their density, as expected from scaling theories. In addition, ligands were coupled to the end of the PEG chains and selective binding was demonstrated using fluorescence microscopy. Our results demonstrate that these constructs are ideal for further characterization and studies with well-defined monomolecular films.

Use of poly(ethylene glycol) to control cell aggregation and fusion

Abstract Although poly(ethylene glycol) (PEG) has been widely used as an agent to induce cell aggregation and fusion, the physicochemical principles of its function are only becoming understood recently. PEG has an extremely high affinity for water. The PEG commonly used for these applications is in the molecular weight range of 8000 to 10 000. At low concentrations (0–15 wt.%), PEG in this molecular weight range tends to deplete from cell or lipid surfaces, creating an osmotic gradient which brings cells or lipid vesicles together. The depletion force is measured using a surface force apparatus. The corresponding reduction of surface viscosity is verified by shear viscosity measurements and by vesicle tumbling experiments. At higher concentrations (15–45 wt.%), the extremely high osmotic pressure generated by PEG compresses apposing surfaces of aggregated cells or vesicles to within limits where the membrane is no longer stable, and fusion occurs at point defects. A fusion lumen is formed with the help of cell swelling. If PEG is adsorbed or covalently link to the cell or vesicle surface, the surface force profile becomes entirely repulsive, and aggregation and fusion is inhibited. The repulsion is accountable by steric and electrostatic forces. Therefore, the fusogenic function of PEG can be explained quantitatively by colloidal stability theories.

Membrane texture induced by specific protein binding and receptor clustering: active roles for lipids in cellular function

Biological membranes are complex, self-organized structures that define boundaries and compartmentalize space in living matter. Composed of a wide variety of lipid and protein molecules, these responsive surfaces mediate transmembrane signaling and material transport within the cell and with its environment. It is well known that lipid membrane properties change as a function of composition and phase state, and that protein-lipid interactions can induce changes in the membrane’s properties and biochemical response. Here, molecular level changes in lipid organization induced by multivalent toxin binding were investigated using grazing incidence X-ray diffraction. Structural changes to lipid monolayers at the air-water interface and bilayers at the solid-water interface were studied before and after specific binding of cholera toxin to membrane embedded receptors. At biologically relevant surface pressures, protein binding perturbed lipid packing within monolayers and bilayers resulting in topological defects and the emergence of a new orientationally textured lipid phase. In bilayers this altered lipid order was transmitted from the receptor laden exterior membrane leaflet to the inner leaflet, representing a potential mechanism for lipid mediated outside-in signaling by multivalent protein binding. It is further hypothesized that cell-surface micro-domains exhibiting this type of lipid order may serve as nucleation sites for vesicle formation in clathrin independent endocytosis of cholera toxin.

Structure and Thermodynamics of Lipid Bilayers on Polyethylene Glycol Cushions: Fact and Fiction of PEG Cushioned Membranes

In developing well hydrated polymer cushioned membranes, structural studies are often neglected. In this work, neutron and X-ray reflectivity studies reveal that hybrid bilayer/polyethylene glycol (PEG) systems created from mixtures of phospholipids and PEG conjugated lipopolymers do not yield a hydrated cushion beneath the bilayer unless the terminal ends of the lipopolymers are functionalized with reactive end groups and can covalently bind (tether) to the underlying support surface. While reactive PEG tethered systems yielded bilayers with near complete surface coverage, a bimodal distribution of heights with sub-micrometer lateral dimensions was observed consisting of cushioned membrane domains and uncushioned regions in close proximity to the support. The membrane fraction cushioned by the hydrated polymer could be controlled by adjusting the molar ratio of lipopolymer in the bilayer. A general phase diagram based on the free energy of the various configurations is derived that qualitatively predicts the observed behavior and the resulting structure of such systems a priori. As further evidenced by ellipsometry, atomic force and fluorescence microscopy, the tethered system provides a simple means for fabricating small cushioned domains within a membrane.

Neutron confinement cell for investigating complex fluids

We describe an apparatus for measuring the molecular density and orientation of confined, ultrathin complex fluids under static and dynamic flow conditions. The device essentially couples the utility of the surface forces apparatus—ability to control surface separation and alignment under applied loads—with in situ structural characterization of the intervening material utilizing neutron reflectivity measurements. The apparatus is designed such that single crystal substrates of quartz or sapphire with areas up to tens of square centimeters can be kept parallel at controlled and well-defined separations from millimeters to less than 100 nm. The large substrate surface area enables direct structural measurements of the density profile of “soft” material placed between the aligned substrates. In addition, the cell is also designed to enable steady shear rates from 0.001 to 20 Hz to be applied in order to follow the dynamic structural response of the confined material, especially at the solid-solution interfa...

Mechanism of cavitation damage in thin liquid films: Collapse damage vs. inception damage

Abstract Much experimental and theoretical work has been done on the collapse or bursting of vapour bubbles onto solid surfaces in liquids, and it is generally held that this is also the underlying cause of surface damage (“cavitation” damage). However, due to experimental difficulties, much less work has been done on the time-evolution of bubbles and cavities in thin liquid films, e.g. in thin lubricating films during shear. Thus, the intuition gained from experiments on, for example, hydrofoils in water tunnels, may not apply to tribological situations. We have used the surface forces apparatus technique to observe, at the submicroscopic level, the rapid growth and disappearance of vapour cavities between two moving surfaces while simultaneously monitoring their effects on the deformations and wear of the surfaces. We find that under these conditions the inception of cavities is a much more violent event than their collapse. The sudden nucleation and growth of cavities is associated with the relaxation of high local stresses on nearby surfaces, and it is at this point that damage occurs rather than during the much smoother subsequent collapse of cavities. Time-lapse video photos taken during the life cycles of cavities are presented. These clearly show the highly complex and inter-related processes that occur in the liquid and nearby surfaces during cavitation.

X-ray and neutron surface scattering for studying lipid/polymer assemblies at the air–liquid and solid–liquid interfaces

Simple mono- and bilayers, built of amphiphilic molecules and prepared at air-liquid or solid-liquid interfaces, can be used as models to study such effects as water penetration, hydrocarbon chain packing, and structural changes due to head group modification. In the paper, we will discuss neutron and X-ray reflectometry and grazing incidence X-ray diffraction techniques used to explore structures of such ultra-thin organic films in different environments. We will illustrate the use of these methods to characterize the morphologies of the following systems: (i) polyethylene glycol-modified distearoylphosphatidylethanolamine monolayers at air-liquid and solid-liquid interfaces; and (ii) assemblies of branched polyethyleneimine polymer and dimyristoylphophatidylcholine lipid at solid-liquid interfaces.