Neutron reflectivity studies of bacterial membranes, peptides and proteins

McKinley, Laura Ellen

January 2017

This thesis uses neutron and x-ray reflectivity to measure the interfacial structures of three molecular components associated with bacteria. Firstly, the way in which the membrane targeting sequence of a cell division protein interacts with monolayer models for the inner leaflet of the inner membrane of bacteria was measured at the air-water interface. Secondly, the influence of lipopolysaccharide on a monolayer model for the outer leaflet of the outer membrane of Gram-negative bacteria was measured at the air-water interface, as well as how this lipopolysaccharide interacts with an antimicrobial peptide. Finally, the structure of a layer of protein found at the surface of a Gram-positive biofilm was measured at the air-water interface. Binding of the membrane targeting sequence of the MinD protein (MinD-mts) to the inner leaflet of the cytoplasmic membrane is thought to be key for bacterial cell division. Modelling this membrane as a monolayer at the air-water interface, it was found that the insertion of the MinD-mts increased with decreasing lateral pressure within the monolayer, as well as with increasing unsaturation of the lipid components, and the incorporation of cardiolipin into the monolayer. Lipopolysaccharide (LPS) is the major component of Gram-negative outer membranes, such as Escherichia coli, and can be considered as having three structural components: lipid A, a core oligosaccharide, and a variable polysaccharide chain. By incorporating LPS into a model membrane at the air-water interface, it was found that the polysaccharide chain undergoes conformational changes depending on the area per molecule. The effect of the antimicrobial peptide Pexiganan on the structure of this LPS layer was also determined, and was found to insert into the polysaccharide chain layer, but have no impact on the conformation of the chains. In nature, many bacteria live within a biofilm structure. A critical component of the Gram-positive Bacillus subtilis biofilm is a surface active amphipathic protein called BslA, which gives rise to the formation of the highly hydrophobic surface of the biofilm. The kinetics of this film formation, its thickness, and the lateral packing of the protein at the air-water interface, were measured using both neutron and x-ray reflectivity. It was found that a native BslA protein consistently formed the same structural film, whilst the structure of films formed by mutant proteins depended on the conditions under which the film was formed.

Coarse-grained simulations to predict structure and properties of polymer nanocomposites

Khounlavong, Youthachack Landry

02 February 2011

Polymer Nanocomposites (PNC) are a new class of materials characterized by their large interfacial areas between the host polymer and nanofiller. This unique feature, due to the size of the nanofiller, is understood to be the cause of enhanced mechanical, electrical, optical, and barrier properties observed of PNCs, relative to the properties of the unfilled polymer. This interface can determine the miscibility of the nanofiller in the polymer, which, in turn, influences the PNC's properties. In addition, this interface alters the polymer's structure near the surface of the nanofiller resulting in heterogeneity of local properties that can be expressed at the macroscopic level. Considering the polymer-nanoparticle interface significantly influences PNC properties, it is apparent that some atomistic level of detail is required to accurately predict the behavior of PNCs. Though an all-atom simulation of a PNC would be able to accomplish the latter, it is an impractical approach to pursue even with the most advanced computational resources currently available. In this contribution, we develop (1) an equilibrium coarse-graining method to predict nanoparticle dispersion in a polymer melt, (2) a dynamic coarse-graining method to predict rheological properties of polymer-nanoparticle melt mixtures, and (3) a numerical approach that includes interfacial layer effects and polymer rigidity when predicting barrier properties of PNCs. In addition to the above, we study how particle and polymer characteristics affect the interfacial layer thickness as well as how the polymer-nanoparticle interface may influence the entanglement network in a polymer melt. More specifically, we use a mean-field theory approach to discern how the concentration of a semiflexible polymer, its rigidity and the particle's size determine the interfacial layer thickness, and the scaling laws to describe this dependency. We also utilize molecular dynamics and simulation techniques on a model PNC to determine if the polymer-nanoparticle interaction can influence the entanglement network of a polymer melt. / text

Polymer nanocomposites

Coarse-grained

Rheology

Barrier properties

Semiflexible polymer

Self-consistent field theory

Interfacial layers

Many-body interactions

Polymer Photodetectors: Device Structure, Interlayer and Physics

Liu, Xilan

January 2013

No description available.

Polymers

Materials Science

Electrical Engineering

polymer photovoltaics

polymer photodetectors

bulk heterojunction

high responsivity

detectivity

inverted device structure

interfacial layers

ZnO nanowire

CdTe quantum dot

device physics