Visualizing Protein Interactions at Supported Bilayer Surfaces

Vanderlee, Gillian

10 December 2013

Understanding the mechanisms by which proteins act on membrane surfaces is fundamental if we are to exploit their capabilities or halt the progression of the diseases they are associated with. Arguably, the best way to study these interactions is by using techniques that can obtain molecular-scale information, in real time and under physiologically relevant conditions. Studying supported lipid bilayer systems with high spatial resolution tools, such as atomic force microscopy (AFM), and high temporal resolution techniques, such as polarized total internal reflection fluorescence microscopy (pTIRFM), allows us to meet these requirements [1]. The goal of this project is to use methods that are currently available and further their applications and capabilities to provide insight into the mechanisms by which amyloidogenic and antimicrobial peptides act on membranes.

atomic force microscopy

antimicrobial

amyloid

bilayer

order parameter

0541

Nuclear and Cytoskeletal Prestress Govern the Anisotropic Mechanical Properties of the Nucleus

Macadangdang, Joan Karla

24 September 2012

Physical forces in the cellular microenvironment play an important role in governing cell function. Forces transmitted through the cell cause distinct deformation of the nucleus, and possibly play a role in force-mediated gene expression. The work presented in this thesis drew upon innovative strategies employing simultaneous atomic force and laser-scanning confocal microscopy, as well as parallel optical stretching experiments, to gain unique insights into the response of eukaryotic cell nuclei to external force. Non-destructive approaches confirmed the existence of a clear anisotropy in nuclear mechanical properties, and showed that the nucleus' mechanical response to extracellular forces is differentially governed by both nuclear and cytoskeletal prestress: nuclear prestress regulates shape and anisotropic deformation, whereas cytoskeletal prestress modulates the magnitude and degree of deformation. Importantly, the anisotropic mechanical response was conserved among diverse differentiated cell types from multiple species, suggesting that nuclear mechanical anisotropy plays an important role in cell function.

nucleus

eukaryotic cell

atomic force microscopy

confocal microscopy

optical stretcher

cytoskeleton

force transduction

anisotropy

Metal modified boron doped diamond electrodes and their use in electroanalysis

Toghill, Kathryn E.

January 2011

The experimental work discussed in this thesis explores the effects of metal modification on the electroanalytical ability of boron doped diamond electrodes. Boron doped diamond (BDD) electrodes have found increased application to electroanalysis in the past two decades, yet relatively little of the literature is focused on metal, nano and microparticle modification of the substrate. In this thesis three metals have been used to modify the BDD electrode; bismuth, antimony and nickel. Bismuth and antimony nanoparticle modified BDD electrodes were directly compared to unmodified BDD and a bulk bismuth electrodes in the determination of trace levels of cadmium and lead using anodic stripping voltammetry. In both instances, the modified electrode allowed for the simultaneous determination of each analyte that was otherwise unattainable at the unmodified BDD electrode. The nickel modified BDD (Ni-BDD) electrode was used in the determination of organic analytes, namely glucose, methanol, ethanol and glycerol. The nickel nano and microparticle electrodes gave the characteristic Ni(OH)₂/NiOOH redox couple in alkali pH, the oxidised form of which (NiOOH) catalysed the oxidation of the organic analytes. The chapter on glucose sensing with the Ni-BDD electrode is preceded by an extensive literature review on the advances of non-enzymatic glucose sensing, and the application of catalytic metals and nanomaterials in this field. Throughout the course of this DPhil, there has been a collaborative project between Asylum Research and myself within the Compton group to develop a commercial electrochemical atomic force microscope (EC-AFM) cell. The aim was to produce an adaptable EC-AFM cell capable of dynamic electrochemical experiments whilst simultaneously or instantaneously acquiring an AFM image of the modified surface, in-situ. This project was successful, and the EC-AFM cell has contributed to a number of chapters in this thesis, and has now been commercialised.

541.37

Membrane tension homeostasis of mammalian cells / -mechanosensitive study of the area regulation of adherent cells

Brückner, Bastian Rouven

03 June 2016

No description available.

571.4

Atomic Force Microscopy

Cell Mechanics

Tension Homeostasis

Cell Membrane

Epithelial Cells

Biologie (PPN619462639)

Nanoscale measurements of the mechanical properties of lipid bilayers

Köcher, Paul Tilman

January 2014

Lipid bilayers form the basis of the membranes that serve as a barrier between a cell and its physiological environment. Their physical properties make them ideally suited for this role: they are extremely soft with respect to bending but essentially incompressible under lateral tension, and they are quite permeable to water but essentially impermeable to ions which allows the rapid establishment of the osmotic gradients. The function of membrane proteins, which are vital for tasks ranging from signal transduction to energy conversion, depends on their interactions with the lipid environment. Because of the complexity of natural membranes, model systems consisting of simpler lipid mixtures have become indispensable tools in the study of membrane biophysics. The objective of the work reported here is to develop a deeper understanding of the underlying physics of lipid bilayers through nanoscale measurements of the mechanical properties of mixed lipid systems including cholesterol, a key ingredient of cell membranes. Atomic force microscopy (AFM) has been used extensively to measure the topographical and elastic properties of supported lipid bilayers displaying complex phase behaviour and containing mixtures of important PC, PE lipids and cholesterol. Phase transformations have been investigated varying the membrane temperature, and the effects of cholesterol in controlling membrane fluidity, phase, and energetics have been studied. Elastic modulus measurements were correlated with phase behaviour observations. To aid in the nanoscale probing of lipid bilayers, AFM probes with a high aspect ratio and tip radii of $sim$4~nm were fabricated and characterised. These probes were used to investigate the phase boundary in binary and ternary lipid systems, leading to the discovery of a raised region at the boundary which has implications for the localisation of reconstituted proteins as well as the role of natural domains or lipid rafts. The electrical properties of the probes were examined to assess their potential application for combined structural and electrical measurements in liquid. A novel technique was developed to aid in the study of the physical properties of lipid bilayers. Membrane budding was induced above microfabricated substrates through osmotic pressure. Modification of the adhesion energy of the bilayer through biotin-avidin linking was successful in modulating budding behaviour of liquid disordered bilayers. The free energy of the system was modelled to allow quantitative information to be extracted from the data.

572

Single molecule studies of seven transmembrane domain proteins

Berthoumieu, Olivia

January 2011

This work aimed at studying biophysical properties of two membrane proteins, one of potential nanotechnological use, bacteriorhodopsin, and one potential drug target, the NTS1 neurotensin receptor, at the single molecule scale. Bacteriorhodopsin (BR) is the only protein in the purple membrane (PM) of the halophilic organism Halobacterium salinarium. It is a light-driven proton pump converting light into a transmembrane proton gradient through isomerization of its retinal chromophore. Its stability, as well as its photoactivity remaining in dry protein layers, has made BR an attractive material for biomolecular devices. Numerous studies have been published on this topic; however, they have all used BR within the PM, on relatively large (µm-wide) surfaces. Here, conducting-probe atomic force microscopy (C-AFM) analysis was performed after removing most of the membrane lipids. For the first time, it was shown that the molecular conductance of BR can be reversibly photoswitched with predictable wavelength sensitivity. Intimate and robust coupling to gold electrodes was achieved by using a strategically engineered cysteine which, combined with partial delipidation, generated protein trimers homogenously orientated on the surface. Numerous controls using biophysical (SPR, ellipsometry, Kelvin-probe AFM) and chemical (photocurrent, cyclic voltammetry) techniques confirmed the wavelength specificity of the photoswitch, the anchoring role of the mutation and the homogenous orientation of the protein on the gold surface. Neurotensin is a brain and gastrointestinal 13 amino acid peptide acting as a neuromodulator in the central nervous system and as a hormone in the periphery. Its wide range of biological activities is primarily mediated through its binding to the neurotensin type 1 receptor (NTS1). NTS1 expressed in E.coli was purified and inserted into 100 nm brain polar lipid liposomes in a conformation which retained its ligand-binding capabilities. Initial AFM characterisation was performed as a prelude for ligand-receptor interaction studies, including high resolution imaging, force spectroscopy and solid state NMR approaches.

572.696

Mechanical Characterization of Patterned Silver Columnar Nanorods with the Atomic Force Microscope.

Kenny, Sean

30 April 2012

Patterned silver (Ag) columnar nanorods were prepared by the glancing angle physical vapor deposition method. The Ag columnar nanorods were grown on a Si (100) substrate patterned with posts in a square “lattice” of length 1 μm. An electron beam source was used as the evaporation method, creating the deposition flux which was oriented 85˚ from the substrate normal. A Dimension Icon with NanoScope V controller atomic force microscope was used to measure the spring constant in 10 nm increments along the long axis of five 670 nm long Ag nanorod specimens. The simple beam bending model was used to analyze the data. Unexpected behavior of the spring constant data was observed which prevented a conclusive physically realistic value of the Young’s modulus to be calculated.

AFM

atomic force microscope

force distance spectroscopy

young's modulus

Physical Sciences and Mathematics

Physics

The (Un)Folding of Multidomain Proteins Through the Lens of Single-molecule Force-spectroscopy and Computer Simulation

Scholl, Zackary Nathan

January 2016

<p>Proteins are specialized molecules that catalyze most of the reactions that can sustain life, and they become functional by folding into a specific 3D structure. Despite their importance, the question, "how do proteins fold?" - first pondered in in the 1930's - is still listed as one of the top unanswered scientific questions as of 2005, according to the journal Science. Answering this question would provide a foundation for understanding protein function and would enable improved drug targeting, efficient biofuel production, and stronger biomaterials. Much of what we currently know about protein folding comes from studies on small, single-domain proteins, which may be quite different from the folding of large, multidomain proteins that predominate the proteomes of all organisms.</p><p>In this thesis I will discuss my work to fill this gap in understanding by studying the unfolding and refolding of large, multidomain proteins using the powerful combination of single-molecule force-spectroscopy experiments and molecular dynamic simulations.</p><p>The three model proteins studied - Luciferase, Protein S, and Streptavidin - lend insight into the inter-domain dependence for unfolding and the subdomain stabilization of binding ligands, and ultimately provide new insight into atomistic details of the intermediate states along the folding pathway.</p> / Dissertation

Biophysics

Molecular biology

Biochemistry

atomic force microscopy

molecular dynamics

protein folding

single-molecule force-spectroscopy

Structural optimization of polypod-like structured DNA based on structural analysis and interaction with cells / 構造解析および細胞との相互作用解析に基づく多足型DNA構造体の構造最適化に関する研究

Tan, Mengmeng

23 March 2020

京都大学 / 0048 / 新制・課程博士 / 博士(薬科学) / 甲第22397号 / 薬科博第119号 / 新制||薬科||13(附属図書館) / 京都大学大学院薬学研究科薬科学専攻 / (主査)教授 髙倉 喜信, 教授 山下 富義, 教授 小野 正博 / 学位規則第4条第1項該当 / Doctor of Pharmaceutical Sciences / Kyoto University / DFAM

DNA nanostructure

nanotechnology

atomic force microscopy

small-angle X-ray scattering

structure–activity relationship

499.3

[en] SEMICONDUCTOR NANOSTRUCTURE FABRICATION IN MECHANICAL DEFECTS PRODUCED BY ATOMIC FORCE MICROSCOPY / [pt] FABRICAÇÃO DE NANOESTRUTURAS SEMICONDUTORAS EM DEFEITOS PRODUZIDOS POR MICROSCOPIA DE FORÇA ATÔMICA

HENRIQUE DUARTE DA FONSECA FILHO

23 January 2009

[pt] A combinação de alta densidade, locais seletivos de nucleação e controle da distribuição de tamanho de nanoestruturas semicondutoras tem acelerado o desenvolvimento de dispositivos ópticos e eletrônicos. Para construir estruturas satisfazendo essas necessidades, várias combinações de técnicas deposição de pontos quânticos e nanolitografia foram desenvolvidas. A nanolitografia por AFM foi aplicada em diversos materiais abrindo uma possibilidade para fabricar dispositivos opto-eletrônicos.Nesta tese de Doutorado, apresentamos um estudo sistemático de crescimento de nanoestruturas de InAs em buracos produzidos na superfície (100) de substratos de InP por nanoindentação com o AFM. Para isto, a ponta precisa exercer uma força no InP que produz deformações plásticas na superfície. A pressão aplicada entre a extremidade da ponta de AFM e a superfície da amostra pode ser variada de modo controlado através do ajuste de alguns parâmetros operacionais do microscópio tais como setpoint, raio da ponta e constante de mola do cantilever. A habilidade para controlar a forma do padrão indentado assim como a natureza dos defeitos cristalinos permite controlar o crescimento seletivo de InAs por epitaxia em fase de vapor de metais orgânicos. Também é apresentada a fabricação de nanoestruturas de InAs/InP alinhadas em uma dimensão. A nanoindentação é produzida pelo arraste da ponta do AFM sob força constante ao longo das direções <100> e <110> do InP. Observamos que o número e o tamanho das nanoestruturas nucleadas são dependentes da distância entre as linhas litografadas. Esses resultados sugerem que o mecanismo de crescimento das nanoestruturas de InAs não é governado por degraus atômicos gerados durante a indentação. Os dados sugerem que, a densidade de defeitos induzidos mecanicamente, tais como discordâncias e fraturas, é o responsável pelo número de nanoestruturas nucleadas. / [en] The combination of high density, site selective nucleation, and size distribution control of semiconductor nanostructures has become a challenge in the development of effective optical and electronic devices. In order to build structures satisfying these requirements, various combinations of quantum dot deposition and nanolithography techniques have been developed. The AFM nanolithography technique has been applied on several materials opening a possibility to fabricate opto-electronic devices. In this Phd Thesis, we present a systematic study of growth of InAs nanostructures on pits produced on (100) InP by nanoindentation with the AFM. For that purpose, the AFM tip needs to exert a force on the InP that produces plastic deformation on the surface. The applied pressure between the very end of the AFM tip and the sample surface may be varied in a controlled way by adjusting some of the microscope operational parameters like set point, tip radius and cantilever normal bending constant. The ability to control the shape of the indentation pattern as well as the nature of the crystalline defects allows control of the selective growth of InAs by metal organic vapor phase epitaxy. We also report the fabrication of one-dimensional arrays of InAs/InP nanostructures. The nanoindentation is produced by dragging the AFM tip under constant force of the substrate, along the <100> and <110> InP crystallographic directions. We have observed that the number and the size of nucleated nanostructures are dependent on the distance between the lithographed lines. These results suggest that the growth mechanism of the InAs nanostructures on the pits produced by AFM on InP is not governed by the number of atomic steps generated during the scratching. Instead, the data suggests that, the density of mechanically induced defects, like dislocations and cracks, are responsible for the number of nucleated nanostructures.

[pt] SEMICONDUCTORES

[en] SEMICONDUCTORS

[pt] NANOESTRUTURAS

[en] NANOSTRUCTURES

[pt] MICROSCOPIA DE FORCA ATOMICA

[en] ATOMIC FORCE MICROSCOPY