Spelling suggestions: "subject:"single molecule biophysical""
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Super-long single-molecule tracking reveals dynamic-anchorage-induced integrin function / 超長時間1分子追跡法の開発によるインテグリンの動的接着機構の解明Takaaki, Tsunoyama 26 November 2018 (has links)
京都大学 / 0048 / 新制・論文博士 / 博士(医学) / 乙第13214号 / 論医博第2164号 / 京都大学大学院医学研究科医学専攻 / (主査)教授 渡邊 直樹, 教授 安達 泰治, 教授 江藤 浩之 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Application of magnetic torque on the bacterial flagellar motorLim, Ren Chong January 2015 (has links)
There is a strong need to develop a mechanical method to apply external torque to the bacterial flagellar motor. Such a method will allow us to probe the behaviour of the motor at a range of different speeds under different external conditions. In this thesis, I explored various methods to deliver torque at the single-molecule level, in particular the use of angular optical trapping and magnetic tweezers. I have identified rutile particles as suitable handles for use in angular optical trapping due to their high birefringence. Further progress was not achieved using angular optical trapping due to the lack of a suitable method to attach birefringent particles to the bacterial flagellar motor. On the other hand, I was able to make further progress using magnetic tweezers. A highly-reproducible and high-yielding magnetic bead assay was developed along with electromagnets capable of generating fast-rotating magnetic fields at magnitudes on the order of tens of mT. Using the system of delivering magnetic torque developed, I was able to stall and rotate the motor forward at speeds up to 220 Hz and in the reverse direction. Stalling experiments carried out on the motor revealed the stator mechanosensing depends on torque and not rotation. Signatures of stators dropping out at low load experiments further confirm the load dependence of stators.
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The Structural Basis for Microtubule Binding and Release by DyneinRedwine, William Bret 06 February 2015 (has links)
Eukaryotic cells face a considerable challenge organizing a complicated interior with spatial and temporal precision. They do so, in part, through the deployment of the microtubule- based molecular motors kinesin and dynein, which translate chemo-mechanical force production into the movement of diverse cargo. Many aspects of kinesin’s motility mechanism are now known in detail, whereas fundamental aspects of dynein’s motility mechanism remain unclear. An important unresolved question is how dynein couples rounds of ATP binding and hydrolysis to changes in affinity for its track, a requisite for a protein that takes steps. Here we report a sub- nanometer cryo-EM reconstruction of the high affinity state of dynein’s microtubule binding domain in complex with the microtubule. Using molecular dynamics flexible fitting, we determined a pseudoatomic model of the high affinity state. When compared to previously reported crystal structure of the free microtubule binding domain, our model revealed the conformational changes underlying changes in affinity. Surprisingly, our simulations suggested that specific residues within the microtubule binding domain may tune dynein’s affinity for the microtubule. We confirmed this observation by directly measuring dynein’s motile properties using in vitro single molecule motility assays, which demonstrated that single point mutations of these residues dramatically enhance dynein’s processivity. We then sought to understand why dynein has been selected to be a restrained motor, and found that dynein-driven nuclear oscillations in budding yeast are defective in the context of highly processive mutants. Together, these results provide a mechanism for the coupling of ATPase activity to microtubule binding and release by dynein, and the degree to which evolution has fine-tuned this mechanism. I conclude with a roadmap of future approaches to gain further insight into dynein’s motility mechanism, and describe our work developing materials and methods towards this goal.
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Visualizing Influenza Virus Membrane Fusion: Inhibition and KineticsOtterstrom, Jason John 04 February 2015 (has links)
The influenza virus hemagglutinin (HA) surface protein is a primary antigenic target for neutralization of viral infection. HA also mediates membrane fusion between the virus and a cell, which is the first critical step during infection. Traditional techniques to study infection neutralization by antibodies or the membrane fusion process rely on ensemble measurements, confounding the precise mechanism of infection neutralization and obscuring transient conformational intermediates. This dissertation describes advances made in a fluorescence microscopy-based single-particle fusion assay to overcome the limitations of ensemble measurements in these types of studies. Virus particles are labeled to visualize lipid mixing between a virus and a target membrane formed upon a glass or polymer support. Optionally, the viral lumen can be labeled to visualize the subsequent release of viral contents.
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Facile Fabrication of Meso-to-Macroscale Single-Molecule Arrays for High-Throughput Digital AssaysJanuary 2019 (has links)
abstract: One of the single-most insightful, and visionary talks of the 20th century, “There’s plenty of room at the bottom,” by Dr. Richard Feynman, represented a first foray into the micro- and nano-worlds of biology and chemistry with the intention of direct manipulation of their individual components. Even so, for decades there has existed a gulf between the bottom-up molecular worlds of biology and chemistry, and the top-down world of nanofabrication. Creating single molecule nanoarrays at the limit of diffraction could incentivize a paradigm shift for experimental assays. However, such arrays have been nearly impossible to fabricate since current nanofabrication tools lack the resolution required for precise single-molecule spatial manipulation. What if there existed a molecule which could act as a bridge between these top-down and bottom-up worlds?
At ~100-nm, a DNA origami macromolecule represents one such bridge, acting as a breadboard for the decoration of single molecules with 3-5 nm resolution. It relies on the programmed self-assembly of a long, scaffold strand into arbitrary 2D or 3D structures guided via approximately two hundred, short, staple strands. Once synthesized, this nanostructure falls in the spatial manipulation regime of a nanofabrication tool such as electron-beam lithography (EBL), facilitating its high efficiency immobilization in predetermined binding sites on an experimentally relevant substrate. This placement technology, however, is expensive and requires specialized training, thereby limiting accessibility.
The work described here introduces a method for bench-top, cleanroom/lithography-free, DNA origami placement in meso-to-macro-scale grids using tunable colloidal nanosphere masks, and organosilane-based surface chemistry modification. Bench-top DNA origami placement is the first demonstration of its kind which facilitates precision placement of single molecules with high efficiency in diffraction-limited sites at a cost of $1/chip. The comprehensive characterization of this technique, and its application as a robust platform for high-throughput biophysics and digital counting of biomarkers through enzyme-free amplification are elucidated here. Furthermore, this technique can serve as a template for the bottom-up fabrication of invaluable biophysical tools such as zero mode waveguides, making them significantly cheaper and more accessible to the scientific community. This platform has the potential to democratize high-throughput single molecule experiments in laboratories worldwide. / Dissertation/Thesis / Doctoral Dissertation Biomedical Engineering 2019
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NUCLEAR ENVELOPE TRANSMEMBRANE PROTEIN DISTRIBUTION AND TRANSPORT STUDIED BY SINGLE-MOLECULE MICROSCOPYMudumbi, Krishna Chaitanya January 2018 (has links)
The nucleus of eukaryotic cells is a vitally important organelle that sequesters the genetic information of the cell, and protects it with the help of two highly evolved structures, the nuclear envelope (NE) and nuclear pore complexes (NPCs). Together, these two structures mediate the bidirectional trafficking of molecules between the nucleus and cytoplasm by forming a barrier. NE transmembrane proteins (NETs) embedded in either the outer nuclear membrane (ONM) or the inner nuclear membrane (INM) play crucial roles in both nuclear structure and functions, including: genome architecture, epigenetics, transcription, splicing, DNA replication, nuclear structure, organization and positioning. Furthermore, numerous human diseases are associated with mutations and mislocalization of NETs on the NE. There are still many fundamental questions that are unresolved with NETs, but we focused on two major questions: First, the localization and transport rate of NETs, and second, the transport route taken by NETs to reach the INM. Since NETs are involved with many of the mechanisms used to maintain cellular homeostasis, it is important to quantitatively determine the spatial locations of NETs along the NE to fully understand their role in these vital processes. However, there are limited available approaches for this task, and moreover, these methods provide no information about the translocation rates of NETs between the two membranes. Furthermore, while the trafficking of soluble proteins between the cytoplasm and the nucleus has been well studied over the years, the path taken by NETs into the nucleus remains in dispute. At least four distinct models have been proposed to suggest how transmembrane proteins destined for the INM cross the NE through NPC-dependent or NPC-independent mechanisms, based on specific features found on the soluble domains of INM proteins. In order to resolve these two major questions, it is necessary to employ techniques with the capabilities to observe these dynamics at the nanoscale. Current experimental techniques are unable to break the temporal and spatial resolution barriers required to study these phenomena. Therefore, we developed and modified single-molecule techniques to answer these questions. First, to study the distribution of NETs on the NE, we developed a new single-molecule microscopy method called single-point single-molecule fluorescence recovery after photobleaching (smFRAP), which is able to provide spatial resolution <10 nm and, furthermore, provide previously unattainable information about NET translocation rates from the ONM to INM. Secondly, to examine the transport route used by NETs destined for the INM, we used a single-molecule microscopy technique previously developed in our lab called single-point edge-excitation sub-diffraction (SPEED) microscopy, which provides spatio-temporal resolution of <10 nm precision and 0.4 ms detection time. The major findings from my doctoral research work can be classified into two categories: (i) Technical developments to study NETs in vivo, and (ii) biological findings from employing these microscopy techniques. In regards to technical contributions, we created and validated of a new single-molecule microscopy method, smFRAP, to accurately determine the localization and distribution ratios of NETs on both the ONM and INM in live cells. Second, we adapted SPEED microscopy to study transmembrane protein translocation in vivo. My work has also contributed four main biological findings to the field: first, we determined the in vivo translocation rates for lamin-B receptor (LBR), a major INM protein found in the nucleus of cells. Second, we verified the existence of peripheral channels in the scaffolding of NPCs and, for the first time, directly observed the transit of INM proteins through these channels in live cells. Third, our research has elucidated the roles that both the nuclear localization signal (NLS) and intrinsically disordered (ID) domains play in INM protein transport. Finally, my work has elucidated which transport routes are used by NETs destined to localize in the INM. / Biology
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DNA programmed assembly of active matter at the micro and nano scalesGonzalez, Ibon Santiago January 2017 (has links)
Small devices capable of self-propulsion have potential application in areas of nanoscience where autonomous locomotion and programmability are needed. The specific base-pairing interactions that arise from DNA hybridisation permit the programmed assembly of matter and also the creation of controllable dynamical systems. The aim of this thesis is to use the tools of DNA nanotechnology to design synthetic active matter at the micro and nano scales. In the first section, DNA was used as an active medium capable of transporting information faster than diffusion in the form of chemical waves. DNA waves were generated experimentally using a DNA autocatalytic reaction in a microfluidic channel. The propagation velocity of DNA chemical waves was slowed down by creating concentration gradients that changed the reaction kinetics in space. The second section details the synthesis of chemically-propelled particles and the use of DNA as a 'programmable glue' to mediate their interactions. Janus micromotors were fabricated by physical vapour deposition and a wet-chemical approach was demonstrated to synthesise asymmetrical catalytic Pt-Au nanoparticles that function as nanomotors. Dynamic light scattering measurements showed nanomotor activity that depends on H<sub>2</sub>O<sub>2</sub> concentration, consistent with chemical propulsion. Gold nanoparticles/Origami hybrids were assembled in 2D lattices of different symmetries arranged by DNA linkers. The third section details the design process and synthesis of nanomotors using DNA as a structural scaffold. 3D DNA Origami rectangular prisms were functionalised site-specifically with bioconjugated catalysts, i.e. Pt nanoparticles and catalase. Enzymatic nanomotors were also conjugated to various cargoes and their motor activity was demonstrated by Fluorescence Correlation Spectroscopy. In the final section, control mechanisms for autonomous nanomotors are studied, which includes the conformational change of DNA aptamers in response to chemical signals, as well as a design for an adaptive dynamical system based on DNA/enzyme reaction networks.
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Pattern Recognition in Single Molecule Force Spectroscopy DataPaulin, Hilary 05 September 2013 (has links)
We have developed an analytical technique for single molecule force spectroscopy (SMFS) data that avoids filtering prior to analysis and performs pattern recognition to identify distinct SMFS events. The technique characterizes the signal similarity between all curves in a data set and generates a hierarchical clustering tree, from which clusters can be identified, aligned, and examined to identify key patterns. This procedure was applied to alpha-lactalbumin (aLA) on polystyrene substrates with flat and nanoscale curvature, and bacteriorhodopsin (bR) adsorbed on mica substrates. Cluster patterns identified for the aLA data sets were associated with different higher-order protein-protein interactions. Changes in the frequency of the patterns showed an increase in the monomeric signal from flat to curved substrates. Analysis of the bR data showed a high level of multiple protein SMFS events and allowed for the identification of a set of characteristic three-peak unfolding events.
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