Development of fast-dissociating recombinant antibodies for high-density multiplexed IRIS super-resolution microscopy / 多重高密度超解像顕微鏡IRISのための迅速解離リコンビナント抗体の開発

Zhang, Qianli

24 November 2022

京都大学 / 新制・課程博士 / 博士(生命科学) / 甲第24304号 / 生博第487号 / 新制||生||65(附属図書館) / 京都大学大学院生命科学研究科高次生命科学専攻 / (主査)教授 渡邊 直樹, 教授 見学 美根子, 教授 今吉 格 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM

Super-resolution microscopy

IRIS

Antibody engineering

Nanobody

Fv-clasp

Multiplexed imaging

Synaptic connection

460

Utilizing DNA Nanostructures for the study of the Force Dependency of Receptor – Ligand Interactions

Patton, Randy Alexander

January 2017

No description available.

Mechanical Engineering

DNA Origami

FRET

Single Molecule Force Spectroscopy

Biomechanical Interactions

Super Resolution Microscopy

Estimating rigid motion in sparse sequential dynamic imaging: with application to nanoscale fluorescence microscopy

Hartmann, Alexander

22 April 2016

No description available.

510

motion estimation

image registration

semiparametrics

M-estimation

nanoscale fluorescence microscopy

super resolution microscopy

asymptotic normality

sparsity

registration

Mathematics (PPN61756535X)

N-methyl 4-methyl amphetamine N-alkyl chain extension differentially affects ion flux at the human dopamine and norepinephrine transporters

Harris, Alan C., Jr.

01 January 2016

Amphetamine (AMPH) and its derivatives embody a remarkable breadth of pharmacology. These molecules exert their effects, both therapeutic and pathological, at the human monoamine transporters, which tune synaptic dynamics by evacuating monoamine neuromodulators from the synapse subsequent to neuronal impulses. These transporters are electrogenic, and the transporter-mediated current can be correlated to a surrogate measure of the change in membrane voltage: Ca++ currents from co-transfected L-type Ca++ channels. The present work makes use of this assay, with which it is possible to derive pharmacodynamic metrics from both substrates and inhibitors. This work presents data on a heretofore-unstudied class of amphetamine analogs: the enantiomers of N-Me 4-Me AMPH and N-Et 4-Me AMPH. Remarkably, while both enantiomers of the N-Me version of this compound function as substrates at hDAT, both enantiomers of the N-Et version are inhibitors. This switch does not occur at hNET, where all enantiomers of both N-Me and N-Et 4-Me AMPH function as substrates. Further, (S)-N-Et 4-Me AMPH is a substrate at dDAT. EC50 and IC50 values for all drugs at both transporters are presented. I present the results of super-resolution microscopic co-localization studies on the plasmalemmal spatial relation of the human dopamine transporter and voltage gated calcium channel, L-type 1.2 (CaV1.2). I discuss future aims toward a unified understanding of the mechanisms of monoamine transporter function, with an emphasis on what amphetamine can illuminate in this regard.

amphetamine

hDAT

dDAT

hNET

voltage-gated calcium channels

S1 site

N-SIM super-resolution microscopy

Chemical and Pharmacologic Phenomena

Biochemical and structural studies of amyloid proteins

Wirthensohn, David Christopher

January 2019

Amyloidogenic neurodegenerative disorders such as Alzheimer's disease (AD) and Parkinson's disease (PD) are an important health issue. However, the underlying molecular mechanisms of the disease-related protein aggregates, that are present in humans, are only understood partially. I have used and developed biophysical methods to study the structural and biological properties of individual aggregates of Amyloid β peptide and α-Synuclein, proteins whose aggregation is associated with the development of Alzheimer's and Parkinson's disease respectively. I expanded the single aggregate visualisation through enhancement (SAVE) technique, which is a method based on the fluorescent dye Thioflavin T (ThT) that reversibly bind to the aggregates and whose fluorescence increases upon binding. I firstly explored the use of other dyes for these experiments and found that a ThT dimer has higher affinity to α-Synuclein aggregates in vitro. I then applied the SAVE method to the cerebral spinal fluid (CSF) of a cohort of AD patients and control CSF and observed no clear difference in aggregate number. However, these experiments provided insights into how antibodies bind the aggregates in human CSF. I could show, that despite altering the Ca2+ influx into both cells and vesicles, the antibody did not measurably affect the aggregate structure. To study the size specific effects of the Amyloid β 42 (Aβ42) peptide in more detail, I used and optimised gradient ultracentrifugation combined with single aggregate imaging to study the structural properties of the isolated aggregates. This aggregation kinetic independent method allowed me to compare the properties of fluorescently labelled and unlabelled Aβ42 and characterize the size dependent properties of aggregates in a single experiment. Since I could measure the relative concentration of different size aggregates it was also possible to compare the properties of single aggregates of different sizes. I then used biological assays to examine the ability of aggregates to permeabilise membranes resulting in the entry of calcium ions, and their ability to induce TNFα production in microglia cells. Both processes are thought to play key roles in the development of AD. I found that small soluble oligomers are most potent at inducing Ca2+ influx, whereas longer protofilaments are the most potent inducers of TNFα production. My results suggest that the mechanism by which aggregates damage cells changes as aggregation proceeds, as longer aggregates with different structures are formed. Protofilaments with a diameter of 1 nm or less have a structure that could make them particularly potent at causing the signalling of toll-like receptors, providing a molecular basis for their ability to induce TNFα production.

Mécanisme d’action d’une classe d’antibiotiques depuis leur entrée jusqu’à leur cible chez la bactérie : visualisation en temps réel / Mechanism of action of a class of antibiotics from their entry to their target in bacteria : a real time visualization

Okuda, Maho

30 September 2015

Des techniques variées de visualisation de molécules d’intérêt sur cellules vivantes ou fixées ont permis de suivre leur synthèse, localisation, dégradation et autres activités. Dans cette étude, nous avons développé deux outils de fluorescence pour étudier la synthèse des protéines sur bactéries vivantes. Le premier décrit l’utilisation du système Spinach pour l’imagerie du ribosome. Cette approche diffère des méthodes conventionnelles qui utilisent des protéines fluorescentes puisque l’ARN ribosomal 16S contient un aptamère qui rend fluorescent un composé fluorogène. Une étude comparative de la performance de différents aptamères Spinach a été réalisée. Un deuxième outil se focalise sur l’accumulation d’un antibiotique de la famille des aminoglycosides (ligand du ribosome) conjugué à un fluorophore. Ce nouveau conjugué, qui a conservé son activité bactéricide permet pour la première fois de visualiser l’accumulation de l’antibiotique sur bactérie vivante. Cela permet une analyse au niveau de la cellule unique d’une population bactérienne exposée à l’antibiotique. Nous avons également obtenu des données sur la localisation de l’antibiotique une fois qu’il a pénétré dans la bactérie à une résolution inégalée par microscopie super-résolutive. Nous espérons que ces deux méthodes vont maintenant permettre une meilleure compréhension de la synthèse des protéines et fournir une vue nouvelle de la pénétration des antibiotiques dans les bactéries pour y produire leur action bactéricide. / Various visualizing techniques have previously enabled monitoring the fate of molecules of interest: their expression, localization, degradation and other activities in live or fixed cells. In this study, we have developed two fluorescent tools to study protein synthesis in live bacterial cell. The first one describes the application of Spinach system to ribosomes imaging. This is different from conventional methods (that use fluorescent proteins) in that 16S rRNA contains an inserted RNA aptamer that elicits fluorescence of a fluorogenic compound. A comparative study of the performance of different Spinach aptamers was performed here. A second system focuses on the uptake of a fluorescently labeled ligand of the ribosome, an antibiotic of the class of aminoglycosides. This novel conjugate, which kept its bactericidal activity allows for the first time imaging of aminoglycoside uptake on live bacteria. This opened the door to a single cell analysis of bacterial cell populations. We also obtained data about the localization of the antibiotic once inside the bacteria to an unprecedented resolution using super resolution microscopy. We hope that both of these methods will contribute to a better understanding of protein synthesis as well as provide a novel view on the way antibiotics penetrate into cells and perform their bactericidal action.

Microscopie de fluorescence

Microscopie super-résolutive

Traduction

Ribosome

Aminoglycosides

Aptamère Spinach

Fluorescence microscopy

Super-resolution microscopy

Translation

Ribosome

Aminoglycosides

Spinach aptamer

Widefield fluorescence correlation spectroscopy

Nicovich, Philip R.

26 March 2010

Fluorescence correlation spectroscopy has become a standard technique for modern biophysics and single molecule spectroscopy research. Here is presented a novel widefield extension of the established single-point technique. Flow in microfluidic devices was used as a model system for microscopic motion and through widefield fluorescence correlation spectroscopy flow profiles were mapped in three dimensions. The technique presented is shown to be more tolerant to low signal strength, allowing image data with signal-to-noise values as low as 1.4 to produce accurate flow maps as well as utilizing dye-labeled single antibodies as flow tracers. With proper instrumentation flows along the axial direction can also be measured. Widefield fluorescence correlation spectroscopy has also been utilized to produce super-resolution confocal microscopic images relying on the single-molecule microsecond blinking dynamics of fluorescent silver clusters. A method for fluorescence modulation signal extraction as well as synthesis of several novel noble metal fluorophores is also presented.

Correlation spectroscopy

Super resolution microscopy

Single molecule spectroscopy

Velocimetry

Microfluidics

Fluorescence spectroscopy

Spectrum analysis

Flow visualization

Axial flow

Image analysis

Single particle imaging in the cell nucleus : a quantitative approach

Récamier, Vincent

20 November 2013

The cell nucleus is a chemical reactor. Nuclear components interact with each other to express genes, duplicate the chromosomes for cell division, and protect DNA from alteration. These reactions are regulated along the cell cycle and in response to stress. One of the fundamental nuclear processes, transcription, enables the production of a messenger RNA from a template DNA sequence. While mandatory for the cell, transcription nevertheless may involve a very small number of molecules. Indeed, a single gene would have only few copies in the genome. During my PhD, I studied nuclear processes in human cells nuclei at the single molecule level with novel imaging techniques. I developed new statistical tools to quantify nuclear components movement that revealed a dynamic nuclear architecture. Since the 90s, simple methods have been developed for the observation of single molecules in the cell. These experiments can be conducted in an ordinary inverted microscope. We used these methods to monitor nuclear molecules called transcription factors (TF) that regulate transcription. From TF dynamics, we concluded that nuclear exploration by transcription factors is regulated by their chemical interactions with partners. The organization of the components of the nucleus guide transcription factors in their search of a gene. As an example of this organization, we then studied chromatin, the de-condensed form of nuclear DNA, proving that it displays the characteristics of a self-organized fractal structure. This structure changes in response to cellular fate and stress. In yeast, we showed that the interminglement of chromatin constrained DNA locus movement in a reptation regime. All these results show the interdependence of the structure of the nucleus and of its chemical reactions. With combination of realistic modeling and high resolution microscopy, we have enlightened the specificity of the nucleus as a chemical reactor. This thesis has also enabled the development of accurate methods for the statistical analysis of single molecule data.

Nucleus organization

Transcription

Target search

Super resolution microscopy

Single particle imaging in the cell nucleus : a quantitative approach

Récamier, Vincent

20 November 2013

The cell nucleus is a chemical reactor. Nuclear components interact with each other to express genes, duplicate the chromosomes for cell division, and protect DNA from alteration. These reactions are regulated along the cell cycle and in response to stress. One of the fundamental nuclear processes, transcription, enables the production of a messenger RNA from a template DNA sequence. While mandatory for the cell, transcription nevertheless may involve a very small number of molecules. Indeed, a single gene would have only few copies in the genome. During my PhD, I studied nuclear processes in human cells nuclei at the single molecule level with novel imaging techniques. I developed new statistical tools to quantify nuclear components movement that revealed a dynamic nuclear architecture. Since the 90s, simple methods have been developed for the observation of single molecules in the cell. These experiments can be conducted in an ordinary inverted microscope. We used these methods to monitor nuclear molecules called transcription factors (TF) that regulate transcription. From TF dynamics, we concluded that nuclear exploration by transcription factors is regulated by their chemical interactions with partners. The organization of the components of the nucleus guide transcription factors in their search of a gene. As an example of this organization, we then studied chromatin, the de-condensed form of nuclear DNA, proving that it displays the characteristics of a self-organized fractal structure. This structure changes in response to cellular fate and stress. In yeast, we showed that the interminglement of chromatin constrained DNA locus movement in a reptation regime. All these results show the interdependence of the structure of the nucleus and of its chemical reactions. With combination of realistic modeling and high resolution microscopy, we have enlightened the specificity of the nucleus as a chemical reactor. This thesis has also enabled the development of accurate methods for the statistical analysis of single molecule data.

Nucleus organization

Transcription

Target search

Super resolution microscopy

STED nanoscopy of synaptic substructures in living mice

Masch, Jennifer-Magdalena

19 October 2017

No description available.

571.4

super-resolution microscopy

in vivo STED nanoscopy

PSD-95

far-red tissue imaging

protein labeling

Biologie (PPN619462639)