High-resolution optical analyses of IP3-evoked Ca2+ signals

Mataragka, Stefania

January 2019

Ca2+ is a universal intracellular messenger that regulates many cellular responses. Most cells express inositol 1,4,5-trisphosphate receptors (IP3R) that mediate Ca2+ release from the endoplasmic reticulum (ER) when they bind IP3 produced after activation of cell-surface receptors. Vertebrate genomes encode three closely related subtypes of IP3R (IP3R1-3). High-resolution optical analyses have revealed a hierarchy of IP3-evoked Ca2+ signals that are thought to arise from the co-regulation of IP3Rs by IP3 and Ca2+. The smallest events ('blips') report the opening of single IP3Rs, Ca2+ 'puffs' report the almost simultaneous opening of a few clustered IP3Rs, and as stimulus intensities increase further Ca2+ signals propagate regeneratively as Ca2+ waves. The aim of this study was to establish whether all three IP3R subtypes can generate Ca2+ puffs. I first used a haploid cell line (HAP1 cells) to generate, using CRISPR/Cas9, a line lacking all endogenous IP3Rs. However, for analyses of Ca2+ puffs, I used HEK cells that had been engineered, using CRISPR/Cas9 to disrupt endogenous genes, to express single IP3R subtypes. Local Ca2+ signals evoked by flash-photolysis of caged- IP3 were recorded using Cal520 and total internal reflection fluorescence (TIRF) microscopy in human embryonic kidney (HEK) cells. The Flika algorithm was used, and validated, for automated detection of Ca2+ puffs and to measure their properties. IP3 evoked Ca2+ puffs in wild-type HEK cells and in cells expressing single IP3R subtypes. In wild-type cells, the Ca2+ signals invariably propagated regeneratively to give global increases in cytosolic [Ca2+]. This occurred less frequently in cells expressing single IP3R subtypes, commensurate with their lower overall levels of IP3R expression. The properties of the Ca2+ puffs, including their rise and decay times, durations, the size of the unitary fluorescence steps as channels closed channel during the falling phase, and the estimated number of active IP3Rs in each Ca2+ puff, were broadly similar in each of the four cell lines. The latter observation suggests that despite lower overall levels of IP3R expression (~30%) in cells with single subtypes relative to WT cells, there is a mechanism that ensures formation of similarly sized IP3R clusters. The only significant differences between cell lines were the slower kinetics of the Ca2+ puffs evoked by IP3R2, which may suggest dissociation of IP3 from its receptor contributes to the termination of Ca2+ puffs. My results demonstrate, for the first time, that all three IP3R subtypes can generate Ca2+ puffs. I conclude that Ca2+ puffs are fundamental building blocks of all IP3-evoked Ca2+ signals.

Investigation of Amyloid β Oligomer Dissociation Mechanisms by Single Molecule Fluorescence Techniques

Abdalla, Hope Cook

01 January 2019

Alzheimer’s disease (AD) is currently considered the most prevalent neurodegenerative disease and places a large financial burden on society as healthcare resources are limited and the disease does not have a cure. Alzheimer’s disease is characterized by the presence of amyloid beta (Aβ) plaques and neurofibrillary tangles; however current literature suggests Aβ oligomers are the main aggregating species leading to AD symptoms. Therefore, the underlying cause of Alzheimer’s, accumulation of amyloid beta, is currently being studied in hopes of developing treatment options. Our research aims at determining the mechanism and kinetics of Aβ oligomer dissociation into non-toxic monomers in the presence of denaturants or small molecule dissociators. These highly active small molecule dissociators, selected from the Apex Screen 5040 library, were previously identified by ELISA studies by the laboratory of Dr. Harry LeVine. We have used fluorescence correlation spectroscopy (FCS) to characterize the size distribution and mole fraction of synthetically prepared fluorescein labeled Aβ (1-42) oligomers. Our FCS results show that in the presence of denaturants or small molecule dissociators, oligomer dissociation may proceed by at least two different mechanisms; high order cooperative dissociation and linear dissociation. A cooperative mechanism is more desirable for therapeutics as oligomer directly dissociates into monomer rather than through various oligomer intermediates. Our FCS studies show the most efficient dissociators proceed through the cooperative dissociation mechanism. We also observed a large retardation of the oligomer dissociation in the presence of gallic acid. We also started preliminary work to develop a total internal reflection fluorescence (TIRF) spectroscopy method to image Aβ (1-42) oligomers. This technique if successful will help to verify the two distinct mechanisms seen by FCS or determine if there is one mechanism that occurs at different rates as TIRF allows for faster analysis.

Alzheimer’s disease

Amyloid β

oligomer dissociators

fluorescence correlation spectroscopy

dissociation mechanisms

Biochemistry

Chemistry

Experimental study of the kinetics of two systems : DNA complexation by the NCp7 protein and probe dynamics in a glassy colloidal suspension / Etude expérimentale de cinétique de deux systèmes : complexation de l'ADN par la protéine NCp7 et dynamique d'une suspension colloïdale vitreuse

Klajner, Piotr

11 May 2012

Dans la première partie de cette thèse, nous étudions la cinétique de la complexation d'un double brin d'ADN par la protéine NCp7. Pour ce faire, nous étudions l'évolution des propriétés mécaniques de l'ADN au fur et à mesure de sa complexation, en étirant la complexe ADN/NCp7 à l'aide d'un montage de piégeage optique. Nous avons observé que la longueur de persistance du complexe diminue au fur et à mesure de la complexation. En utilisant un modèle statistique décrivant l'évolution de la flexibilité de l'ADN complexé par NCp7. Notre principal résultat est que la fraction//phi de paires de bases ayant réagi n'est pas une fonction linéaire du temps aux faibles //phi. Nous interprétons nos résultats en supposant que l'adsorption de NCp7 sur l'ADN est fortement coopérative. Dans deuxième chapitre, nous décrivons la dynamique de particules sondes dans une suspension vitreuse colloïdale de Laponite. La Laponite est une particule colloïdale discoïdale de 25nm de diamètre et de 0.92 nm d'épaisseur. Nous utilisons une expérience de microscopie en onde évanescente, et suivons le mouvement de particules fluorescentes de latex. Nous imageons ensuite ces particules. Nous montrons que, pour un mouvement possédant une seule échelle de temps caractéristique, elle est simplement une fonction linéaire du temps. Nous obtenons que, quelle que soit leur taille, le mouvement des particules sondes peut être décrit par une succession de deux modes dynamiques, où le mode le plus rapide correspond à la diffusion des particules dans un fluide viscoélastique. / In the first part of this thesis, we study the kinetics of the complexation of a double-stranded DNA byNCp7 protein. To do this, we study the evolution of mechanical properties of DNA and its complexation by stretching the DNA/NCp7 complex with a optical trap. We observed that the persistence length of the complex decreases progressively during the complexation. Using astatistical model we describe the evolution of the flexibility of DNA complexed with NCp7. Our main result is that the fraction phi of base pairs that have reacted is not a linear function of time at low phi.We interpret our results assuming that the adsorption of NCp7 on DNA is highly cooperative. In the second chapter, we describe the dynamics of probe particles in a colloidal glassy suspension of Laponite. Laponite is a colloidal discoidal particle of 25 nm in diameter and 0.92 nm thick. We take advantage of evanescent wave microscopy, and follow the movement of fluorescent latex particles.Then we image these particles. We show that for a movement that has a single characteristic time scale, it is simply a linear function of time. We find that, what ever their size, the motion of probe particles can be described by a succession of two dynamic modes, where the fastest mode corresponds to the diffusion of particles in a viscoelastic fluid.

NCp7

Laponite

Single molecule

Real time

Optical tweezers

Optical trap

TIRFM

541.34

Experimental study of the kinetics of two systems : DNA complexation by the NCp7 protein and probe dynamics in a glassy colloidal suspension

Klajner, Piotr

11 May 2012

In the first part of this thesis, we study the kinetics of the complexation of a double-stranded DNA byNCp7 protein. To do this, we study the evolution of mechanical properties of DNA and its complexation by stretching the DNA/NCp7 complex with a optical trap. We observed that the persistence length of the complex decreases progressively during the complexation. Using astatistical model we describe the evolution of the flexibility of DNA complexed with NCp7. Our main result is that the fraction phi of base pairs that have reacted is not a linear function of time at low phi.We interpret our results assuming that the adsorption of NCp7 on DNA is highly cooperative. In the second chapter, we describe the dynamics of probe particles in a colloidal glassy suspension of Laponite. Laponite is a colloidal discoidal particle of 25 nm in diameter and 0.92 nm thick. We take advantage of evanescent wave microscopy, and follow the movement of fluorescent latex particles.Then we image these particles. We show that for a movement that has a single characteristic time scale, it is simply a linear function of time. We find that, what ever their size, the motion of probe particles can be described by a succession of two dynamic modes, where the fastest mode corresponds to the diffusion of particles in a viscoelastic fluid.

[CHIM:OTHE] Chemical Sciences/Other

[CHIM:OTHE] Chimie/Autre

Single molecule

Real time

Optical tweezers

Optical trap

TIRFM

Single-molecule studies of bacterial DNA replication and translesion synthesis

Zhao, Gengjing

January 2018

Faithful replication of genomic DNA is crucial for the survival of a cell. In order to achieve high-level accuracy in copying its genome, all cells employ replicative DNA polymerases that have intrinsic high fidelity. When an error occurs on the template DNA strand, in the form of lesions caused by diverse chemicals, reactive oxygen species, or UV light, the high-fidelity replicative DNA polymerases are stalled. To bypass these replication blocks, cells harbor multiple specialized translesion DNA polymerases that are error-prone and therefore able to accommodate the lesions and continue DNA synthesis. As a result of their low fidelity, the translesion polymerases are associated with increased mutagenesis, drug resistance, and cancer. Therefore, the access of the translesion polymerases to DNA needs to be tightly controlled, but how this is achieved has been the subject of debate. This Thesis presents the development of a co-localization single-molecule spectroscopy (CoSMoS) method to directly visualize the loading of the Escherichia coli replicative polymerase on DNA, as well as the exchange between the replicative polymerase and the translesion polymerases Pol II and Pol IV. In contrast to the toolbelt model for the exchange between the polymerases, this work shows that the translesion polymerases Pol II and Pol IV do not form a stable complex with the replicative polymerase Pol IIIα on the β-clamp. Furthermore, we find that the sequential activities of the replication proteins: clamp loader, clamp, and Pol IIIα, are highly organized while the exchange with the translesion polymerases is disordered. This exchange is not determined by lesion-recognition but instead a concentration-dependent competition between the replicative and translesion polymerases for the hydrophobic groove on the surface of the β-clamp. Hence, our results provide a unique insight into the temporal organization of events in DNA replication and translesion synthesis.

The Copper(I)-catalyzed Azide–Alkyne Cycloaddition: A Modular Approach to Synthesis and Single-Molecule Spectroscopy Investigation into Heterogeneous Catalysis

Decan, Matthew

January 2015

Click chemistry is a molecular synthesis strategy based on reliable, highly selective reactions with thermodynamic driving forces typically in excess of 20 kcal mol-1. The 1,3-dipolar cycloaddition of azides and alkynes developed by Rolf Huisgen saw dramatic rate acceleration using Cu(I) as a catalyst in 2002 reports by Barry Sharpless and Morten Meldal enabling its click chemistry eligibility. Since these seminal reports, the copper(I)-catalyzed azide-alkyne cycloaddition (CuAAC) has become the quintessential click reaction finding diverse utility. The popularity of the CuAAC has naturally led to interest in new catalyst systems with improved efficiency, robustness, and reusability with particular focus on nanomaterial catalysts, a common trend across the field of catalysis. The high surface area of nanomaterials lends to their efficacy as colloidal and heterogeneous nanocatalysts, but the latter boasts the added benefit of easy separation and recyclability. With any heterogeneous catalyst, a common question arises as to whether the active catalyst species is truly heterogeneous or rather homogeneous through metal ion leaching. Differentiating these processes is critical, as the latter would result in reduced efficiency, higher cost, and inevitable environmental and heath side effects. This thesis explores the CuAAC from an interdisciplary approach. First as a synthetic tool, applying CuAAC-formed triazoles as functional, modular building blocks in the synthesis of optical cation sensors by combining azide and alkyne modified components to create a series of sensors selective for different metal cations. Next, single-molecule spectroscopy techniques are employed to observe the CuNP-catalyzed CuAAC in real time. Combining bench-top techniques with single-molecule microscopy to monitor single-catalytically generated products proves to be an effective method to establish catalysis occurs directly at the surface of copper nanoparticles, ruling out catalysis by ions leached into solution. This methodology is extended to mapping the catalytic activity of a commercial heterogeneous catalyst by applying super-localization analysis of single-catalytic events. The approach detailed herein is a general one that can be applied to any catalytic system through the development of appropriate probes. This thesis demonstrates single-molecule microscopy as an accessible, effective, and unparalleled tool for exploring the catalytic activity of nanomaterials by monitoring single-catalytic events as they occur.

Click Chemistry

CuAAC

Single-Molecule Fluorescence

Heterogeneous Catalysis

Single-Molecule Localization Microscopy

Copper

Nanomaterials

Metal Ion Sensing

Elucidation of subcellular regulation of voltage-dependent calcium channel functions via β subunit interacting molecules / 電位依存性Ca2+チャネルβサブユニット相互作用タンパク質による、細胞内局所的なCa2＋チャネル機能調節機構の解明に関する研究

Mitsuru, Hirano

24 July 2017

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第20633号 / 工博第4371号 / 新制||工||1679(附属図書館) / 京都大学大学院工学研究科合成・生物化学専攻 / (主査)教授 森 泰生, 教授 浜地 格, 教授 跡見 晴幸 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

voltage dependent Ca2+ channel

Rab3-interacting molecule

neurotransmitter release

voltage dependent inactivation

total internal reflection fluorescence

nuclear fraction

co-immunoprecipitation

500

An Investigation of a G-Quadruplex and Its Interactions with Human Replication Protein A at the Single Molecule Level

Malcolm, Dominic W.

15 May 2012

No description available.

Biology

Biophysics

Optics

Physics

FRET

single molecule

G-Quadruplex

GQ

Replication Protein A

RPA

smFRET

DNA

Biophysics

TIRFM

Relation entre l’annexine A6 et la phospholipase D1 pendant le processus d’exocytose dans les cellules PC12 / Interplay between AnnexinA6 and Phospholipase D1 during the process of exocytosis in PC12 cells

Do, Le Duy

19 September 2014

L'exocytose régulée, est un processus qui permet la communication entre les cellules à travers la sécrétion des hormones et des neurotransmetteurs. Dans les neurones et les cellules neuroendocrines, l'exocytose est strictement contrôlée par des signaux extracellulaires tels que le potentiel trans-membranaire et la fixation des ligands sur des récepteurs. Des progrès substantiels ont été effectués afin de comprendre le mécanisme moléculaire de l'exocytose. Les composants majeurs de la machinerie de sécrétion ont été dévoilés. Maintenant, la question qui émerge concerne le rôle de la plateforme de protéines qui semble avoir une action coordonnée entre chaque protéine. Dans le cas de la famille des annexines, qui est bien connue pour son action dans l'exocytose, leurs modes d'interactions séquentielles ou concertées avec d'autres protéines ainsi que leurs effets régulateurs sur l'exocytose ne sont pas encore bien établis. Des résultats précédents indiquent que l'Annexine A6 (AnxA6) affecte l'homéostasie du calcium et la sécrétion de la dopamine à partir des cellules PC12, utilisées comme un modèle cellulaire de neurosécrétion (Podszywalow Bartnicka et al., 2010). Afin de déterminer l'effet inhibiteur de l'AnxA6 sur l'exocytose de la dopamine, nous cherchons des partenaires moléculaires de l'AnxA6 dans les cellules PC12. Nous faisons l'hypothèse que l'AnxA6 interagit avec la PLD1, une enzyme active dans l'étape de la fusion des vésicules avec la membrane plasmique. En utilisant la microscopie confocale et la microscopie à onde évanescente, nous avons trouvé que l'isoforme 1 de l'AnxA6 et la PLD1 sont tous les deux recrutés sur la surface des vésicules au cours de la stimulation des cellules PC12. AnxA6 inhibait l'activité de la PLD comme indiqué par notre méthode d'analyse enzymatique au moyen de la spectroscopie infrarouge. En conclusion, nous proposons que l'AnxA6 n'est pas seulement impliquée dans la réorganisation des membranes par ses capacités à se lier avec des phospholipides négativement chargés et avec le cholestérol, mais elle influence également l'activité de la PLD1, changeant la composition lipidique des membranes / The regulated exocytosis is a key process allowing cell-cell communication through the release of hormone and neurotransmitters. In neurons and neuroendocrine cells, it is strictly controlled by extracellular signal such as transmembrane potential and ligand bindings to receptors. Substantial progress has been made to understand the molecular mechanism of exocytosis. Major components of secretory machinery have been brought to light. Now the emergent question concerns the role of scaffolding proteins that are thought to coordinate the action of each other. In the case of annexin family well known to be involved in exocytosis, their modes of –sequential or concerted- interactions with other proteins, and their regulatory effects on exocytosis are not very well established. Previous findings indicated that Annexin A6 (AnxA6) affected calcium homeostasis and dopamine secretion from PC12 cells, used as cellular model of neurosecretion (Podszywalow-Bartnicka et al., 2010). To determine the inhibitory effect of AnxA6 on exocytosis of dopamine, we were looking for molecular partners of AnxA6 in PC12 cells. We hypothesized that AnxA6 interacts with phospholipase D1 (PLD1), an enzyme involved in the fusion step. By using confocal microscopy and total internal reflection fluorescence microscopy, we found that isoform 1 of AnxA6 and Phospholipase D1 are both recruited on the surface of vesicles upon stimulation of PC12 cells. AnxA6 inhibited phospholipase D activity as revealed by our enzymatic assay based on infrared spectroscopy. To conclude, we propose that AnxA6 is not only implicated in membrane organization by its capacity to bind to negative charged phospholipids and to cholesterol, but AnxA6 is also affecting PLD1 activity, changing membrane lipids composition

Exocytose

Cellule PC12

Annexin A6

Phospholipase D1

Microscopie à onde évanescence

Microscopie confocale

Imagerie calcique

Spectroscopie infrarouge

Exocytosis

PC12 cell

Annexin A6

Phospholipase D1

Laser scanning confocal microscopy

Calcium imaging

Infrared spectroscopy

572

Combinatorial Microscopy of Molecular Interactions at Membrane Interfaces

Oreopoulos, John

13 June 2011

Biological membranes are heterogeneous two-dimensional fluids composed of lipids, sterols and proteins that act as complex gateways and define the cell boundary. The functions of these interfaces are diverse and specific to individual organisms, cell types, and tissues. Membranes must take up nutrients and small molecules, release waste products, bind ligands, transmit signals, convert energy, sense the environment, maintain cell adhesion, control cell migration, and much more while forming a tight barrier around the cell. The molecular mechanisms and structural details responsible for this diverse set of functions of biological membranes are still poorly understood, however. Developing new tools capable of probing and determining the local molecular organization, structure, and dynamics of membranes and their components is critical for furthering our knowledge about these important cellular processes that are often linked to health and diseases. Combinatorial microscopy takes advantage of the rich properties of light (intensity, wavelength, polarization, etc.) to create new forms of imaging that quantify the motions, orientations, and binding kinetics of the sample’s biomolecular constituents. These new optical imaging modalities can also be further combined with other types of microscopy to produce spatially correlated micrographs that provide complementary pieces of information about the sample under investigation that would otherwise remain hidden from the observer if the two imaging techniques were applied independently. The first part of this thesis provides a detailed account of the construction of a specialized hybrid microscopy platform that combines polarized total internal reflection fluorescence microscopy (pTIRFM) with atomic force microscopy (AFM) for the purpose of studying fundamental sterol-lipid and antimicrobial peptide-lipid interactions in model membranes. The second half describes a combined pTIRFM and Förster resonance energy transfer (FRET) imaging method to elucidate the oligomeric state and spatial distribution of carcinoembryonic-antigen-related cell-adhesion molecules (CEACAMs) in the membranes of living cells.

atomic force microscopy

fluorescence polarization microscopy

FRET microscopy

model membranes

supported lipid bilayers

antimicrobial peptides

charge-cluster mechanism

CEACAM

membrane protein

dimerization

oligomerization

combinatorial microscopy

AFM

pTIRFM

TIRFPM

0786