Pokročilé fluorescenční techniky ve výzkumu micelárních systémů a jejich interakcí s biopolymery / Advanced Fluorescence Techniques in Research on Micellar Systems and Their Interactions with Biopolymers

Holínková, Petra

January 2019

The dissertation thesis deals with study of advanced steady-state and time-resolved fluorescence techniques, which can be used for study of micellar systems properties. Selected fluorescence techniques were used for characterization of Septonex and CTAB cationic micellar systems and theirs interactions with hyaluronan. Fluorescent probe pyrene was used for determination of critical micelle concentration (CMC) and micellar aggregation number of these surfactants. The changes of fluorescence behaviour of fluorescein and prodan were studied in wide concentration range of Septonex. Next chapter of thesis deals with study of Förster resonance energy transfer between perylene and fluorescein in Septonex and CTAB micellar solutions and the effect of hyaluronan addition to these systems. Also steady-state and time-resolved fluorescence anisotropy studies were used for research of the effect of hyaluronan addition to micellar solutions. The last chapter of this thesis is focused on photophysical behaviour of Prodan in different solutions (water, Septonex solutions below CMC, hyaluronan solution, Septonex micellar solution and Septonex micellar solution with hyaluronan), which was discussed on the basis of time-resolved emission spectra.

Technika anisotropie a časově rozlišené anisotropie ve výzkumu koloidních systémů / Anisotropy and time-resolved anisotropy techniques in colloidal systems research

Holínková, Petra

January 2014

In this diploma thesis were investigated in terms of microviscosity liquid and condensed systems composed of hyaluronan (Hya) and cationic surfactant cetyltrimethylammonium bromide (CTAB). The excitation and emission spectra, lifetime, steady-state fluorescence anisotropy and time-resolved fluorescence anisotropy of the samples were measured. First, was studied the formation of hydrophobic domains in the system Hya-CTAB at concentration of CTAB lower than its critical micelle concentration in an aqueous solution and 0.15M NaCl. It was found that in an aqueous solution small hydrophobic domains linked to chains Hya are formed. Then an increasing concentration of CTAB leads to phase separation and formation of gel. Due to the addition of NaCl then leads to the reorganization of this system and probably the formation of free micelles in the solution. Were also studied condensed phase of system Hya-CTAB-NaCl at high concentrations of surfactant during fourteen days of ageing. It was found that the microviscosity of hydrophobic domains is constant, but the microviscosity of hydrophilic parts gradually decreases.

Charackterizace vazby ligandu na M1 muskarinový acetylcholinový receptor za použití metody fluorescenční anizotropie / Characterization of ligand binding to M1 muscarinic acetylcholine receptor using fluorescence anisotropy method

Danková, Hana

January 2020

Charles University Faculty of Pharmacy in Hradec Králové Department of Pharmacology and Toxicology Student: Hana Danková Supervisors: Prof. Ago Rinken, PhD. MSc. Tõnis Laasfeld PharmDr. Ivan Vokřál, PhD. Title of diploma thesis: Characetrization of ligand binding to M1 muscarinic receptor using fluorescence anisotropy method Muscarinic acetylcholine receptors (mAChRs), members of the superfamily of G-protein coupled receptors (GPCRs), regulate vital physiological processes and are important targets in drug research. Five different subtypes (M1 - M5) have been identified. M1 mAChR is mainly distributed in the central nervous system and is linked to pathophysiology of neurodegenerative diseases. In recent years, fluorescent methods have been frequently used in studies of ligand binding to receptors. The fluorescence anisotropy (FA) is a homogenous assay to characterize ligand binding to receptors. In this work, we have evaluated the FA method with fluorescent ligand MK342 binding to M1 mAChRs expressed on budded baculovirus (BBV) particles. The fluorescence ligand was binding with the high affinity (4,4 nM) to M1 receptor in constructed BBV preparation. The apparent binding affinities (pKi) of eleven classical and three bitopic muscarinic ligands were screened and compared to previously published...

Mécanisme de formation du complexe de démarrage de la traduction chez les Archées / Study of Archeal translation initiation complex

Monestier, Auriane

14 October 2016

Une cellule est soumise à différents stimuli internes et externes. Pour remplir ses fonctions, elle doit donc s’adapter rapidement. Cela implique une régulation fine de l’expression génique. Celle-ci s’effectue au niveau transcriptionnel, mais également au niveau traductionnel. La traduction comprend trois phases : le démarrage, l’allongement et la terminaison. C’est au cours du démarrage de la traduction que s’effectue la sélection du codon de démarrage et donc le choix du cadre de lecture de l’ARNm. D’un point de vue cinétique, le démarrage de la traduction est l’étape limitante. Ainsi, il apparait comme une cible privilégiée pour le contrôle traductionnel.Chez les archées, le démarrage de la traduction met en jeu un complexe macromoléculaire formé de la petite sous-unité du ribosome, d’un ARNm, d’un ARN de transfert initiateur méthionylé (Met-ARNtiMet) et de trois facteurs de démarrage de la traduction (aIF1, aIF1A et aIF2). De manière intéressante, ces trois facteurs de démarrage ont chacun un orthologue eucaryote.Les ARNti archées et eucaryotes possèdent une paire de bases très conservée A1-U72, au sommet de la tige acceptrice. Cette paire de base a été montrée importante pour la discrimination des ARNt initiateurs et élongateurs. De plus, des travaux suggèrent l’importance de la géométrie de la paire A1-U72 pour l’identité initiatrice de ces ARNts. Cependant, au début de ma thèse, aucune donnée structurale n’était disponible pour expliquer comment les caractéristiques de la paire A1-U72 participaient à la sélection de l’ARNt initiateur. Dans un premier temps, mon travail de thèse a consisté en la construction d’une souche bactérienne d’E.coli utilisant comme seul source d’ARNti un variant d’ARNt initiateur bactérien (ARNtfMet) possédant une paire de base A1-U72 (ARNtfMetA1-U72). L’utilisation de cette souche nous a permis d’obtenir de grandes quantités d’ARNtfMetA1-U72 purifié. De plus, la structure cristallographique de cet ARNtA1-U72 a pu être déterminée à 2.8 Å de résolution. Un arrangement inhabituel des bases A1 et U72 a été observé.Tous les acteurs du démarrage de la traduction de l’archée P. abyssi étant disponibles au laboratoire, une étude du complexe de démarrage de la traduction archée par cryo-microscopie électronique a pu être réalisée. L’étude a permis d’identifier deux conformations de l’ARNti dans le complexe de démarrage, IC0-Premote (5.3 Å de résolution) et IC1-Pin (7.5 Å de résolution). Ces deux conformations permettent de proposer un modèle pour l’accommodation de l’ARNt initiateur lors de l’appariement au codon de démarrage.Finalement, je me suis également intéressée au rôle du facteur aIF1. La disponibilité de structures 3D et de modèles d’assemblage, ainsi que les alignements des séquences aIF1 d’archées ont permis de proposer des régions ou acides aminés pouvant être impliqués dans la liaison au ribosome et/ou dans la sélection des ARNt initiateurs lors de la formation du complexe de démarrage. Afin de pouvoir étudier l’implication de ces régions ou acides aminés, j’ai mis au point une méthode d’étude de la liaison d’aIF1 à la petite sous-unité du ribosome par anisotropie de fluorescence. Cette étude met en évidence deux résidus basiques d’aIF1 impliqués dans la liaison au ribosome. D’autre part, les rôles d’aIF1 dans la sélection du codon de démarrage de la traduction et dans la stabilisation du complexe de démarrage sur l’ARNm sont étudiés par la méthode d’empreinte du ribosome ou toeprint. / A cell is subjected to different internal and external stimuli and must adapt quickly to fulfill its functions. This involves a fine regulation of gene expression. This occurs at the transcriptional level, but also at the translational level. Translation has three phases: initiation, elongation and termination. Selection of the start codon and therefore the choice of the mRNA reading frame is performed during translation initiation. From a kinetic point of view, translation initiation is the rate limiting step. Thus, it appears as a prime target for translational control.In archaea, initiation of translation involves a macromolecular complex containing the small subunit of the ribosome, mRNA, an initiator methionyl tRNA (Met-tRNAiMet) and three initiation factors (aIF1, aIF1A and aIF2). Interestingly, each of three initiation factors has an ortholog in eukaryotes.Archaeal and eukaryotic tRNAi have highly conserved bases A1-U72, at the extremity of the acceptor stem. This base pair was shown to be important for discrimination of initiator tRNAs from elongator tRNAs. In addition, other studies suggest the importance of the geometry of the A1-U72 pair for the initiator identity of those tRNAs. At the beginning of my thesis, no structural information was available to explain how the characteristics of the A1-U72 pair were involved in the selection of the initiator tRNA. At first, my thesis work involved the construction of an E. coli strain using as only source of tRNAi, a bacterial variant of tRNA initiator (tRNAfMet) having a base pair A1-U72 (tRNAfMetA1-U72). The use of this strain allowed us to obtain large quantities of purified tRNAfMetA1-U72. In addition, the crystal structure of this tRNAfMetA1-U72 has been determined at 2.8 Å of resolution. An unusual arrangement of bases A1 and U72 was observed.All archaeal translation initiation actors being available in the laboratory, a study of the archeal translation initiation complex by cryo-electron microscopy was achieved. The study identified two conformations of the tRNAi. In the first complex, both conformations (IC0-Premote (5.3 Å resolution) and IC1-Pin (7.5 Å resolution)) allowed us to propose a model for the accommodation of the initiator tRNA during start codon recognition.Finally, I was also interested in the role of the aIF1 factor. Availability of 3D structures, assembly models and alignments of the archeal aIF1 sequences allowed us to identify amino acids or regions that could be involved in ribosome binding and/or in the selection of initiator tRNA. In order to study the involvement of these regions, I have developed a method to study the binding of aIF1 to the small ribosomal subunit using fluorescence anisotropy. This study highlights two basic residues of aIF1 involved in binding to the ribosome. On the other hand, the roles of aIF1 in the selection of the start codon and in the stabilization of initiation complex on the mRNA were studied by the ribosome footprint method also called « toeprint ».

Traduction

Archée

Facteur de démarrage

Toeprint

Anisotropie de fluorescence

Translation

Archaea

Initiation factor

Toeprint

Fluorescence anisotropy

Charackterizace vazby ligandu na M1 muskarinový acetylcholinový receptor za použití metody fluorescenční anizotropie / Characterization of ligand binding to M1 muscarinic acetylcholine receptor using fluorescence anisotropy method

Danková, Hana

January 2020

Charles University Faculty of Pharmacy in Hradec Králové Department of Pharmacology and Toxicology Student: Hana Danková Supervisors: Prof. Ago Rinken, PhD. MSc. Tõnis Laasfeld PharmDr. Ivan Vokřál, PhD. Title of diploma thesis: Characetrization of ligand binding to M1 muscarinic receptor using fluorescence anisotropy method Muscarinic acetylcholine receptors (mAChRs), members of the superfamily of G-protein coupled receptors (GPCRs), regulate vital physiological processes and are important targets in drug research. Five different subtypes (M1 - M5) have been identified. M1 mAChR is mainly distributed in the central nervous system and is linked to pathophysiology of neurodegenerative diseases. In recent years, fluorescent methods have been frequently used in studies of ligand binding to receptors. The fluorescence anisotropy (FA) is a homogenous assay to characterize ligand binding to receptors. In this work, we have evaluated the FA method with fluorescent ligand MK342 binding to M1 mAChRs expressed on budded baculovirus (BBV) particles. The fluorescence ligand was binding with the high affinity (4,4 nM) to M1 receptor in constructed BBV preparation. The apparent binding affinities (pKi) of eleven classical and three bitopic muscarinic ligands were screened and compared to previously published...

Photophysical Properties of Amphiphilic Naphthalene Diimide Nanoassemblies and Cadmium Sulfide Nanoparticles and Poly(phenylene-ethynylene) Nanocomposites

Romano, Natalie C.

January 2014

No description available.

Chemistry

Development of pH-triggered, Self-assembling Peptide Amphiphiles as Tumor Targeting Imaging Vehicles.

Ghosh, Arijit

17 October 2014

No description available.

Chemistry

Peptide amphiphile

self-assembly

phase diagram

CD, fluorescence anisotropy

cancer imaging

MRI

Investigation of Skin and Skin Components Using Polarized Fluorescence and Polarized Reflectance Towards the Detection of Cutaneous Melanoma

Yuan, Ye

20 June 2006

No description available.

Biophotonics

Fluorescence anisotropy

Autofluorescence

Reflectance

Polarization

Tissue diagnostics

Cell diagnostics

Skin

Cancer detection

Melanoma

Synthesis and Analysis of Modified SNARE Proteins with Respect to Assembly and Disassembly of the SNARE Complex

Junius, Meike Pauline Wilhelmine

26 August 2016

No description available.

572

Synaptobrevin

SNARE Complex

SNARE Disassembly

caged Synaptobrevin

Fluorescence Anisotropy

Complexin

alpha-SNAP

NSF

SPPS

Biologie (PPN619462639)

Simulation of Fluorescence Spectroscopy Experiments / Simulation fluoreszenzspektroskopischer Experimente

Schröder, Gunnar

06 October 2004

No description available.

530 Physik

Mathematics and Computer Science

Einzelmolekül

FRET

Molekulardynamiksimulation

Fluoreszenzanisotropie

single-molecule

FRET

molecular dynamics simulation

fluorescence anisotropy

33.10

35.25

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