Global ETD Search

21	Electronic Properties of Organic Nanomaterials Studied by Scanning Tunneling Microscopy and Spectroscopy Meyer, Jörg 26 February 2016 (has links) In this work organic molecules, namely derivatives of BODIPY and poly-para-phenyls are investigated on different metal surfaces by means of LT-STM. These molecule are important for the development of molecular electronics and spintronics. I show that aza-BODIPY molecules form a weak chemical bond with the Au(111) substrate and the molecular structure significantly changes upon adsorption. Due to the low corrugation of the Au(111) surface, diffusion of the molecule is observed for applied bias in excess of ±1 V. The temperature dependent formation of different molecular nanostructures formed by polyparaphenyls and Au adatoms is discussed. The diffusing Au adatoms act as coordination centers for the cyano groups present on one end of the molecules. The structure of the super molecular assemblies completely changes in a temperature range of only 60 K. Furthermore, I investigate in this work the hybridization of atomic orbitals within the molecular ligand. The Kondo resonance of a Co atom incorporated into an other aza-BODIPY derivative is investigated in detail on Ag(100). The hybridization of the atomic Co orbital with the organic ligands molecular orbitals is shown by spectroscopy measurements with submolecular resolution. The changing line shape of the Kondo resonance for the molecule-substrate system is discussed. This data is compared to measurements of Co incorporated in another molecular binding motive and on different metal samples to show the importance of the local environment for molecular materials.:Introduction 1 1 Basic Principles 5 1.1 The Scanning Tunneling Microscope 6 1.2 Theory of STM/STS 8 1.2.1 Scanning Tunneling Microscopy 8 1.2.2 Scanning Tunneling Spectroscopy 12 1.2.3 dI/dV-maps and SPECGRIDs 15 1.3 Lateral Manipulation of Adsorbates 15 1.4 The Kondo Effect 17 1.4.1 Investigation of Kondo Systems by STM 19 2 Experimental Setup 23 2.1 LT-STM and UHV System 24 2.2 Substrates 26 2.2.1 Au(111) 26 2.2.2 Ag(100) 28 2.2.3 Cu(110) 28 2.2.4 Surface Preparation 29 2.3 The Molecules 29 2.3.1 aza-BODIPY 29 2.3.2 6Ph-CN 30 2.3.3 Co-(BiPADI)2, Co-BiPADI, and BiPADI 31 2.3.4 Sample Preparation 32 2.4 Organic Photovoltaics 32 3 Aza-BODIPY on Au(111) 35 3.1 Experimental Results 36 3.1.1 STM Images 36 3.1.2 Spectroscopy 38 3.1.3 Lateral Manipulation 38 3.2 Discussion 39 4 6Ph-CN on Au(111) 43 4.1 Experimental Results 44 4.1.1 STM Images 44 4.1.2 Temperature Dependent Nanostructure Formation 44 4.1.3 Spectroscopy 46 4.2 Discussion 47 5 Co-BiPADI on Ag(100) and Cu(110) 55 5.1 Experimental Results 56 5.1.1 Co-BiPADI on Ag(100) 56 5.1.1.1 STM Images and Identification 56 5.1.1.2 Adsorption Geometry 56 5.1.1.3 Spectroscopy and Kondo Resonance 59 5.1.1.4 Temperature Dependent Measurements 63 5.1.1.5 SPECGRID Measurements and Comparison with Molecular Structure 64 5.1.1.6 Interaction of Several Co-BiPADI Molecules and Related Changes of Their Kondo Resonances 67 5.1.1.7 Determination of Adsorption Position of Molecules in SPECGRID Measurements 69 5.1.2 Co-BiPADI on Cu(110) 71 5.1.2.1 STM Images and Identification 71 5.1.2.2 STS Measurements and dI/dV Maps 72 5.2 Discussion 74 6 Co-(BiPADI)2 on Au(111) 81 6.1 Experimental Results 82 6.1.1 STM Images 82 6.1.2 Spectroscopy 82 6.2 Discussion 86 7 Conclusions and Outlook 89 Bibliography 93 List of Publications 101 Acknowledgments 103 A Appendices 105 A.1 Fitting Routine for Kondo STS 105 A.2 Background Subtraction in Kondo STS 107 A.3 MATLAB Fitting Tool fit.m 107 A.4 Import Routine and Fitting Script for SPECGRID Files 111 A.5 Calibration of Piezo Constants from Atomically Resolved Images 112 A.5.1 Au(111) 112 A.5.2 Ag(100) 112 Confirmation 113 / In dieser Arbeit werden organische Moleküle, Derivate von BODIPY und poly-para-Phenyl, auf verschiedenen Metalloberflächen mittels Tief-Temperatur Rastertunnelmikroskopie (LT-STM) untersucht. Diese Moleküle sind wichtig für die Entwicklung von molekularer Elektronik und Spintronik. Ich zeige, dass aza-BODIPY-Moleküle eine schwache chemische Bindung mit dem Au(111)- Substrat eingehen und die molekulare Struktur bei der Adsorption deutlich verändert wird. Wegen der geringen Rauigkeit der Au(111)-Oberfläche wird bereits bei einer angelegten Spannungen über ±1 V die Diffusion der Moleküle beobachtet. Die temperaturabhängige Bildung verschiedener molekularer Nanostrukturen aus poly-para-Phenyl und frei beweglichen Goldatomen wird diskutiert. Die diffundierenden Goldatome agieren hierbei als Koordinationszentren für die Cyanogruppen am einen Ende der Moleküle. Die Struktur der supramolekularen Anordnungen verändert sich dabei in einem Temperaturbereich von nur 60 K vollkommen. Außerdem beschäftige ich mich in dieser Arbeit mit der Hybridisierung atomare Orbitale im molekularen Verbund. Die Kondo-Resonanz eine Co-Atoms, welches in einem anderen aza-BODIPY-Derivat gebunden ist, wird detailliert auf der Ag(100)-Oberfläche untersucht. Die Hybridisierung des atomaren Co-Orbitals mit den molekularen Orbitalen des organischen Liganden wird an Hand von Spektroskopiemessungen mit submolekularer Auflösung gezeigt. Die veränderte Form der Kondo-Resonanz für dieses Molekül-Substrat-System wird diskutiert. Diese Daten werden mit Messungen an Co-Atomen in anderen molekularen Bindungsschemen und auf anderen Substraten verglichen um dieWichtigkeit der lokalen Umgebung für molekulare Materialien zu verdeutlichen.:Introduction 1 1 Basic Principles 5 1.1 The Scanning Tunneling Microscope 6 1.2 Theory of STM/STS 8 1.2.1 Scanning Tunneling Microscopy 8 1.2.2 Scanning Tunneling Spectroscopy 12 1.2.3 dI/dV-maps and SPECGRIDs 15 1.3 Lateral Manipulation of Adsorbates 15 1.4 The Kondo Effect 17 1.4.1 Investigation of Kondo Systems by STM 19 2 Experimental Setup 23 2.1 LT-STM and UHV System 24 2.2 Substrates 26 2.2.1 Au(111) 26 2.2.2 Ag(100) 28 2.2.3 Cu(110) 28 2.2.4 Surface Preparation 29 2.3 The Molecules 29 2.3.1 aza-BODIPY 29 2.3.2 6Ph-CN 30 2.3.3 Co-(BiPADI)2, Co-BiPADI, and BiPADI 31 2.3.4 Sample Preparation 32 2.4 Organic Photovoltaics 32 3 Aza-BODIPY on Au(111) 35 3.1 Experimental Results 36 3.1.1 STM Images 36 3.1.2 Spectroscopy 38 3.1.3 Lateral Manipulation 38 3.2 Discussion 39 4 6Ph-CN on Au(111) 43 4.1 Experimental Results 44 4.1.1 STM Images 44 4.1.2 Temperature Dependent Nanostructure Formation 44 4.1.3 Spectroscopy 46 4.2 Discussion 47 5 Co-BiPADI on Ag(100) and Cu(110) 55 5.1 Experimental Results 56 5.1.1 Co-BiPADI on Ag(100) 56 5.1.1.1 STM Images and Identification 56 5.1.1.2 Adsorption Geometry 56 5.1.1.3 Spectroscopy and Kondo Resonance 59 5.1.1.4 Temperature Dependent Measurements 63 5.1.1.5 SPECGRID Measurements and Comparison with Molecular Structure 64 5.1.1.6 Interaction of Several Co-BiPADI Molecules and Related Changes of Their Kondo Resonances 67 5.1.1.7 Determination of Adsorption Position of Molecules in SPECGRID Measurements 69 5.1.2 Co-BiPADI on Cu(110) 71 5.1.2.1 STM Images and Identification 71 5.1.2.2 STS Measurements and dI/dV Maps 72 5.2 Discussion 74 6 Co-(BiPADI)2 on Au(111) 81 6.1 Experimental Results 82 6.1.1 STM Images 82 6.1.2 Spectroscopy 82 6.2 Discussion 86 7 Conclusions and Outlook 89 Bibliography 93 List of Publications 101 Acknowledgments 103 A Appendices 105 A.1 Fitting Routine for Kondo STS 105 A.2 Background Subtraction in Kondo STS 107 A.3 MATLAB Fitting Tool fit.m 107 A.4 Import Routine and Fitting Script for SPECGRID Files 111 A.5 Calibration of Piezo Constants from Atomically Resolved Images 112 A.5.1 Au(111) 112 A.5.2 Ag(100) 112 Confirmation 113 info:eu-repo/classification/ddc/620 ddc:620 STM, single molecule, spectroscopy
22	Single-Molecule Spectroscopy And Imaging Studies Of Protein Folding-Unfolding Conformational Dynamics: The Multiple-State And Multiple-Channel Energy Landscape Wang, Zijian 20 April 2016 (has links) No description available. Chemistry Protein Folding Single-Molecule Spectroscopy Protein-Protein Interactions Condensed Phase Dynamics
23	Observing Biomolecular Dynamics from Nanoseconds to Hours with Single-Molecule Fluorescence Spectroscopy Hartmann, Andreas 31 August 2018 (has links) Molecular dynamics of biomolecules, like proteins and nucleic acids dictate essential biological processes allowing life to function. They are involved in a vast number of cellular tasks including DNA replication, genetic recombination, transcription and translation, as well as signalling, translational motion, structure formation, biochemical synthesis, immune response, and many more. Developed over billions of years by evolution they constitute fine-tuned networks modulated by temperature and regulatory mechanisms. A better understanding of the thermodynamic fundamentals of inter- and intramolecular conformational changes can shed light on the underlying processes of diseases and enables the transfer of biological architectures, properties and compositions to nanotechnological applications. Dynamics of biomolecules occur on a wide range of timescales covering more than twelve orders of magnitude. Fluorescence spectroscopy techniques like time-correlated single photon counting (TCSPC), fluorescence correlation spectroscopy (FCS), and immobilized and freely diffusing single-molecule Förster resonance energy transfer (FRET) spectroscopy represent powerful tools monitoring the dynamics at different ranges within this large span of timescales. However, a unified approach covering all biological relevant timescales remains a goal in the field of fluorescence spectroscopy. This would comprise a methodological workflow for qualitative and quantitative analysis of biomolecular dynamics ranging from nanoseconds to hours. In this work, a custom built single-molecule fluorescence spectroscopy set-up was constructed combining confocal single-molecule FRET spectroscopy with TCSPC, FCS and fluorescence anisotropy techniques for multiparameter fluorescence detection (MFD). The set-up allows the complementary observation of single-molecules over an extensive timescale ranging from fast reconfiguration dynamics of polymers (nanoseconds) to slow membrane protein folding (hours) without the need of molecular synchronization. Freely diffusing molecules enable high throughput measurements in heterogeneous membrane-mimetic and denaturing environments. Additionally, routines for data acquisition and processing were developed followed by the elaboration of a methodological workflow for the qualitative and quantitative analysis of biomolecular dynamics. Finally, the applicability was demonstrated on a big diversity of biological systems (DNA hairpin, Holliday junction, soluble and membrane proteins) in aqueous, membrane-mimetic and denaturing environments covering conformational dynamics from nanoseconds to hours.:Chapter 1: Introduction Chapter 2: Dynamics of Biomolecules 2.1 Dynamics of Nucleic Acids 2.1.1 DNA Hairpin Dynamics 2.1.2 Dynamics of Holliday Junctions 2.2 Dynamics of Proteins 2.2.1 Model Systems of Protein Folding Chapter 3: Fundamentals of Fluorescence Spectroscopy 3.1 Basics of Fluorescence 3.2 Förster Resonance Energy Transfer (FRET) Chapter 4: Multiparameter Fluorescence Detection 4.1 Single-Molecule FRET Spectroscopy 4.1.1 Confocal Microscopy 4.1.2 Freely Diffusing Molecules 4.1.3 Fluorescence Spectroscopy 4.2 Time-Correlated Single-Photon Counting (TCSPC) 4.3 Pulsed Interleaved Excitation (PIE) 4.4 Fluorescence Anisotropy 4.5 Fluorescence Correlation Spectroscopy (FCS) 4.6 MFD Setup 4.7 Analysis Software Chapter 5: Analysis of Molecular Dynamics 5.1 Sub-Microseconds – Peptide Chain Dynamics 5.1.1 Identification of Peptide Chain Dynamics 5.1.2 Quantification of Peptide Chain Dynamics 5.1.3 Discussion 5.2 Microseconds – Dynamics of Barrier Crossing 5.2.1 Maximum Likelihood Estimation of the Transition-Path Time 5.2.2 Quantification of the Upper Bound of the Transition-Path Time 5.2.3 Discussion 5.3 Milliseconds – Fast Protein Folding Dynamics 5.3.1 Correlation of the Relative Donor Lifetime (τD(A) / τD(0)) with FRET Efficiency (E) 5.3.2 Burst-Variance Analysis (BVA) 5.3.3 FRET-Two-Channel Kernel-Based Density Distribution Estimator (FRET-2CDE) 5.3.4 Estimation of the Conformational Relaxation Rate using Bin-Time Analysis 5.3.5 Extracting Folding Kinetics using the Three-Gaussian (3G) Approximation 5.3.6 Dynamic Probability Distribution Analysis (dPDA) 5.3.7 Folding and Unfolding Rate Estimation using a Maximum-Likelihood Estimator 5.3.8 Discussion 5.4 Milliseconds to Seconds – Stacking Dynamics of DNA 5.4.1 Identification of Dynamics on the Recurrence Timescale 5.4.2 Quantification of Dynamics on the Recurrence Timescale 5.4.3 Discussion 5.5 Minutes to Hours – Slow Protein Folding Dynamics 5.5.1 Identification of Slow Protein Folding Dynamics 5.5.2 Quantification of Slow Protein Folding Dynamics 5.5.3 Discussion Chapter 6: Conclusion and Outlook Chapter 7: Appendices 7.1 Derivation of Equation 4.6 (inspired by Daniel Nettels) 7.2 Protein sequences 7.3 Identification of dynamics on the recurrence timescale 7.4 Dependency of psame on the sample concentration 7.5 Effect of fluorescence quenching on MFD parameters Chapter 8: References / Biomoleküle, wie Proteine und Nukleinsäuren, sind essentielle Bausteine des Lebens und permanent an biologischen Prozessen beteiligt. Innerhalb der Zelle nehmen sie eine Vielzahl von Aufgaben wahr, darunter DNA-Replikation, genetische Rekombination, Transkription und Translation, sowie Signalübertragung, Transport, Strukturbildung, biochemische Synthese und Immunreaktion. In Milliarden von Jahren evolutionärer Entwicklung wurden biomolekulare Prozesse immer feiner aufeinander Abgestimmt. Um den zugrundeliegenden Mechanismus von Krankheiten besser zu Verstehen und um die einzigartigen Eigenschaften und Kompositionen biologischer Systeme auf nanotechnologische Anwendungen übertragen zu können, ist es unbedingt notwendig ein besseres Verständnis thermodynamischer Grundlagen inter- und intramolekularer Konformationsänderungen zu erlangen. Dabei finden sich Dynamiken von Biomolekülen über eine Zeitskale von mehr als zwölf Größenordnungen verteilt. Fluoreszenzspektroskopietechniken, wie zeitkorrelierte Einzel-photonenzählung (TCSPC), Fluoreszenzkorrelationsspektroskopie (FCS), und Förster-Resonanzenergietransfer (FRET)–Spektroskopie von immobilisierten und frei diffundierenden Molekülen, stellen leistungsfähige Werkzeuge dar, welche es ermöglichen Dynamiken in der den Techniken entsprechenden Zeitskala aufzulösen. Dennoch, besteht der dringende Bedarf nach einer einheitlichen Methode, der in der Fluoreszenzspektroskopie alle biologisch relevanten Zeitskalen abdeckt. Dies würde einen methodischen Workflow für die qualitative und quantitative Analyse der biomolekularen Dynamik von Nanosekunden bis Stunden bedeuten. In dieser Arbeit wurde ein speziell angefertigter Multiparamter-Fluoreszenzspektroskopie-Aufbau konstruiert, welcher die konfokale Einzelmolekül-FRET-Spektroskopie mit den TCSPC-, FCS- und Fluoreszenz-Anisotropie-Techniken kombiniert. Der Aufbau ermöglicht die Beobachtung komplementärer Eigenschaften von Einzelmolekülen über eine umfangreiche Zeitskala hinweg. Dynamiken von schnell rekonfigurierenden Polymeren (Nanosekunden) bis hin zu langsam faltenden Membranproteinen (Stunden) sind ohne molekulare Synchronisation möglich. Darüber hinaus, ermöglicht der Einsatz frei diffundierender Moleküle einen hohen Messdurchsatz und die Anwendung heterogener membranmimetischer und denaturierender Lösungen. Zusätzlich wurden Routinen zur Datenerfassung und -verarbeitung entwickelt, gefolgt von der Ausarbeitung eines methodischen Workflows zur qualitativen und quantitativen Analyse von biomolekularen Dynamiken. Abschließend wurde die Anwendbarkeit an fünf biologischen Modelsystemen (DNA-Haarnadel, Holliday-Junction, lösliche und Membranproteine) in wässrigen, membranmimetischen und denaturierenden Umgebungen demonstriert und alle biologisch relevanten Zeitskalen von Nanosekunden bis Stunden abgedeckt.:Chapter 1: Introduction Chapter 2: Dynamics of Biomolecules 2.1 Dynamics of Nucleic Acids 2.1.1 DNA Hairpin Dynamics 2.1.2 Dynamics of Holliday Junctions 2.2 Dynamics of Proteins 2.2.1 Model Systems of Protein Folding Chapter 3: Fundamentals of Fluorescence Spectroscopy 3.1 Basics of Fluorescence 3.2 Förster Resonance Energy Transfer (FRET) Chapter 4: Multiparameter Fluorescence Detection 4.1 Single-Molecule FRET Spectroscopy 4.1.1 Confocal Microscopy 4.1.2 Freely Diffusing Molecules 4.1.3 Fluorescence Spectroscopy 4.2 Time-Correlated Single-Photon Counting (TCSPC) 4.3 Pulsed Interleaved Excitation (PIE) 4.4 Fluorescence Anisotropy 4.5 Fluorescence Correlation Spectroscopy (FCS) 4.6 MFD Setup 4.7 Analysis Software Chapter 5: Analysis of Molecular Dynamics 5.1 Sub-Microseconds – Peptide Chain Dynamics 5.1.1 Identification of Peptide Chain Dynamics 5.1.2 Quantification of Peptide Chain Dynamics 5.1.3 Discussion 5.2 Microseconds – Dynamics of Barrier Crossing 5.2.1 Maximum Likelihood Estimation of the Transition-Path Time 5.2.2 Quantification of the Upper Bound of the Transition-Path Time 5.2.3 Discussion 5.3 Milliseconds – Fast Protein Folding Dynamics 5.3.1 Correlation of the Relative Donor Lifetime (τD(A) / τD(0)) with FRET Efficiency (E) 5.3.2 Burst-Variance Analysis (BVA) 5.3.3 FRET-Two-Channel Kernel-Based Density Distribution Estimator (FRET-2CDE) 5.3.4 Estimation of the Conformational Relaxation Rate using Bin-Time Analysis 5.3.5 Extracting Folding Kinetics using the Three-Gaussian (3G) Approximation 5.3.6 Dynamic Probability Distribution Analysis (dPDA) 5.3.7 Folding and Unfolding Rate Estimation using a Maximum-Likelihood Estimator 5.3.8 Discussion 5.4 Milliseconds to Seconds – Stacking Dynamics of DNA 5.4.1 Identification of Dynamics on the Recurrence Timescale 5.4.2 Quantification of Dynamics on the Recurrence Timescale 5.4.3 Discussion 5.5 Minutes to Hours – Slow Protein Folding Dynamics 5.5.1 Identification of Slow Protein Folding Dynamics 5.5.2 Quantification of Slow Protein Folding Dynamics 5.5.3 Discussion Chapter 6: Conclusion and Outlook Chapter 7: Appendices 7.1 Derivation of Equation 4.6 (inspired by Daniel Nettels) 7.2 Protein sequences 7.3 Identification of dynamics on the recurrence timescale 7.4 Dependency of psame on the sample concentration 7.5 Effect of fluorescence quenching on MFD parameters Chapter 8: References info:eu-repo/classification/ddc/530 ddc:530
24	Studies on HIV-1 nucleocapsid chaperone role in protein/nucleic acid interactions by single molecule spectroscopy approaches Ma, Xiaojing, 1982- 20 August 2010 (has links) HIV-NC is a multifunctional protein which plays an important role in almost every step of the retroviral life cycle. NC is essential in catalyzing stand transfers of HIV-1 reverse transcription, including the annealing of the transactivation response element (TAR) of the viral genome to the complementary TAR DNA in minus-strong-stop DNA. In this dissertation, the research starts with focus on elucidating the reaction mechanism of NC-facilitated TAR DNA/RNA annealing using single molecule spectroscopy (SMS) approaches. The results indicate that nucleation of TAR DNA/RNA annealing occurs in an encounter complex form in which one or two DNA/RNA strands in the partially open “Y” form associated with multiple NC molecules. This encounter complex leads to annealing through the 3’/5’ termini, namely “zipper” pathway and the annealing through the hairpin loop region, namely “kissing” pathway. By employing target oligonucleotides for specific TAR regions, we directly probed kinetic reversibility and the chaperone role of NC. Concentration-dependence of NC chaperoned melting and annealing of TAR hairpins was investigated and the results further support the proposed reaction mechanism. Additionally, we used a single-stranded DNA (ssDNA) as model to study ssDNA conformational change upon NC binding. Here we present observation of NC binding to d(TG)n and d(T)n, including NC effect on flexibility and conformation of these oligonucleotides chains. Our results reveal that the rigidity of ssDNA chain is dramatically reduced through interaction with NC. Meanwhile the results of NC dissociation experiments indicate the interaction of NC/ssDNA is complex and heterogeneous. Finally, we used SMS in vitro to systematically compare and contrast the RNA/protein interactions for the zinc-finger-binding-motif protein (NC) and the arginine-rich-binding-motif (ARM) protein (Tat) encoded by HIV-1. Tat and NC use different RNA binding motifs to recognize and interact with RNA hairpin, giving rise to very different changes in the RNA secondary structure upon protein binding. Competition experiments show that the presence of Tat can effectively inhibit the NC binding-induced local melting of TAR RNA hairpins. These results indicate that Tat specifically binds and stabilizes the TAR RNA hairpin structure, which likely inhibits the local melting of the hairpin induced by NC. / text HIV-1 nucleocapsid Protein Nucleic acid chaperone Single molecule spectroscopy Arginine rich binding motif
25	Widefield fluorescence correlation spectroscopy Nicovich, Philip R. 26 March 2010 (has links) 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
26	Dynamique des interactions de la protéine de la nucléocapside avec la transcriptase inverse du VIH-1 : étude en molécule unique / Dynamics of the interactions between nucleocapsid protein and the reverse transcriptase of HIV-1 : single molecule study Jouonang, Armelle 17 January 2013 (has links) La transcriptase inverse (RT) est un hétéro-dimère p66/p51 avec des activités ADN polymérase et ribonucléase H qui jouent un rôle critique dans le cycle viral du VIH-1. La RT convertit l’ARN génomique viral simple brin en ADN proviral double brin dans le cytoplasme de la cellule infectée. L’efficacité de la RT est augmentée par la protéine de la nucléocapside (NC) grâce à son activité chaperonne vis-à-vis des acides nucléiques et/ou une coopération entre les deux protéines. Dans ce travail, nous avons étudié par la technique de smFRET (single molecule Fluorescence Resonance Energy Transfer) les effets de la NC sur l’interaction entre la RT et un substrat d’ADN au niveau de deux sites de pause de la synthèse de l’ADN(+). Nous avons d’abord réalisé et validé le montage de smFRET. Lors de la validation du montage avec des fluorophores Cy3 encapsulés dans des vésicules lipidiques, nous avons mis en évidence deux mécanismes différents entrainant le photoblanchiment du Cy3. Ensuite, après avoir déterminé les propriétés de liaison à l’équilibre de la RT et la NC sur différents substrats amorce/matrice à l’aide de mesures d’ensemble en solution, nous avons confirmé par smFRET que la RT adopte plusieurs conformations sur son substrat d’ADN, incluant celle qui conduit à la polymérisation de l’ADN. En présence de la NC, nous n’avons observé qu’une réorganisation modérée des différentes conformations du complexe RT/substrat. Par contre, une réorganisation beaucoup plus importante est induite par la NC en présence du dNTP, avec une très forte exaltation des conformations compétentes pour la polymérisation. Nous avons également montré que la NC augmente l’efficacité de synthèse de l’ADN au niveau de sites de pause en diminuant ou en augmentant le temps de dissociation du complexe RT/substrat/dNTP selon le type de site de pause. L’ensemble de ces données permet de mieux comprendre les mécanismes polyvalents par lesquels NC facilite l’activité de la RT. / The reverse transcriptase (RT) is a p66/p51 hetero-dimer with DNA polymerase and ribonuclease H activities which plays a critical role in the viral cycle of HIV-1. RT converts the viral genomic RNA to proviral DNA in the cytoplasm of infected cells. The efficiency of RT is increased by the nucleocapsid protein (NC) through its nucleic acids chaperone properties and/or via direct interaction with RT. In the present work, we investigated the effects of NC on the interaction between RT and its DNA substrate attwo pause sites during the synthesis of (+)DNA by using the smFRET (single molecule Fluorescence Resonance Energy Transfer) technique. In a first step, we implemented and validated the smFRET set-up. Within the validation step, using Cy3 fluorophores encapsulated, in lipid vesicles, we monitored the photobleaching of Cy3 dyes and found out that it was governed by two parallel mechanisms. In a second step, we determined the affinity of RT and NC to different primer/template substrates by using steady-state fluorescence. Then, we confirmed by smFRET that RT adopts different conformations on its DNA substrate, including the one that leads to DNA polymerization. In the presence of NC, we observed only a moderate reorganization of the different conformations of RT/substrate complex. However, NC was found to induce a more important reorganization in the presence of dNTP, with a very strong promotion of the polymerization-competent conformations. We also showed that NC increases the efficiency of DNA synthesis at pause sites by either decreasing or increasing the dissociation time of the RT/substrate/dNTP complex, depending on the type of pause site. Together, these data allow us to further elucidate the mechanisms by which NC facilitates the RT. Transcriptase inverse Spectroscopie en molécule unique La protéine de la nucléocapside VIH-1 Reverse transcriptase Single molecule spectroscopy Nucleocapsid protein HIV-1 572.8 616.97
27	In vitro, in silico and in vivo studies of the structure and conformational dynamics of DNA polymerase I Sustarsic, Marko January 2016 (has links) DNA polymerases are a family of molecular machines involved in high-fidelity DNA replication and repair, of which DNA polymerase I (Pol) is one the best-characterized members. Pol is a strand-displacing polymerase responsible for Okazaki fragment synthesis and base-excision repair in bacteria; it consists of three protein domains, which harbour its 5’-3' polymerase, 3’-5’ exonuclease and 5’ endonuclease activities. In the first part of the thesis, we use a combination of single-molecule Förster resonance energy transfer (smFRET) and rigid-body docking to probe the structure of Pol bound to its gapped-DNA substrate. We show that the DNA substrate is highly bent in the complex, and that the downstream portion of the DNA is partly unwound. Using all-atom molecular dynamics (MD) simulations, we identify residues in the polymerase important for strand displacement and for downstream DNA binding. Moreover, we use coarse-grained simulations to investigate the dynamics of the gapped-DNA substrate alone, allowing us to propose a model for specific recognition and binding of gapped DNA by Pol. In the second part of the thesis, we focus on the catalytically important conformational change in Pol that involves the closing of the ‘fingers’ subdomain of the protein around an incoming nucleotide. We make use of the energy decomposition method (EDM) to predict the stability-determining residues for the closed and open conformations of Pol, and test their relevance by site-directed mutagenesis. We apply the unnatural amino acid approach and a single-molecule FRET assay of Pol fingers-closing, to show that substitutions in the stability-determining residues significantly affect the conformational equilibrium of Pol. In the final part of the thesis, we attempt to study Pol in its native environment of the living cell. We make use of the recently developed method of internalization by electroporation, and optimize it for organically labelled proteins. We demonstrate the internalization and single-molecule tracking of Pol, and provide preliminary data of intra-molecular FRET in Pol, both at the single-cell and single-molecule levels. Finally, by measuring smFRET within an internalized gapped-DNA construct, we observe DNA binding and bending by endogenous Pol, confirming the physiological relevance of our in vitro Pol-DNA structure. 572.8
28	Extending Resolution in All Directions: Image Scanning Microscopy and Metal-induced Energy Transfer Isbaner, Sebastian 13 February 2019 (has links) No description available. 571.4 Fluorescence Microscopy Fluorescence Lifetime Imaging Superresolution Microscopy Single Molecule Spectroscopy Image Scanning Microscopy Metal-induced Energy Transfer Biologie (PPN619462639)
29	On the Integration of Single Emitters in Solids and Photonic Nano-Structures Neitzke, Oliver Björn 16 April 2018 (has links) Quantentechnologien sind im Begriff sich von Laborversuchen zu effizienten Anwendungen zu entwickeln. Die Quantenzustände einzelner Photonen spielen dabei die Rolle als Bindeglied zwischen stationären Quantensystemen. Ein hybrider Ansatz wird verfolgt, um die Wechselwirkung gezielt zwischen im Wellenleiter geleiteten Photonen und gekoppelten Quantenemittern zu erreichen. Die Dissertation untersucht zwei zentrale Aspekte solcher hybriden photonischen Quantentechnologien: die effiziente Erzeugung von Photonen und die Optimierung von photonischen Strukturen. Der erste Teil dieser Arbeit behandelt die Entwicklung einer optischen Mikrotechnology. Integrierte nano-photonische Wellenleiter aus Siliziumnitrid wurden für die Kopplung zu Quantenemittern entworfen, optimiert und optisch untersucht. Das finale Design wurde erfolgreich in Kopplungsexperimenten verwendet, bei denen 42 % der Fluoreszenz eines einzelnen Moleküls an einen Wellenleiter gekoppelt wurde. Der zweite Teil der Arbeit untersucht zwei Einzelphotonenquellen. Zunächst wurde ein neuartiger Einzelphotonenemitter basierend auf Defektzentren in Zinkoxid optisch bei tiefen Temperaturen untersucht. Es konnte im Zuge dieser Arbeit erstmals gezeigt werden, dass die Photonen von nano-strukturiertem Zinkoxid sehr schmalbandige Emission aufweisen. Im letzten Teil, wird eine Einzelphotonenquelle bestehend aus einem organischen Molekül untersucht. Bei kryogenen Temperaturen wurden Lebenszeit-limitierte Linienbreiten auf den Molekülproben detektiert. Die Rabi-Oszillationen zwischen den Molekülzuständen konnten akkurat durch eine quantenmechanische Theorie beschrieben werden, wodurch die Vermessung der Dephasierung des Quantensystems durch die nanoskopische Umgebung präzise studiert werden konnte. Die Ergebnisse dieser Arbeit zur Kopplung von Einzelphotonenquellen stellen die Grundlage für weitere Anwendungen durch eine photonische Quantentechnologie dar. / Quantum technologies are on the verge to transition from laboratory experiments to efficient integrated applications. The quantum states of photons are the connecting link between individual stationary quantum systems. A hybrid approach is employed to tailor the interaction of routed photons with optically coupled quantum systems. The thesis investigates two core aspects of a hybrid photonic quantum technology: efficient single photon generation and optimized photonic micro-structures, suitable to form a hybrid system. In the first part of this work, nano-photonic integrated structures were optimized for efficient coupling to quantum emitters. Optical waveguides based on silicon nitride (SiN) were designed, fabricated, and optically characterized. The final design was successfully employed in coupling experiments, where up to 42% of the fluorescence from a single molecule was coupled to a waveguide. In the second part of this thesis two single photon sources are investigated towards their implementation into a hybrid photonic system. First, a novel single photon source based on a defect center in zinc oxide was optically investigated at room-temperature and cryogenic temperature. Spectrally narrow zero-phonon lines of the fluorescence from nano-structured zinc oxide were measured for the first time during this work. A second emitter system, based on an organic dye molecule was investigated in the final part of this research. At cryogenic temperatures, single molecules showed lifetime-limited linewidths of <50MHz. A resonant laser source drives Rabi oscillations, which are accurately described by the quantum mechanical theory of a two-level system. The system's decoherence was mapped, illustrating the quantum sensing capabilities of the system. The results presented in this thesis on coupling efficiencies and single emitter performance provide the necessary background of the elements composing a future hybrid technology. Quantenoptik Einzelphotonenquellen Konfokalmikroskopie Photonik Einzelmolekülspektroskopie Nano-photonik Optik quantum optics confocal microscopy single photon sources nano-photonics single molecule spectroscopy photonics optics 530 Physik UH 5600 ddc:530
30	Optical Investigation of Single Fluorophores and their Application as Sensitive Probes in Soft Matter Science Krause, Stefan 06 May 2015 (has links) (PDF) Im Mittelpunkt dieser Arbeit steht die Verwendung verschiedener Fluoreszenzfarbstoffe in Form photostabiler Perylenbisimide sowie etallischer Nanopartikel zur Untersuchung von Polymeren und nanoskopischen Flüssigkeitsfilmen. Einzelmoleküluntersuchungen zeigen, dass eine chemische Modifizierung der Farbstoffe durch löslichkeitserhöhende Seitengruppen, Molekülkonformationen mit stark variierenden Emissionswellenlängen je nach Seitengruppen-orientierung zur Folge hat. Zeitabhängige Fluoreszenzmessungen an einzelnen Molekülen ermöglichen eine direkte Beobachtung von Übergängen zwischen diesen molekularen Konformationen deren Dynamik vorwiegend durch die Eigenschaften der umgebenden Polymermatrix bestimmt wird. Die gewonnenen Ergebnisse lassen somit Rückschlüsse auf die nanoskopische Umgebung des Moleküls zu. Es werden diskrete Zustände innerhalb der Molekülumgebung sowie eine erhöhte Konformationsdynamik im Falle von alkylsubstituierten Perylenbisimiden beobachtet. Darüber hinaus werden die nanoskopischen Auswirkungen von makroskopischen, mechanischen Deformationen auf amorphe Polymerfilme mikrorheologisch mit Hilfe von stäbchenförmigen Perylenbisimiden studiert. Die gewonnenen Einzelmoleküldaten ermöglichen die Berechnung der lokalen, mikroskopischen Deformation sowie der Orientierung der Sondenmoleküle, welche gut mit einem Model für stäbchenförmige Objekte in einem uniaxial deformierten Kontinuum übereinstimmt. In weiteren Experimenten gelingt der Nachweis ultradünner Wasserfilme auf SiO2-Oberflächen durch Messung der Diffusion von Silbernanopartikeln. Die verwendeten Nanopartikel weisen hierbei eine monodisperse Größenverteilung im Bereich von einem Nanometer als Resultat ihrer Synthese in Y-Zeolith-Kristallen auf. Die Untersuchungen ergeben eine Filmdickenabhängigkeit des Diffusionsverhaltens sowie einen starken Einfluss durch Oberflächensilanisierung bzw. Hydroxylierung. Ag-Nanopartikel Einzelmolekülspektroskopie Fluoreszenz Perylenbisimid Polymerdynamik Polymerrheologie Ag-Nanoparticles Single Molecule Spectroscopy Fluorescence Perylendiimide Polymerdynamics Poylmerrheology ddc:500 ddc:530 ddc:539 Einzelmolekülspektroskopie Nanopartikel Rheologie Polymere

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