Estudo de sondas orgânicas e estratégias de marcação fluorescente de DNA: da fotoquímica básica à microscopia óptica de super-resolução / Study of organic probes and strategies for DNA fluorescent labelling: From basic photochemistry to super-resolution optical microscopy

Lauer, Milena Helmer

12 May 2016

A microscopia de fluorescência é uma das técnicas mais poderosas disponíveis atualmente, uma vez que proporciona uma combinação excepcional de alta sensibilidade na detecção, alta especificidade, além de ser consideravelmente não invasiva. Avanços recentes permitiram a detecção em resolução de subdifração, o que eleva sua potencialidade de investigação de um maior número de sistemas e, consequentemente, de avanço científico. O estudo de novas sondas fluorescentes é de fundamental importância para a aplicação em métodos avançados de microscopia óptica. Na primeira vertente da pesquisa, Capítulo 2, foi realizado o estudo fotofísico de uma série de compostos bisarilados derivados do anidrido maleico e de maleimidas sintetizados pela reação de Heck-Matsuda. Visando o aprimoramento do design dessas moléculas, foi realizada a ciclização fotoquímica de tais compostos, resultando em moléculas com anéis condensados, nomeados como derivados de fenantreno, as quais proporcionaram maior estabilidade fotoquímica. A dinâmica do estado excitado remete ao efeito push-pull, em que há um deslocamento de carga notável, mas não completo. Para os compostos com a substituição 4-hidroxifenil foi observado um processo de deslocamento de carga combinado com uma transferência de próton no estado excitado assistida por solvente. Ademais, o estudo dos compostos derivados de fenantreno em microscopia confocal demonstrou que as propriedades locais do solvente afetam a dinâmica de relaxação de fluorescência em diferentes meios condensados e que os mesmos são passíveis de serem aplicados a técnicas avançadas de microscopia de fluorescência. A segunda vertente desta tese, Capítulo 3, explora um sistema biológico em nível de uma única molécula. Especificamente, este capítulo concerne à investigação de uma metodologia ótima para a marcação fluorescente de DNA em sequência específica, através de microscopia de fluorescência com super-resolução. As reações foram conduzidas utilizando uma metodologia de marcação de duas etapas, de acordo com o princípio mTAG. Na primeira etapa, grupamentos contendo alquino terminal, azida ou amina primária são transferidos do cofator análogo ao S-adenosil-L-metionina para o DNA através de uma enzima metiltransferase. Foi utilizada a enzima M.TaqI, a qual tem como alvo a sequência 5\'- TGCA -3\' para modificação. Na segunda etapa é realizado o acoplamento do fluoróforo aos sítios funcionais do plasmídeo (pUC19) através de reações químicas bioortogonais, tais como reação click catalisada por cobre (CuAAC), reação click na ausência de cobre (SPAAC) e acoplamento do grupo amina primária com NHS-éster. Também foi desenvolvida uma metodologia direta de uma etapa, na qual o fluoróforo é diretamente transferido do cofator análogo para o DNA em uma única etapa reacional. Para acompanhar o desempenho das reações foi desenvolvido um ensaio single-molecule para a contagem do número de moléculas de corante ligadas a plasmídeos individuais. A topologia dos plasmídeos após a marcação foi investigada por imagens de AFM em alta resolução. A combinação de ambas as análises demonstrou que a reação SPAAC assim como a reação direta de uma etapa promoveram uma marcação fluorescente quase completa e a técnica de AFM confirmou que o acoplamento de fluoróforos não induziu danos à estrutura dos plasmídeos, os quais preservaram sua morfologia nativa, superenrolada. Além disso, os plasmídeos marcados foram aplicados com sucesso a procedimentos de transfecção em células de mamíferos, indicando que o DNA reteve sua capacidade de codificar informação genética, mesmo na presença de fluoróforos ligados. / Fluorescence microscopy is one of the most powerful techniques currently available, since it provides the unique combination of a high sensitivity in detection, a high specificity, and a considerable non-invasiveness. Recent developments have allowed the detection at a sub-diffraction resolution, which elevates its potentiality to investigate several systems and hence to go further in science. The study of new fluorescent probes is crucial for the application in advanced methods in optical microscopy. In the first extent of this research, Chapter 2, a photophysical study of maleic anhydride and maleimide derivatives, synthesized by the Heck-Matsuda reaction, was performed. Aiming at the improvement of the design of these molecules, a photochemical cyclization was carried out, resulting in molecules with condensed rings, termed as phenanthrene derivatives, which promoted more photochemical stability. The excited state dynamics rely on the push-pull effect, in which a notable, but not complete, charge shift takes place. For the compounds with a 4-hydroxyl substituent, a charge shift combined with an excited state solvent-assisted proton transfer was observed. Additionally, the confocal microscopy study of the phenanthrene derivatives showed that the local properties of the solvent modulate the fluorescence relaxation dynamics in condensed media and hence such dyes can be potential candidates for use in advanced fluorescence microscopy techniques. The second extent of this thesis, Chapter 3, explores a biological system at the single-molecule level. Specifically, this chapter concerns to an investigation of an optimal sequence-specific DNA fluorescent labelling, using super-resolution fluorescence microscopy. The reactions were performed using a two-step methodology, according to the mTAG approach. In the first step, moieties containing a terminal alkyne, azide, or primary amine group are transferred from an S-adenosyl-L-methionine analogue cofactor to the DNA by a methyltransferase enzyme. Herein, the enzyme M.TaqI was used, which targets the 5\'- TCGA -3\' sequence for modification. In the second step, a fluorophore is coupled to the functional sites of the plasmid (pUC19) using bio orthogonal reactions, such as the click reaction catalysed by copper (CuAAC), the copper-free click reaction (SPAAC), and the amino-to-NHS-ester coupling reaction. A direct one-step approach in which the fluorophore is directly transferred to the DNA from the analogue cofactor in a single reaction step, was also developed. A single-molecule assay was developed for counting the number of fluorophores associated with the individual plasmids. The topology of the plasmids after labelling was also investigated by high-resolution AFM imaging. Combining both analysis, the SPAAC as well as the direct one-step reactions were found to promote near-complete labelling and the AFM showed that the fluorophore coupling did not damage the structure of the plasmids and that their native, supercoiled, morphology was preserved. Moreover, labelled plasmids were successfully applied for transfection into mammalian cells, implying that the DNA retained its ability to encode genetic information, even while carrying bound fluorophores.

push-pull

AFM

AFM

anidrido maleico

DNA

DNA

maleic anhydride

microscopia single-molecule

push-pull

single-molecule microscopy

Estudo de sondas orgânicas e estratégias de marcação fluorescente de DNA: da fotoquímica básica à microscopia óptica de super-resolução / Study of organic probes and strategies for DNA fluorescent labelling: From basic photochemistry to super-resolution optical microscopy

Milena Helmer Lauer

12 May 2016

A microscopia de fluorescência é uma das técnicas mais poderosas disponíveis atualmente, uma vez que proporciona uma combinação excepcional de alta sensibilidade na detecção, alta especificidade, além de ser consideravelmente não invasiva. Avanços recentes permitiram a detecção em resolução de subdifração, o que eleva sua potencialidade de investigação de um maior número de sistemas e, consequentemente, de avanço científico. O estudo de novas sondas fluorescentes é de fundamental importância para a aplicação em métodos avançados de microscopia óptica. Na primeira vertente da pesquisa, Capítulo 2, foi realizado o estudo fotofísico de uma série de compostos bisarilados derivados do anidrido maleico e de maleimidas sintetizados pela reação de Heck-Matsuda. Visando o aprimoramento do design dessas moléculas, foi realizada a ciclização fotoquímica de tais compostos, resultando em moléculas com anéis condensados, nomeados como derivados de fenantreno, as quais proporcionaram maior estabilidade fotoquímica. A dinâmica do estado excitado remete ao efeito push-pull, em que há um deslocamento de carga notável, mas não completo. Para os compostos com a substituição 4-hidroxifenil foi observado um processo de deslocamento de carga combinado com uma transferência de próton no estado excitado assistida por solvente. Ademais, o estudo dos compostos derivados de fenantreno em microscopia confocal demonstrou que as propriedades locais do solvente afetam a dinâmica de relaxação de fluorescência em diferentes meios condensados e que os mesmos são passíveis de serem aplicados a técnicas avançadas de microscopia de fluorescência. A segunda vertente desta tese, Capítulo 3, explora um sistema biológico em nível de uma única molécula. Especificamente, este capítulo concerne à investigação de uma metodologia ótima para a marcação fluorescente de DNA em sequência específica, através de microscopia de fluorescência com super-resolução. As reações foram conduzidas utilizando uma metodologia de marcação de duas etapas, de acordo com o princípio mTAG. Na primeira etapa, grupamentos contendo alquino terminal, azida ou amina primária são transferidos do cofator análogo ao S-adenosil-L-metionina para o DNA através de uma enzima metiltransferase. Foi utilizada a enzima M.TaqI, a qual tem como alvo a sequência 5\'- TGCA -3\' para modificação. Na segunda etapa é realizado o acoplamento do fluoróforo aos sítios funcionais do plasmídeo (pUC19) através de reações químicas bioortogonais, tais como reação click catalisada por cobre (CuAAC), reação click na ausência de cobre (SPAAC) e acoplamento do grupo amina primária com NHS-éster. Também foi desenvolvida uma metodologia direta de uma etapa, na qual o fluoróforo é diretamente transferido do cofator análogo para o DNA em uma única etapa reacional. Para acompanhar o desempenho das reações foi desenvolvido um ensaio single-molecule para a contagem do número de moléculas de corante ligadas a plasmídeos individuais. A topologia dos plasmídeos após a marcação foi investigada por imagens de AFM em alta resolução. A combinação de ambas as análises demonstrou que a reação SPAAC assim como a reação direta de uma etapa promoveram uma marcação fluorescente quase completa e a técnica de AFM confirmou que o acoplamento de fluoróforos não induziu danos à estrutura dos plasmídeos, os quais preservaram sua morfologia nativa, superenrolada. Além disso, os plasmídeos marcados foram aplicados com sucesso a procedimentos de transfecção em células de mamíferos, indicando que o DNA reteve sua capacidade de codificar informação genética, mesmo na presença de fluoróforos ligados. / Fluorescence microscopy is one of the most powerful techniques currently available, since it provides the unique combination of a high sensitivity in detection, a high specificity, and a considerable non-invasiveness. Recent developments have allowed the detection at a sub-diffraction resolution, which elevates its potentiality to investigate several systems and hence to go further in science. The study of new fluorescent probes is crucial for the application in advanced methods in optical microscopy. In the first extent of this research, Chapter 2, a photophysical study of maleic anhydride and maleimide derivatives, synthesized by the Heck-Matsuda reaction, was performed. Aiming at the improvement of the design of these molecules, a photochemical cyclization was carried out, resulting in molecules with condensed rings, termed as phenanthrene derivatives, which promoted more photochemical stability. The excited state dynamics rely on the push-pull effect, in which a notable, but not complete, charge shift takes place. For the compounds with a 4-hydroxyl substituent, a charge shift combined with an excited state solvent-assisted proton transfer was observed. Additionally, the confocal microscopy study of the phenanthrene derivatives showed that the local properties of the solvent modulate the fluorescence relaxation dynamics in condensed media and hence such dyes can be potential candidates for use in advanced fluorescence microscopy techniques. The second extent of this thesis, Chapter 3, explores a biological system at the single-molecule level. Specifically, this chapter concerns to an investigation of an optimal sequence-specific DNA fluorescent labelling, using super-resolution fluorescence microscopy. The reactions were performed using a two-step methodology, according to the mTAG approach. In the first step, moieties containing a terminal alkyne, azide, or primary amine group are transferred from an S-adenosyl-L-methionine analogue cofactor to the DNA by a methyltransferase enzyme. Herein, the enzyme M.TaqI was used, which targets the 5\'- TCGA -3\' sequence for modification. In the second step, a fluorophore is coupled to the functional sites of the plasmid (pUC19) using bio orthogonal reactions, such as the click reaction catalysed by copper (CuAAC), the copper-free click reaction (SPAAC), and the amino-to-NHS-ester coupling reaction. A direct one-step approach in which the fluorophore is directly transferred to the DNA from the analogue cofactor in a single reaction step, was also developed. A single-molecule assay was developed for counting the number of fluorophores associated with the individual plasmids. The topology of the plasmids after labelling was also investigated by high-resolution AFM imaging. Combining both analysis, the SPAAC as well as the direct one-step reactions were found to promote near-complete labelling and the AFM showed that the fluorophore coupling did not damage the structure of the plasmids and that their native, supercoiled, morphology was preserved. Moreover, labelled plasmids were successfully applied for transfection into mammalian cells, implying that the DNA retained its ability to encode genetic information, even while carrying bound fluorophores.

push-pull

AFM

anidrido maleico

DNA

microscopia single-molecule

AFM

DNA

maleic anhydride

push-pull

single-molecule microscopy

Influence of gangliosides in the dynamics and partitioning of CD82 and its partners / Influence des gangliosides dans la dynamique et la compartimentation de la tétraspanine CD82 et de ses partenaires

Fernandez, Laurent

22 September 2017

Un membre de la famille des tétraspanines, CD82, est une protéine transmembranaire et l'un des rares suppresseurs de métastase identifié jusqu'à présent. Cependant, le mécanisme de suppression de métastase induite par CD82 reste mal compris. Les tétraspanines, y compris CD82, ont la propriété unique de créer un réseau d'interactions protéines-protéines à la membrane plasmique, appelé « tetraspanin web ». Dans ce réseau, CD82 est connu pour interagir avec d’autres tétraspanines, y compris CD9, CD81 et CD151, en plus d’autres protéines membranaires telles que les intégrines, les récepteurs de facteurs de croissance et les protéines de type immunoglobuline. De plus, des travaux antérieurs ont identifié que l'interaction de CD82 avec l’EGFR, d'autres tétraspanines et les intégrines dépend de l'expression des gangliosides au sein de la membrane plasmique.À ce jour, les études dans ce domaine ont utilisé des techniques d'ensemble qui ne peuvent pas tenir compte de la dynamique et de la stochasticité de la membrane, alors qu'il est maintenant bien établi que l'organisation spatio-temporelle de ses composants est cruciale pour certaines fonctions cellulaires.Ainsi, lors de ma thèse de doctorat, j'ai cherché à étudier à la fois la dynamique et la compartimentation de CD82 et de ses partenaires à la membrane plasmique des cellules épithéliales mammaires HB2. Pour ce faire, la technique de pistage en molécule unique basée sur l’utilisation d’un microscope TIRF a été utilisée afin d’obtenir des informations directes à l'échelle nanométrique sur la dynamique de protéines individuelles dans les cellules vivantes. Nos expériences en pistage de molécule unique ont démontré que l'expression de CD82 augmentait la dynamique CD81 à la membrane plasmique des cellules HB2 et modifiait ses interactions au sein du tetraspanin web. En revanche, les dynamiques de CD9 et de l’intégrine α3 n'ont pas été modifiées par l'expression de CD82. De plus, en modifiant enzymatiquement l'expression des gangliosides, nous avons montré que ces lipides sont impliqués à la fois dans la dynamique et la compartimentation des tétraspanines à la membrane plasmique. En effet, la déplétion en gangliosides entraine une augmentation de la dynamique de CD82, CD81 et de l’intégrine α3 ainsi qu'une redistribution des tétraspanines à la membrane plasmique. Nous avons également étudié la migration en 2D des cellules HB2 et montré que CD82 et les gangliosides modifiaient de façon différentielle la migration des cellules HB2.L’ensemble de nos résultats démontrent que CD82 et les gangliosides modulent de manière différente la dynamique et la compartimentation des tétraspanines et de leurs partenaires à la membrane plasmique des cellules HB2. Enfin, ce travail suggère que l'activité de CD82 en tant que suppresseur de métastase pourrait être en partie liée à sa capacité, en coopération avec les gangliosides, à moduler l'organisation spatio-temporelle de ses partenaires au sein du tetraspanin web. / A member of the family of tetraspanins, CD82, is a transmembrane protein and one of the rare metastasis suppressors identified so far. However, the mechanism of CD82-induced metastasis suppression remains not fully revealed. Tetraspanins, including CD82, have the unique property to create a network of protein-protein interactions within the plasma membrane, called tetraspanin web. Within this network, tetraspanins interact with each other (eg. CD82 with CD9, CD81 and CD151) as well as with other proteins, such as: integrins, growth factor receptors and immunoglobulin-like proteins. Additionally previous work has identified that the interaction of CD82 with EGFR, other tetraspanins and integrins depends on the expression of gangliosides at the plasma membrane.To date, studies in this field have employed ensemble-averaging techniques which are unable to account for membrane dynamics and stochasticity. Nevertheless, it is now well established that the spatio-temporal organization of its components is crucial for cellular functions.Thus, during my PhD thesis I aimed to study both the dynamics and partitioning of CD82 and its partners at the plasma membrane of HB2 mammary cells. To achieve this aim, a TIRF-based Single Molecule Tracking (SMT) approach was employed to provide direct nanoscale insights by observing individual proteins in living cells. Our SMT experiments demonstrated that CD82 overexpression increased CD81 dynamics at the plasma membrane of HB2 cells and modified its interaction within the tetraspanin web. In contrast, CD9 and α3 integrin dynamics were not modified by CD82 expression. Moreover, by enzymatically tuning gangliosides expression, we showed that these lipids are involved in both dynamics and partitioning of tetraspanins at the plasma membrane. Indeed, gangliosides depletion resulted in an increase in CD82, CD81 and α3 integrin dynamics as well as a redistribution of tetraspanins at the plasma membrane. We also investigated the 2D migration of HB2 cells showing that CD82 and gangliosides differentially altered the cellular migration of HB2 cells.Taken together, our results demonstrate that both CD82 and gangliosides differentially modulate the dynamics and partitioning of tetraspanins and their partners at the plasma membrane of HB2 cells. Finally, this work suggests that CD82 activity as metastasis suppressor could be in part linked to its ability, in cooperation with gangliosides, to modulate the spatio-temporal organization of its partners within the tetraspanin web.

Tétraspanine

Gangliosides

Molécule unique

Microscopie à super-Résolution

Pistage en molécule unique

Tetraspanin

Gangliosides

Single molecule

Super resolution microscopy

Single molecule tracking

In vitro, in silico and in vivo studies of the structure and conformational dynamics of DNA polymerase I

Sustarsic, Marko

January 2016

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

Facile Fabrication of Meso-to-Macroscale Single-Molecule Arrays for High-Throughput Digital Assays

January 2019

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

Biomedical engineering

Nanotechnology

DNA origami

High-throughput

Low-cost digital diagnostics

Nanosphere lithography

Single molecule arrays

Single-molecule biophysics

Access to the Genome: A Study of Transcription Factor Binding Within Nucleosomes

Brehove, Matthew Steven

January 2016

No description available.

Biochemistry

Biophysics

Physics

Nucleosome

Hexasome

transcription factor

single molecule

single-molecule

FRET

PIFE

Histone octamer

TIRF

Fluorescence Resonance Energy Transfer

Synthesis and characterisation of 3d-4f-complexes and their magnetic properties / Synthèse et caractérisations de matériaux moléculaires magnétiques

Feuersenger, Jürgen

20 December 2010

Ce travail de thèse décrit (i) la synthèse de complexes hétérométalliques d’ions 3d et 4f à partir de précuseurs de Mn, Fe et Co, de sels de lanthanides et de ligands organiques et (ii) l'étude de leurs structures et propriétés. 41 complexes polynucléaires ont été synthétisés dans le cadre de ce travail. Les structures moléculaires de tous les composés ont été déterminées par diffraction des rayons X. Les propriétés magnétiques de 22 complexes ont été étudiées, dont quatre montrent une relaxation lente de leur aimantation considérée comme la signature d’un comportement de molécule-aimant. L'activité catalytique du complexe {Mn4Dy6Li2} calciné a aussi été étudiée et s'est avérée efficace pour l'oxydation du monoxyde de carbone. L'étude systématique de complexes isostructuraux de lanthanides a montré que l'incorporation d’ions 4f peut introduire de l’anisotropie magnétique et que l’ion DyIII est généralement le meilleur candidat pour le ciblage de molécules-aimants hétérométalliques 3d- 4f. / This dissertation describes the syntheses of 3d-4f-metal complexes starting from preformed compounds of Mn, Fe and Co, lanthanide salts and organic ligands and also the investigation of their structures and properties. 41 new polynuclear heterometallic metal complexes were synthesised in the course of this work with different interesting properties. The structures of all obtained compounds have been confirmed using X-ray diffraction. The magnetic properties of 22 complexes were studied, of which four show frequency dependent out-of-phase signals as expected for SMMs. The catalytic activity of calcinated {Mn4Dy6Li2} was investigated and proved effective for the oxidation of CO. It was established, that the use of precursors leads to new families of compounds. Moreover the study of isostructural compounds across the lanthanide series showed 1) that the incorporation of 4f ions introduces magnetic anisotropy and 2) DyIII is usually the best candidate for targeting 3d-4f-SMMs.

Aimants moléculaires

Single-Molecule Magnet

Effet tunnel quantique

Relaxation lente de l’aimantation

Single-Molecule Magnet

3d-4f complexes

Slow relaxation of magnetisation

Síntese, caracterização, estudos fotofísicos e acompanhamento in situ da reação de formação do corante (E)-2-[3-[4-(difenilamina)-fenil]-1-(p-tolil)-alilideno] malononitrila por microscopia de fluorescência / Synthesis, characterization, photophysics studies and monitoring in situ of the dye forming reaction (E) -2- [3- [4- (diphenylamine) phenyl] -1- (p-tolyl) -alilideno] malononitrile by fluorescence microscopy

Lino, Aline Monteiro

18 February 2016

Neste trabalho foi sintetizado o corante (E)-2-[3-[4-(difenilamina)-fenil]-1-(p-tolil)- alilideno]-malononitrila (DFTAM), a partir da reação de condensação entre 4- (difenilamino)-benzaldeído e 2- [1- (4- metilfenil)-etilideno]-malononitrila, com catálise básica de piperidina. O produto obtido foi purificado por cromatografia líquida de alta eficiência (HPLC) e caracterizado pelas técnicas de espectrometria de massas, ressonância magnética nuclear de 13C e 1H e espectroscopia no infravermelho com transformada de Fourier. Para estudar suas propriedades fotofísicas, espectros de absorção e emissão de fluorescência, decaimento de fluorescência e espectro de absorção de transientes foram feitos em diferentes solventes, variando-se a polaridade e viscosidade do meio. Duas bandas de absorção foram observadas, uma em 303 nm e outra em cerca de 490 nm, a qual apresentou deslocamento batocrômico com o aumento da polaridade do solvente. Para essa região de excitação a banda de emissão variou entre 517 e 630 nm, com o aumento da polaridade do meio. Os decaimentos de fluorescência mostraram duas componentes, uma na ordem de picossegundos e a outra de nanossegundos. Os experimentos de absorção de transientes apresentaram três espécies, uma mais longa (maior que 10 ms) e duas outras de cerca 2 e 22 μs. Surfactantes catiônicos, não iônico, e aniônico também foram usados para produzir micelas e fazer os experimentos já citados. Pôde-se observar que o corante interagiu com as micelas, melhorando sua fluorescência e aumentando o tempo de vida do estado singleto. Por fim, acompanhou-se in situ, através da técnica de microscopia TIRF, a reação de formação de DFTAM a nível single molecule com catalise básica de nanopartículas de MgO e lamínulas de vidro funcionalizadas com piperazina. Através da intermitência de fluorescência dos filmes feitos de ambas as amostras, observou-se a formação de moléculas do corante através de ciclos de catálise da piperazina. / In this project the synthesis of (E) -2- [3- [4- (diphenylamine) phenyl] -1- (p-tolyl) - allylidene] -malononitrile (DFTAM) dye, from the condensation reaction between 4- (diphenylamino) benzaldehyde and 2- [1- (4-methylphenyl) ethylidene]-malononitrile using piperidine basic catalysis has been achieved. The dye was purified by high-performance liquid chromatography (HPLC) and characterized by mass spectrometry, nuclear magnetic resonance 13C and 1H and Fourier Transform infrared spectroscopy techniques. To study DFTAM photophysical properties, absorption and fluorescence emission spectra, fluorescence decay and transient absorption spectrum were recorded in solvents with different polarity and viscosity. Two absorption bands of DFTAM were observed, the first one at 303 nm was solvent independent while the second one at about 490 nm, had bathochromic shift with increasing polarity of the medium. In the visible region of excitation the maximum of the dye emission band observed varied between 517 and 630 nm, upon increasing solvent polarity. Fluorescence decays showed two distinct components, a fast one in picosecond time scale and a slow one in nanoseconds. Transient absorption experiments indicated the presence of three species with different lifetimes, one longer than 10 ms and the other two with lifetimes about 2 and 22 μs. Cationic, nonionic, anionic surfactants were also used to produce micelles for easy solubilization of DFTAM. It was observed that the dye interacted with the micelles, improving its fluorescence yield and lifetime. Finally, the DFTAM formation reaction was monitored in situby TIRF wide field microscopy technique at single molecule level. The basic catalysis was tested for MgO nanoparticles and glass surface functionalized with bound piperazine. Through the fluorescence intermittency time trace obtained from TIRF movies, the discrete formation of dye molecules was only observed in the case of piperazine catalytic cycles.

basic catalysis

catálise básica

fluoróforo orgânico

intramolecular charge transfer

microscopia TIRF

organic fluorophore

single molecule

single molecule

TIRF microscopy

transferência de carga intramolecular

Readout Strategies for Biomolecular Analyses

Göransson, Jenny

January 2008

This thesis describes three readout formats for molecular analyses. A common feature in all works is probing techniques that upon specific target recognition ideally results in equimolar amounts of DNA circles. These are then specifically amplified and detected using any of the techniques presented herein. The first paper presents a method that enables homogeneous digital detection and enumeration of biomolecules, represented as fluorescence-labelled DNA macromolecules. This method offers precise measurements to be performed with a wide linear dynamic range. As an application, two closely related bacterial species were selectively detected. The second paper further investigates and optimizes the properties of the technique presented in paper one. The third paper demonstrates a platform that enables simultaneous quantitative analysis of large numbers of biomolecules. The array format and decoding scheme together propose a digital strategy for decoding of biomolecules. The array and the decoding procedure were characterized and evaluated for gene copy-number measurements. The fourth paper examines a new strategy for non-optical measurements of biomolecules. Characteristics of this technique are investigated, and compared to its optical equivalent, fluorescence polarization.

Padlock probe

Selector probe

Rolling circle amplification

Single molecule detection

Amplified single molecule

Random array

Pattern Recognition in Single Molecule Force Spectroscopy Data

Paulin, Hilary

05 September 2013

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.

biophysics

single molecule biophysics

single molecule force spectroscopy

alpha-lactalbumin

bacteriorhodopsin

pattern recognition

hierarchical clustering

clustering

force spectroscopy

protein adsorption

protein structure

surface curvature

atomic force microscopy