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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
71

Estudo, via simulação molecular, da interação de dois peptídeos da região 115-129 da miotoxina II do veneno da serpente Bothrops asper com membranas celulares. / Estudo, via simulação molecular, da interaão de dois peptídeos da região 115-129 da miotoxina II do veneno da serpente Bothrops asper com membranas celulares

Marcos Roberto Lourenzoni 13 June 2005 (has links)
As ligações de hidrogênio (LH), fundamentais na determinação da estrutura da água, proteínas, etc., são muito importantes no reconhecimento molecular e nos mecanismos de reações enzimáticas. A determinação da energia das LHs intramoleculares em proteínas e intermoleculares entre uma proteína e o solvente água, porque fornece informações sobre a estrutura secundária, terciária e quaternária das proteínas. Um método para quantificar e qualificar as LHs foi desenvolvido utilizando critérios de distância, geométricos e energéticos a partir das trajetórias obtidas por simulações de dinâmica molecular. O método foi testado com o monômero de uma fosfolipase A2 homodimérica, sem atividade catalítica, isolada do veneno da Bothrops asper(BaspMT-II). No dímero, a análise das LHs mostrou que elas são também essenciais na manutenção da estrutura quaternária. Essa análise permitiu identificar movimentos do tipo dobradiça acompanhados da formação transitória, na interface dimérica, de LHs controladas pelo triptofano na posição 77. Esses movimentos podem estar associados à ação danosa às membranas, uma vez que podem promover a inserção da região C-terminal na membrana. Estudos prévios mostraram que o peptídeo sintético (3Y codificado pelos aminoácidos 115-129 da BaspMT-II) apresenta atividade bactericida e citolítica. Um outro peptídeo (3W), mutante de 3Y, no qual três resíduos tirosina são substituidos por triptofano, apresenta um aumento do dano às membranas e do efeito miotóxico. Os mecanismos de ação desses peptídeos e as suas estruturas foram estudados por dinâmica molecular, dicroísmo circular (DC), microscopia de fluorescência e monocamadas de Langmuir (Mlang). As adsorções dos peptídeos em monocamadas de ácido dimiristoil fosfatídico (DMPA) e dimiristoilfosfatidilcolina (DMPC) se processam por mecanismos diferentes ocasionados pelas diferentes naturezas físico-químicas dos resíduos tirosina e triptofano. A microscopia de fluorescência acoplada a Mlang de DMPA com 3W adsorvido mostra um aumento da fluidez da monocamada, enquanto que o 3Y modifica os domínios do DMPA para pequenas estruturas circulares. Foram realizadas simulações dos peptídeos 3Y e 3W em meio aquoso e nas regiões interfaciais água/n-hexano e água/bicamadas de DMPC. Os resultados confirmam os obtidos por Mlang, demonstrando que os peptídeos interagem diferentemente com as membranas por adotar conformações alternativas definidas previamente. Essas conformações, diferentes das observadas em meio aquoso, dependem da natureza da interface. As estruturas encontradas no final das simulaçoes corroboram o mecanismo proposto por Mlang, assim como as estruturas sugeridas por DC. Isso sugere que a atividade biológica reduzida do peptídeo 3Y ocorre porque os seus dois resíduos Leu se adsorvem na interface sem penetrá-la. Ao contrário de 3W, os resíduos carregados do peptídeo 3Y não estão localizados corretamente para promover uma interação suficientemente atrativa para permitir a sua inserção na membrana celular. / Hydrogen bonds (HB) are highly important in the determination of the structure of the water and proteins. They also play a important role in molecular recognition and in enzyme reaction mechanisms. The determination of protein/water intermolecular and protein intramolecular HB energies provide information with respect to the formation and stabilization of secondary, tertiary and quaternary protein structure. A method that quantifies and qualifies the properties of HB was developed using distance, geometric and energy criteria as applied to data obtained from the atomic trajectories generated by molecular dynamics simulations. The method was tested with a monomer of a catalytically inactive homodimeric phospholipase A2 from Bothrops asper(BaspMT-II) venom. HBs at dimmer interface are essential for maintaining the quaternary structure, and are highly conserved during hinge-like movements of the dimmer. HB formed by tryptophan residue at position 77 controls this movement. These motions can be associated to the membrane damaging action since they facilitate the insertion of the C-terminus into the cellular membrane. Previous studies have shown that synthetic peptide (3Y, coding the amino acids 115-129 of BaspMT-II ) presents bactericidal and cytolitic activities. A peptide variant ( 3W ), in which tyrosine residues were substituted by tryptophan residues, presents an enhanced membrane damaging activity increased miotoxic effect. The mechanism of action of the peptides and their structures were studied by molecular dynamics simulations, circular dichroism (CD), fluorescence microscopy and Langmuir monolayers (Mlang). The adsorption of the peptides on a monolayer composed of dimiristoyl phosphatidic acid (DMPA) and dimiristoylphosphatidyl choline (DMPC) occurs through different processes due to the differences in the physic-chemical nature of the tyrosine and tryptophan residues. Fluorescence microscopy together with Mlang of DMPA with adsorbed 3W indicates an increase of the membrane fluidity while small circular domains are formed with DMPA. Simulations were conducted with the 3Y and 3W peptides in aqueous media, is a water/n-hexane and water/DMPC bilayers. The results confirm the Mlang results, showing that the peptides interact differently with the membranes by adopting alternative previously defined conformations. These two conformations, both of which are different to those observed in water, are dependent of the nature of the interfaces. The final simulated configurations confirm the mechanism proposed by Mlang and the structures proposed by CD. It is suggest that the reduced biological activity of the 3Y peptide is due to the two Leu residues that only adsorb to the cellular membrane without penetrating the bilayer. In contrast to the 3W peptide, no charged residue is correctly located to promote the interaction and insertion of the 3Y peptide into the membrane.
72

As ligações de hidrogênio e o efeito do substituinte - Influência na ressonância e aromaticidade de cátions e ácidos orgânicos / Hydrogen bonds and substituent effect - Influence in the resonance and aromaticity of the cations and organic acids

Renato Luis Tâme Parreira 11 July 2006 (has links)
A natureza das ligações de hidrogênio e a influência destas interações na estrutura eletrônica de complexos neutros, catiônicos, aniônicos e radicalares foi estudada utilizando-se análises geométricas, energéticas, eletrônicas e topológicas. Inicialmente, verificaram-se alterações na aromaticidade do cátion pirílio após a complexação com uma a três moléculas de água. Tais complexos foram ainda estudados em meio reacional com constante dielétrica igual a da água com o emprego do modelo PCM (Polarizable Continuum Model). Adicionalmente, os efeitos da hidroxilação na estrutura eletrônica dos cátions benzopirílio e flavílio foram considerados. Posteriormente, analisaram-se os efeitos das fortes ligações de hidrogênio na ressonância do grupo carboxila em complexos formados entre o radical hidroperoxil e os ácidos fórmico, acético e trifluoroacético. Como extensão desse trabalho, estudos envolvendo complexos obtidos com e sem restrições na otimização de geometria possibilitaram obter informações a respeito da ressonância dos grupos carboxila e carboxilato quando o fluoreto de hidrogênio interage linear ou perpendicularmente com todos os átomos do ácido fórmico e do ânion formiato. O desenvolvimento das atividades supracitadas compreendeu a análise da função de onda pelos métodos NBO (Natural Bond Orbital), NSA (Natural Steric Analysis), NRT (Natural Resonance Theory) e AIM (Atoms in Molecules). As alterações em parâmetros geométricos e nas cargas atômicas foram consideradas. Uma análise energética foi realizada com o emprego do método de decomposição de energia proposto por Xantheas. As freqüências vibracionais e a intensidade das bandas do estiramento do grupo X-H, doador da ligação de hidrogênio, foram analisadas. As densidades de spin para os complexos radicalares também foram obtidas. A influência das ligações de hidrogênio e o efeito do substituinte na aromaticidade dos cátions foram verificados com o emprego dos métodos e índices NICS (Nucleus Independent Chemical Shifts), HOMA (Harmonic Oscillator Model of Aromaticity), HOSE (Harmonic Oscillator Stabilization Energy) e PDI (para-Delocalization Index). Os cálculos foram efetuados com os modelos B3LYP/6-31+G(d,p), B3LYP/6-311++G(3df,3pd) e UB3LYP/6-311++G(3df,3pd). Ocasionalmente, outras funções de base (EPR-III e cc-pVDZ), assim como o método MP2, foram utilizados para testar a confiabilidade dos resultados obtidos. As interações intermoleculares pouco alteraram a estrutura eletrônica e a aromaticidade do cátion pirílio. Analogamente, a substituição de um átomo de hidrogênio por um grupo hidroxila em diversas posições dos cátions benzopirílio e flavílio também não provocou modificações muito significativas na estrutura eletrônica desses cátions, embora tenha se verificado uma dependência da aromaticidade com a posição da hidroxila. Por outro lado, a distorção geométrica associada às ligações de hidrogênio foram responsáveis pelo incremento ou diminuição da ressonância do grupo carboxila nos ácidos fórmico, acético, trifluoroacético e do grupo carboxilato no ânion formiato. Os efeitos dos grupos doador e sacador de elétrons na estabilização dos complexos radicalares foram evidenciados. Adicionalmente, pode-se atribuir um caráter covalente parcial em algumas ligações de hidrogênio. / The nature of hydrogen bonds and their influence on electronic structure of neutral, cationic, anionic, and radical complexes was studied by using geometric, energetic, electronic, and topological analysis. The changes in aromaticity of the pyrylium cation upon complexation with one up to three water molecules were investigated. The PCM (Polarizable Continuum Model) model was employed to study the pyrylium-water complexes in a water reaction medium. In addition, the effects of hydroxylation on electronic structure of the benzopyrylium and flavilium cations were also considered. In addition, the effects of strong hydrogen bonds on carboxyl group resonance in the complexes formed between the hydroperoxyl radical and formic, acetic, and trifluoroacetic acids were analyzed. In extension of this work, studies including complexes, obtained with and without geometric restrictions, provided information about the resonance of the carboxyl and carboxylate groups when the hydrogen fluoride interacts, linear or perpendicularly, with all atoms of formic acid and formate anion. The analysis of the wavefunction by using NBO (Natural Bond Orbital), NSA (Natural Steric Analysis), NRT (Natural Resonance Theory), and AIM (Atoms in Molecules) methods was necessary to the development of the above mentioned activities. The changes in geometric parameters and atomic charges were also considered. An energetic analysis of complexes was done with the energy decomposition method proposed by Xantheas. The vibrational frequencies and the intensity of the X-H (hydrogen bond donor group) stretching bands were studied. The spin densities for the radical complexes were also obtained. The Nucleus Independent Chemical Shifts (NICS), Harmonic Oscillator Model of Aromaticity (HOMA), HOSE (Harmonic Oscillator Stabilization Energy), and PDI (para-Delocalization Index) aromaticity criteria were employed to verify the hydrogen bond influence and the effect of hydroxylation in the aromaticity of the cations. The calculations were carried out by using B3LYP/6-31+G(d,p), B3LYP/6-311++G(3df,3pd), and UB3LYP/6-311++G(3df,3pd) models. Occasionally, other basis set (EPR-III and cc-pVDZ), as well as the MP2 method, were applied to test the accuracy of the results. The intermolecular interactions lead to small alterations in the electronic structure and aromaticity of pyrylium cation. Similarly, the substitution at different positions of the benzopyrylium and flavilium cations by a hydroxyl group does not cause significant changes in the electronic structure of these cations. However, a dependence of the hydroxyl group position on aromaticity was observed. On the other hand, for formic, acetic, trifluoroacetic acids, as well as for the formate anion, the resonance of the carboxyl and carboxylate groups is affected not only by the geometric distortions but also by the hydrogen bonds. The effects of the electron-donating and electron-withdrawing groups in the stabilization of radical complexes were characterized. Furthermore, a partial covalent character can be attributed to some hydrogen bonds.
73

Crystal structures of 2-[3,5-bis­­(bromo­meth­yl)-2,4,6-tri­ethyl­benz­yl]isoindoline-1,3-dione and 2-{5-(bromo­meth­yl)-3-[(1,3-dioxoisoindolin-2-yl)meth­yl]-2,4,6-tri­ethyl­benz­yl}isoindoline-1,3-dione

Stapf, Manuel, Leibiger, Betty, Schwarzer, Anke, Mazik, Monika 12 July 2024 (has links)
The title compounds, C23H25Br2NO2 (1) and C31H29BrN2O4 (2), crystallize in the space group P21/n with two (1-A and 1-B) and one mol­ecules, respectively, in the asymmetric unit of the cell. The mol­ecular conformation of these compounds is stabilized by intra­molecular C—H⋯O hydrogen bonds and C—H⋯N or C—H⋯π inter­actions. The crystal structure of 1 features a relatively strong Br⋯O=C halogen bond, which is not observed in the case of 2. Both crystal structures are characterized by the presence of C—H⋯Br hydrogen bonds and numerous inter­molecular C—H⋯O hydrogen-bonding inter­actions.
74

Synthese und Charakterisierung von enolisierbaren Barbituratfarbstoffen als Sensoren für Nukleinbasenderivate

Schade, Alexander 13 December 2016 (has links) (PDF)
In dieser Arbeit wird die Synthese neuartiger 5-monosubstituierter Barbituratfarbstoffe mit elektronenziehenden Substituenten in 5-Position beschrieben. Durch diese Funktionalisierung entstehen schaltbare Farbstoffe mit einer farblosen Ketoform und einer farbigen Enolform. Die Einflüsse verschieden stark elektronenziehender Substituenten sowie unterschiedlich großer konjugierter π-Systeme auf die Keto-Enol-Tautomerie wurden untersucht. Dies erfolgt einerseits mittels Röntgeneinkristallstrukturanalysen der Festkörper und andererseits mit solvatochromen Untersuchungen in Lösung. Durch die Keto-Enol-Tautomerie der Barbituratfarbstoffe wird die Wasserstoffbrücken¬bindungssequenz beim Übergang zwischen Keto- und Enol-Form verändert. Es wurde gezeigt, dass durch Zugabe von Rezeptoren mit komplementärer Wasserstoffbrückenbindungssequenz zur Enol-Form das tautomere Gleichgewicht der Barbitursäuren hin zur Enol-Form verschoben werden kann. Um hierzu verlässliche Aussagen zu erhalten wurden vergleichende Experimente mit N,N´-dialkylierten Barbituratfarbstoffen durchgeführt. Aufgrund der Synthesestrategie der Barbituratfarbstoffe, welche ausgehend von Barbituratanionen über nukleophile aromatische Substitutionsreaktionen hergestellt wurden, war es zweckmäßig die Nukleophilieparameter der Barbituratanionen zu ermitteln. Dazu wurde der Ansatz von Mayr gewählt und die Nukleophilie von vier Barbituratanionen bestimmt. Weiterhin konnte in dieser Arbeit die Charakterisierung von ionischen Flüssigkeiten nach der 4-Parameter-Gleichung von Catalán umgesetzt werden. Dabei gelang es erstmal für eine vielzahl verschiedener ionischer Flüssigkeiten die Polarisierbarkeit und Dipolarität getrennt voneinander mit Hilfe zweier solvatochromer Farbstoffe zu ermitteln.
75

Soli 2-aminoethanolu a ferrocenových kyselin / Salts of 2-aminoethanol and ferrocene-based acids

Zábranský, Martin January 2014 (has links)
Combination of the compact but sterically flexible ferrocene scaffold with intermolecular binding potential and conformational variability of (2-hydroxyethyl)ammonium structural motif was utilised in the construction of solid crystalline materials. Crystallisation in systems containing ferrocenecarboxylic, 2-ferrocenylacetic, 3-ferrocenylpropionic, 3-ferrocenyl- acrylic, 3-ferrocenylacrylic, 3-ferrocenylpropiolic, ferrocene-1,1'-dicarboxylic or ferrocene- sulfonic acid with 2-aminoethanol afforded crystals of the corresponding salts. The resulting crystalline products were characterised with the usual methods (proton nuclear magnetic resonance, infrared spectroscopy, elemental analysis) and their crystal structures were determined by means of single-crystal X-ray diffraction analysis. The crystal structures of the salts mentioned above usually contain rather complicated two dimensional networks of charge-assisted hydrogen bonds. With the aim of studying potentially more simple hydrogen-bonded structures, additional crystallisation experiments were conducted in systems of ferrocenecarboxylic acid and 2-(methylamino)ethanol or 2-(dimethylamino)ethanol. These experiments yielded simple salt of the former amine and adducts of salts of both bases with ferrocenecarboxylic acid in the ratio of 1:1. The...
76

Exploring Protein-Nucleic Acid Interactions Using Graph And Network Approaches

Sathyapriya, R 03 1900 (has links)
The flow of genetic information from genes to proteins is mediated through proteins which interact with the nucleic acids at several stages to successfully transmit the information from the nucleus to the cell cytoplasm. Unlike in the case of protein-protein interactions, the principles behind protein-nucleic acid interactions are still not very (Pabo and Nekludova, 2000) and efforts are still underway to arrive at the basic principles behind the specific recognition of nucleic acids by proteins (Prabakaran et al., 2006). This is mainly due to the innate complexity involved in recognition of nucleotides by proteins, where, even within a given family of DNA binding proteins, different modes of binding and recognition strategies are employed to suit their function (Luscomb et al., 2000). Such difficulties have also not made possible, a thorough classification of DNA/RNA binding proteins based on the mode of interaction as well as the specificity of recognition of the nucleotides. The availability of a large number of structures of protein-nucleic acids complexes (albeit lesser than the number of protein structures present in the PDB) in the past few decades has provided the knowledge-base for understanding the details behind their molecular mechanisms (Berman et al., 1992). Previously, studies have been carried out to characterize these interactions by analyzing specific non-covalent interactions such as hydrogen bonds, van der Walls, and hydrophobic interactions between a given amino acid and the nucleic acid (DNA, RNA) in a pair-wise manner, or through the analysis of interface areas of the protein-nucleic acid complexes (Nadassy et al., 1998; Jones et al., 1999). Though the studies have deciphered the common pairing preferences of a particular amino acid with a given nucleotide of DNA or RNA, there is little room for understanding these specificities in the context of spatial interactions at a global level from the protein-nucleic acid complexes. The representation of the amino acids and the nucleotides as components of graphs, and trying to explore the nature of the interactions at a level higher than exploring the individual pair-wise interactions, could provide greater details about the nature of these interactions and their specificity. This thesis reports the study of protein-nucleic interactions using graph and network based approaches. The evaluation of the parameters for characterizing protein-nucleic acid graphs have been carried out for the first time and these parameters have been successfully employed to capture biologically important non-covalent interactions as clusters of interacting amino acids and nucleotides from different protein-DNA and protein-RNA complexes. Graph and network based approaches are well established in the field of protein structure analysis for analyzing protein structure, stability and function (Kannan and Vishveshwara, 1999; Brinda and Vishveshwara, 2005). However, the use of graph and network principles for analyzing structures of protein-nucleic acid complexes is so far not accomplished and is being reported the first time in this thesis. The matter embodied in the thesis is presented as ten chapters. Chapter 1 lays the foundation for the study, surveying relevant literature from the field. Chapter 2 describes in detail the methods used in constructing graphs and networks from protein-nucleic acid complexes. Initially, only protein structure graphs and networks are constructed from proteins known to interact with specific DNA or RNA, and inferences with regard to nucleic acid binding and recognition were indirectly obtained . Subsequently, parameters were evaluated for representing both the interacting amino acids and the nucleotides as components of graphs and a direct evaluation of protein-DNA and Protein-RNA interactions as graphs has been carried out. Chapter 3 and 4 discuss the graph and network approaches applied to proteins from a dataset of DNA binding proteins complexed with DNA. In chapter 3, the protein structure graphs were constructed on the basis of the non-covalent interactions existing between the side chains of amino acids. Clusters of interacting side chains from the graphs were obtained using the graph spectral method. The clusters from the protein-DNA interface were analyzed in detail for the interaction geometry and biological importance (Sathyapriya and Vishveshwara, 2004). Chapter 4 also uses the same dataset of DNA binding proteins, but a network-based approach is presented. From the analysis of the protein structure networks from these DNA binding proteins, interesting observations relating the presence of highly connected nodes(or hubs) of the network to functionally important amino acids in the structure, emerged. Also, the comparison between the hubs identified from the protein-protein and the protein-DNA interfaces in terms of their amino acid composition and their connectivity are also presented (Sathyapriya and Vishveshwara, 2006) Chapter 5 and 6 deal with the graph and network applications to a specific system of protein-RNA complex (aminoacyl-tRNA synthetases) to gain insights into their interface biology based on amino acid connectivity. Chapter 5 deals with a dataset of aminoacyl-tRNA synthetase (aaRS) complexes obtained with various ligands like ATP, tRNA and L-amino acids. A graph based identification of side chain clusters from these ligand-bound aaRS structures has highlighted important features of ligand-binding at the catalytic sites of the two structurally different classes of aaRS (Class I and Class II). Side chain clusters from other regions of aaRS such as the anticodon binding region and the ligand-activation sites are discussed. A network approach is used in a specific system of aaRS(E.coli Glutaminyl-tRNA synthetase (GlnRS) complexed with its ligands, to specifically understand the effects of different ligand binding., in chapter 6. The structure networks of E.coli GlnRS in the ligand-free and different ligand-bound states are constructed. The ligand-free and the ligand-bound complexes are compared by analyzing their network properties and the presence of hubs to understand the effect of ligand-binding. These properties have elegantly captured the effects of ligand-binding to the GlnRS structure and have also provided an alternate method for comparing three dimensional structures of proteins in different ligand-bound states (Sathyapriya and Vishveshwara, 2007). In contrast to protein structure graphs (PSG), both the interacting amino acids and nucleotides (DNA/RNA) form the components of the protein-nucleic acid graphs (PNG) from protein-nucleic acid complexes. These graphs are constructed based on the non-covalent interactions existing between the side chains of the amino acids and nucleotides. After representing the interacting nucleotides and amino acids as graphs, clusters of the interacting components are identified. These clusters are the strongly interacting amino acids and nucleotides from the protein-nucleic acid complexes. These clusters can be generated at different strengths of interaction between the amino acid side chain and the nucleotide (measured in terms of its atomic connectivity) and can be used for detecting clusters of non-specific as well as specific interactions of amino acids and nucleotides. Though the methodology of graph construction and cluster identification are given in chapter 2, the details of the parameters evaluated for constructing PNG are given in chapter 7. Unlike in the previous chapters, the succeeding chapters deal exclusively with results that are obtained from the analyses of PNG. Two examples of obtaining clusters from a PNG are given, one each for a protein-DNA and a protein-RNA complex. In the first example, a nucleosome core particle is subjected to the graph based analysis and different clusters of amino acids with different regions of the DNA chain such as phosphate, deoxyribose sugar and the base are identified. Another example of aminoacyl-tRNA synthetase complexed with its cognate tRNA is used to illustrate the method with a protein-RNA complex. Further, the method of constructing and analyzing protein-nucleic acid graphs has been applied to the macromolecular machinery of the pre-translocation complex of the T. thermophilus 70S ribosome. Chapter 8 deals exclusively with the results identified from the analysis of this magnificent macromolecular ensemble. The availability of the method that can handle interactions between both amino acids and the nucleotides of the protein-nucleic acid complexes has given us the basis fro evaluating these interactions in a level higher than that of analyzing pair-wise interactions. A study on the evaluation of short hydrogen bonds(SHB) in proteins, which does not fall under the realm of the main objective of the thesis, is discussed in the Chapter 9. The short hydrogen bonds, defined by the geometrical distance and angle parameters, are identified from a non-redundant dataset of proteins. The insights into their occurrence, amino acid composition and secondary structural preferences are discussed. The SHB are present in distinct regions of protein three-dimensional structures, such that they mediate specific geometrical constraints that are necessary for stability of the structure (Sathyapriya and Vishveshwara, 2005). The significant conclusions of various studies carried out are summarized in the last chapter (Chapter 10). In conclusion, this thesis reports the analyses performed with protein-nucleic acid complexes using graph and network based methods. The parameters necessary for representing both amino acids and the nucleotides as components of a graph, are evaluated for the first time and can be used subsequently for other analyses. More importantly, the use of graph-based methods has resulted in considering the interaction between the amino acids and the nucleotides at a global level with respect to their topology of the protein-nucleic acid complexes. Such studies performed on a wide variety of protein-nucleic acid complexes could provide more insights into the details of protein-nucleic acid recognition mechanisms. The results of these studies can be used for rational design of experimental mutations that ascertain the structure-function relationships in proteins and protein-nucleic acid complexes.
77

Relaxationen in komplexen Fluiden / Relaxations of complex fluids

Schwabe, Moritz 02 November 2010 (has links)
No description available.
78

Etude quantique des liaisons fortes et faibles : développement de fonctionnelles "doubles-hybrides" et de surfaces de potentiel analytiques / Quantum study of strong and weak interactions : development of double-hybrid functionals and of analytic potential surfaces

Cornaton, Yann 03 September 2013 (has links)
Les travaux réalisés au cours de cette thèse se décomposent en deux thèmes principaux, eux-même subdivisés enplusieurs projets. D'une part, des travaux ont été menés concernant l'analyse et le développement de fonctionnelles « doubles hybrides ». Une analyse des fonctionnelles « doubles hybrides » à séparation linéaire le long de la connexionadiabatique a été proposée. Une nouvelle fonctionnelle « double hybride » à séparation de portée basée sur uneséparation alternative de l'énergie d'échange et de corrélation, RSDHf, a été développée. D'autre part, des travaux quant au développement de surfaces d'énergie potentielle (SEP) analytiques ont été menés. Un nouveau potentiel analytique a été proposé pour la description de la SEP des systèmes triatomiques. La combinaison de ce potentiel avec un potentiel électrostatique a été utilisé pour le développement de SEP analytiques pour de petits systèmes en interaction faible : H2O···HF, HF2-, Ne···ClF. / Works done during this thesis split into two main themes, themselves subdivided in several projects. On the one hand, works have been led concerning the analysis and the development of double-hybrid functionals. An analysis of linearly-separated double-hybrid functionals along the adiabatic connection has been proposed. A new range-separated double-hybrid functional based on an alternative separation of the exchange-correlation energy, RSDHf, has been developed. On the other hand, works related to the development of analytic potential energy surfaces (PES) has been led. A new analytic potential has been proposed for the description of the PES of triatomic systems. The combinaition of this potential with an electrostatic potential has been used for the development of analytic PES for small systems in weak interaction : H2O···HF, HF2-, Ne···ClF.
79

Synthese und Charakterisierung von enolisierbaren Barbituratfarbstoffen als Sensoren für Nukleinbasenderivate

Schade, Alexander 07 November 2016 (has links)
In dieser Arbeit wird die Synthese neuartiger 5-monosubstituierter Barbituratfarbstoffe mit elektronenziehenden Substituenten in 5-Position beschrieben. Durch diese Funktionalisierung entstehen schaltbare Farbstoffe mit einer farblosen Ketoform und einer farbigen Enolform. Die Einflüsse verschieden stark elektronenziehender Substituenten sowie unterschiedlich großer konjugierter π-Systeme auf die Keto-Enol-Tautomerie wurden untersucht. Dies erfolgt einerseits mittels Röntgeneinkristallstrukturanalysen der Festkörper und andererseits mit solvatochromen Untersuchungen in Lösung. Durch die Keto-Enol-Tautomerie der Barbituratfarbstoffe wird die Wasserstoffbrücken¬bindungssequenz beim Übergang zwischen Keto- und Enol-Form verändert. Es wurde gezeigt, dass durch Zugabe von Rezeptoren mit komplementärer Wasserstoffbrückenbindungssequenz zur Enol-Form das tautomere Gleichgewicht der Barbitursäuren hin zur Enol-Form verschoben werden kann. Um hierzu verlässliche Aussagen zu erhalten wurden vergleichende Experimente mit N,N´-dialkylierten Barbituratfarbstoffen durchgeführt. Aufgrund der Synthesestrategie der Barbituratfarbstoffe, welche ausgehend von Barbituratanionen über nukleophile aromatische Substitutionsreaktionen hergestellt wurden, war es zweckmäßig die Nukleophilieparameter der Barbituratanionen zu ermitteln. Dazu wurde der Ansatz von Mayr gewählt und die Nukleophilie von vier Barbituratanionen bestimmt. Weiterhin konnte in dieser Arbeit die Charakterisierung von ionischen Flüssigkeiten nach der 4-Parameter-Gleichung von Catalán umgesetzt werden. Dabei gelang es erstmal für eine vielzahl verschiedener ionischer Flüssigkeiten die Polarisierbarkeit und Dipolarität getrennt voneinander mit Hilfe zweier solvatochromer Farbstoffe zu ermitteln.
80

Contrôle de l'organisation moléculaire en 2D et 3D par l’utilisation de liaisons hydrogène, de coordination métallique et d'autres interactions

Duong, Adam 04 1900 (has links)
La stratégie de la tectonique moléculaire a montré durant ces dernières années son utilité dans la construction de nouveaux matériaux. Elle repose sur l’auto-assemblage spontané de molécule dite intelligente appelée tecton. Ces molécules possèdent l’habilité de se reconnaitre entre elles en utilisant diverses interactions intermoléculaires. L'assemblage résultant peut donner lieu à des matériaux moléculaires avec une organisation prévisible. Cette stratégie exige la création de nouveaux tectons, qui sont parfois difficiles à synthétiser et nécessitent dans la plupart des cas de nombreuses étapes de synthèse, ce qui empêche ou limite leur mise en application pratique. De plus, une fois formées, les liaisons unissant le corps central du tecton avec ces groupements de reconnaissance moléculaire ne peuvent plus être rompues, ce qui ne permet pas de remodeler le tecton par une procédure synthétique simple. Afin de contourner ces obstacles, nous proposons d’utiliser une stratégie hybride qui se sert de la coordination métallique pour construire le corps central du tecton, combinée avec l'utilisation des interactions plus faibles pour contrôler l'association. Nous appelons une telle entité métallotecton du fait de la présence du métal. Pour explorer cette stratégie, nous avons construit une série de ligands ditopiques comportant soit une pyridine, une bipyridine ou une phénantroline pour favoriser la coordination métallique, substitués avec des groupements diaminotriazinyles (DAT) pour permettre aux complexes de s'associer par la formation de ponts hydrogène. En plus de la possibilité de créer des métallotectons par coordination, ces ligands ditopiques ont un intérêt intrinsèque en chimie supramoléculaire en tant qu'entités pouvant s'associer en 3D et en 2D. En parallèle à notre étude de la chimie de coordination, nous avons ii examiné l'association des ligands, ainsi que celle des analogues, par la diffraction des rayons-X (XRD) et par la microscopie de balayage à effet tunnel (STM). L'adsorption de ces molécules sur la surface de graphite à l’interface liquide-solide donne lieu à la formation de différents réseaux 2D par un phénomène de nanopatterning. Pour comprendre les détails de l'adsorption moléculaire, nous avons systématiquement comparé l’organisation observée en 2D par STM avec celle favorisée dans les structures 3D déterminées par XRD. Nous avons également simulé l'adsorption par des calculs théoriques. Cette approche intégrée est indispensable pour bien caractériser l’organisation moléculaire en 2D et pour bien comprendre l'origine des préférences observées. Ces études des ligands eux-mêmes pourront donc servir de référence lorsque nous étudierons l'association des métallotectons dérivés des ligands par coordination. Notre travail a démontré que la stratégie combinant la chimie de coordination et la reconnaissance moléculaire est une méthode de construction rapide et efficace pour créer des réseaux supramoléculaires. Nous avons vérifié que la stratégie de la tectonique moléculaire est également efficace pour diriger l'organisation en 3D et en 2D, qui montre souvent une homologie importante. Nous avons trouvé que nos ligands hétérocycliques ont une aptitude inattendue à s’adsorber fortement sur la surface de graphite, créant ainsi des réseaux organisés à l'échelle du nanomètre. L’ensemble de ces résultats promet d’offrir des applications dans plusieurs domaines, dont la catalyse hétérogène et la nanotechnologie. Mots clés : tectonique moléculaire, interactions intermoléculaires, stratégie hybride, coordination métallique, diffraction des rayons-X, microscopie de balayage à effet tunnel, graphite, phénomène de nanopatterning, calculs théoriques, ponts hydrogène, chimie supramoléculaire, ligands hétérocycliques, groupements DAT, catalyse hétérogène, nanotechnologie. / In recent years, molecular tectonics has been a useful strategy in the construction of new materials. It relies on the spontaneous self-assembly of molecules called tectons. These molecules have the ability to recognize themselves using various intermolecular interactions. The resulting assembly can produce molecular materials with predictable organization. This strategy requires the creation of new tectons, which are sometimes difficult to synthesize and require in most cases many synthetic steps, which prevents or limits their practical application. Moreover, once formed, the bonds joining the central core of the tecton with the groups used for molecular recognition cannot be broken, which means that it is not possible to recycle or reform the tecton by simple synthetic procedures. To avoid these obstacles, we propose to use a hybrid strategy that uses metal coordination to build the central core of the tecton, combined with the use of weaker interactions to control the association. We call such entities metallotectons due to the presence of metal. To explore this strategy, we constructed a series of ditopic ligands containing either pyridine, bipyridine or phenanthroline to promote metal coordination, substituted with diaminotriazinyl groups (DAT) to allow inter-complex association by the formation of hydrogen bonds. In addition to the possibility of creating metallotectons by coordination, these ditopic ligands have an intrinsic interest in supramolecular chemistry as entities that can associate in 3D and 2D. In parallel to our study of coordination chemistry, we examined the association of ligands by X-ray diffraction (XRD) and scanning tunneling microscopy (STM). The adsorption of these molecules on the graphite surface at the liquid-solid interface results in the formation of different networks through a process of 2D nanopatterning. To understand the details of iv molecular adsorption, we systematically compared the 2D organization observed STM with the 3D structures determined by XRD. We also simulated the adsorption by theoretical calculations. This integrated approach is essential to characterize the molecular organization in 2D and to understand the origin of the observed preferences. These studies of the ligands themselves may therefore serve as a reference when we study the association of metallotectons derived by ligands coordination. Our work demonstrates that the strategy combining coordination chemistry and molecular recognition is a rapid and an efficient method to create supramolecular networks. We verified that the strategy of molecular tectonics is also effective in leading the organization in 3D and 2D, which often shows a significant homology. We found that our heterocyclic ligands have unexpected ability to adsorb strongly on the graphite surface, creating networks organize in nanoscale. Together, these results provide promising applications in several fields, including heterogeneous catalysis and nanotechnology. Keywords : molecular tectonics, intermolecular interactions, hybrid strategy, metal coordination, X-ray diffraction, scanning tunneling microscopy, graphite, nanopatterning phenomenon, theoretical calculations, hydrogen bonds, supramolecular chemistry, ligands, DAT groups, heterogeneous catalysis, nanotechnology.

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