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Synthesis and structural studies of group 16 peri-substituted naphthalenes and related compoundsKnight, Fergus Ross January 2010 (has links)
Understanding how atoms interact is a fundamental aspect of chemistry, biology and materials science. There have been great advances in the knowledge of covalent and ionic bonding over the past twenty years but one of the major challenges for chemistry is to develop full understanding of weak interatomic/intermolecular forces. This thesis describes fundamental studies that develop the basic understanding of weak interactions between heavier polarisable elements. The chosen methodology is to constrain heavy atoms using a rigid naphthalene backbone. When substituents larger than hydrogen, are positioned at close proximity at the peri-positions of a naphthalene molecule they experience steric strain; the extent of which is dictated by intramolecular interactions. These interactions can be repulsive due to steric hindrance or attractive due to weak or strong bonding. In efforts to understand the factors which influence distortion in sterically crowded naphthalenes and study possible weak intramolecular interactions between peri-atoms, investigations focussed on previously unknown mixed 1,8-disubstituted naphthalene systems. Mixed phosphorus-chalcogenide species were initially studied; three mixed phosphine compounds of the type Nap[ER][PPh2] were prepared along with their chalcogenides and a series of metal complexes. The study of interactions between heavy atoms was progressed by investigations into a series of mixed chalcogenide compounds of the type Nap[EPh][E’Ph] (E = S, Se, Te). Subsequent reaction of the chalcogenide systems with the di-halogens, dibromine and diiodine, afforded a mixture of charge transfer and insertion adducts displaying an array of different geometries around the chalcogen atom. From molecular structural studies, a collection of intramolecular peri-interactions were found, extending from no interaction due to repulsive effects, weak attractive 3c-4e type interactions and one example containing a strong covalent peri-bond. Further weak intramolecular interactions observed include CH-π and E•••E’ type interactions plus π-π stacking between adjacent phenyl rings. It was discovered that the bulk of the peri-atoms is influential on the distance between them, but this is not the only factor determining the naphthalene geometry. Inter- and intramolecular interactions can also have an impact and furthermore the number, size and electronic properties of substituents attached to the peri-atoms can determine molecular distortion.
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Tunnels and Grooves : Structure-Function Studies in Two Disparate EnzymesEricsson, Daniel January 2009 (has links)
This thesis describes structural and binding studies in enzymes from two different organisms: ribonucleotide reductase from Mycobacterium tuberculosis (RNR) and lipase A from Candida antarctica (CalA). RNR is viable as a target for new drugs against the causative agent of tuberculosis. The biologically active form of RNR is a heterotetramer with an α2β2 substructure. Here we show that an N-acetylated heptapeptide based on the C-terminal sequence of the smaller RNR subunit can disrupt the formation of the holoenzyme sufficiently to inhibit its function. An N-terminal truncation, an alanine scan and a novel statistical molecular design approach based on the heptapeptide Ac-Glu-Asp-Asp-Asp-Trp-Asp-Phe-OH were applied. A full-length acetylated heptapeptide was necessary for inhibition, and Trp5 and Phe7 were also essential. Exchanging the acetyl for the N-terminal Fmoc protective-group increased the binding potency ten-fold. Based on this, several truncated and N-protected peptides were evaluated in a competitive fluorescence polarization assay. The single-amino acid Fmoc-Trp inhibits the RNR holoenzyme formation with a dissociation constant of 12µM, making it an attractive candidate for further development of non-peptidic inhibitors Lipases are enzymes with major biotechnological applications. We report the x-ray structure of CalA, the first member of a novel family of lipases. The fold includes a well-defined lid as well as a classical α/β hydrolase domain. The structure is that of the closed/inactive state of the enzyme, but loop movements near Phe431 will provide virtually unlimited access to solvent for the alcohol moiety of an ester substrate. The structure thus provides a basis for understanding the enzyme's preference for acyl moieties with long, straight tails, and for its highly promiscuous acceptance of widely different alcohol and amine moieties. An unconventional oxyanion hole is observed in the present structure, although the situation may change during interfacial activation.
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Leukotriene A4 hydrolase : studies of structure-function relationships by site-directed mutagenesis and X-ray crystallography /Rudberg, Peter C., January 2004 (has links)
Diss. (sammanfattning) Stockholm : Karol. inst., 2004. / Härtill 4 uppsatser.
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Crystal structure of cleaved vaspin (serpinA12)Pippel, Jan, Kuettner, E. Bartholomeus, Ulbricht, David, Daberger, Jan, Schultz, Stephan, Heiker, John T., Sträter, Norbert 06 March 2019 (has links)
The adipokine vaspin (serpinA12) is mainly expressed in white adipose tissue and exhibits various beneficial effects on obesity-related processes. Kallikrein 7 is the only known target protease of vaspin and is inhibited by the classical serpin inhibitory mechanism involving a cleavage of the reactive center loop between P1 (M378) and P1′ (E379). Here, we present the X-ray structure of vaspin, cleaved between M378 and E379. We provide a comprehensive analysis of differences between the uncleaved and cleaved forms in the shutter, breach, and hinge regions with relation to common molecular features underlying the serpin inhibitory mode. Furthermore, we point out differences towards other serpins and provide novel data underlining the remarkable stability of vaspin. We speculate that the previously reported FKGx1Wx2x3 motif in the breach region may play a decisive role in determining the reactive center loop configuration in the native vaspin state and might contribute to the high thermostability of vaspin. Thus, this structure may provide a basis for future mutational studies.
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Oxygen Bridged Metal Systems: Heterometallic Compounds Containing Main Group Metal, Transtion Metal and f-Elements / Oxygen Bridged Metal Systems: Heterometallic Compounds Containing Main Group Metal, Transtion Metal and f-ElementsZhang, Zhensheng 08 November 2010 (has links)
No description available.
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Synthesis and X-ray Structural Characterization of Oxygen Bridged Complexes for Olefin Polymerization: A Theoretical Interpretation of Structure and Activity RelationshipPrabhuodeyara Matada, Gurubasavaraj 30 October 2007 (has links)
No description available.
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Catalysis at the Interface- Elucidation of the Activation Process and Coupling of Catalysis and Compartmentalization of the Peripheral Membrane Protein Pyruvate Oxidase from Escherichia coliSitte, Astrid 24 April 2013 (has links)
No description available.
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Caractérisation structurale et fonctionnelle d'une lectine de type-C des cellules de Langerhans : La Langérine / Structural and functional characterization of Langerin : lectin receptor of Langerhans cellsChabrol, Eric 29 May 2012 (has links)
Les cellules dendritiques jouent un rôle primordial dans le système immunitaire. En effet, ces cellules sont à l'interface entre l'immunité innée et adaptative par leur capacité de reconnaissance, d'internalisation et de dégradation de pathogènes afin de présenter des antigènes aux lymphocytes. La capacité de reconnaissance est engendrée par l'expression de différents récepteurs à la surface de ces cellules. Parmi ces récepteurs, deux grandes familles permettent la reconnaissance d'un large panel de différents pathogènes, comme les TLRs (« Toll-Like Receptors) et les lectines de type-C. Ces récepteurs sont utilisés comme marqueurs des différents sous-types de cellules dendritiques. Par exemple, parmi les lectines de type-C, DC-SIGN est majoritairement exprimée dans les cellules dendritiques dermiques alors que la Langérine est, quand à elle, fortement exprimée par les cellules dendritiques épidermiques, les cellules de Langerhans. Ces deux sous-types de cellules dendritiques divergent par leur réponse à l'infection par le VIH (« virus d'immunodéficience humain »). En effet, le virus utilise DC-SIGN pour détourner le rôle de ces cellules afin d'infecter les lymphocytes T alors que la reconnaissance du VIH par la Langérine, dans les cellules de Langerhans, conduit à la clairance de virus par son internalisation dans le granule de Birbeck. Cet organite est spécifique des cellules de Langerhans et nécessite l'expression de la Langérine. Ce travail de thèse s'est donc focalisé sur la caractérisation structurale et fonctionnelle de la Langérine. Il a permis de mettre en évidence l'importance de la structure tertiaire du domaine CRD et de la structure quaternaire de la protéine pour la formation et la bonne structuration du granule de Birbeck. Ensuite, l'étude fonctionnelle de cette lectine, notamment par résonance plasmonique de surface, nous a conduit à identifier une nouvelle spécificité de reconnaissance de la Langérine pour les glycosaminoglycanes dans un site d'interaction différent du site canonique. Enfin, nous avons caractérisé une spécificité de reconnaissance du site canonique pour les monosaccharides sulfatés de type glucosamine en utilisant la résonance plasmonique de surface et la cristallographie. / Dendritic cells play a crucial role in the immune system. Indeed, these cells are at the interface between innate and acquired immunity by their capacities of recognition, internalisation and pathogen degradation to present antigens to T lymphocytes. The recognition capacity is generated by the expression of diverse receptors onto the cell surface. Among these receptors, two large families allow the recognition of a large panel of different pathogens, as TLRs (“Toll-Like Receptor) and C-type lectins. These receptors are used as markers of different dendritic cells subtypes. For example, and among the C-type lectins, DC-SIGN is mainly expressed onto dermic dendritic cells contrary to langerin, which is highly expressed onto epidermic dendritic cells, called Langerhans cells. These two subtypes of dendritic cells differ in their response of HIV infection. Indeed, the virus recognition by DC-SIGN enables hijacking the dendritic cell to infect T lymphocyte contrary to langerin recognition, in Langerhans cells, which allows the clearance of the virus by its internalisation into Birbeck granules. This organite is specific of Langerhans cells and requires langerin expression. This work is focused on structural and functional characterisation of langerin. It highlights the importance of the CRD tertiary structure and the quaternary structure of the protein for the formation and the structure of Birbeck granules. Then, functional study by surface plasmon resonance enabled us to identify a new binding site of langerin for glycosaminoglycans. Finally, we have characterised a recognition specificity of langerin for sulphated monosaccharide of glucosamine type using surface plasmon resonance and crystallography.
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Lidské glutamátkarboxypeptidasy II a III / Human glutamate carboxypeptidases II and IIINavrátil, Michal January 2016 (has links)
The herein presented Ph.D. dissertation describes kinetic and structural characterization of human glutamate carboxypeptidases II and III (GCPII and GCPIII) using a complete panel of their natural substrates. These enzymes hydrolyze C-terminal glutamate from their substrates. They share 67 % sequence identity and also similar enzymatic activities. This thesis quantitatively compares human GCPII and GCPIII in terms of their ability to hydrolyze the substrates N-acetyl-L-aspartyl-L-glutamate (NAAG), folyl-poly-γ-L-glutamic acids (FolGlun) and β-citryl-L-glutamate (BCG). We demonstrated that GCPIII hydrolyzes its substrates in a metal- dependent manner, that BCG is a specific substrate of GCPIII, and that NAAG and FolGlun are specific substrates of GCPII. We also provide indirect biochemical evidence that GCPIII might feature a heterometallic active-site cluster. Additionally, we characterized the relevance of a surface exosite of GCPII, the arene-binding site (ABS), for the hydrolysis of FolGlun substrates using mutagenesis and enzyme kinetics and showed that polymorphic His475Tyr variant of GCPII hydrolyzes FolGlun substrates with the same kinetic parameters as the wild-type enzyme. Furthermore, this thesis focuses on structural aspects of the substrate specificities of GCPII and GCPIII: we present...
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Komplexy 2,6-bis[(N-methylpiperazin-1-yl)methyl]-4-formyl fenolu / Complexes of 2,6-bis[(N-methylpiperazine-1-yl)methyl]-4-formyl phenolMarečková, Vendula January 2012 (has links)
Thirteen new dinuclear complexes of ligand 2,6-bis[(N-methylpiperazine-1- yl)methyl]-4-formyl phenol (L1) were prepared. Copper(II) and palladium(II) salts were used for the syntheses. Following compounds were prepared: [Cu2L1(CH3COO)2]ClO4, [Cu2L1(CF3COO)2(ClO4)][Cu2L1(CF3COO)2]ClO4, [Pd2L1(CH3COO)3], [Pd2L1(CF3COO)3], [Pd2L1(Cl)4]. These ones should act as anion receptors. The acetates were exchanged for phenylphosphinates in the case of the complex cation [Cu2L1(CH3COO)2]+ and the structure of [Cu2L1(phPO2H)2]ClO4 was obtained. Geometry of coordination shell of Cu2+ - ions in prepared complexes is tetragonal pyramid. The UV-VIS spectroscopy was used for study of interactions in system of the ligand - metal - anion. Interactions between the ligand and metals in oxidation state 2 were observed as well as interactions between the complex [Cu2L1(CH3COO)2]ClO4 and sodium salts.
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