Global ETD Search

221	Barrel opening in the two-partner-secretion transporter FhaC studied via gas-phase molecular dynamics simulations Wei, Chongyao January 2022 (has links) No description available. Biochemistry and Molecular Biology Biokemi och molekylärbiologi Chemical Sciences Kemi
222	Investigating the unknown CdiA-CT-2 toxin used by E. coli D12 to outcompete other bacteria Björnör, Saga January 2024 (has links) No description available. Cell Biology Cellbiologi Biochemistry and Molecular Biology Biokemi och molekylärbiologi Microbiology Mikrobiologi
223	Interaction Studies of Secreted Aspartic Proteases (Saps) from Candida albicans : Application for Drug Discovery Backman, Dan January 2005 (has links) This thesis is focused on enzymatic studies of the secreted aspartic proteases (Saps) from Candida albicans as a tool for discovery of anti-candida drugs. C. albicans causes infections in a number of different locations, which differ widely in the protein substrates available and pH. Since C. albicans needs Saps during virulent growth, these enzymes are good targets for drug development. In order to investigate the catalytic characteristics of Saps and their inhibitor affinities, substrate-based kinetic assays were developed. Due to the low sensitivity of these assays, especially at the sub-optimal pH required to mimic the different locations of infections, these assays were not satisfactory. Therefore, a biosensor assay was developed whereby, it was possible to study interaction between Saps and inhibitors without the need to optimise catalytic efficacy. Furthermore, the biosensor assay allowed determination of affinity, as well as the individual association and dissociation rates for inhibitor interactions. Knowledge about substrate specificity, Sap subsite adaptivity, and the pH dependencies of catalytic efficacy has been accumulated. Also, screening of transition-state analogue inhibitors designed for HIV-1 protease has revealed inhibitors with affinity for Saps. Furthermore, the kinetics and pH dependencies of their interaction with Saps have been investigated. One of these inhibitors, BEA-440, displayed a complex interaction with Saps, indicating a conformational change upon binding and a very slow dissociation rate. A time dependent interaction was further supported by inhibition measurements. The structural information obtained affords possibilities for design of new more potent inhibitors that might ultimately become drugs against candidiasis. The strategy to combine substrate specificity studies with inhibitor screening has led to complementary results that generate a framework for further development of potent inhibitors. Biochemistry SPR Biosensor Secreted aspartic proteases Candida albicans interaction kinetics drug discovery protease inhibitor Biokemi Biochemistry and Molecular Biology Biokemi och molekylärbiologi
224	X-ray characterization of PaPheOH, a bacterial phenylalanine hydroxylase Ekström, Fredrik January 2003 (has links) <p>Many human diseases are associated with the malfunction of enzymes in the aromatic amino acid hydroxylase family, e.g. phenylketonuria (PKU), hyperphenylalaninemia (HPA), schizophrenia and Parkinson's disease. The family of aromatic aminoacid hydroxylases comprises the enzymes phenylalanine hydroxylase (PheOH), tyrosine hydroxylase (TyrOH) and tryptophane hydroxylase (TrpOH). These enzymes require the cofactor (6R)-L-erythro-5,6,7,8-tetrahydrobiopterin (BH4) and atomic oxygen. In eukaryotes, the aromatic amino acid hydroxylases share the same organization with a N-terminal regulatory domain, a central catalytic domain and a C-terminal tetramerization domain. Aromatic amino acid hydroxylases that correspond to the core catalytic domain of the eukaryotic enzymes are found in bacteria. The main focus of this thesis is the structural characterization of a phenylalanine hydroxylase from the bacterium Pseudomonas aeruginosa (PaPheOH). </p><p>To initiate the structural characterization, the active site environment was investigated with X-ray absorption spectroscopy (XAS). The experimental data support a model where the active site iron is coordinated by four oxygen atoms and two nitrogen atoms. We suggest that two water molecules, His121, His126 and Glu166 coordinates the active site iron. In this model, Glu166 provides two of the oxygen atoms in a bidentate binding geometry. EXAFS and XANES studies indicate that structural rearrangements are induced in the second and third coordination shells in samples of PaPheOH with BH4 and/or L-Phe. </p><p>The 1.6 Å X-ray structure of PaPheOH shows a catalytic core that is composed of helices and strands in a bowl-like arrangement. The iron is octahedrally coordinated, by two water molecules and the evolutionary conserved His121, His126 and Glu166 that coordinates the iron with bidentate geometry. The pterin binding loop of PaPheOH (residue 81-86) adopts a conformation that is displaced by 5-6 Å from the expected pterin binding site. Consistent with the unfavourable position of the pterin binding loop is the observation that PaPheOH has a low specific activity compared to the enzymes from human and Chromobacterium violaceum. </p><p>The second part of this thesis focus on the crystallization and structure determination of the actin binding domain of a-actinin (ABD). a-Actinin is located in the Z-disc of skeletal muscle were it crosslinks actin filaments to the filamentous protein titin. The ABD domain of a-actinin crystallizes in space group P21 with four molecules in the asymmetric unit. The structure of the ABD domain has been solved to a d-spacing of 2.0 Å. The two CH-domains of ABD is composed of 5 a-helices each. The a-helices fold into a closed compact conformation with extensive intramolecular contacts between the two domains.</p> Biochemistry PaPheOH PheOH PAH phhA phenylalanine hydroxylase protein crystallography a-actinin microcrystal ABD CH-domain Biokemi Biochemistry Biokemi
225	Protein folding studies of human superoxide dismutase and ALS associated mutants Lindberg, Mikael January 2004 (has links) <p>Proteins are among the most abundant biological macromolecules. The cellular machinery is coupled to exact structural shape and properties of the more than 100 000 different proteins. Still, proteins can sometimes completely change their character and as a result trigger neuro degenerative disease. Exactly what happens is yet poorly understood but misfolding and aggregation leading to toxic gain of function is probable causes, i.e. the protein adopts new noxious properties. In 1993 the protein superoxide dismutase (SOD) was found to be associated with the neuro degenerative disease ALS. Up to date more than 100 mutations in SOD have been associated with ALS. However, the mutations are scattered all over the structure and no common denominator for the disease mechanism has been found. </p><p>This work has been focused on the molecular mechanism of the toxic gain-of - function of mutant SOD from the perspective of protein folding and structural stability. To facilitate the studies of SOD and its ALS associated mutations, an expression system resulting in increased copper content was developed. Coexpression with the copper chaperone for superoxide dismutase (yCCS) leads to increased expression levels, especially for the destabilised ALS mutants. Through thermodynamic studies, I show that with the exception of the most disruptive mutations the holo protein is only marginally destabilised, whereas all mutations show a pronounced destabilisation on the apo protein. Kinetic studies suggest further that the dimeric apoSOD folds via a three-state process where the dimerisation proceeds via a marginally stable monomer. The apoSOD monomer folds by a two-state process. The disulphide bond is not critical for the folding of the apoSOD monomer although it contributes significantly to its stability. Interestingly, in the absence of metals, reduction of the disulphide bond prevents the formation of the dimer. A mutation can affect the protein stability in various ways: either from destabilisation of the monomer (case 1), weakening of the dimer interface (case 2) or, in the worst case, from a combination of both (case 1+2). Thus, therapeutic strategies to prevent the noxious effects of mutant SOD must include both mechanisms. An important finding in this study is that we can see a correlation between the stability for each mutation and the mean survival time. This could be an opening in the development of therapeutic substances that counteract the defect in SOD upon mutation.</p> Biochemistry superoxide dismutase ALS protein folding equilibrium titration protein stability apo protein disulphide bridge chevron plot Biokemi Biochemistry Biokemi
226	Structural Plasticity and Function in Cytochrome <i>cd</i><sub>1</sub> Nitrite Reductase Sjögren, Tove January 2001 (has links) <p>Cytochrome <i>cd</i><sub>1</sub> nitrite reductase is a bifunctional enzyme, which catalyses the one-electron reduction of nitrite to nitric oxide, and the four-electron reduction of oxygen to water. The latter is a cytochrome oxidase reaction. Both reactions occur on the <i>d</i><sub>1</sub> haem iron of the enzyme.</p><p>Time resolved crystallographic studies presented here show that the mechanisms of nitrite and oxygen reduction share common elements. This is of interest from an evolutionary point of view since aerobic respiratory enzymes are thought to have evolved from denitrifying enzymes. Despite of similarities, the results also imply different requirements for the timing of electron transfer to the active site in these reactions.</p><p>Quantum chemical calculations suggest that nitric oxide, the product of nitrite reduction, is not spontaneously released from the haem iron while this is not the case with water. Reduction of the haem while nitric oxide is still bound to it would result in a tight dead-end complex. A mechanism must therefore exist for the selective control of electron transfer during the reaction.</p><p>Structural studies with a product analogue (carbon monoxide) combined with flash photolysis of the complex in solution revealed an unexpected proton uptake by the active site as the neutral CO molecule left the enzyme. This led to the suggestion that the increased positive potential of the active site triggers preferential electron transfer when the active site is empty.</p><p>Crystallisation and structure determination of the reduced enzyme revealed extremely large domain rearrangements. These results offer insights into the role of tethered electron shuttle proteins in complex redox systems, and suggests a mechanism for conformational gating in catalysis.</p> Biochemistry cytochrome cd1 nitrite reductase oxidase redox protein electron transfer proton transfer X-ray crystallography Biokemi Biochemistry Biokemi
227	Viral Control of SR Protein Activity Estmer Nilsson, Camilla January 2001 (has links) <p>Viruses modulate biosynthetic machineries of the host cell for a rapid and efficient virus replication. One important way of modulating protein activity in eukaryotic cells is by reversible phosphorylation. In this thesis we have studied adenovirus and vaccinia virus, two DNA viruses with different replication stategies. Adenovirus replicates and assembles new virions in the nucleus, requiring the host cell transcription and splicing machinieries, whereas vaccinia virus replicates in the cytoplasm, only requiring the cellular translation machinery for its replication. </p><p>Adenovirus uses alternative RNA splicing to produce its proteins. We have shown that adenovirus takes over the cellular splicing machinery by modulating the activity of the essential cellular SR family of splicing factors. Vaccinia virus, that does not use RNA splicing, was shown to completely inactivate SR proteins as splicing regulatory factors. SR proteins are highly phosphorylated, a modification which is important for their activity as regulators of cellular pre-mRNA splicing. We have found that reversible phosphorylation of SR proteins is one mechanism to regulate alternative RNA splicing. We have demonstrated that adenovirus and vaccinia virus induce SR protein dephosphorylation, which inhibit their activity as splicing repressor and splicing activator proteins. We further showed that the adenovirus E4-ORF4 protein, which binds to the cellular protein phosphatase 2A, induced dephosphorylation of a specific SR protein, ASF/SF2, and that this mechanism was important for regulation of adenovirus alternative RNA splicing.</p><p>Inhibition of cellular pre-mRNA splicing results in a block in nuclear- to cytoplasmic transport of cellular mRNAs, ensuring free access of viral mRNAs to the translation machinery. We propose that SR protein dephosphorylation may be a general viral mechanism by which mammalian viruses take control over host cell gene expression.</p> Biochemistry adenovirus ASF/SF2 dephosphorylation E4-ORF4 L1 MLTU PP2A splicing SR proteins vaccinia virus Biokemi Biochemistry Biokemi
228	Tumor Stroma in Anaplastic Thyroid Carcinoma : Interstitial Collagen and Tumor Interstitial Fluid Pressure Lammerts, Ellen January 2001 (has links) <p>Anaplastic thyroid carcinoma (ATC) is an aggressive malignancy in man with stromal fibrosis as one of the main features. Carcinoma cells synthesized no or little collagen I protein. Pro-α1(I) collagen mRNA was expressed by stromal cells throughout the tumor, but expression of procollagen type I protein was restricted to stromal cells situated close to nests of carcinoma cells. These data suggest that the carcinoma cells stimulated collagen type I deposition by increasing pro-α1(1) collagen mRNA translation. </p><p>Cocultures, of the human ATC cell line KAT-4, with fibroblasts under conditions that allow the study of stimulatory factors on collagen mRNA translation, showed that the KAT-4 cells stimulated collagen type I protein synthesis in fibroblasts. Specific inhibitors of PDGF and TGF-β1 and -β3 were able to inhibit this carcinoma cell-induced stimulation of collagen type I synthesis. These findings suggest that tumor cells were able to stimulate collagen mRNA translation in stromal fibroblasts by, at least in part, transferring PDGF and/or TGF-β1 and -β3.</p><p>Xenograft transplantation of different ATC cell lines into athymic mice demonstrated that the low collagen producing carcinoma cell lines were less tumorigenic compared to non-collagen producing carcinoma cell lines. The morphology of tumors derived from non-collagen producing ATC cell lines showed a well demarked stroma surrounding carcinoma cell nests. </p><p>TGF-β1 and -β3 were found to play a role in generating a high tumor interstitial fluid pressure (TIPF) in experimental KAT-4 tumors. A specific inhibitor of TGF-β1 and -β3 was able to lower TIPF and reduce tumor growth after a prolonged period of treatment, suggesting that TGF-β1 and -β3 have a role in maintaining a stroma that support tumor growth.</p> Biochemistry Collagen I synthesis Fibrosis Tumor - stroma interactions PDGF TGF-β Inhibitor Cell cycle Tumor growth Hyaluronan Biokemi Biochemistry Biokemi
229	True Monoliths as Separation Media : Homogeneous Gels for Electrophoresis and Electrochromatography in the Capillary and Microchip Modes Végvári, Ákos January 2002 (has links) <p>The thesis focuses on the development of new homogeneous gels for the separation of drug enantiomers, peptides, DNA and virus by electrophoresis and electrochromatography in capillaries and microchips. This type of separation media offers high resolution and small zone broadening. Compared to particulate beds the resolution in this type of separation media is high because the eddy diffusion is zero and the resistance to mass transfer is small, since the diffusional distance between two polymer chains in the gel is considerably shorter than that between two beads in a packed bed.</p><p>The gels have been characterized in terms of plate heights, plate numbers, resolution, etc. Gels of agarose, polyvinyl alcohol, albumin and polyacrylamide have been employed for electrochromatography or electrophoresis. <i>N,N’</i>-methylene-bisacrylamide, the most widely used crosslinker in polyacrylamide gels, was exchanged for allyl-β-cyclodextrin to get a multi-purpose gel, <i>i.e.,</i> a separation medium the separation properties of which is determined not only by the polyacrylamide chains, but also by β-cyclodextrin with its complexation power.</p><p>A cost-effective, hybrid microdevice has been designed for fast electrophoretic and electrochromatographic analyses as well as for microchromatography. It consists of a fused silica capillary mounted on a supporting plate which integrates most of the compartments necessary for automation and sensitive detection at short UV wavelengths.</p> Biochemistry capillary electrophoresis capillary electrochromatography gel electrophoresis agarose polyacrylamide b-cyclodextrin DNA peptide glutathione drug enantiomers microchip Biokemi Biochemistry Biokemi
230	Role of the 3'UTR in translation and stability of HCV and HPV mRNAs Wiklund, Lisa January 2002 (has links) <p>Virus mRNAs can be divided into functional regions. The focus of this thesis will be to investigate the function of one of these regions, the 3’ untranslated region (UTR). The 3’UTR of HCV contains a U-rich element and the late 3’UTR of HPV-1 contains an AU-rich element. The roles of these regions in translation and stability of HCV and HPV have been studied. </p><p>A method was established for studying translation of HCV mRNA in living cells. Noninfectious minivirus clones were synthesised <i>in vitro </i>and were transfected into cells by electroporation. This made it possible to bypass the nucleus and to transfer RNA directly into the cell cytoplasm. We found that HCV mRNAs that are translated from the HCV internal ribosome entry site (IRES) are inefficiently translated in comparison to capped and polyadenylated cellular mRNAs. Interestingly, the addition of a cap and a poly(A) tail resulted in a tremendous increase in the initiation of translation at the HCV IRES. This was the result of a discontinuous scanning or shunting mechanism. We also found that the 3’UTR had a small but not significant effect on the virus mRNA translation. Next, we set up an <i>in vitro </i>stability assay to investigate if HCV 3’UTR affects the stability of the virus mRNA. We found that the HCV 3’UTR is very unstable but interaction with the cellular La protein protects the mRNA from premature degradation.</p><p>In parallel experiments, we studied translation and stability of the HPV-1 late mRNAs. By studying an AU-rich sequence in the 3’UTR, we mapped two minimal inhibitory sequence elements, UAUUUAU and UAUUUUUAU that reduced mRNA half-life. We found that the same motifs in the AU-rich element inhibit mRNA translation, demonstrating that the AU-rich element acts via a bimodal mechanism to reduce mRNA stability and inhibit translation.</p> Biochemistry Hepatitis C virus Human Papillomavirus 3’ untranslated region AU-rich sequence mRNA stability translation Biokemi Biochemistry Biokemi

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