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A Novel Route for Construction of Multipurpose Receptors through Chemical Modification of Glutathione TransferasesViljanen, Johan January 2008 (has links)
This thesis describes how the human Alpha class glutathione transferase (GST) A1-1 can be reprogrammed either to function as a multipurpose biosensor for detection of small molecule analytes, or as a handle providing for more efficient protein purification. A novel, user-friendly, and efficient method for site-specific introduction of functional groups into the active site of hGST A1-1 is the platform for these achievements. The designed thioester reagents are glutathione-based and they are able to label one single nucleophile (Y9) and leave the other 50 nucleophiles (in hGST A1-1) intact. The modification reaction was tested with five classes of GSTs (Alpha, Mu, Pi, Theta and Omega) and was found to be specific for the Alpha class isoenzymes. The reaction was further refined to target a single lysine residue, K216 in the hGST A1-1 mutant A216K, providing a stable amide bond between the protein and the labeling group. To further improve the labeling process, biotinylated reagents that could deliver the acyl group to Y9 (wt hGST A1-1) or K216 in the lysine mutant, while attached to streptavidin-coated agarose beads, were designed and synthesized. A focused library of eleven A216K/M208X mutants was made via random mutagenesis to provide an array of proteins with altered micro-environments in the hydrophobic binding site, where M208 is situated. Through the invented route for site-specific labeling, a fluorescent probe (coumarin) was introduced on K216 in all double mutants, with the purpose of developing a protein-based biosensor, akin to the olfactory system. The array of coumarin-labeled proteins responded differently to the addition of different analytes, and the responses were analyzed through pattern recognition of the fluorescence signals. The labeled proteins could also be site-specifically immobilized on a PEG-based biosensor chip via the single C112 on the surface of the protein, enabling development of surface-based biosensing systems. Also, a refined system for efficient detection and purification of GST-fusion proteins is presented. Through a screening process involving A216K and all produced A216K/M208X mutants, two candidates (A216K and A216K/M208F) were singled out as scaffolds for the next generation of fusion proteins. In addition to the features present in commercially available GST fusion constructs, the new mutants can be site-specifically labeled with a fluorophore in bacterial lysates providing quick and sensitive monitoring of expression and purification. Furthermore, the proteins could be labeled with a unique aldehyde moiety providing for a novel protein purification scheme.
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Multidrug transporter MdfA as a target for high-resolution structural studiesO'Grady, Christopher Brian 28 January 2010
The MdfA is a 410 amino acid-long integral membrane protein, which belongs to the Major Facilitator superfamily of multidrug transporters. It is predicted to consist of 12 transmembrane helices. MdfA uses the energy of the transmembrane proton gradient to pump a variety of toxic compounds out of E. coli cells. No high resolution structure of MdfA is available. The goals of this research project were to develop a practical method for purification of MdfA, to evaluate the feasibility of structure determination by Nuclear Magnetic Resonance (NMR) and X-ray crystallography, and to develop an activity assay for purified MdfA. To this end, MdfA, with a hexa-histidine tag attached to facilitate protein purification, was successfully expressed and incorporated into the cell membrane using an E. coli expression system. MdfA was extracted from the cell membrane with the detergents 1,2-diheptanoyl-sn-glycero-3-phosphocholine (DHPC), n-dodecyl-B-D-maltoside (DDM), and 1-myristoyl-2-hydroxy-sn-glycero-3-[phospho-rac-(1-glycerol)] (LMPG) and purified by affinity chromatography on nickel-nitrilotriacetic acid agarose. Pure protein was found to be monodisperse in DHPC, DDM and LMPG micelles. To achieve simple amino acid selective isotope labeling for high-resolution NMR studies, MdfA was expressed in a cell-free translation system. To determine if the purified protein was properly folded, 19F NMR experiments were carried out on 5-fluoro-tryptophan-labeled MdfA while titrating the MdfA substrates ethidium bromide and chloramphenicol into the fluoro-tryptophan-labeled MdfA sample. An activity assay was developed for MdfA incorporated into liposomes using the fluorescent dye 9-amino-6-chloro-2-methoxyacridine (ACMA) to detect proton translocation coupled to substrate transport. Results from both the 19F NMR and the transport activity assay indicated that the purified MdfA was properly folded and functional. NMR experiments with pure MdfA yielded spectra of insufficient quality for high-resolution structure determination but did indicate that structural studies of MdfA by NMR are feasible. Crystallization trials yielded crystals that are likely to contain protein and will serve as a starting point for further optimization of crystallization conditions for X-ray structure determination.
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In vitro and In vivo High-throughput Analysis of Protein:DNA InteractionsShahravan, Seyed Hesam 06 December 2012 (has links)
In this thesis, emphasis has been placed on development of new approaches for high-throughput analysis of protein:DNA interactions in vitro and in vivo. In vitro strategies for detection of protein:DNA interaction require isolation of active and soluble protein. However, current methodologies for purification of proteins often fail to provide high yield of pure and tag-free protein mainly because enzymatic cleavage reactions for tag removal do not exhibit stringent sequence specificity. Solving this problem is an important step towards high-throughput in vitro analysis of protein:DNA interactions. As a result, parts of this thesis are devoted to developing new approaches to enhance the specificity of a proteolysis reaction. The first approach was through manipulation of experimental conditions to maximize the yield of the desired protein products from enterokinase proteolysis reactions of two His-tagged proteins. Because it was suspected that accessibility of the EK site was impeded, that is, a structural problem due to multimerization of proteins, focus was based on use of denaturants as a way to open the structure, thereby essentially increasing the stoichiometry of the canonical recognition site over noncanonical, adventitious sites. Promoting accessibility of the canonical EK target site can increase proteolytic specificity and cleavage yield, and general strategies promoting a more open structure should be useful for preparation of proteins requiring endoprotease treatment. One such strategy for efficient EK proteolysis is proposed: by heterodimerizing with a separate leucine zipper, the bZIP basic region and amino-terminus can become more open and potentially more accessible to enterokinase.
In vivo strategies have the advantage over their in vitro counterparts of providing a native-like environment for assessing protein:DNA interactions, yet the most frequently used techniques often suffer from high false-positive and false-negative rates. In this thesis, a new bioprobe system for high-throughput detection of protein:DNA interactions in vivo is presented. This system offers higher levels of accuracy and sensitivity as well as accessibility and ease of manipulation in comparison with existing technologies.
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In vitro and In vivo High-throughput Analysis of Protein:DNA InteractionsShahravan, Seyed Hesam 06 December 2012 (has links)
In this thesis, emphasis has been placed on development of new approaches for high-throughput analysis of protein:DNA interactions in vitro and in vivo. In vitro strategies for detection of protein:DNA interaction require isolation of active and soluble protein. However, current methodologies for purification of proteins often fail to provide high yield of pure and tag-free protein mainly because enzymatic cleavage reactions for tag removal do not exhibit stringent sequence specificity. Solving this problem is an important step towards high-throughput in vitro analysis of protein:DNA interactions. As a result, parts of this thesis are devoted to developing new approaches to enhance the specificity of a proteolysis reaction. The first approach was through manipulation of experimental conditions to maximize the yield of the desired protein products from enterokinase proteolysis reactions of two His-tagged proteins. Because it was suspected that accessibility of the EK site was impeded, that is, a structural problem due to multimerization of proteins, focus was based on use of denaturants as a way to open the structure, thereby essentially increasing the stoichiometry of the canonical recognition site over noncanonical, adventitious sites. Promoting accessibility of the canonical EK target site can increase proteolytic specificity and cleavage yield, and general strategies promoting a more open structure should be useful for preparation of proteins requiring endoprotease treatment. One such strategy for efficient EK proteolysis is proposed: by heterodimerizing with a separate leucine zipper, the bZIP basic region and amino-terminus can become more open and potentially more accessible to enterokinase.
In vivo strategies have the advantage over their in vitro counterparts of providing a native-like environment for assessing protein:DNA interactions, yet the most frequently used techniques often suffer from high false-positive and false-negative rates. In this thesis, a new bioprobe system for high-throughput detection of protein:DNA interactions in vivo is presented. This system offers higher levels of accuracy and sensitivity as well as accessibility and ease of manipulation in comparison with existing technologies.
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Multidrug transporter MdfA as a target for high-resolution structural studiesO'Grady, Christopher Brian 28 January 2010 (has links)
The MdfA is a 410 amino acid-long integral membrane protein, which belongs to the Major Facilitator superfamily of multidrug transporters. It is predicted to consist of 12 transmembrane helices. MdfA uses the energy of the transmembrane proton gradient to pump a variety of toxic compounds out of E. coli cells. No high resolution structure of MdfA is available. The goals of this research project were to develop a practical method for purification of MdfA, to evaluate the feasibility of structure determination by Nuclear Magnetic Resonance (NMR) and X-ray crystallography, and to develop an activity assay for purified MdfA. To this end, MdfA, with a hexa-histidine tag attached to facilitate protein purification, was successfully expressed and incorporated into the cell membrane using an E. coli expression system. MdfA was extracted from the cell membrane with the detergents 1,2-diheptanoyl-sn-glycero-3-phosphocholine (DHPC), n-dodecyl-B-D-maltoside (DDM), and 1-myristoyl-2-hydroxy-sn-glycero-3-[phospho-rac-(1-glycerol)] (LMPG) and purified by affinity chromatography on nickel-nitrilotriacetic acid agarose. Pure protein was found to be monodisperse in DHPC, DDM and LMPG micelles. To achieve simple amino acid selective isotope labeling for high-resolution NMR studies, MdfA was expressed in a cell-free translation system. To determine if the purified protein was properly folded, 19F NMR experiments were carried out on 5-fluoro-tryptophan-labeled MdfA while titrating the MdfA substrates ethidium bromide and chloramphenicol into the fluoro-tryptophan-labeled MdfA sample. An activity assay was developed for MdfA incorporated into liposomes using the fluorescent dye 9-amino-6-chloro-2-methoxyacridine (ACMA) to detect proton translocation coupled to substrate transport. Results from both the 19F NMR and the transport activity assay indicated that the purified MdfA was properly folded and functional. NMR experiments with pure MdfA yielded spectra of insufficient quality for high-resolution structure determination but did indicate that structural studies of MdfA by NMR are feasible. Crystallization trials yielded crystals that are likely to contain protein and will serve as a starting point for further optimization of crystallization conditions for X-ray structure determination.
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Mutagenesis of the sugar donor site of the Arabidopsis thaliana glycosyltransferase UGT72B1Palmqvist, Emma January 2010 (has links)
The Arabidopsis thaliana glycosyltransferase UGT72B1 is one of many enzymes which catalyze the reaction oflinking a glucose moiety from UDP-glucose to an acceptor molecule, in this case a chloroaniline or a chlorophenol. This is part of a detoxification system of the plant cell, similar to that in humans where a glucuronosyltransferases are enabling drug metabolism. It would be of interest to investigate the activity of the human enzyme towards different pharmaceuticals and determine the effect the linkage of glucose has to properties of the compounds. However, the human enzymes are membrane proteins and thus difficult to purify and crystallize. Here, an attempt was made to instead change the substrate specificity of UGT72B1 from UDPglucose to UDP-glucuronic acid. Combination of the four point mutations G18S, P139R, W367S and AG387ED were introduced in UGT72B1. However, no UDP-glucuronic acid activity was obtained. Single mutants W367S and AG387ED retained similar activity as of the wildtype while P139R had highly reduced activity and G18S was not expressed at all. All other combinations of mutations resulted in even less activity. Four chimeric proteins were also constructed. They were combinations of the UGT72B1 and the human enzyme UGT2B4. These were all soluble proteins but no activity could be determined. / Glykosyltransferaset UGT72B1 från Arabidopsis thaliana är ett av många enzymer som katalyserar reaktionen där en glukosenhet från UDP-glukos länkas till en acceptormolekyl, i det här fallet en kloranilin eller en klorfenol. Det är en del av ett detoxifieringssytem i växtcellen, som liknar det i människan, där ett glukuronosyltransferas möjliggör nedbrytning av bl.a. läkemedel. Det vore intressant att kunna undersöka de humana enzymernas aktivitet mot olika läkemedel och även fastställa effekten glukoslänkningen har på dessa substansers egenskaper. De humana enzymerna är dock membranprotein och är därför svåra att rena fram och att kristallisera. Här har istället ett försök gjorts för att ändra substratspecificiteten hos UGT72B1 från UDP-glukos till UDP-glukuronsyra. Kombinationer av de fyra punktmutationerna G18S, P139R, W367S och AG387ED introducerades i UGT72B1. Ingen aktivitet med UDP-glukuronsyra erhölls dock. Enkelmutanterna W367S och AG387ED bibehöll liknande aktivitet som vildtypen, medan P139R hade starkt reducerad aktivitet och G18S uttrycktes inte alls. Alla andra kombinationer av mutationer resulterade i ännu lägre aktivitet. Fyra chimeriska proteiner konstruerades också. De skapades genom kombination av UGT72B1 och det humana enzymet UGT2B4. Dessa var alla lösliga proteiner men ingen av dem uppvisade någon aktivitet.
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Spezifität der Wechselwirkung von Collybistin 2 mit Phosphatidylinositolphosphaten: Einfluss der verschiedenen Proteindomänen / Specificity of collybistin interaction with phosphoinositides: Impact of the individual protein domainsLudolphs, Michaela 27 April 2015 (has links)
No description available.
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Co-purification of Nuclear Receptor Ligand(s) and Interacting Proteins from Zebrafish EmbryosShih, Norrapat 17 March 2014 (has links)
The main focus of this project was to optimize a protocol for small molecule ligand co-purification from an in-vivo tissue source. For this purpose, I employed a transgenic zebrafish line called the pLT-gypsy, which expresses a fusion protein containing a tagged-NR LBD (Tiefenbach et al., 2010). The particular line I used to optimize the ligand identification protocol is the pLT-PPARγ zebrafish line, which expresses the tagged-PPARγ receptor's LBD (also called PPARγ-fusion protein). By using rosiglitazone (a known PPARγ ligand) as a positive control, I managed to optimize a protocol to purify the PPARγ-fusion protein and identify the co-purified ligand by mass spectrometry. This protocol can be used to identify the physiological/endogenous ligand for the PPARγ receptor as well as other orphan NRs. Compared to previous methods of ligand identification, this method allows for the identification of the ligand from the tissues where it is functional.
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Co-purification of Nuclear Receptor Ligand(s) and Interacting Proteins from Zebrafish EmbryosShih, Norrapat 17 March 2014 (has links)
The main focus of this project was to optimize a protocol for small molecule ligand co-purification from an in-vivo tissue source. For this purpose, I employed a transgenic zebrafish line called the pLT-gypsy, which expresses a fusion protein containing a tagged-NR LBD (Tiefenbach et al., 2010). The particular line I used to optimize the ligand identification protocol is the pLT-PPARγ zebrafish line, which expresses the tagged-PPARγ receptor's LBD (also called PPARγ-fusion protein). By using rosiglitazone (a known PPARγ ligand) as a positive control, I managed to optimize a protocol to purify the PPARγ-fusion protein and identify the co-purified ligand by mass spectrometry. This protocol can be used to identify the physiological/endogenous ligand for the PPARγ receptor as well as other orphan NRs. Compared to previous methods of ligand identification, this method allows for the identification of the ligand from the tissues where it is functional.
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Extraction, purification et caractérisation d’isoformes d’hexokinase du tubercule de pomme de terre (Solanum tuberosum)Moisan, Marie-Claude 12 1900 (has links)
L’hexokinase (HK) est la première enzyme du métabolisme des hexoses et catalyse la
réaction qui permet aux hexoses d’entrer dans le pool des hexoses phosphates et donc par le
fait même la glycolyse. Bien que le glucose soit son principal substrat, cette enzyme peut
aussi phosphoryler le mannose et le fructose. Malgré son importance dans le métabolisme
primaire, l’HK n’a jamais été purifiée à homogénéité sous forme native. Le but de ce travail
était donc de purifier une isoforme d’HK à partir de tubercule de Solanum tuberosum et par
la suite de caractériser ses propriétés cinétiques.
Bien avant que je commence mon travail, un groupe de recherche avait déjà séparé et
partiellement purifié trois isoformes d’HK de S. tuberosum. Un protocole d’extraction était
donc disponible, mais l’HK ainsi extraite était peu stable d’où le besoin d’y apporter
certaines modifications. En y ajoutant certains inhibiteurs de protéases ainsi qu’en
modifiant les concentrations de certains éléments, le tampon d’extraction ainsi modifié a
permis d’obtenir un extrait dont l’activité HK était stable pendant au moins 72h après
l’extraction, en empêchant la dégradation.
À l’aide du tampon d’extraction optimisé et d’une chromatographie sur colonne de butyl
sépharose, il a été possible de séparer 4 isoformes d’HKs. Par la suite, une isoforme d’HK
(HK1) a été purifiée à l’homogénéité à l’aide de 5 étapes de chromatographie
supplémentaires. En plus de caractériser les propriétés cinétiques de cette enzyme, l’analyse
de séquençage par MS/MS a permis de l’associer au produit du gène StHK1 de Solanum
tuberosum. Avec une activité spécifique de 10.2 U/mg de protéine, il s’agit de l’HK
purifiée avec l’activité spécifique la plus élevée jamais rapportée d’un tissu végétal.L’ensemble des informations recueillies lors de la purification de HK1 a ensuite été utilisée
pour commencer la purification d’une deuxième isoforme (HK3). Ce travail a permis de
donner des lignes directrices pour la purification de cette isoforme et certains résultats
préliminaires sur sa caractérisation enzymatique. / Hexokinase (HK) catalyzes the first step of hexose metabolism by phosphorylating hexose
to generate the corresponding hexose phosphate thereby allowing hexose entrance in
glycolysis. Even though glucose is the main substrate, HK can also phosphorylate a broad
spectrum of hexoses. Despite its importance this enzyme has never been purified to
homogeneity in a native form. The aim of this work was therefore to purify this enzyme
from Solanum tuberosum tubers and subsequently characterize its kinetic properties.
Before I started this work, another group had already separated and partially purified 3 HK
isoform from S. tuberosum. An extraction protocol was available but improvement was
necessary since the extracted HK had little stability. By adding some protease inhibitors
and by modifying the concentration of certain components in the extraction buffer we were
able to obtain an extract with a HK activity stable for at least 72 h after extraction by
preventing degradation.
With this buffer and chromatography on butyl sepharose it was possible to separate 4 HK
isoforms from S. tuberosum. After 5 more chromatographic steps, one HK isoform was
purified to homogeneity (HK1). This enzyme was characterized and sequenced by MS/MS.
We were able to associate this protein sequence with the gene product of StHK1 from S.
tuberosum. With a specific activity of 10.2 U/mg of protein, this is the HK with the highest
specific activity ever reported from a plant tissue.
All the information gathered while purifying HK1 was used to undertake the purification of
a second isoform (HK3). We were able to obtain preliminary results on its kinetic
properties.
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