Global ETD Search

11	Structural Studies on PP2A and Methods in Protein Production Magnúsdóttir, Auður January 2008 (has links) PP2A is a major phosphatase in the cell that participates in multiple cell signaling pathways. It is a heterotrimer of a core dimer and variable regulatory subunits. Details of its structure, function and regulation are slowly emerging. Here, the structure of two regulators of PP2A are de-scribed; PTPA and B56γ. PTPA is a highly conserved enzyme that plays a crucial role in PP2A activity but whose biochemical function is still unclear. B56γ is a PP2A regulatory subunit linked to cancer and the structure presented here of B56γ in its free form is particularly valuable in light of the recent structures of the PP2A holoenzyme and core dimer. Protein production is a major bottleneck in structural genomic projects. Here, we describe two novel methods for improved protein production. The first is a colony based screening method where any DNA library can be screened for soluble expression of recombinant proteins in E.coli. The second method involves improvements of the well established IMAC purification method. We have seen that a low molecular weight component of E.coli lysate decreases the binding capacity of IMAC columns and by removing the low molecular weight components, recombinant proteins only present at low levels in E.coli lysate can be purified, which has previously been believed to be unfeasible. PP2A PTPA B56γ Protein Production Structural biology Strukturbiologi
12	Structural studies of three cell signaling proteins : crystal structures of EphB1, PTPA, and YegS Bakali, Amin January 2007 (has links) Kinases and phosphatases are key regulatory proteins in the cell. The disruption of their activities leads ultimately to the abolishment of the homeostasis of the cell, and is frequently correlated with cancer. EphB1 is a member of the largest family of receptor tyrosine kinases. It is associated with neurogenesis, angiogenesis, and cancer. The cytosolic part of the human EphB1 receptor is composed of two domains. Successful generation of soluble constructs, using a novel random construct screening approach, led to the structure determination of the kinase domain of this receptor. The native structure and the complex structure with an ATP analogue revealed novel features in the regulation of the Eph family of kinases. The structure of PTPA, an activator of protein phosphatase 2 A, a tumor suppressor and a key phosphatase in the cell was solved. The structure revealed a novel fold containing a conserved cleft predicted to be involved in interaction with PP2A. Finally, the structure of YegS, an Escherichia coli protein annotated as a putative diacylglycerol kinase, has been determined. Beside the elucidation of its atomic structure, a phosphatidylglycerol (PG) kinase activity, never seen before, has been assigned to YegS based on biochemical studies. The YegS structure shows resemblance to the fold previously seen in NAD kinases. The structure also revealed the existence of a novel metal site that could potentially play a regulatory role. The YegS structure has important implications for understanding related proteins in pathogenic organisms and is the first homologue of a human lipid kinase for which the structure has been elucidated. protein production structural genomics cell signaling Biochemistry Biokemi
13	Polyhedrin gene expression on protein production and polyhedra Shang, Hui 26 July 2018 (has links) No description available. Microbiology baculovirus polyhedrin protein production BEVS polyhedra virion occlusion AcMNPV
14	Impact of glucose feed rate on productivity and recombinant protein quality in Escherichia coli Sandén, Anna Maria January 2005 (has links) <p>The goal of this work was to contribute to the fed-batch process optimisation task by deriving parameters that have considerable impact on productivity as well as product quality The chosen parameters were I) the design of the glucose feed profile, II) the choice of induction strategy, with respect to the method of addition, and III) the time of the induction, with respect to the specific glucose consumption rate. </p><p>The present fed-batch experiments using the lacUV5-promoter, for production of b-galactosidase, have shown that a high glucose feed rate gives a specific production rate, q<sub>p</sub>, that is twice as high, after induction, compared to a feed rate that is 2.5 times lower. The constant accumulation of lacZ-mRNA indicates that the translational capacity is initially limiting the synthesis machinery, but after four hours of maximum specific production and a corresponding drop in lacZ-mRNA production, the cultivation is likely to be transcription limited. The high feed-rate system resulted in high accumulation of β-galactosidase, corresponding to 40% of total cellular proteins.</p><p>By design of feed profiles in a fed-batch process the detrimental effects of overflow metabolism, giving acetic acid formation, can be avoided. However, the results show that a one-dose addition of isopropyl-β-D-galactopyranoside (IPTG), provokes a non-growth associated production of acetic acid. This response can be alleviated by; lowering the inducer concentration (in this case to below 165 μM), by further reducing the feed rate of glucose or by using alternative induction methods. The use of a stepwise addition or a feed of IPTG thus delayed and reduced the level of acetic acid accumulation. It was also shown that a small change in the time-point of induction lead to large variability, regarding both productivity and acetic acid accumulation, in a fed-batch cultivation, </p><p>In order to further investigate the protein quality two additional proteins were studied in fed-batch cultivations using high and low glucose feed. The aim was to prove the hypothesis that the feed related change in the rate of synthesis of the nascent polypeptide controls the product quality. For the two proteins: Zb-MalE (wt) and Zb-MalE31 (mutant), the transcription rate, in terms of amount of IPTG, and translation rate, in terms of changes in feed rate, influences the percentage of inclusion body formation and degradation of nascent polypeptide. The data show a higher rate of inclusion body formation for the model protein Zb-MalE31 during high feed rate cultivations, as well as at high levels of inducer. Furthermore, the rate of proteolysis was significantly higher for a high feed rate. The high feed rate thus results in a higher rate of synthesis but a lower corresponding quality, for the model proteins studied.</p><p>In the present investigation of fed-batch cultivations using several different expression vectors, it was found that the central alarmone guanosine tetraphosphate (ppGpp) was formed at both high and low feed rates upon induction. It could be shown, however, that by secretion of Zb-MalE to the periplasm, the stringent response could be avoided. This might be due to the decreased burden on the host where the secretion of product further seems to make the cell able to redirect the carbon flux from overflow metabolism, since no acetic acid was produced. The secretion also demonstrates that the growth arrest could be aborted, which is otherwise gained in the P<sub>malK </sub>production system.</p><p>A novel fed-batch process based on the promoters for the universal stress proteins A and B (P<sub>uspA</sub>, P<sub>uspB</sub>) was designed to make use of these powerful promoters in an industrial production context. It was concluded that the process had to start from a high specific growth rate and induction was performed once a limiting feed started. This was done to purposely induce the stringent response and/or acetic acid accumulation since this was required for induction. In the suggested system, induction has to be performed and maintained at continuous substrate feeding, whilst avoiding exceeding the cellular capacity, since the stationary phase starvation alone did not lead to production. In conclusion, a new stress induction based production system was achieved resulting in high accumulations of product protein without any detected metabolic side effects.</p> Biochemistry Escherichia coli recombinant protein production fed-batch feed profile specific growth rate Biokemi Biochemistry Biokemi
15	From protein production to genome evolution in Escherichia coli Schlegel, Susan January 2013 (has links) The aim of my Ph.D. studies was to improve production yields of membrane- and secretory proteins in the widely used E. coli protein production strain BL21(DE3). In this strain expression of the gene encoding the protein of interest is driven by the powerful T7 RNA polymerase (T7 RNAP) whose gene is located on the chromosome and under control of the strong, IPTG-inducible lacUV5 promoter. Unfortunately, the production of many membrane and secretory proteins is 'toxic' to BL21(DE3), resulting in poor growth and low production yields. To understand this ‘toxicity’, the BL21(DE3) derived mutant strains C41(DE3) and C43(DE3) were characterized. Somehow, these strains can efficiently produce many ‘toxic’ membrane and secretory proteins. We showed that mutations weakening the lacUV5 promoter are responsible for this. These mutations result in a slower onset of protein production upon the addition of IPTG, which avoids saturating the Sec-translocon capacity. The Sec-translocon is a protein-conducting channel in the cytoplasmic membrane mediating the biogenesis of membrane proteins and translocation of secretory proteins. Next, we constructed a BL21(DE3)-derivative, Lemo21(DE3), in which the activity of T7 RNAP can be precisely controlled by titrating in its natural inhibitor T7 lysozyme using the rhamnose promoter system. In Lemo21(DE3), the expression level of genes encoding membrane and secretory proteins can be set such that the Sec-translocon capacity is not saturated. This is key to optimizing membrane and secretory protein production yields. Finally, reconstructing the evolution of C41(DE3) from BL21(DE3) in real time showed that during its isolation C41(DE3) had acquired mutations critical for surviving the starvation conditions used, and provided insight in how the mutations in the lacUV5 promoter had occurred. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 3: Manuscript.</p> Escherichia coli BL21(DE3) protein production membrane proteins secretory proteins genome evolution
16	Optimisation de la production et de la purification du canal hERG en vue d’une caractérisation biophysique et structurale / hERG channel optimisation of production and purification for biophysical and structural studies Vasseur, Lucie 27 November 2017 (has links) La protéine humaine hERG (human ether-à-go-go related gene) s’associe en homo-tétramère pour former le canal potassique voltage-dépendant Kv11.1. C’est un acteur majeur de la repolarisation du potentiel d’action cardiaque par sa capacité à externaliser le potassium du cardiomyocyte. L’altération de sa fonction induit le syndrome du QT long à l’origine d’arythmies cardiaques et pouvant conduire à un arrêt du cœur. Ce syndrome parfois génétique provient le plus souvent d’une inhibition pharmacologique. De nombreux médicaments ont montré leur capacité à inhiber hERG en se fixant dans la lumière du canal. L’étude des interactions moléculaires entre hERG et médicaments intéresse les scientifiques depuis de nombreuses années. Très récemment, la première structure atomique de hERG à l’état ouvert par cryo-microscopie électronique a permis une avancée majeure dans la compréhension de l’agencement du pore du canal. De nombreuses questions restent malgré tout non résolues concernant les mécanismes de liaison des ligands. Plus encore, le développement d’approches biophysiques à partir de canal purifié permettraient de caractériser et d’anticiper des interactions avec les médicaments. Dans cette perspective, nous avons testé plusieurs stratégies pour obtenir le canal hERG purifié dans une forme stable, homogène et fonctionnelle. Notre étude est basée sur une construction simplifiée et chimérique du canal hERG, la version hERG(S1-coil). Chaque étape permettant la production et la purification d’une protéine membranaire a été optimisée en testant différentes techniques proposées par la littérature. Nous avons comparé les rendements d’expression du canal dans différents systèmes recombinants procaryotes ou eucaryotes. La quantité de protéine totale et le pourcentage de protéine fonctionnelle dans les membranes ont été étudiés. Dans un deuxième temps, le canal a été solubilisé puis purifié. Nous avons comparé les rendements de solubilisation et la stabilité protéique en fonction du type de détergent. En parallèle, nous avons mis au point des moyens techniques pour évaluer la fonction du canal au fur et à mesure du processus de production et purification. Le canal hERG(S1-coil) tétramérique et fonctionnel a finalement été identifié dans la fraction purifiée. Cependant, des optimisations sont encore à apporter pour conserver l’agencement tétramérique et empêcher l’agrégation au cours du temps avant de pouvoir envisager des études biophysiques et structurales. A terme, ces travaux pourraient profiter à la production et à la purification d’autres protéines membranaires oligomériques. / The human protein hERG (human ether-à-go-go related gene) assembles as homo-tetramer to form the voltage-gated potassium channel Kv11.1. This channel is involved in repolarization of the cardiac action potential by regulating the potassium release from cardiomyocytes. hERG malfunction was found to cause long QT syndrome, a disorder that predisposes affected patients to arrhythmias and sudden death. This can be due to congenital mutation in the hERG gene and, most frequently, it is caused by pharmacological agents. Several drugs are known to block the channel ion pathway, resulting in off-target inhibition of hERG. Consequently, understanding the molecular basis of drug binding to hERG has become a high priority. The recent determination of a near-atomic resolution structure of the opened channel, using cryo-electron microscopy, provides insights into how this channel work. But several questions are still unanswered to understand the mechanisms of hERG function and drug binding. Moreover, new biophysical protocols with the purified hERG channel would help scientists and industries to anticipate drug side effects. In this context, we investigated strategies to purify a stable, homogenous and functional hERG channel. Our study was based on a shorter and chimeric hERG channel, the hERG(S1-coil) version. We optimized each step from production to purification of membrane proteins by testing experimental protocols found in the literature. In this thesis project, we first compared production rates of the channel in several prokaryote and eukaryotes recombinant systems. Total protein produced and the percent of functional channel were investigated in membranes from each recombinant system. Then, the channel was extracted from membranes before purification. Solubilizing rates and channel stability were compared depending on detergents. In another hand, we also developed protocols to investigate the channel stability and function along production and purification. A tetrameric and functional channel was finally purified and identified by this strategy. More work however is still needed to improve channel homogeneity and stability before to be suitable for biophysical and structural studies. In the future, this work could also help investigations in production and purification of other oligomeric membrane proteins. Production de protéines Purification Canal potassique Protéine membranaire Protein production Purification Potassium channel Membrane protein
17	NMR and in silico studies of fucosylated chondroitin sulfate (fCS) and its interactions with selectins Brodaczewska, Natalia Anna January 2018 (has links) This thesis describes structural studies on the interactions between the fucosylated chondroitin sulfate (fCS) oligosaccharides and human proteins known as selectins. fCS is a carbohydrate obtained from sea cucumbers, that can be classified as a branched glycosaminoglycan (GAG). It has attracted much attention due to its anti-coagulant, anti-inflammatory, antimetastatic and anti-HIV properties and its structure was previously determined by NMR. Selectins constitute a family of proteins involved in cell adhesion processes, such as inflammation, attachment of viral particles and migration of tumour cells. fCS oligosaccharides have been shown to bind to selectins, which is likely a reason behind their biological activity. However, the mechanism of this interaction is currently unknown. The initial part of the thesis describes the experimental work on expression and purification of the recombinant L- and P-selectin constructs in Pichia pastoris, Escherichia coli and HEK 293 cells. The aim of these experiments was to produce two constructs for each selectin, a single domain construct, consisting of the C-type lectin domain only, and a double domain construct, consisting of both the C-type lectin and the EGF-like domains. The intention was that the recombinant proteins would be labelled with 13C and 15N to allow for the in-depth structural NMR studies on the fCS-selectin interaction. Various experimental approaches have been explored, including the use of different cell lines, modifications to construct design, as well as alterations to expression and purification conditions. Although it was not possible to produce soluble selectin constructs in either bacterial or yeast cells, protein expression tests in HEK293 cells, performed in collaboration with the Oxford Protein Production facility (OPPF), led to production of a soluble L-selectin construct, consisting of the L-selectin C-type lectin domain. The produced L-selectin construct, as well as two commercially available constructs of the Land P-selectin extracellular domains, were used in the Saturation Transfer Difference (STD) NMR experiments to provide new information about the nature of the fCS-selectin binding. The STD experiments allowed to identify the regions within the fCS oligosaccharides that are in direct contact with the protein and likely play an important role in this interaction. Experiments on different protein constructs allowed the comparison of fCS binding to P-selectin and to two different recombinant constructs of L-selectin. Results of these studies suggest that the binding occurs via a similar mechanism for both L- and P-selectins and that the fCS oligosaccharides bind to one-domain L-selectin construct with similar affinity as to a larger construct, consisting of the entire extracellular region of the protein. Alongside the experimental work, theoretical in silico studies on the fCS-selectin binding were undertaken as part of this project. The existing X-ray structures of selectin complexes were subjected to Molecular Dynamics (MD) simulations, which allowed to explore the dynamic behaviour of E-selectin upon binding to sialyl Lewis x (sLex). It was found that sLex forms a more favourable interaction with the extended conformation of E-selectin and that the protein in this conformation is characterised by a high degree of interdomain flexibility, with a new type of interdomain movement observed in the MD studies on this complex. In further in silico studies, the fCS oligosaccharides were docked to the existing P-selectin structures. The docking tests were performed on the computationally produced fCS trisaccharides with fucose branches either 2,4 or 3,4-sulfated. Results were evaluated with MD simulations and analysed in the light of current knowledge of selectin-ligand binding and the STD NMR experimental results. The in silico studies allowed to identify a subset of P-selectin residues that are likely involved in the interaction with fCS oligosaccharides in vivo. The conformational behaviour of P-selectin upon binding to fCS was also explored and it was found that the interdomain hinge is flexible during this interaction and allows transition from bent to extended conformational state. Finally, a new NMR method was developed to facilitate the studies of complex carbohydrates, incorporating the concepts of G-matrix Fourier Transform (GFT) NMR into 2D HSQC and 2D HSQC-TOCSY experiments. The method allows to separate peaks in the regions of high spectral overlap, providing information that can simplify the assignment process. The new experiments facilitated the structural evaluation of a sample containing a mixture of oligosaccharides resulting from the depolymerisation of fCS polysaccharide.
18	Structural studies of human GABA-A receptors Masiulis, Simonas January 2017 (has links) Type-A Î3-amino-butyric acid receptors (GABA<sub>A</sub>Rs) are pentameric ligand-gated ion channels (pLGICs), which mediate the majority of fast inhibitory neurotransmission in the animal central nervous system. Their dysfunction is related to numerous conditions including epilepsy, insomnia, anxiety, panic disorders, depression and schizophrenia. GABA<sub>A</sub>Rs are therefore major targets of clinically important drugs, including benzodiazepines and the intravenous general anaesthetics etomidate and propofol, as well as endogenous modulators, for example neurosteroids. Despite recent progress in structural biology of pLGICs, GABA<sub>A</sub>R structures remain notoriously elusive. Structural information available at the beginning of this project was limited to the benzamidine-bound homopentameric GABA<sub>A</sub>R-Î23, in a desensitised conformation. A large number of fundamental questions, including the molecular architecture of physiological, heteromeric GABA<sub>A</sub>Rs, their signalling mechanisms, the binding and action modes of their numerous ligands, remained to be answered. During this DPhil project, I employed structural biology techniques (X-ray crystallography and single particle cryo-electron microscopy) to further the molecular understanding of human GABAARs. I used subunit-specific llama nanobodies to aid crystallization of homomeric GABA<sub>A</sub>-β3 receptors, which led to a 3.16 Å structure in complex with the general anaesthetic etomidate. This structure elucidates the binding mode of the etomidate, the basis for its subunit selectivity and illustrates conformational changes it triggers. I then used cryo-electron microscopy to determine the first structure of a heteromeric GABA<sub>A</sub>R, the human α1b3g2, bound to an activating llama nanobody at a medium (5.2 Å) resolution. The numerous other insights obtained range from unambiguously establishing the subunit arrangement and stoichiometry, to proposing a mechanism for receptor assembly and discovering an unexpected role played by N-linked glycans in this process. The work described here opens multiple avenues for future research. Immediate opportunities include high resolution structural characterization of heteromeric GABA<sub>A</sub>Rs, via cryo-electron microscopy, further development of nanobodies as novel, high affinity and subunit specific tools to modulate GABA-ergic signalling, and structural characterization of numerous small-molecule modulators, of clinical and physiological relevance, bound to human GABA<sub>A</sub>Rs.
19	Transient viral infection of plant tissue culture and plants for production of virus and foreign protein Shih, Sharon Min-Hsuan , Biotechnology & Biomolecular Sciences, Faculty of Science, UNSW January 2007 (has links) This work was aimed to investigate the basic viral infection protocols mainly focusing on Nicotiana benthamiana hairy root cultures and wild-type tobacco mosaic virus (TMV). The application of transgenic virus containing the gene for green fluorescent protein (GFP) for foreign protein production in plant tissue cultures and whole plants was also studied. The effect on viral accumulation of the form of plant tissue culture used, such as hairy roots, shooty teratomas and suspended cells, was investigated. Viral infection was shown to have no effect on culture growth and morphology. Hairy root cultures are a superior host for viral propagation and production in vitro. The maximum specific rate of viral accumulation occurred mainly during the root growth phase. The average maximum virus concentration in the hairy roots was 0.82 ?? 0.14 mg g-1 dry weight and virus protein represented a maximum of approximately 6% of total soluble protein in the root biomass. Proportional scale-up of TMVinfected hairy roots in shake flasks and bioreactors can be achieved without changing the average virus concentration accumulated in the hairy roots. The level of viral accumulation was much lower in N. benthamiana hairy roots infected with transgenic virus containing GFP (TMVGFPC3) compared with TMV and low levels or no GFP was detected. Viral accumulation and GFP production in whole plants was studied using different generations of transgenic TMV-GFPC3 virus. Hybrid viruses with the foreign gene GFPC3 deleted may have been formed in successive TMV-GFPC3 generations, resulting in the loss of GFP production and enhanced viral infectivity. In vitro generated RNA transcript and first generation TMV-GFPC3 were found to be more suitable for infection than the second generation TMV-GFPC3. However, the accumulation of GFP and virus concentration did not occur at the same ratio. Provided a more genetically stable transgenic viral vector is used for infection, transient viral infection of hairy roots can be a potential alternative system for foreign protein production than plants grown in the field as the containment or safety issues can be addressed. Viral production. Plant tissue culture. Transient viral infection. Foreign protein production. Virus diseases of plants. Proteins -- Synthesis.
20	Protein production, characterization and structure determination in structural genomics Woestenenk, Esmeralda A. January 2004 (has links) This thesis covers the process from expression of a heterologous gene in Escherichia coli to structure determination of a protein by nuclear magnetic resonance (NMR) spectroscopy. The first part concerns structural genomics-related parallel screening studies on the effect of fusion tags (in particular the His tag) on protein solubility and the use of fusion tags in fast, parallel purification protocols intended for initial biophysical characterization of human proteins produced in E. coli. It was found that for most proteins the His tag has a negative influence on protein solubility. This influence appears to be more pronounced for our C-terminal His tag than for the N-terminal His tags used in this study. Moreover, high ratios of soluble per total protein do not always guarantee a high yield of soluble protein after purification, as different vector - target protein combinations result in large differences in host cell growth rates. Protein purification protocols for different fusion tags were developed that make it possible to express, purify and study structural properties of low concentration samples of 15N-labeled proteins in one or two days. The second part of this thesis describes the assignment and solution structure determination of ribosomal protein L18 of Thermus thermophilus. The protein is a mixed α/β structure with two α-helices on one side of a four-stranded β-sheet. Comparison to RNA-bound L18 showed that the protein to a large extent adopts identical structures in free and bound states, with exception of the loop regions and the flexible N-terminus. Keywords: protein production, protein solubility, fusion tags, nuclear magnetic resonance, structure determination, ribosomal protein Biology protein production protein solubility fusion tags nuclear magnetic resonance structure determination Biologi Biology Biologi

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