Global ETD Search

21	ELUCIDATING BINDING, FUSION AND ENTRY OF HUMAN METAPNEUMOVIRUS Klimyte, Edita M. 01 January 2016 (has links) Human metapneumovirus (HMPV) is a respiratory pathogen in the Paramyxoviridae family that infects nearly 100% of the world population. This enveloped RNA virus causes severe viral respiratory disease in infants, the elderly, and immunocompromised patients worldwide. Despite its prevalence and importance to human health, no therapies are available against this pathogen. Entry of paramyxoviruses into host cells generally requires the coordinated activity of the attachment glycoprotein, G, which interacts with a cell receptor, and the fusion glycoprotein, F, which promotes subsequent fusion of viral and cellular membranes. However, HMPV F is the primary viral protein mediating both binding and fusion for HMPV. Previous work that showed HMPV F mediates attachment to heparan sulfate proteoglycans (HSPGs), and some HMPV F fusion activity can be promoted by acidic pH. The work presented here provides significant advances in our understanding of the fusion and binding events during HMPV infection. We demonstrated that low pH promotes fusion in HMPV F proteins from diverse clades, challenging previously reported requirements and identifying a critical residue that enhances low pH promoted fusion. These results support our hypothesis that electrostatic interactions play a key role in HMPV F triggering and further elucidate the complexity of viral fusion proteins. Additionally, we characterized the key features of the binding interaction between HMPV and HSPGs using heparan sulfate mimetics, identifying an important sulfate modification, and demonstrated that these interactions occur at the apical surface of polarized airways tissues. We identified differences in particle binding related to the presence or absence of the HMPV G and SH glycoproteins. Lastly, we characterized paramyxovirus infection in cystic fibrosis bronchial epithelial cells, identifying a potential specific susceptibility to HMPV infection in these individuals. The work presented here contributes to our understanding of HMPV infection, from mechanisms of early events of entry to clinical scenarios. Paramyxovirus Human Metapneumovirus Fusion Protein Membrane Fusion Binding Heparan Sulfate Cystic Fibrosis Other Immunology and Infectious Disease
22	Role of membrane fusion protein Ykt6 in regulating epithelial cell-cell and cell-matrix adhesions. Joshi, Supriya 01 May 2014 (has links) Intercellular junctions and cell-matrix adhesions play important roles in the maintenance of epithelial integrity. Assembly and remodeling of the plasma membrane complexes are regulated by membrane trafficking and fusion. This thesis is aimed to elucidate the roles of an important membrane fusion protein, Ykt6, in the regulation of epithelial cell adhesion and migration. For the first time, we show that Ykt6 is essential for assembly of adherens junctions and tight junctions in human prostate epithelial cells. We also observed that Ykt6 negatively regulates both collective epithelial cell migration and cell invasion into Matrigel. The effects of YKT6 on epithelial junctions involves expressional regulation of key junctional proteins, E-cadherin and claudin-4, whereas its effects on cell motility can be explained by antagonizing functions of junctional adhesion molecule-A. Overall, this study identifies YKT6 as a novel regulator of epithelial cell adhesions and motility. membrane fusion protein Ykt6 Medical Genetics Medical Sciences Medicine and Health Sciences
23	Construction of a Fusion Gene : to anchor a truncated version of the inflammatory receptor NLRP3 to the cell membrane Postigo Peláez, Miguel Ángel January 2019 (has links) Inflammasomes are a group of protein complex that regulate inflammation throughcomplex signal transduction, although their specific mechanisms and structures have notbeen fully described. As the protein that kickstarts assembly of a type of inflammasome,NLRP3 is a key regulator of inflammation and may play a relevant role in the developmentof inflammatory diseases. In this project it has been attempted to perform a Gene Fusionbetween a segment of NLRP3 and regions of Toll-Like Receptor 4 by means of overlapextensionPCR, a technique that employs hybrid primers to create an overlap between bothsequences that can be filled by a polymerase, causing them to merge. Results suggest GeneFusion was successful, however cloning and expression of the construct have not beenachieved so far. If expressed as a fusion protein, the added transmembrane domain willanchor two domains of NLRP3 to the membrane, allowing more precise study of thecomposition and functionality of the inflammasome. Removal of the terminal domain ofNLRP3 will help determine its implication and relevance in the assembly process of theprotein complex. NLRP3 Inflammation Fusion gene PCR Fusion protein Biochemistry and Molecular Biology Biokemi och molekylärbiologi
24	Investigation of the physiological roles of SRSF1-mediated translation Haward, Fiona January 2018 (has links) The serine/arginine-rich (SR-) family proteins constitute a diverse group of pre-mRNA splicing factors that are essential for viability. They can be characterised based on the presence of one or two RRMs and an RS domain. A subset, of which SRSF1 is the prototype, is capable of nucleocytoplasmic shuttling; a process governed by continual cyclic phosphorylation of the RS domain. In contrast, SRSF2, another member of the SR family, is unable to shuttle due to the presence of a nuclear retention sequence (NRS) at the C-terminus of its RS domain. When this NRS is fused to SRSF1, it prevents nucleocytoplasmic shuttling of the SRSF1-NRS fusion protein. In addition to its nuclear roles, SRSF1 is directly associated with the translation machinery and can activate mRNA translation of target transcripts via an mTOR-dependent mechanism. The specific mRNA translational targets that SRSF1 serves to regulate encode numerous factors including RNA processing factors and cell-cycle proteins. The aim of this work is to study the physiological relevance of SRSF1 cytoplasmic functions, as previous data have relied on overexpression systems. CRISPR/Cas9 editing was used to knock-in the NRS naturally present in SRSF2 at the SRSF1 genomic locus, creating an SRSF1-NRS fusion protein. After numerous attempts, it was only possible to obtain a single viable homozygous clone in mouse embryonic stem cells (mESCs), despite being able to successfully tag the genomic SRSF1 locus. This strongly suggests that the ablation of SRSF1 shuttling ability is highly selected against in mESCs. To assess the physiological importance of SRSF1 nucleocytoplasmic shuttling during development, a mouse model for SRSF1-NRS was also developed. SRSF1-NRS homozygous mice are born at correct Mendelian ratios, but are small in size and present with severe hydrocephalus. Finally, proteomics was used to identify interactors of endogenous cytoplasmic SRSF1 and those that bind the NRS of SRSF2 to gain insights into the mechanism of nuclear retention for non-shuttling SR proteins. In summary, this work analyses the physiological relevance of cytoplasmic SRSF1 function and the consequences of the SRSF1-NRS allele in mouse development.
25	Construction of a fusion protein for anchoring the inflammatory receptor NLRP3 to the cell membrane Ling, Rebecca January 2019 (has links) The innate immune system are a cooperation of many components – receptors being one of them. Both membrane-bound and cytosolic receptors play a large role in the defence system against pathogens and danger. NLRP3 is a receptor which assembles a protein complex called inflammasome in response to cytosolic stress and is responsible for many autoimmune diseases if it malfunctions. The activation of the NLRP3 inflammasome leads to secretion of inflammatory cytokines and in many cases to programmed cell death. The structure, function and activation of the NLRP3 inflammasome is still not fully understood and the urge to understand the mechanisms behind are important for future medical improvements. The aim was to anchor the NLRP3 inflammasome by the cell membrane - By Overlap PCR, the NLRP3 cDNA was fused extracellular and trans-membrane parts of the TLR4 cDNA to anchor the NLRP3 to the membrane and in turn analyse the inflammasome with LPI™ technology. Multiple primers and a TLR4 nucleotide were designed and the NLRP3 was amplified with specific overhangs by PCR. The fusion protein was successfully linked together by Overlap PCR but not confirmed by sequencing. The gene fusion demands high quality primers for amplification and further evaluation must be made to the details of the laboratory. To anchor the protein complex to the cell membrane, continue to be of full importance and can be an asset in many structural studies and biopharmaceuticals trials. NLRP3 inflammasome Overlap PCR Fusion Protein LPI™ technology Biochemistry and Molecular Biology Biokemi och molekylärbiologi
26	Recombinant Enzymes in Pyrosequencing Technology Nourizad, Nader January 2004 (has links) Pyrosequencing is a DNA sequencing method based on thedetection of released pyrophosphate (PPi) during DNA synthesis.In a cascade of enzymatic reactions, visible light isgenerated, which is proportional to the number of nucleotidesincorporated into the DNA template. When dNTP(s) areincorporated into the DNA template, inorganic PPi is released.The released PPi is converted to ATP by ATP sulfurylase, whichprovides the energy to luciferase to oxidize luciferin andgenerate light. The excess of dNTP(s) and the ATP produced areremoved by the nucleotide degrading enzyme apyrase. The commercially available enzymes, isolated from nativesources, show batch-tobatch variations in activity and quality,which decrease the efficiency of the Pyrosequencing reaction.Therefore, the aim of the research presented in this thesis wasto develop methods to recombinantly produce the enzymes used inthe Pyrosequencing method. Production of the nucleotidedegrading enzyme apyrase by Pichia pastoris expression system,both in small-scale and in an optimized large-scale bioreactor,is described. ATP sulfurylase, the second enzyme in thePyrosequencing reaction, was produced inEscherichia coli. The protein was purified and utilizedin the Pyrosequencing method. Problems associated with enzymecontamination (NDP kinase) and batch-to-batch variations wereeliminated by the use of the recombinant ATP sulfurylase. As a first step towards sequencing on chip-format,SSB-(single-strand DNA binding protein)-luciferase and KlenowDNA polymerase-luciferase fusion proteins were generated inorder to immobilize the luciferase onto the DNA template. The application field for the Pyrosequencing technology wasexpanded by introduction of a new method for clone checking anda new method for template preparation prior the Pyrosequencingreaction. Keywords:apyrase, Pyrosequencing technology, Zbasictag fusion, luciferase, ATP sulfurylase, dsDNAsequencing, clone checking, Klenow-luciferase, SSB-luciferase,Pichia pastoris, Echerichia coli. apyrase pyrosequencing pichia pastoris protein expression fusion protein luciferase DNA template clone checking DNA polymerase
27	Recombinant Enzymes in Pyrosequencing Technology Nourizad, Nader January 2004 (has links) <p>Pyrosequencing is a DNA sequencing method based on thedetection of released pyrophosphate (PPi) during DNA synthesis.In a cascade of enzymatic reactions, visible light isgenerated, which is proportional to the number of nucleotidesincorporated into the DNA template. When dNTP(s) areincorporated into the DNA template, inorganic PPi is released.The released PPi is converted to ATP by ATP sulfurylase, whichprovides the energy to luciferase to oxidize luciferin andgenerate light. The excess of dNTP(s) and the ATP produced areremoved by the nucleotide degrading enzyme apyrase.</p><p>The commercially available enzymes, isolated from nativesources, show batch-tobatch variations in activity and quality,which decrease the efficiency of the Pyrosequencing reaction.Therefore, the aim of the research presented in this thesis wasto develop methods to recombinantly produce the enzymes used inthe Pyrosequencing method. Production of the nucleotidedegrading enzyme apyrase by Pichia pastoris expression system,both in small-scale and in an optimized large-scale bioreactor,is described. ATP sulfurylase, the second enzyme in thePyrosequencing reaction, was produced in<i>Escherichia coli</i>. The protein was purified and utilizedin the Pyrosequencing method. Problems associated with enzymecontamination (NDP kinase) and batch-to-batch variations wereeliminated by the use of the recombinant ATP sulfurylase.</p><p>As a first step towards sequencing on chip-format,SSB-(single-strand DNA binding protein)-luciferase and KlenowDNA polymerase-luciferase fusion proteins were generated inorder to immobilize the luciferase onto the DNA template.</p><p>The application field for the Pyrosequencing technology wasexpanded by introduction of a new method for clone checking anda new method for template preparation prior the Pyrosequencingreaction.</p><p><b>Keywords:</b>apyrase, Pyrosequencing technology, Z<sub>basic</sub>tag fusion, luciferase, ATP sulfurylase, dsDNAsequencing, clone checking, Klenow-luciferase, SSB-luciferase,<i>Pichia pastoris, Echerichia coli</i>.</p> apyrase pyrosequencing pichia pastoris protein expression fusion protein luciferase DNA template clone checking DNA polymerase
28	The Cystine Binding Protein (BspA) of Lactobacillus fermentum BR11 Hung, Jacky January 2005 (has links) BspA was first identified on the basis of being the major constituent of 5 M LiCl washes of whole Lactobacillus fermentum BR11 cells. The bspA gene is encoded within a putative ATP-binding cassette (ABC) transport operon, and sequence analysis revealed that it is a member of the family III solute binding proteins. Unlike the majority of solute binding proteins from Gram-positive bacteria, BspA is not tethered to a lipid anchor in the cell membrane, and hence is not a lipoprotein. Extraction of BspA with concentrated salt solutions such as 5 M LiCl is consistent with the notion that electrostatic interactions are responsible for securing it to the L. fermentum BR11 cell. L. fermentum PNG201 is a BspA negative mutant strain created by disrupting bspA. This strain was shown to be incapable of cystine uptake. Thus, the genetic and biochemical evidence strongly suggests BspA is a cystine binding protein of an ABC transporter. Measurement of the binding affinity between BspA and L-cystine has confirmed high affinity binding (dissociation constant is 0.2 µM), and high specificity (over 100-fold excess of non-target amino acids did not disrupt BspA / L-cystine binding). In addition, collagen did not appear to affect BspA/cystine binding, indicating extracellular matrix (ECM) binding capacity noted by other researchers may be unrelated to amino acid binding. An interesting phenotypic characteristic of L. fermentum PNG201 is its apparent increased sensitivity to oxygen and the superoxide-generating chemical - paraquat compared to the parent L. fermentum BR11 strain. Catalase supplemented aerobic cultures of L. fermentum BR11, and L. fermentum PNG201 were protected from oxidative stress, suggesting hydrogen peroxide is responsible for the observed oxidative stress. It was found that addition of cystine to aerobic cultures of L. fermentum BR11 or L. fermentum PNG201 protected both strains from oxidative stress, with L. fermentum BR11 able to utilize smaller concentrations of cystine compared to L. fermentum PNG201. Detection of hydrogen peroxide in aerobic cultures of L. fermentum BR11 and L. fermentum PNG201 confirmed the production of hydrogen peroxide is responsible for causing oxidative stress. The BspA mutant strain L. fermentum PNG201 consistently produced more hydrogen peroxide per optical density compared with the wild type, indicating it overproduced hydrogen peroxide. When 0.4 mM hydrogen peroxide has been accumulated by growing cell cultures, both L. fermentum BR11 and L. fermentum PNG201 enters stationary phase, suggesting both strains have a similar sensitivity to hydrogen peroxide. Small epitopes from the HIV gp41 protein and the Chlamydia psittaci major outer membrane protein have been successfully displayed on the cell surface of L. fermentum BR11 as fusion proteins to the BspA molecule. However, the capability of BspA in exporting larger polypeptides has not been tested. In this study, the large extracellular enzyme - glucosyltransferase (GtfJ) from Streptococcus salivarius ATCC 25975 was fused to BspA to demonstrate that this expression system is capable of exporting large functional enzymes to the cell surface of L. fermentum BR11. The native GtfJ is 160kDa in size and also contained an export signal, which was deleted in the cloning process and replaced with BspA, resulting in a fusion protein of 175kDa. Export of the BspA/GtfJ fusion protein is dependant entirely on BspA's export signal. Recombinant enzyme expression and glucosyltransferase activity were detected by measuring the glucan formed by sonicated cell extracts in acrylamide gels. Enzyme activity measurements on whole cells has revealed the recombinant Lactobacillus was incorporating 20-40 nmol of sucrose-derived-glucose into glucan per ml of cell culture per OD unit, which is comparable to activity levels exhibited by the native bacteria that expressed this enzyme. Comparison of GtfJ enzyme activity between whole cells and sonicated cell extracts of recombinant L. fermentum confirmed the extracellular location of BspA/GtfJ as enzyme activity was essentially identical. Lactobacillus ABC uptake system cystine affinity constant oxidative stress hydrogen sulfide fusion protein glucosyltransferase.
29	Towards a mucosal vaccine against group A streptococcus based on a live bacterial delivery system Melina Mary Georgousakis Unknown Date (has links) No description available.
30	Characterization of putative methyltransferase MT420 in \kur{Trypanosoma brucei.} PROCHÁZKOVÁ, Michaela January 2010 (has links) Localization and characterization of putative mitochondrial methzltransferase acc. No.: Tb10.6k15.0440 in Trypanosoma brucei was performed. Employed molecular methods included immunofluorescence, sub-cellular fractionation and tandem affinity purification. Protein was overexpressed in an E. coli expression system, using an in-fusion expression vector pOPINM with maltose binding protei (MBP) tag.

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