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Nuclear BMP2 and the Immune ResponseOlsen, Daniel S. 08 July 2013 (has links) (PDF)
Nuclear bone morphogenetic protein 2 (nBMP2) is a nuclear variant of the secreted growth factor BMP2. Experiments in nBmp2NLStm mutant mice, which lack nBMP2 in the nucleus, have shown that nBMP2 affects intracellular calcium transport in skeletal muscle and hippocampal neurons. The objective of this study was to determine whether nBMP2 affects the immune system, since activation of lymphocytes and other immune cells depends on intracellular calcium transport. We found that spleens in nBmp2NLStm mutant mice were 24% smaller than in wild type mice. The white pulp of the spleen contains many immune cells, particularly B and T lymphocytes and reduced spleen size in the nBmp2NLStm mutant mice could be caused by a reduced number of lymphocytes migrating to the spleen. When mutants and wild types were challenged with an intravenous infection of 10^7 CFU of S. aureus, they showed similar immune responses. Samples of blood, liver, spleen, kidney and lymph nodes cultured three days after infection showed no difference in post infection bacterial load between mutant and wild type. Likewise, post-infection weight loss and percent survival were similar between mutant and wild type, suggesting that the innate immune response is functional in nBmp2NLStm mice. However, when mice were challenged with a secondary infection, immune response and spleen function were severely impaired. Mutant mice showed higher levels of bacteria remaining in the blood and had lower rate of survival to day 3 after secondary infection. In addition, CD4+ and CD8+ T-cell levels within mutant lymph nodes were significantly reduced, indicating that nBMP2 is involved in the secondary immune response.
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Mechanisms of nuclear localization of glutathione reductase, subnuclear colocalization with thioredoxin, and genetic analysis of a chemically induced glutathione reductase knockoutRogers, Lynette K. 19 October 2004 (has links)
No description available.
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HMGB1 regulates the nuclear import of huntingtin in a ROS-dependent mannerSon, Susie January 2017 (has links)
In healthy cells, huntingtin is primarily found in the cytoplasm; however, upon cellular stress, huntingtin is phosphorylated (phospho-huntingtin) at serines 13 and 16 of the amino-terminal N17 domain and shuttled into the nucleus. Such dynamism in nucleocytoplasmic translocation and post-translational modification suggests an important role for huntingtin in Huntington’s disease (HD) pathogenesis as these phenotypes propose possible mechanisms for disease progression. Huntingtin nuclear import is also facilitated by its proline-tyrosine nuclear localization signal (PY-NLS), which harbours a highly conserved intervening sequence specific to the huntingtin gene. This encouraged a proteome investigation to identify potential protein partners of the PY- NLS. Results of this study revealed that high mobility group box 1 (HMGB1), a cofactor of base excision repair, uniquely bound to the wild-type PY-NLS, but not the PY-NLS KK177/178AA mutant. Immunofluorescence microscopy in human telomerase reverse transcriptase (hTERT) immortalized fibroblast cells using HMGB1- and phospho- huntingtin-specific antibodies revealed a promising association between the two, as changes in nuclear levels of HMGB1 positively correlated with nuclear levels of phospho- huntingtin. This relationship was further confirmed by co-immunoprecipitation of HMGB1 by the PY-NLS and N17 domain. Also, when exogenous oxidative stress was introduced, increased interaction between HMGB1 and huntingtin was observed. This suggests that HMGB1 facilitates the nuclear import of huntingtin in a ROS-dependent manner, and thus, presents a novel avenue to a potential therapeutic target in HD pathogenesis. / Thesis / Master of Science (MSc)
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STRAIN-SPECIFIC PROTEIN INTERACTION AND LOCALIZATION OF TWO STRAINS OF POTATO YELLOW DWARF VIRUS AND FUNCTIONAL DOMAINS OF THEIR MATRIX PROTEINJang, Chanyong 01 January 2019 (has links)
Potato yellow dwarf virus (PYDV) is the type species of the genus nucleorhabdovirus which is typified by its nucleotropic characters of the members. The virus accomplishes its replication and morphogenesis in the nuclei of infected cells. Two strains, Constricta strain (CYDV) and Sanguinolenta strain (SYDV) have been described at the level of vector-specificity. CYDV is vectored by Agallia constricta and SYDV is transmitted by Aceratagllia sanguinolenta. The full-length genome of CYDV was sequenced. The 12,792 nt antisense genome encodes seven open reading frames in the order of, nucleocapsid protein (N), unknown protein (X), phosphoprotein (P), movement protein (Y), matrix protein (M), glycoprotein (G), and large polymerase protein (L). The features of each protein including a nuclear localization signal, isoelectric point, and transmembrane domain, were determined by predictive algorithms. The gene coding region was flanked by leader and trailer, and each ORF was separated by a conserved intergenic junction. In the intergenic junctions, the highly conserved cis-regulatory elements, polyadenylation signal, gene spacer, and transcription start site, were identified. The similarities of amino acid sequences between each cognate protein of SYDV and CYDV were higher than 80% except for X and P proteins. The protein localization and interaction assays of each CYDV protein identified strain-specific associations in comparison with those of SYDV and generated unique protein interaction and localization map compared to SYDV. Phylogenetic analysis using L protein identified that CYDV forms a clade with other leafhopper-transmitted rhabdoviruses. Protein sequence comparisons revealed that CYDV X has greater similarity to the cognate protein of Eggplant mottle disease virus than to SYDV X. The localization patterns of CYDV-N and -Y were different compared the cognate proteins of SYDV. The functional nuclear export domain of SYDV M was identified using c-terminal fragments of the Mwt(aa 211-243), MLL223AA(aa 211-243), and MKR225AA(aa 211-243). Based on the data, the functional domains M mediating membrane association, nuclear import and export were mapped for both strains and suggested a model whereby M mediates intra- and intercellular movement of PYDV nucleocapsid.
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Functional Characterization of the Evolutionarily Conserved Adenoviral Proteins L4-22K and L4-33KÖstberg, Sara January 2014 (has links)
Regulation of adenoviral gene expression is a complex process directed by viral proteins controlling a multitude of different activities at distinct phases of the virus life cycle. This thesis discusses adenoviral regulation of transcription and splicing by two proteins expressed at the late phase: L4-22K and L4-33K. These are closely related with a common N-terminus but unique C-terminal domains. The L4-33K protein is an alternative RNA splicing factor inducing L1-IIIa mRNA splicing, while L4-22K is stimulating transcription from the major late promoter (MLP). The L4-33K protein contains a tiny RS-repeat in its unique C-terminal end that is essential for the splicing enhancer function of the protein. Here we demonstrate that the tiny RS-repeat is required for localization of the protein to the nucleus and viral replication centers. Further, we describe an auto-regulatory loop where L4-33K enhances splicing of its own intron. The preliminary characterization of the responsive RNA-element suggests that it differs from the previously defined L4-33K-responsive element activating L1-IIIa mRNA splicing. L4-22K lacks the ability to enhance L1-IIIa splicing in vivo, and here we show that the protein is defective in L1-IIIa or other late pre-mRNA splicing reactions in vitro. Interestingly, we found a novel function for the L4-22K and L4-33K proteins as regulators of E1A alternative splicing. Both proteins selectively upregulated E1A-10S mRNA accumulation in transfection experiments, by a mechanism independent of the tiny RS-repeat. Although L4-22K is reported to be an MLP transcriptional enhancer protein, here we show that L4-22K also functions as a repressor of MLP transcription. This novel activity depends on the integrity of the major late first leader 5’ splice site. The model suggests that at low concentrations L4-22K activates MLP transcription while at high concentrations L4-22K represses transcription. So far, characterizations of the L4-22K and L4-33K proteins have been limited to human adenoviruses 2 or 5 (HAdV-2/5). We expanded our experiments to include HAdV-3, HAdV-4, HAdV-9, HAdV-11 and HAdV-41. The results demonstrated that the transcription- or splicing-enhancing properties of L4-22K and L4-33K, respectively, are evolutionarily conserved and non-overlapping. Thus, the sequence-based conservation is mirrored by the functions, as expected for functionally important proteins.
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MAPKs regulate nuclear import of human papillomavirus type 11 replicative helicase E1Yu, Jei-Hwa. January 2008 (has links) (PDF)
Thesis (Ph. D.)--University of Alabama at Birmingham, 2008. / Title from first page of PDF file (viewed June 5, 2008). Includes bibliographical references.
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Beyond the name : the characterization of the phosphatidylserine receptor /Davis, Lisa Ann. January 2008 (has links)
Thesis (Ph.D. in Immunology) -- University of Colorado Denver, 2008. / Typescript. Includes bibliographical references (leaves 174-182). Free to UCD Anschutz Medical Campus. Online version available via ProQuest Digital Dissertations;
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SAMHD1 Negatively Regulates the Innate Immune Responses to Inflammatory Stimuli and Viral InfectionQin, Zhihua 30 September 2020 (has links)
No description available.
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Charakterisierung der viralen Genprodukte p10 und P des Borna Disease Virus / Characterization of the viral gene products p10 and P of the Borna disease virusUnterstab, Gunhild January 2005 (has links)
Das Borna Disease Virus (BDV, Bornavirus) besitzt ein einzelsträngiges RNA-Genom negativer Polarität und ist innerhalb der Ordnung Mononegavirales der Prototyp einer eigenen Virusfamilie, die der Bornaviridae. Eine außergewöhnliche Eigenschaft des Virus ist seine nukleäre Transkription und Replikation, eine weitere besteht in seiner Fähigkeit, als neurotropes Virus sowohl in vivo als auch in vitro persistente Infektionen zu etablieren. Die zugrunde liegenden Mechanismen sowohl der Replikation als auch der Persistenz sind derzeit noch unzureichend verstanden, auch deshalb, weil das Virus noch relativ „jung“ ist: Erste komplette Sequenzen des RNA-Genoms wurden 1994 publiziert und erst vor einigen Monaten gelang die Generierung rekombinanter Viren auf der Basis klonierter cDNA. Im Mittelpunkt dieser Arbeit standen das p10 Protein und das Phosphoprotein (P), die von der gemeinsamen Transkriptionseinheit II in überlappenden Leserahmen kodiert werden.
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Als im Kern der Wirtszelle replizierendes Virus ist das Bornavirus auf zelluläre Importmechanismen angewiesen, um den Kernimport aller an der Replikation beteiligten viralen Proteine zu gewährleisten. Das p10 Protein ist ein negativer Regulator der viralen RNA-abhängigen RNA-Polymerase (L). In vitro Importexperimente zeigten, dass p10 über den klassischen Importin alpha/beta abhängigen Kernimportweg in den Nukleus transportiert wird. Dies war unerwartet, da p10 kein vorhersagbares klassisches Kernlokalisierungssignal (NLS) besitzt und weist darauf hin, dass der zelluläre Importapparat offensichtlich flexibler ist als allgemein angenommen. Die ersten 20 N-terminalen AS vermitteln sowohl Kernimport als auch die Bindung an den Importrezeptor Importin alpha. Durch Di-Alanin-Austauschmutagenese wurden die für diesen Transportprozess essentiellen AS identifiziert und die Bedeutung hydrophober und polarer AS-Reste demonstriert.
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Die Fähigkeit des Bornavirus, persistente Infektionen zu etablieren, wirft die Frage auf, wie das Virus die zellulären antiviralen Abwehrmechanismen, insbesondere das Typ I Interferon (IFN)-System, unterwandert. Das virale P Protein wurde in dieser Arbeit als potenter Antagonist der IFN-Induktion charakterisiert. Es verhindert die Phosphorylierung des zentralen Transkriptionsfaktors IRF3 durch die zelluläre Kinase TBK1 und somit dessen Aktivierung. Der Befund, dass P mit TBK1 Komplexe bildet und zudem auch als Substrat für die zelluläre Kinase fungiert, erlaubt es, erstmalig einen Mechanismus zu postulieren, in dem ein virales Protein (BDV-P) als putatives TBK1-Pseudosubstrat die IRF3-Aktivierung kompetitiv hemmt. / The Borna Disease Virus (BDV) harbors a single stranded RNA genome of negative polarity. Within the order of Mononegavirales it is the prototype of a new virus family named Bornaviridae. Unique features of this neurotrope virus are its nuclear transcription and replication as well as its ability to establish persistent infections both in vivo and in vitro. The underlying mechanisms of BDV replication and persistence are currently not well understood amongst others due to the fact that BDV is quite a young virus: First complete sequences of the RNA genome have been published in 1994. Only a few months ago the generation of a recombinant Bornavirus from cloned cDNA has been accomplished.
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The work presented here focused on the viral p10 protein and the phosphoprotein P that are both encoded by two overlapping reading frames of the transcription unit II.
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Nuclear replication of the Bornavirus relies on cellular import mechanisms to allow for nuclear import of viral proteins involved in viral replication. The p10 protein has been described as a negative regulator of the viral RNA dependent RNA polymerase (L). In vitro import experiments revealed that p10 translocates into the nucleus via the classical importin alpha/beta; dependent pathway. This was unexpected since p10 does not contain a predictable classical nuclear localization signal (NLS) suggesting that the cellular import machinery is more flexible than generally believed. The first 20 amino acids mediate nuclear import and binding to the import receptor importin alpha. Analysis of di-alanine-exchange mutants identified essential amino acids and furthermore revealed the impact of hydrophobic and polar side chains in receptor binding and nuclear import.
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The ability of the Bornavirus to establish persistent infections rises the question of how the virus circumvents cellular antiviral defense mechanisms, in particular the type I interferon system. This work characterizes the viral P protein as a potent antagonist of IFN beta induction. It prevents the activation of the central transcription factor IRF3 by interfering with the cellular kinase TBK1. The finding that P forms complexes with TBK1 and moreover serves as a kinase substrate allows to postulate a mechanism for the first time, in which a viral protein (BDV-P) acts as a putative TBK1 pseudo-substrate and thereby competitively inhibits IRF3 activation.
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Nuclear localization of proteins with a charge periodicity of 28 residuesSAKIYAMA, Noriyuki, 崎山, 則征, KE, Runcong, 柯, 閏聡, SAWADA, Ryuusuke, 澤田, 隆介, SONOYAMA, Masashi, 園山, 正史, MITAKU, Shigeki, 美宅, 成樹 January 2007 (has links) (PDF)
No description available.
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