Global ETD Search

11	Processing Body Formation Limits Proinflammatory Cytokine Synthesis in Endotoxin-Tolerant Monocytes and Murine Septic Macrophages McClure, Clara, Brudecki, Laura, Yao, Zhi Q., McCall, Charles E., El Gazzar, Mohamed 16 October 2015 (has links) An anti-inflammatory phenotype with pronounced immunosuppression develops during sepsis, during which time neutrophils and monocytes/macrophages limit their Toll-like receptor 4 responses to bacterial lipopolysaccharide (LPS/endotoxin). We previously reported that during this endotoxin-tolerant state, distinct signaling pathways differentially repress transcription and translation of proinflammatory cytokines such as TNFα and IL-6. Sustained endotoxin tolerance contributes to sepsis mortality. While transcription repression requires chromatin modifications, a translational repressor complex of Argonaute 2 (Ago2) and RNA-binding motif protein 4 (RBM4), which bind the 3′-UTR of TNFα and IL-6 mRNA, limits protein synthesis. Here, we show that Dcp1 supports the assembly of the Ago2 and RBM4 repressor complex into cytoplasmic processing bodies (p-bodies) in endotoxin-tolerant THP-1 human monocytes following stimulation with LPS, resulting in translational repression and limiting protein synthesis. Importantly, this translocation process is reversed by Dcp1 knockdown, which restores TNFα and IL-6 protein levels. We also find this translational repression mechanism in primary macrophages of septic mice. Because p-body formation is a critical step in mRNA translation repression, we conclude that Dcp1 is a major component of the translational repression machinery of endotoxin tolerance and may contribute to sepsis outcome. Dcp1 endotoxin tolerance microRNA sepsis severe systemic inflammation toll-like receptor signaling translation repression Internal Medicine
12	The Individual Contribution of Transcription Factors Mobilized Following T-cell Receptor (TCR) or Mitogenic Activation in the Reactivation of HIV from Latency Hokello, Joseph Francis 20 May 2010 (has links) No description available. Biomedical Research Molecular Biology Virology T-cell Receptor Signaling Reactivation of HIV Latency HIV transcription regulation
13	Alterations and mutations in Bruton's tyrosine kinase affect the transcriptional profile and phenotype of chronic lymphocytic leukemia cells Guinn, Daphne Allyn 26 September 2016 (has links) No description available. Biomedical Research
14	SUPPRESSION OF ANTI-TUMOR IMMUNITY IN CHRONIC LYMPHOCYTIC LEUKEMIA VIA INTERLEUKIN-10 PRODUCTION Alhakeem, Sara 01 January 2017 (has links) The most common human leukemia is B-cell chronic lymphocytic leukemia (B-CLL), which is characterized by a progressive accumulation of abnormal B-lymphocytes in blood, bone marrow and secondary lymphoid organs. Typically disease progression is slow, but as the number of leukemic cells increases, they interfere with the production of other important blood cells, causing the patients to be in an immunosuppressive state. To study the basis of this immunoregulation, we used cells from the transgenic Eμ-TCL1 mouse, which spontaneously develop B-CLL due to a B-cell specific expression of the oncogene, TCL1. Previously we showed that Eμ-TCL1 CLL cells constitutively produce an anti-inflammatory cytokine, IL-10. Here we studied the role of IL-10 in CLL cell survival in vitro and the development of CLL in vivo. We found that neutralization of IL-10 using anti-IL-10 antibodies or blocking the IL-10 receptor (IL-10R) using anti-IL-10R antibodies did not affect the survival of CLL cells in vitro. On the other hand, adoptively transferred Eμ-TCL1 cells grew at a slower rate in IL-10R KO mice vs. wild type (WT) mice. There was a significant reduction in CLL cell engraftment in the spleen, bone marrow, peritoneal cavity and liver of the IL-10R KO compared to WT mice. Further studies revealed that IL-10 could be playing a role in the tumor microenvironment possibly by affecting anti-tumor immunity. This was seen by a reduction in the activation of CD8+ T cells as well as a significantly lower production of IFN-γ by CD4+ T cells purified from CLL-injected WT mice compared to those purified from CLL-injected IL-10R KO mice. Also CLL-primed IL-10R null T cells were more effective than those from similarly CLL-primed wild type mice in controlling CLL growth in immunodeficient recipient mice. These studies demonstrate that CLL cells suppress host anti-tumor immunity via IL-10 production. This led us to investigate possible mechanisms by which IL-10 is produced. We found a novel role of B-cell receptor (BCR) signaling pathway in constitutive IL-10 secretion. Inhibition of Src or Syk family kinases reduces the constitutive IL-10 production by Eμ-TCL1 cells in a dose dependent manner. We identified the transcription factor Sp1 as a novel regulator of IL-10 production by CLL cells and that it is regulated by BCR signaling via the Syk/MAPK pathway. Chronic Lymphocytic Leukemia Interleukin-10 Anti-tumor Immunity B Cell Receptor Signaling Specific Protein 1 Medicine and Health Sciences
15	Generation of hepatocellular cell line capable of supporting the full replication cycle of Hepatitis B Virus / B型肝炎ウイルスの完全複製を支持する肝細胞株の樹立 Yao, Wan-Ling 23 May 2017 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(生命科学) / 甲第20592号 / 生博第380号 / 新制\|\|生\|\|50(附属図書館) / 京都大学大学院生命科学研究科統合生命科学専攻 / (主査)教授藤田尚志, 教授朝長啓造, 教授豊島文子 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM HBV HBV infection/replication NTCP IPS-1 Innate Immunity RIG-I-like receptor signaling Viral particles 460
16	Cell-to-cell transmission and intrinsic mechanisms that influence human immunodeficiency virus infection Pedro, Kyle D. 18 February 2021 (has links) Early in the course of human immunodeficiency virus (HIV) infection a population of latently infected cells is established which persists despite long-term anti-retroviral treatment. This latent reservoir of HIV-infected cells, which reflects mechanisms of transcriptional repression, is the major barrier to cure. Efforts to target the latent reservoir have been inefficient, indicating a need for a more complete understanding of how HIV transcription is regulated. The molecular networks involved in the regulation of HIV transcription remain incompletely defined. I hypothesized that utilization of a high throughput enhanced yeast one-hybrid assay would reveal novel host transcription factor-long terminal repeat (LTR) interactions and transcriptional networks that regulate HIV. The screen identified 42 human transcription factors and 85 total protein-DNA interactions with HIV LTRs. I investigated a subset of these factors for transcriptional activity in cell-based models of infection. Krüppel-like factors 2 and 3 (KLF2 and KLF3) are repressors of HIV-1 and HIV-2 transcription whereas PLAG1-like zinc finger 1 (PLAGL1) is an activator of HIV-2 transcription. These factors regulate HIV expression through direct protein-DNA interactions and correlate with epigenetic modifications of the HIV LTR. Multiple signals converging from the cellular environment and cell-cell interactions converge at the HIV LTR to determine HIV replication and transcription. Previous work in our lab has shown that strong signaling through the T cell receptor (TCR) was required to support HIV expression and the establishment of an inducible latent infection, whereas weak TCR signaling was insufficient for these outcomes. I hypothesized that dendritic cells-CD4+ T cell interactions provide signals that compensate for weak TCR signaling, supporting HIV-1 expression and generation of inducible latent infection. I used CD4+ T cells that express chimeric antigen receptors in a dendritic cell coculture model to deliver differential signals to CD4+ T cells during cell-to-cell transmission of HIV. I found that signals from dendritic cells compensate for weak TCR signaling, facilitating cell activation, HIV expression and establishment of an inducible infection. Microbiology CD4+ T cell Chimeric antigen receptor Dendritic cell HIV latency HIV transcription T cell receptor signaling
17	Editorial: “Purinergic Signaling 2020: The State-of-The-Art Commented by the Members of the Italian Purine Club” Ciruela, Francisco, Fuxe, Kjell, Illes, Peter, Ulrich, Henning, Caciagli, Francesco 30 March 2023 (has links) Editorial on the Research Topic. Purinergic Signaling 2020: The State-of-The-Art Commented by the Members of the Italian Purine Club. info:eu-repo/classification/ddc/610 ddc:610
18	Rôle du jeûne et de la perturbation de la cascade de signalisation de l'insuline sur le clivage du précurseur de la protéine amyloïde (APP) Licea, Sara 09 1900 (has links) La maladie d’Alzheimer est majoritairement sporadique et peu est connu sur les mécanismes déclenchant le développement de cette forme de la maladie. Les études sur la forme familiale ont attribué une importance particulière à la bêta-amyloïde (Aβ), un produit de clivage du précurseur de la protéine amyloïde (APP). Plusieurs facteurs de risques ont été identifiés comme déclencheurs potentiels du développement de la maladie d’Alzheimer dont le diabète de type II (T2D). En effet, la déficience de la signalisation de l’insuline par la désensibilisation des récepteurs de l’insuline (IR) dans le cerveau semble être une caractéristique commune aux deux maladies. Les effets à long terme de la résistance à l’insuline sur l’accumulation d’Aβ et sur la phosphorylation de Tau ont été étudiés, mais les effets de la perturbation aiguë des IR sont moins bien caractérisés. Aussi, les désordres métaboliques sont également des caractéristiques communes aux deux maladies. Le but de notre étude est de déterminer si la perturbation aiguë des IR peut affecter le clivage de l’APP et si la privation énergétique par le jeûne peut sensibiliser ce clivage à la perturbation aiguë des IR. Pour évaluer ceci, nous avons utilisé la Tyrphostin AG1024 à faible dose pour simuler une perturbation des IR plutôt qu’un blocage complet des récepteurs. Pour quantifié le clivage de l’APP, nous avons mesuré les changements de la quantité d’APP taille pleine totale par immunobuvardage de type Western. Pour s’assurer que les changements de la quantité d’APP taille pleine traduisait bien un clivage, nous avons développé un système de lecture par luciférase. Ce système nous permet de suivre le clivage de l’APP via l’expression de la luciférase Firefly puisque le facteur de transcription GAL4 est lié à la portion C-terminale de l’APP . Tout d’abord, nous avons observé que la perturbation aiguë des IR par la Tyrphostin mène au clivage de l’APP et que le jeûne augmente la vulnérabilité au clivage de l’APP suite à une plus petite dose de Tyrphostin. Ce clivage serait imputable à la voie amyloïdogénique puisque l’inhibition de la β-secrétase et de la γ-secrétase empêche le clivage de l’APP. Nous avons aussi montré que la perturbation des IR est nécessaire alors que la perturbation spécifique des IGF-1R n’est pas suffisante. De plus, ni l’autophagie, ni les caspases et ni le protéasomes ne semblent impliqués dans le clivage de l’APP suivant la combinaison du jeûne et de la petite perturbation des IR. L’activité de mTOR n’est également pas requise. Cependant, l’activité de la GSK3 est nécessaire au clivage et semble affecter le clivage par la γ-secrétase. Nous avons ensuite confirmé dans des cultures primaires neuronales que la combinaison du jeûne et de la perturbation aiguë des IR cause le clivage de l’APP et que la GSK3 est encore une fois fortement active. Ainsi, nos résultats suggèrent que la perturbation de la signalisation de l’insuline tel qu’observé dans le T2D augmente le clivage de l’APP via la voie amyloïdogénique et, donc, contribue à la pathologie de la maladie d’Alzheimer. / Little is known about the mechanisms that trigger the onset of Alzheimer’s disease (AD), a primarily sporadic disease. Studies on the familial form of AD attributed a particular importance to Amyloid beta (Aβ), a cleavage product of the Amyloid precursor protein (APP). Many risk factors have been identified as potential triggers of the development of AD including Type 2 diabetes (T2D). Indeed, the impairment of insulin signaling by the desensitization of insulin receptors (IR) in the brain seems to be a common hallmark of both diseases. The long term effects of IR resistance on the accumulation of Aβ and Tau hyperphosphorylation have been studied, but the acute effects of IR perturbation is less characterized. Also, both diseases show metabolic defects. Our research aimed to determine whether acute perturbation of IR signaling affects APP processing and if starving (energy deprivation) could sensitize this processing to acute perturbation of IR. To assess this, we used small doses of Tyrphostin AG1024 to simulate IR perturbations rather than a complete blocakade of the receptors. To quantify APP processing, we measured the change of total full- lenght APP by Western blot. To ensure that this change reflected APP processing we developed a luciferase based readout system. This system allowed us to monitor the occurrence of APP cleavage via GAL4-UAS Firefly luciferase driven expression because we linked GAL4 transcription factor to the C-terminal region of APP. First, we showed that IR perturbation with Tyrphostin leads to APP processing and that starving increased IR susceptibility to a smaller doses of Tyrphostin. This APP processing occurs via the amyloidogenic pathway because inhibition of β- and γ-secretase inhibited APP processing. We showed that this processing absolutely requires IR perturbation, while IGF-1R perturbation alone is insufficient. Furthermore, neither autophagy, caspases nor proteasome seemed to be implicated in APP processing following starvation and small IR perturbation. The activity of mTOR is also not required. On the contrary, GSK3 activation is necessary for the processing and seems to affect γ-secretase cleavage. We then confirmed in primary cultured neurons that the combination of acute starvation and small IR perturbation causes APP cleavage and GSK3 is again strongly activated. Taken together, our results suggest that the impairment of IR signalling seen in T2D increases the processing of APP via the amyloidogenic pathway and thereby contributes to the pathology of AD. Alzheimer APP GSK3 diabète signalisation de l'insuline vulnérabilité jeûne Alzheimer’s disease Diabetes Starving Susceptibility Insulin receptor signaling
19	Dysbalanced BCR signaling in B cells of patients with systemic lupus erythematosus Fleischer, Sarah Jessica 16 September 2015 (has links) Die systemische Autoimmunerkrankung Systemischer Lupus Erythematodes (SLE) ist durch die Produktion von autoreaktiven Antikörpern charakterisiert. In wie weit veränderte B-Zellrezeptor (BZR) Signalwege oder Co-Rezeptoren in diesem Prozess involviert sind, ist noch nicht ausreichend im humanen SLE untersucht worden. Aus diesem Grund wurde in der vorliegenden Arbeit eine detaillierte Analyse des inhibitorischen Co-Rezeptors CD22, der Kinase Syk und Akt in B-Zellen des peripheren Blutes von SLE Patienten durchgeführt. SLE Patienten zeigten eine Dysbalance in BZR abhängigen Signalwegen, welche eine B-Zellsubpopulationen unabhängige Reduktion der p-Syk/p-Akt Ratio versursacht. Diese Verschiebung könnte zu einer defekten negativen Selektion und somit zur Bildung von autoreaktiven Zellen führen, die wiederum durch Überlebensvorteile persistieren könnten. Zusätzlich wurde im peripheren Blut von SLE Patienten eine bislang nicht bekannte CD27 Syk++ B-Zellpopulation nachgewiesen. Diese wies, trotz des fehlenden Gedächtnismarkers CD27, Gedächtnismerkmale auf und könnte für die bekannte erhöhte Plasmazell-induktion in SLE Patienten verantwortlich sein. Somit konnte Syk als intrazellulärer Marker einer Gedächtnispopulation identifiziert werden. Des Weiterem stellt die Wiederherstellung der Balance von Syk- und Akt Phosphorylierung nach BZR Aktivierung einen erfolgsversprechenden Therapieansatz bei SLE Patienten dar, um die Entstehung und das Überleben von autoreaktiven B- und Plasmazellen besser kontrollieren zu können. / Systemic lupus erythematosus (SLE) is a severe systemic autoimmune disease in which loss of tolerance to nucleic acids results into the production of autoreactive antibodies (Ab) Therefore, B cells might play a key role in the pathogenesis of this disease. However, abnormalities of BCR associated co receptors and downstream kinases with potential implications in selection processes are rare for human SLE. Thus, a comprehensive analysis of the inhibitory BCR co-receptor CD22, the spleen tyrosine kinase (Syk) and the pro-survival serine kinase Akt has been undertaken to gain new insights into potential BCR signaling disturbances in this autoimmune disease. This data indicate that B cells from SLE patients display an intrinsically disturbed balance of BCR related signaling pathways, resulting in a B cell subset independent reduced p-Syk/p-Akt ratio. This may lead to a diminished BCR dependent negative selection and enhanced survival of SLE B cells, permitting the emergence of autoreactive B and plasma cells. Furthermore, SLE patients exhibit an increased frequency of a novel CD27-Syk++ B cell subset with memory features, enhanced tonic BCR signaling and the capacity to differentiate in auto-Ab secreting cells. The current study provides evidence that the use of intracellular markers, such as Syk, could permit a more precise delineation of CD27- memory B cell subsets in autoimmune diseases since the conventional used memory marker CD27 has some limitations. In addition, the balance between the BCR associated kinases Syk and Akt might be a promising therapeutic target to reduce the occurrence of autoreactive B and plasma cells. Autoimmunität B-Zelle SLE B-Zellrezeptor Signalweiterleitung Autoimmunity SLE B cells B cell receptor signaling 570 Biowissenschaften, Biologie 32 Biologie WF 9880 XG 4400 ddc:570
20	Regulation of B cell development by antigen receptors Hauser, Jannek January 2011 (has links) The developmental processes of lymphopoiesis generate mature B lymphocytes from hematopoietic stem cells through increasingly restricted intermediates. Networks of transcription factors regulate these cell fate choices and are composed of both ubiquitously expressed and B lineage-specific factors. E-protein transcription factors are encoded by the three genes E2A, E2-2 (SEF2-1), and HEB. The E2A gene is required for B cell development and encodes the alternatively spliced proteins E12 and E47. During B lymphocyte development, the cells have to pass several checkpoints verifying the functionality of their antigen receptors. Early in the development, the expression of a pre-B cell receptor (pre-BCR) with membrane-bound immunoglobulin (Ig) heavy chain protein associated with surrogate light chain (SLC) proteins is a critical checkpoint that monitors for functional Ig heavy chain rearrangement. Signaling from the pre-BCR induces survival and a limited clonal expansion. Here it is shown that pre-BCR signaling rapidly down-regulates the SLCs l5 and VpreB and also the co-receptor CD19. Ca2+ signaling and E2A were shown to be essential for this regulation. E2A mutated in its binding site for the Ca2+ sensor protein calmodulin (CaM), and thus with CaM-resistant DNA binding, makes l5, VpreB and CD19 expression resistant to the inhibition following pre-BCR stimulation. Thus, Ca2+ down-regulates SLC and CD19 gene expression upon pre-BCR stimulation through inhibition of E2A by Ca2+/CaM. A general negative feedback regulation of the pre-BCR proteins as well as many co-receptors and proteins in signal pathways from the receptor was also shown. After the ordered recombination of Ig heavy chain gene segments, also Ig light chain gene segments are recombined together to create antibody diversity. The recombinations are orchestrated by the recombination activating gene (RAG) enzymes, other enzymes that cleave/mutate/assemble DNA of the Ig loci, and the transcription factor Pax5. A key feature of the immune system is the concept that one lymphocyte has only one antigen specificity that can be selected for or against. This requires that only one of the alleles of genes for Ig chains is made functional. The mechanism of this allelic exclusion has however been an enigma. Here pre-BCR signaling was shown to down-regulate several components of the recombination machinery including RAG1 and RAG2 through CaM inhibition of E2A. Furthermore, E2A, Pax5 and the RAGs were shown to be in a complex bound to key sequences on the IgH gene before pre-BCR stimulation and instead bound to CaM after this stimulation. Thus, the recombination complex is directly released through CaM inhibition of E2A. Upon encountering antigens, B cells must adapt to produce a highly specific and potent antibody response. Somatic hypermutation (SH), which introduces point mutations in the variable regions of Ig genes, can increase the affinity for antigen, and antibody effector functions can be altered by class switch recombination (CSR), which changes the expressed constant region exons. Activation-induced cytidine deaminase (AID) is the mutagenic antibody diversification enzyme that is essential for both SH and CSR. The AID enzyme has to be tightly controlled as it is a powerful mutagen. BCR signaling, which signals that good antibody affinity has been reached, was shown to inhibit AID gene expression through CaM inhibition of E2A. SH increases the antigen binding strength by many orders of magnitude. Each round of SH leads to one or a few mutations, followed by selection for increased affinity. Thus, BCR signaling has to enable selection for successive improvements in antibodies (Ab) over an extremely broad range of affinities. Here the BCR is shown to be subject to general negative feedback regulation of the receptor proteins as well as many co-receptors and proteins in signal pathways from the receptor. Thus, the BCR can down-regulate itself to enable sensitive detection of successive improvements in antigen affinity. Furthermore, the feedback inhibition of the BCR signalosome and most of its protein, and most other gene regulations by BCR stimulation, is through inhibition of E2A by Ca2+/CaM. Differentiation to Ab-secreting plasmablasts and plasma cells is antigen-driven. The interaction of antigen with the membrane-bound Ab of the BCR is critical in determining which clones enter the plasma cell response. Genome-wide analysis showed that differentiation of B cells to Ab-secreting cell is induced by BCR stimulation through very fast regulatory events, and induction of IRF-4 and down-regulation of Pax5, Bcl-6, MITF, Ets-1, Fli-1 and Spi-B gene expressions were identified as immediate early events. Ca2+ signaling through CaM inhibition of E2A was essential for these rapid down-regulations of immediate early genes after BCR stimulation in initiation of plasma cell differentiation. calcium calmodulin e-proteins E2A B cell development antigen receptor signaling surrogate light chains RAG allelic exclusion V(D)J recombination AID negative feedback regulation plasma cell differentiation

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