1 |
The sequelae of CXCR4 engagementMurphy, Brendan John January 2001 (has links)
No description available.
|
2 |
Characterisation of the erythrocyte membrane components which carry the antigens of the LW, Duffy and Cromer blood group systemsMallinson, Gary January 1995 (has links)
No description available.
|
3 |
An investigation into the role of endothelial cells and dendritic cells in the events leading to allograft tolerance or rejection following liver transplantationGoddard, Sarah January 2002 (has links)
No description available.
|
4 |
The Role of CCR5 in Vaccinia virus PathogenesisRahbar, Ramtin 08 March 2011 (has links)
Viral appropriation of chemokine receptors is an effective way to prevent a host immune response against the invading virus. Many viruses, including poxviruses, subvert the host immune response by encoding several chemokine receptor homologues, capable of binding to and thereby precluding chemokines from activating their cognate cell surface receptors. All poxviruses employ strategies to modulate chemokine activity, including virus-encoded chemokine-binding proteins, receptor homologues and ligand mimics. The potential for the involvement of certain chemokine receptors in poxviral infection was suggested in studies utilizing the rabbit poxvirus, myxoma. Specifically, CCR5 was implicated in mediating cell target susceptibility to infection. Our data suggest virus-CCR5 interactions may lead to the selective activation of distinct signaling pathways that are advantageous for the virus.
VACV, a member of the poxvirus family, produces two structurally distinct forms of virions, the intracellular mature virus (IMV) and the extracellular enveloped virus (EEV), for which the immediate events following cell entry are ill-defined. Using confocal microscopy, we provided evidence that IMV and EEV enter both permissive and non-permissive cells, and that introduction of CCR5 into non-permissive cells – mouse fibroblasts and human PM1 T cells - renders them permissive for VACV replication. We showed that virus activation of CCR5 leads to the selective activation of distinct signaling pathways that are advantageous for the virus. We demonstrated that VACV infection in permissive cells is inhibited by siRNA knockdown of cell surface CCR5 expression and by the CCR5 antagonist, TAK-779. The importance of tyrosine phosphorylation of CCR5 was suggested by the observation that introduction of a CCR5 mutant, in which all the intracellular tyrosines are replaced by phenylalanines, effectively reduces VACV infection in permissive cells. Moreover, tyrosine-339 was implicated in CCR5 as the critical residue for mediating viral infection, since cells expressing CCR5.Y339F do not support viral replication. The cascade of events that leads to permissive phenotype of these cells includes phosphorylation activation of multiple signaling effectors: Jak-2, IRS-2, ERK1/ 2 and Grb2. These data were supported by findings that viral replication in permissive CCR5 expressing cells is blocked by Herbimycin A, and the Jak2 inhibitor, tyrophostin AG490, but not pertussis toxin. Viewed altogether, a critical role of post-entry events, specifically intracellular tyrosine phosphorylation events, was established in determining permissiveness of cells to VACV replication. Furthermore, evidence was provided that introduction of CCR5 in primary human T cells renders them permissive to VACV replication. Since permissive infection of T cells might represent a mechanism for VACV dissemination throughout the lymphatic system, we hypothesized that the absence of CCR5 may be protective against VACV infection in vivo.
To test this hypothesis, wild-type and CCR5 null mice were challenged with VACV by intranasal inoculation. In time course studies we identified aggressive viral replication in the lungs and spleens of CCR5+/+ mice, with no evidence of infection in the CCR5-/- mice. Moreover, associated with VACV infection, we provided evidence for CD4+ and CD8+ T as well as CD11c+ and F4/80+ cell infiltration into the lungs of CCR5+/+ but not CCR5-/- mice, and showed that CCR5-expressing T cells harbor replicating virus. We showed that this CCR5-dependence is VACV-specific, since CCR5-/- mice were as susceptible to intranasal influenza (A/WSN/33) infection as CCR5+/+ mice. In a final series of experiments we provided evidence that adoptive transfer of CCR5+/+ bone marrow into CCR5-/- mice restored VACV permissiveness, with evidence of lung and spleen infection. Taken together, our data showed a critical and novel role for CCR5 in VACV infection and dissemination in vivo.
Moreover, our confocal studies suggested a possible physical interaction between cellular proteins and the VACV in cytosole. Using mass spectrometry-based proteomics, glomulin was identified as a host cell protein that interacts with VACV. Knockdown of glomulin expression in human PM1.CCR5 T cells reduced VACV infection. We demonstrate that treatment of PM1.CCR5 T cells with a c-Met phosphorylation inhibitor led to a significant reduction in VACV infectivity. The data indicated that inhibition of c-Met phosphorylation, reduces the cytosolic availability of activated glomulin, thus leading to a decrease in VACV infectivity. These data identify glomulin as a permissivity factor for VACV infection, and as a potential therapeutic target for VACV.
|
5 |
The Role of CCR5 in Vaccinia virus PathogenesisRahbar, Ramtin 08 March 2011 (has links)
Viral appropriation of chemokine receptors is an effective way to prevent a host immune response against the invading virus. Many viruses, including poxviruses, subvert the host immune response by encoding several chemokine receptor homologues, capable of binding to and thereby precluding chemokines from activating their cognate cell surface receptors. All poxviruses employ strategies to modulate chemokine activity, including virus-encoded chemokine-binding proteins, receptor homologues and ligand mimics. The potential for the involvement of certain chemokine receptors in poxviral infection was suggested in studies utilizing the rabbit poxvirus, myxoma. Specifically, CCR5 was implicated in mediating cell target susceptibility to infection. Our data suggest virus-CCR5 interactions may lead to the selective activation of distinct signaling pathways that are advantageous for the virus.
VACV, a member of the poxvirus family, produces two structurally distinct forms of virions, the intracellular mature virus (IMV) and the extracellular enveloped virus (EEV), for which the immediate events following cell entry are ill-defined. Using confocal microscopy, we provided evidence that IMV and EEV enter both permissive and non-permissive cells, and that introduction of CCR5 into non-permissive cells – mouse fibroblasts and human PM1 T cells - renders them permissive for VACV replication. We showed that virus activation of CCR5 leads to the selective activation of distinct signaling pathways that are advantageous for the virus. We demonstrated that VACV infection in permissive cells is inhibited by siRNA knockdown of cell surface CCR5 expression and by the CCR5 antagonist, TAK-779. The importance of tyrosine phosphorylation of CCR5 was suggested by the observation that introduction of a CCR5 mutant, in which all the intracellular tyrosines are replaced by phenylalanines, effectively reduces VACV infection in permissive cells. Moreover, tyrosine-339 was implicated in CCR5 as the critical residue for mediating viral infection, since cells expressing CCR5.Y339F do not support viral replication. The cascade of events that leads to permissive phenotype of these cells includes phosphorylation activation of multiple signaling effectors: Jak-2, IRS-2, ERK1/ 2 and Grb2. These data were supported by findings that viral replication in permissive CCR5 expressing cells is blocked by Herbimycin A, and the Jak2 inhibitor, tyrophostin AG490, but not pertussis toxin. Viewed altogether, a critical role of post-entry events, specifically intracellular tyrosine phosphorylation events, was established in determining permissiveness of cells to VACV replication. Furthermore, evidence was provided that introduction of CCR5 in primary human T cells renders them permissive to VACV replication. Since permissive infection of T cells might represent a mechanism for VACV dissemination throughout the lymphatic system, we hypothesized that the absence of CCR5 may be protective against VACV infection in vivo.
To test this hypothesis, wild-type and CCR5 null mice were challenged with VACV by intranasal inoculation. In time course studies we identified aggressive viral replication in the lungs and spleens of CCR5+/+ mice, with no evidence of infection in the CCR5-/- mice. Moreover, associated with VACV infection, we provided evidence for CD4+ and CD8+ T as well as CD11c+ and F4/80+ cell infiltration into the lungs of CCR5+/+ but not CCR5-/- mice, and showed that CCR5-expressing T cells harbor replicating virus. We showed that this CCR5-dependence is VACV-specific, since CCR5-/- mice were as susceptible to intranasal influenza (A/WSN/33) infection as CCR5+/+ mice. In a final series of experiments we provided evidence that adoptive transfer of CCR5+/+ bone marrow into CCR5-/- mice restored VACV permissiveness, with evidence of lung and spleen infection. Taken together, our data showed a critical and novel role for CCR5 in VACV infection and dissemination in vivo.
Moreover, our confocal studies suggested a possible physical interaction between cellular proteins and the VACV in cytosole. Using mass spectrometry-based proteomics, glomulin was identified as a host cell protein that interacts with VACV. Knockdown of glomulin expression in human PM1.CCR5 T cells reduced VACV infection. We demonstrate that treatment of PM1.CCR5 T cells with a c-Met phosphorylation inhibitor led to a significant reduction in VACV infectivity. The data indicated that inhibition of c-Met phosphorylation, reduces the cytosolic availability of activated glomulin, thus leading to a decrease in VACV infectivity. These data identify glomulin as a permissivity factor for VACV infection, and as a potential therapeutic target for VACV.
|
6 |
The role of CD4 and CXCR4 mediated apoptosis in T cell depletion during HIV-1 infectionRitsou, Elena January 2001 (has links)
No description available.
|
7 |
Adherence of microfilariae of the filarial nematode Brugia malayi to human endothelial cells and their effect on human endothelial cell mediated immune responsesSchroeder, Jan-Hendrik January 2010 (has links)
No description available.
|
8 |
Rôle des récepteurs monocytaires aux chimiokines dans la physiopathologie du sepsis / Role of monocytic chemokine receptors in sepsis pathophysiologyChousterman, Benjamin Glenn 30 September 2015 (has links)
Le sepsis est la réaction inflammatoire généralisée secondaire à une infection. C’est une pathologie fréquente et grave qui fait intervenir le système immunitaire. L’action de l’immunité innée se fait par l’activation et le recrutement des monocytes, des cellules mononuclées circulantes qui modulent le phénomène inflammatoire. La mobilisation des monocytes fait intervenir les cytokines chimiotactiques (chimiokines) et leurs récepteurs. Nous nous sommes spécifiquement intéressé dans ce travail au rôle de l’expression monocytaire des récepteurs aux chimiokines CCR2 et CX3CR1 au cours du sepsis. Pour ce faire, nous avons utilisé des modèles murins de sepsis et analysé le rôle d’un polymorphisme génétique de CX3CR1 dans une cohorte de malades atteints de sepsis. Nous avons montré qu’au cours du sepsis, les monocytes présentaient une augmentation de l’adhérence aux parois vasculaire contrôlée par le récepteur CX3CR1. Nous avons également montré que les monocytes inflammatoires jouaient un rôle essentiel dans la régulation du phénomène inflammatoire au cours du sepsis en protégeant le rein des lésions septiques. Cette protection est médiée par l’expression de CX3CR1. L’allèle I249 du gène Cx3cr1, à l’origine d’une augmentation des propriétés adhésives du couple CX3CR1/CX3CL1, est un facteur protecteur dans la survenue d’insuffisance rénale aiguë chez le malade atteint de sepsis. Collectivement, ces travaux confirment un rôle régulateur des monocytes inflammatoires au cours du sepsis et identifient de potentielles nouvelles cibles thérapeutiques. / Sepsis is the generalized inflammatory response secondary to an infection. This is a common and serious condition that involves the immune system. The action of innate immunity in sepsis is mediated by the activation and recruitment of monocytes, which are mononuclear circulating cells, which modulate the inflammatory process. The mobilization of monocytes involves chemotactic cytokines (chemokines) and their receptors. This work was specifically focused on the role of monocyte expression of chemokine receptors CCR2 and CX3CR1 in sepsis. To this end, we used mouse models of sepsis and analyzed the role of a common genetic polymorphism of CX3CR1 in a cohort of patients with sepsis.We have shown that in sepsis, monocytes’ motility was modified with an increase of their adhesion to vascular walls that was controlled in part by CX3CR1. We have also shown that inflammatory monocytes play a key role in the regulation of the inflammatory phenomenon in sepsis and that they protected the kidney from septic lesions via a CX3CR1 mediated adhesion mechanism. The I249 allele of CX3CR1, confering increased adhesive properties to monocytes, is a protective factor regarding the occurrence of acute kidney injury in septic patients. Collectively, these data confirm a a regulatory role for inflammatory monocytes during sepsis and identify potential new therapeutic targets.
|
9 |
Study of the activation mechanisms of the CXC chemokine receptor 4 (CXCR4) and the atypical chemokine receptor 3 (ACKR3) / Untersuchung zum Aktivierungsmechanismus des CXC Chemokin‐Rezeptor 4 (CXCR4) und des atypischen Chemokin‐Rezeptor 3 (ACKR3)Perpiñá Viciano, Cristina January 2020 (has links) (PDF)
The CXC chemokine receptor 4 (CXCR4) and the atypical chemokine receptor 3 (ACKR3) are seven transmembrane receptors that are involved in numerous pathologies, including several types of cancers. Both receptors bind the same chemokine, CXCL12, leading to significantly different outcomes. While CXCR4 activation generally leads to canonical GPCR signaling, involving Gi proteins and β‐arrestins, ACKR3, which is predominantly found in intracellular vesicles, has been shown to signal via β‐arrestin‐dependent signaling pathways. Understanding the dynamics and kinetics of their activation in response to their ligands is of importance to understand how signaling proceeds via these two receptors.
In this thesis, different Förster resonance energy transfer (FRET)‐based approaches have been combined to individually investigate the early events of their signaling cascades. In order to investigate receptor activation, intramolecular FRET sensors for CXCR4 and ACKR3 were developed by using the pair of fluorophores cyan fluorescence protein and fluorescence arsenical hairpin binder. The sensors, which exhibited similar functional properties to their wild‐type counterparts, allowed to monitor their ligand-induced conformational changes and represent the first RET‐based receptor sensors in the field of chemokine receptors. Additional FRET‐based settings were also established to investigate the coupling of receptors with G proteins, rearrangements within dimers, as well as G protein activation. On one hand, CXCR4 showed a complex activation mechanism in response to CXCL12 that involved rearrangements in the transmembrane domain of the receptor followed by rearrangements between the receptor and the G protein as well as rearrangements between CXCR4 protomers, suggesting a role of homodimers in the activation course of this receptor. This was followed by a prolonged activation of Gi proteins, but not Gq activation, via the axis CXCL12/CXCR4. In contrast, the structural rearrangements at each step of the signaling cascade in response to macrophage migration inhibitory factor (MIF) were dynamically and kinetically different and no Gi protein activation via this axis was detected. These findings suggest distinct mechanisms of action of CXCL12 and MIF on CXCR4 and provide evidence for a new type of sequential signaling events of a GPCR. Importantly, evidence in this work revealed that CXCR4 exhibits some degree of constitutive activity, a potentially important feature for drug development. On the other hand, by cotransfecting the ACKR3 sensor with K44A dynamin, it was possible to increase its presence in the plasma membrane and measure the ligand‐induced activation of this receptor. Different kinetics of ACKR3 activation were observed in response to CXCL12 and three other agonists by means of using the receptor sensor developed in this thesis, showing that it is a valuable tool to study the activation of this atypical receptor and pharmacologically characterize ligands. No CXCL12‐induced G protein activation via ACKR3 was observed even when the receptor was re-localized to the plasma membrane by means of using the mutant dynamin. Altogether, this thesis work provides the temporal resolution of signaling patterns of two chemokine receptors for the first time as well as valuable tools that can be applied to characterize their activation in response to pharmacologically relevant ligands. / Der CXC Chemokin‐Rezeptor 4 (CXCR4) und der atypische Chemokin‐Rezeptor 3 (ACKR3) sind heptatransmembranäre
Rezeptoren, die in zahlreichen Krankheitsbildern eine Rolle spielen, wie in einigen Krebsarten. Beide Rezeptoren werden zwar von dem gleichen Chemokin CXCL12 aktiviert, allerdings mit unterschiedlichen Signalweiterleitungsmustern. Die Aktivierung von CXCR4 führt zu kanonischer GPCR Signaltransduktion über Gi‐Proteine und β‐Arrestine. Die Signalweiterleitung des Rezeptors ACKR3 hingegen, welcher hauptsächlich in intrazellulären Vesikeln vorliegt, erfolgt über ß‐Arrestinabhängige Signalwege. Es ist von großer Wichtigkeit die Dynamik und Kinetik dieser beiden Rezeptoren hinsichtlich der Aktivierung durch ihre Liganden und der Signalweiterleitung zu verstehen. In dieser Arbeit wurden verschiedene Förster‐Resonanzenergietransfer (FRET) Anwendungen kombiniert, um
die frühen Phasen der Signal‐Kaskade von CXCR4 und ACKR3 zu untersuchen. Zur genaueren Aufklärung der Rezeptoraktivierung wurden intramolekulare FRET‐Sensoren entwickelt, hierzu wurden die Fluorophore Cyan‐fluoreszierendes Protein und engl. fluorescence arsenical hairpin binder verwendet. Die generierten Sensoren zeigten ähnliche funktionelle Eigenschaften wie die
unveränderten Rezeptoren. Liganden‐induzierte Änderungen der Rezeptorkonformation können mittels dieser Sensoren beobachtet werden und stellen die ersten RET‐basierten Sensoren auf dem Forschungsgebiet der Chemokin‐Rezeptoren dar. Weitere FRET‐basierte Methoden wurden zur
Untersuchung von Interaktionen zwischen Rezeptor und G‐Protein, Neuanordnung von Dimeren, sowie der G‐Protein Aktivierung eingesetzt und für beide Chemokin‐Rezeptoren etabliert. CXCR4 zeigte einen komplexen Aktivierungsmechanismus nach Stimulation durch CXCL12, bei welchem zunächst eine Neuordnung der Rezeptor‐Transmembrandomäne gefolgt von Neuordnungen zwischen
Rezeptor und G‐Protein und zuletzt eine Neuordnung zwischen CXCR4 Protomeren erfolgte. Dies
impliziert, dass im Aktivierungsprozess des Rezeptors Homodimere eine Rolle spielen. Zudem wurde
eine verlängerte Gi ‐Protein Aktivierung gegenüber der Gq‐Protein Aktivierung bei CXCL12 stimuliertem CXCR4 beobachtet. Hingegen zeigte eine Stimulierung mit dem Macrophage Migration Inhibitory Factor (MIF) bei jedem Schritt der frühen Singal‐Kaskade veränderte Dynamiken und
Kinetiken im Vergleich zu CXCL12. Darüber hinaus konnte keine Gi ‐Protein Aktivierung festgestellt werden. Dieser Befund zeigt individuelle Mechanismen für MIF und CXCL12 am CXCR4‐Rezeptor und liefert Belege für eine neuer Art von sequenziellen Signalweiterleitungen an GPCRs. Eine wichtige Beobachtung dieser Arbeit für eine potentielle Medikamentenentwicklung ist das CXCR4 ligandenunabhängige
Aktivität zeigt. Um die Aktivierung des ACKR3 Sensors messen zu können wurde durch eine Co‐Transfektion mit K44A Dynamin eine höhere Membranständigkeit erreicht. CXCL12 und drei weiteren Agonisten zeigten am hier entwickelten ACKR3‐Sensor unterscheidbare Kinetiken. Mit diesem wertvollen Werkzeug können Liganden an diesem atypischen Rezeptor pharmakologisch charakterisiert werden. Es konnte keine CXCL12‐induzierte G‐Protein Aktivierung gemessen werden, trotz der stärkeren Präsenz an der Plasmamembran mit Hilfe der Dynamin‐Mutante. In Summe liefert
diese Arbeit zum ersten Mal eine zeitliche Auflösung von Signalweiterleitungsmustern von zwei
Chemokin‐Rezeptoren sowie wertvolle Werkzeuge zur Charakterisierung der frühen Phase der Signal‐Kaskade durch andere pharmakologisch relevanten Liganden.
|
10 |
Cannabinoid Modulation of Chemotaxis of Macrophages and Macrophage-like CellsRaborn, Erinn Shenee 01 January 2007 (has links)
Exogenous and endogenous cannabinoids have been reported to modulate functional activities of macrophages. It is recognized that macrophages express primarily the CB2 cannabinoid receptor, but recent studies indicate that its expression is differential in relation to activation state with maximal levels occurring when cells are in "responsive" and "primed" states. The functional activities of macrophages when in these states of activation are the most susceptible to the action of cannabinoids, at least in terms of a functional linkage to the CB2. To assess the effect of cannabinoid treatment on macrophage chemotaxis and test the hypothesis that cannabinoids inhibit the chemotactic response of macrophages and microglia to endogenous and exogenous, pathogen-derived stimuli, primary murine peritoneal macrophages and neonatal rat microglia were used. Chemotaxis assays and scanning electron microscopy studies demonstrated that cannabinoids inhibit chemotaxis, a signature activity attributed to "responsive" macrophage-like cells, to the endogenous chemokine RANTES (Regulated upon Activation Normal T-cell Expressed and Secreted) and to Acanthamoeba conditioned medium containing secreted proteases. The partial agonist delta-9-tetrahydrocannabinol (THC), administered in vitro, inhibited the chemotactic response of peritoneal macrophages to the chemokine RANTES and to Acanthamoeba conditioned medium. In vivo treatment with THC also resulted in inhibition of the in vitro chemotactic response of murine peritoneal macrophages to RANTES and amoebic conditioned medium. Pharmacological studies employing cannabinoid receptor agonists and antagonists demonstrated the involvement of CB2 in cannabinoid-mediated inhibition of peritoneal macrophage chemotaxis to RANTES and Acanthamoeba conditioned medium, implying that signaling through cannabinoid receptors may desensitize chemokine receptors. Treatment with cannabinoids had no apparent effect on chemokine receptor mRNA levels, but did enhance CCR5 protein phosphorylation. Macrophage migration to Acanthamoeba conditioned medium may involve activation and signaling through protease activated receptors (PARs), as pathogen-derived proteases have been shown to activate PARs and initiate cellular migration; however, further studies are required to demonstrate PAR activation by amoebic conditioned medium and to assess the effects of cannabinoids on PAR signaling. Acanthamoeba are opportunistic pathogens that cause Granulomatis amoebic encephalitis, an infection of the CNS that is often fatal. THC treatment has been shown to increase mortality to Acanthamoeba infections and is characterized by an absence of granuloma formation. We hypothesize that inhibitory effect of THC on macrophage migration may be a key factor in cannabinoid-mediated immunosuppression. To assess the effect of cannabinoids on microglial migration to Acanthamoeba conditioned medium, chemotaxis assays were performed using primary rat microglia treated with cannabinoids. These studies demonstrated that cannabinoids inhibit microglial chemotaxis to amoebic conditioned medium. Furthermore, the studies demonstrate that cannabinoids, acting through cannabinoid receptors, may cross-talk with a diverse array G-protein coupled receptors so as to modulate responsiveness of macrophage and macrophage-like cells.
|
Page generated in 0.0775 seconds