Global ETD Search

1	Studies on the Expression and Phosphorylation of the USP4 Deubiquitinating Enzyme Bastarache, Sophie 26 August 2011 (has links) The USP4 is a deubiquitinating enzyme found elevated in certain human lung and adrenal tumours. USP4 has a very close relative, USP15, which has caused great difficulty in studying only one or the other. We have had generated two antibodies specific to USP4 and USP15, and have confirmed that the two do not cross react. Although there have been previous findings of interacting partners, possible substrates and pathways in which it is involved, the biological role of USP4 is mostly unknown. We have used these antibodies to determine that USP4 and USP15 expression differs across tissue and cell types, and that expression changes as the organism ages. We have shown that USP4 plays a role in canonical Wnt signaling, perhaps by stabilizing Beta-catenin, and identified GRK2 as a kinase, phosphorylating USP4. These data have provided enough information to form a hypothesis, implicating USP4 with the destruction complex in the Wnt signaling pathway. USP4 Ubiquitin Proteasome B-catenin Wnt signaling GRK2
2	Studies on the Expression and Phosphorylation of the USP4 Deubiquitinating Enzyme Bastarache, Sophie 26 August 2011 (has links) The USP4 is a deubiquitinating enzyme found elevated in certain human lung and adrenal tumours. USP4 has a very close relative, USP15, which has caused great difficulty in studying only one or the other. We have had generated two antibodies specific to USP4 and USP15, and have confirmed that the two do not cross react. Although there have been previous findings of interacting partners, possible substrates and pathways in which it is involved, the biological role of USP4 is mostly unknown. We have used these antibodies to determine that USP4 and USP15 expression differs across tissue and cell types, and that expression changes as the organism ages. We have shown that USP4 plays a role in canonical Wnt signaling, perhaps by stabilizing Beta-catenin, and identified GRK2 as a kinase, phosphorylating USP4. These data have provided enough information to form a hypothesis, implicating USP4 with the destruction complex in the Wnt signaling pathway. USP4 Ubiquitin Proteasome B-catenin Wnt signaling GRK2
3	Studies on the Expression and Phosphorylation of the USP4 Deubiquitinating Enzyme Bastarache, Sophie 26 August 2011 (has links) The USP4 is a deubiquitinating enzyme found elevated in certain human lung and adrenal tumours. USP4 has a very close relative, USP15, which has caused great difficulty in studying only one or the other. We have had generated two antibodies specific to USP4 and USP15, and have confirmed that the two do not cross react. Although there have been previous findings of interacting partners, possible substrates and pathways in which it is involved, the biological role of USP4 is mostly unknown. We have used these antibodies to determine that USP4 and USP15 expression differs across tissue and cell types, and that expression changes as the organism ages. We have shown that USP4 plays a role in canonical Wnt signaling, perhaps by stabilizing Beta-catenin, and identified GRK2 as a kinase, phosphorylating USP4. These data have provided enough information to form a hypothesis, implicating USP4 with the destruction complex in the Wnt signaling pathway. USP4 Ubiquitin Proteasome B-catenin Wnt signaling GRK2
4	Studies on the Expression and Phosphorylation of the USP4 Deubiquitinating Enzyme Bastarache, Sophie January 2011 (has links) The USP4 is a deubiquitinating enzyme found elevated in certain human lung and adrenal tumours. USP4 has a very close relative, USP15, which has caused great difficulty in studying only one or the other. We have had generated two antibodies specific to USP4 and USP15, and have confirmed that the two do not cross react. Although there have been previous findings of interacting partners, possible substrates and pathways in which it is involved, the biological role of USP4 is mostly unknown. We have used these antibodies to determine that USP4 and USP15 expression differs across tissue and cell types, and that expression changes as the organism ages. We have shown that USP4 plays a role in canonical Wnt signaling, perhaps by stabilizing Beta-catenin, and identified GRK2 as a kinase, phosphorylating USP4. These data have provided enough information to form a hypothesis, implicating USP4 with the destruction complex in the Wnt signaling pathway. USP4 Ubiquitin Proteasome B-catenin Wnt signaling GRK2
5	The Role of Mitochondrial GRK2 in the Pathogenesis and Progression of Heart Failure Ferrero, Kimberly, 0000-0001-9711-7683 January 2022 (has links) Rationale: G protein-coupled receptor (GPCR) kinases (GRKs) are important regulators of cardiac function whose primary role is the phosphorylation of GPCRs and attenuation of downstream signaling, and GRK2 is upregulated after cardiac stress, injury, and during heart failure (HF). Recent studies have identified novel non-GPCR roles for GRKs such as cytoskeletal assembly, insulin signaling, fibrosis and pro-death signaling. One of the most compelling discoveries regarding novel roles of GRK2 in HF pathogenesis is its mitochondrial translocation (mtGRK2) following cardiac injury, which is associated with increased ROS production, decreased FA metabolic oxygen consumption, and pro-death signaling. Moreover, this localization is dependent on phosphorylation of serine 670 (S670) by kinases such as ERK1/2. Of note, expression of a GRK2 C-terminus peptide, βARKct, which contains S670 but no kinase domain or activity, is cardioprotective following injury in part due to inhibition of endogenous mtGRK2. This is significant because growing evidence demonstrates that cardiomyocyte metabolism is regulated by levels and activities of individual mitochondrial proteins Objective: This study sought to identify mitochondrial proteins which GRK2 interacts with either basally or after injury- or stress-induced translocation, and to determine whether functional regulation of mitochondrial function via phosphorylation of these proteins contributes to the phenomenon of bioenergetic defects during the development of HF. Methods and Results: Co-immunoprecipitation of GRK2 in vitro from primary ventricular cardiomyocytes and a human transformed cardiomyocyte-derived cell line was followed by liquid-chromatography mass-spectroscopy identification of all GRK2- interacting proteins. We followed this with proteomics analysis using DAVID and iv Ingenuity software to identify main pathways altered by GRK2 during stress or injury, focusing on mitochondrial dysfunction which revealed that GRK2 interacts with all major components of the electron transport chain (ETC). Using recombinant proteins as well as in vitro and in vivo models of myocardial infarction (MI), we demonstrate that GRK2 is able to phosphorylate the catalytic barrel of mitochondrial ATP synthase (complex V). Moreover, reduction of GRK2 levels in vivo using a GRK2 knockdown mouse model appears to protect against injury-induced bioenergetic deficits, whereas increased GRK2 levels in a transgenic GRK2 overexpression mouse model reveals both baseline deficits in ATP production as well as worsened post-MI outcomes. Conclusions: These collective data highlight the significance of the mitochondrial GRK2 interactome as a driver of cardiac bioenergetic deficits, particularly as a response to MI injury which progresses to HF. Given the current lack of effective HF treatments, this highly novel mechanism of GRK2 regulation of the mitochondrial ETC emphasizes the need for GRK2-targeting therapies for treating HF. / Molecular & Cellular Biosciences Molecular biology Pharmacology Physiology GRK2 Heart failure Myocardial infarction Proteomics
6	Études des fonctions ℓ-adrénergiques dans les cardiomyocytes isolés de coeur de chien en insuffisance cardiaque Laurent, Charles-Édouard January 2001 (has links) Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal. Récepteur ℓ-adrénergiques Adénylyl cyclase Désensibilisation Contraction GRK2/GRK5 PKC IL-6
7	Papel do receptor toll-like 9 na falência de migração dos neutrófilos na sepse / The role of toll-like receptor 9 on failure of neutrophil migration during sepsis. Trevelin, Silvia Cellone 20 December 2010 (has links) O recrutamento de neutrófilos para o sítio da infecção é um evento crucial para o combate aos microrganismos e sobrevivência na sepse. A migração destes polimorfonucleares é dirigida através de um gradiente quimiotático por meio do reconhecimento de quimiocinas por receptores acoplados a proteína G (GPCRs), os quais são regulados por quinases específicas (GRKs). Estudos prévios demonstraram que na sepse ocorre uma falência na migração de neutrófilos para o foco infeccioso em função da dessensibilização de receptores quimiotáticos via GRKs induzida pela ativação de receptores toll-like (TLRs), TLR2 e TLR4. Apesar de a ausência de TLR9 em células dendriticas ter sido relacionada a maior sobrevivência de camundongos sépticos, o papel do TLR9 atuando diretamente em neutrófilos não foi avaliado. Objetivando preencher esta lacuna, propôs-se avaliar o papel direto de TLR9 na falência de migração de neutrófilos na sepse. Os camundongos TLR9-/- apresentaram maior sobrevivência a sepse polimicrobiana avaliada por meio do modelo de ligadura e perfuração do ceco (CLP). A deficiência de TLR9 também acarretou em aumento na migração de neutrófilos para o foco da infecção, menor seqüestro de neutrófilos no pulmão, bem como, menor número de bactérias no lavado peritoneal e sangue. A ativação de TLR9 por oligodeoxinucleotídeo contendo o dinucleotídeo CpG não metilado (ODN CpG) nos neutrófilos reduziu a quimiotaxia destes em direção a quimiocina CXCL2 e expressão do receptor quimiotático CXCR2. Além disso, neutrófilos estimulados com ODN CpG apresentaram aumento na expressão da quinase tipo 2 relacionada a receptores acoplados a proteína G (GRK2). Dessa forma, a ativação de TLR9 em neutrófilos circulantes no sangue é prejudicial na sepse por reduzir a quimiotaxia destes para o foco da infecção ao induzir a dessensibilização de CXCR2 via GRK2. / The recruitment of neutrophils to the site of infection is a crucial event for combating the microorganisms and survival on sepsis. The neutrophil migration is directed by a chemotactic gradient through the recognition of chemokines by G protein-coupled receptors (GPCRs), which are regulated by specific kinases (GRKs). Previous studies have shown a failure of neutrophil migration into infectious focus on sepsis due to chemotactic receptor desensitization via GRKs induced by activation of toll- like receptors (TLRs), TLR2 and TLR4. Despite the absence of activation of TLR9 in dendritic cells have been related to increase survival of septic mice, the role of TLR9 acting directly on neutrophils was not evaluated. We proposed to verify the direct role of TLR9 in the failure of neutrophil migration on sepsis. The TLR9 knockout mice (TLR9-/-) showed high survival to polymicrobial sepsis using cecal ligation and puncture model (CLP). TLR9-/- mice had high neutrophil migration to the focus of infection, low neutrophil sequestration in the lung, as well as, few bacteria in the peritoneal exudates and blood. The activation of TLR9 by oligodeoxinucleotide containing unmethylated dinucleotide CpG (CpG ODN) in neutrophils also reduced chemotaxis toward CXCL2 and the expression of chemokine receptor CXCR2. In addition, neutrophils stimulated with CpG ODN showed increased expression of kinase-related G protein-coupled receptor type 2 (GRK2). Thus, the activation of TLR9 in blood circulating neutrophils is harmful on sepsis by reducing their chemotaxis into the site of the infection by inducing CXCR2 desensitization via GRK2. Cecal ligation and puncture (CLP) chemotaxis CXCR2 CXCR2 dessensibilização dessensitization GRK2 GRK2 Ligadura e perfuração do ceco (CLP) migração de neutrófilos neutrophil migration polimorfonucleares polymorphonuclear quimiotaxia receptor toll-like 9. toll-like-receptor 9.
8	Papel do receptor toll-like 9 na falência de migração dos neutrófilos na sepse / The role of toll-like receptor 9 on failure of neutrophil migration during sepsis. Silvia Cellone Trevelin 20 December 2010 (has links) O recrutamento de neutrófilos para o sítio da infecção é um evento crucial para o combate aos microrganismos e sobrevivência na sepse. A migração destes polimorfonucleares é dirigida através de um gradiente quimiotático por meio do reconhecimento de quimiocinas por receptores acoplados a proteína G (GPCRs), os quais são regulados por quinases específicas (GRKs). Estudos prévios demonstraram que na sepse ocorre uma falência na migração de neutrófilos para o foco infeccioso em função da dessensibilização de receptores quimiotáticos via GRKs induzida pela ativação de receptores toll-like (TLRs), TLR2 e TLR4. Apesar de a ausência de TLR9 em células dendriticas ter sido relacionada a maior sobrevivência de camundongos sépticos, o papel do TLR9 atuando diretamente em neutrófilos não foi avaliado. Objetivando preencher esta lacuna, propôs-se avaliar o papel direto de TLR9 na falência de migração de neutrófilos na sepse. Os camundongos TLR9-/- apresentaram maior sobrevivência a sepse polimicrobiana avaliada por meio do modelo de ligadura e perfuração do ceco (CLP). A deficiência de TLR9 também acarretou em aumento na migração de neutrófilos para o foco da infecção, menor seqüestro de neutrófilos no pulmão, bem como, menor número de bactérias no lavado peritoneal e sangue. A ativação de TLR9 por oligodeoxinucleotídeo contendo o dinucleotídeo CpG não metilado (ODN CpG) nos neutrófilos reduziu a quimiotaxia destes em direção a quimiocina CXCL2 e expressão do receptor quimiotático CXCR2. Além disso, neutrófilos estimulados com ODN CpG apresentaram aumento na expressão da quinase tipo 2 relacionada a receptores acoplados a proteína G (GRK2). Dessa forma, a ativação de TLR9 em neutrófilos circulantes no sangue é prejudicial na sepse por reduzir a quimiotaxia destes para o foco da infecção ao induzir a dessensibilização de CXCR2 via GRK2. / The recruitment of neutrophils to the site of infection is a crucial event for combating the microorganisms and survival on sepsis. The neutrophil migration is directed by a chemotactic gradient through the recognition of chemokines by G protein-coupled receptors (GPCRs), which are regulated by specific kinases (GRKs). Previous studies have shown a failure of neutrophil migration into infectious focus on sepsis due to chemotactic receptor desensitization via GRKs induced by activation of toll- like receptors (TLRs), TLR2 and TLR4. Despite the absence of activation of TLR9 in dendritic cells have been related to increase survival of septic mice, the role of TLR9 acting directly on neutrophils was not evaluated. We proposed to verify the direct role of TLR9 in the failure of neutrophil migration on sepsis. The TLR9 knockout mice (TLR9-/-) showed high survival to polymicrobial sepsis using cecal ligation and puncture model (CLP). TLR9-/- mice had high neutrophil migration to the focus of infection, low neutrophil sequestration in the lung, as well as, few bacteria in the peritoneal exudates and blood. The activation of TLR9 by oligodeoxinucleotide containing unmethylated dinucleotide CpG (CpG ODN) in neutrophils also reduced chemotaxis toward CXCL2 and the expression of chemokine receptor CXCR2. In addition, neutrophils stimulated with CpG ODN showed increased expression of kinase-related G protein-coupled receptor type 2 (GRK2). Thus, the activation of TLR9 in blood circulating neutrophils is harmful on sepsis by reducing their chemotaxis into the site of the infection by inducing CXCR2 desensitization via GRK2. CXCR2 dessensibilização GRK2 Ligadura e perfuração do ceco (CLP) migração de neutrófilos polimorfonucleares quimiotaxia receptor toll-like 9. Cecal ligation and puncture (CLP) chemotaxis CXCR2 dessensitization GRK2 neutrophil migration polymorphonuclear toll-like-receptor 9.

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