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Characterization of ras isoform activation by ras guanine nucleotide exchange factors /Clyde-Smith, Jodi. January 2002 (has links) (PDF)
Thesis (Ph. D.)--University of Queensland, 2002. / Includes bibliographical references.
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Functional analysis of the RHOIII and 14-3-3 proteins of Trichoderma reesei /Vasara, Tuija. January 2002 (has links) (PDF)
Thesis (doctoral)--University of Helsinki, 2002. / Includes bibliographical references. Also available on the World Wide Web.
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Regulation of signal transduction by RGS4Brownlie, Zoe. January 2007 (has links)
Thesis (Ph.D.) - University of Glasgow, 2007. / Ph.D. thesis submitted to the Division of Biochemistry and Molecular Biology, Institute of Biomedical and Life Sciences, University of Glasgow, 2007. Includes bibliographical references.
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Roles of transmembrane domains in the folding and assembly of the adenosine A2A receptorThevenin, Damien. January 2007 (has links)
Thesis (Ph. D.)--University of Delaware, 2006. / Principal faculty advisor: Brian J. Bahnson, Dept. of Chemistry & Biochemistry. Includes bibliographical references.
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Characterization of [beta] -arrestin-Modulated Lipid Kinase Activities for Diacylglycerol and Phosphatidylinositol 4-PhosphateNelson, Christopher David, January 2007 (has links)
Thesis (Ph. D.)--Duke University, 2007. / Includes bibliographical references.
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Characterization of the beta-subunit of the mammalian SRP receptor and its role in assembly of the SRP receptor /Legate, Kyle R. Andrews, D. W. January 2003 (has links)
Thesis (Ph.D.)--McMaster University, 2003. / Advisor: David W. Andrews. Includes bibliographical references (leaves 122-141) Also available via World Wide Web.
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Ric-8B, uma GEF putativa do sistema olfatório, interage com Gαolf, Gβ1 e Gγ13 / RIC-8B, a putative GEF of the olfactory system, interacts with Gαolf, Gβ1 e Gγ13Kerr, Daniel Shikanai 05 December 2008 (has links)
O sistema olfatório de mamíferos é capaz de detectar milhares de substâncias químicas diferentes, mesmo em baixas concentrações. Um odorante disperso no ar pode se ligar a um receptor olfatório (OR) iniciando o processo de detecção. Os ORs são membros da super família de receptores acoplados a proteína G (GPCRs). Apesar de a via de transdução de sinal de odorantes estar bem descrita, pouco se sabe sobre os seus moduladores. Em 2005, nosso laboratório identificou RIC-8B como um possível fator de troca de nucleotídeos de guanina (GEF) que poderia amplificar a atividade da proteína G olfatória (Golf). No presente trabalho mostramos que RIC-8B é capaz de interagir com Gγ13. Procurando os outros componentes desse complexo identificamos Gβ1 como sendo a subunidade Gβ mais expressa no epitélio olfatório. Além disso, RIC-8B, Gαolf, Gβ1 e Gγ13 encontram-se concentrados nos cílios dos neurônios olfatórios e se co-localizam nesse compartimento celular. Nossos experimentos de co-imunoprecipitação mostram que RIC-8B interage mais fortemente com Gαolf, na presença de GDP do que na presença de GTP, como esperado para uma GEF. Curiosamente quando Gβ1 e Gβ13 estão presentes, RIC-8B e Gαolf co-imunoprecipitam igual, independente do nucleotídeo de guanina utilizado. Apesar de, na presença de Gβ1 e Gγ13, não observarmos dissociação física de RIC-8B e Gαolf com a mudança do estado de ativação, o efeito de RIC-8B na produção de AMPc não é afetada. Também mostramos que a quantidade de Gαolf, Gβ1 e Gγ13 presentes na membrana celular aumenta quando estas são co-transfectadas com RIC-8B em células de mamíferos. Nossos resultados apontam para um papel duplo da RIC-8B. Primeiro, RIC-8B poderia funcionar como uma chaperona auxiliando na formação e transporte do complexo heterotrimérico, Golf, em neurônios olfatórios. Em segundo lugar, RIC-8B também atuaria como uma GEF sobre Gαolf, aumentando a produção de AMPc e portanto amplificando a via de transdução de sinal de odorantes. Por fim, acreditamos que um possível papel para Gβ1 e Gγ13 nesse complexo seria funcionar como um andaime molecular, aproximando RIC-8B de seu alvo, Gαolf, potencializando ainda mais a atividade de GEF. / The mammalian olfactory system detects small amounts of thousands of different chemical compounds. Odorant perception starts when an odorant in the air binds to an olfactory receptor (OR). ORs belong to the super family of G-protein coupled receptors (GPCRs). Even though the odorant signaling pathway is well known, little is known about its modulators. In 2005, our lab identified RIC-8B as a putative guanine nucleotide exchange factor (GEF) that is able to interact with the olfactory G-protein (Golf) and amplify its activity. Here we show that RIC-8B also interacts with Gγ13. We also found that Gβ1 is the Gβ subunit that is predominantly expressed in the olfactory epithelium. Furthermore, RIC-8B, Gαolf, Gβ1 and Gγ13 are highly concentrated in the cilia of olfactory neurons and co-localize in this cellular compartment. We also show that RIC-8B interaction with Gαolf is stronger in the presence of GDP than GTP, as expected for a GEF. Curiously, in the presence of Gβ1 and Gγ13, RIC-8B and Gαolf remain associated, in the presence of both GDP or GTP, probably through an indirect interaction via Gβ1/Gγ13. We also showed that the amounts of Gαolf, Gβ1 and Gγ13 in the cell membrane increase if RIC-8B is cotransfected in the same cell. Our results suggest that RIC-8B plays two roles. First, it may act as a chaperone which assists in the assembly and trafficking of the G protein complex. Second, RIC-8B would also act as a GEF to increase Gαolf dependent cAMP production and thereby amplify odorant signal transduction. Lastly, we believe that Gβ1 and Gγ13 may act as a scaffold to position RIC-8B close to its target, Gαolf, further enhancing the GEF activity.
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Ric-8B, uma GEF putativa do sistema olfatório, interage com Gαolf, Gβ1 e Gγ13 / RIC-8B, a putative GEF of the olfactory system, interacts with Gαolf, Gβ1 e Gγ13Daniel Shikanai Kerr 05 December 2008 (has links)
O sistema olfatório de mamíferos é capaz de detectar milhares de substâncias químicas diferentes, mesmo em baixas concentrações. Um odorante disperso no ar pode se ligar a um receptor olfatório (OR) iniciando o processo de detecção. Os ORs são membros da super família de receptores acoplados a proteína G (GPCRs). Apesar de a via de transdução de sinal de odorantes estar bem descrita, pouco se sabe sobre os seus moduladores. Em 2005, nosso laboratório identificou RIC-8B como um possível fator de troca de nucleotídeos de guanina (GEF) que poderia amplificar a atividade da proteína G olfatória (Golf). No presente trabalho mostramos que RIC-8B é capaz de interagir com Gγ13. Procurando os outros componentes desse complexo identificamos Gβ1 como sendo a subunidade Gβ mais expressa no epitélio olfatório. Além disso, RIC-8B, Gαolf, Gβ1 e Gγ13 encontram-se concentrados nos cílios dos neurônios olfatórios e se co-localizam nesse compartimento celular. Nossos experimentos de co-imunoprecipitação mostram que RIC-8B interage mais fortemente com Gαolf, na presença de GDP do que na presença de GTP, como esperado para uma GEF. Curiosamente quando Gβ1 e Gβ13 estão presentes, RIC-8B e Gαolf co-imunoprecipitam igual, independente do nucleotídeo de guanina utilizado. Apesar de, na presença de Gβ1 e Gγ13, não observarmos dissociação física de RIC-8B e Gαolf com a mudança do estado de ativação, o efeito de RIC-8B na produção de AMPc não é afetada. Também mostramos que a quantidade de Gαolf, Gβ1 e Gγ13 presentes na membrana celular aumenta quando estas são co-transfectadas com RIC-8B em células de mamíferos. Nossos resultados apontam para um papel duplo da RIC-8B. Primeiro, RIC-8B poderia funcionar como uma chaperona auxiliando na formação e transporte do complexo heterotrimérico, Golf, em neurônios olfatórios. Em segundo lugar, RIC-8B também atuaria como uma GEF sobre Gαolf, aumentando a produção de AMPc e portanto amplificando a via de transdução de sinal de odorantes. Por fim, acreditamos que um possível papel para Gβ1 e Gγ13 nesse complexo seria funcionar como um andaime molecular, aproximando RIC-8B de seu alvo, Gαolf, potencializando ainda mais a atividade de GEF. / The mammalian olfactory system detects small amounts of thousands of different chemical compounds. Odorant perception starts when an odorant in the air binds to an olfactory receptor (OR). ORs belong to the super family of G-protein coupled receptors (GPCRs). Even though the odorant signaling pathway is well known, little is known about its modulators. In 2005, our lab identified RIC-8B as a putative guanine nucleotide exchange factor (GEF) that is able to interact with the olfactory G-protein (Golf) and amplify its activity. Here we show that RIC-8B also interacts with Gγ13. We also found that Gβ1 is the Gβ subunit that is predominantly expressed in the olfactory epithelium. Furthermore, RIC-8B, Gαolf, Gβ1 and Gγ13 are highly concentrated in the cilia of olfactory neurons and co-localize in this cellular compartment. We also show that RIC-8B interaction with Gαolf is stronger in the presence of GDP than GTP, as expected for a GEF. Curiously, in the presence of Gβ1 and Gγ13, RIC-8B and Gαolf remain associated, in the presence of both GDP or GTP, probably through an indirect interaction via Gβ1/Gγ13. We also showed that the amounts of Gαolf, Gβ1 and Gγ13 in the cell membrane increase if RIC-8B is cotransfected in the same cell. Our results suggest that RIC-8B plays two roles. First, it may act as a chaperone which assists in the assembly and trafficking of the G protein complex. Second, RIC-8B would also act as a GEF to increase Gαolf dependent cAMP production and thereby amplify odorant signal transduction. Lastly, we believe that Gβ1 and Gγ13 may act as a scaffold to position RIC-8B close to its target, Gαolf, further enhancing the GEF activity.
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Modulační vliv monovalentních iontů na δ-opioidní receptory / Modulatory effect of monovalent ions on δ-opioid receptorsVošahlíková, Miroslava January 2014 (has links)
The exact role of opioid receptors in drug addiction and modulatory mechanism of action of monovalent cations on these receptors are still not fully understood. Our results support the view that the mechanism of addiction to morphine is primarily based on desensitization of μ- and δ-opioid receptors. Desenzitization of agonist response proceeds already at the level of G protein functional activity. Long-term exposure of rats to morphine resulted in increase of number of δ-opioid receptors and change of their sensitivity to sodium ions. Analysis of the effect of different monovalent ions on agonist binding in δ-OR- Gi1α (Cys351 -Ile351 )-HEK293 cell line confirmed the preferential sensitivity of δ-opioid receptor to sodium ions. We have distinguished the high- and low-affinity Na+ sites. Biophysical analysis of interaction of lithium, sodium, potassium and cesium ions with plasma membranes isolated from HEK293 cells with the help of fluorescent probes indicated that monovalent ions interact, in low-affinity manner, with the polar, membrane-water interface of membrane bilayer. Key words: morphine, forebrain cortex, opioid receptors, G proteins, monovalent ions, plasma membrane, fluorescence spectroscopy.
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Modulační vliv monovalentních iontů na δ-opioidní receptory / Modulatory effect of monovalent ions on δ-opioid receptorsVošahlíková, Miroslava January 2014 (has links)
The exact role of opioid receptors in drug addiction and modulatory mechanism of action of monovalent cations on these receptors are still not fully understood. Our results support the view that the mechanism of addiction to morphine is primarily based on desensitization of μ- and δ-opioid receptors. Desenzitization of agonist response proceeds already at the level of G protein functional activity. Long-term exposure of rats to morphine resulted in increase of number of δ-opioid receptors and change of their sensitivity to sodium ions. Analysis of the effect of different monovalent ions on agonist binding in δ-OR- Gi1α (Cys351 -Ile351 )-HEK293 cell line confirmed the preferential sensitivity of δ-opioid receptor to sodium ions. We have distinguished the high- and low-affinity Na+ sites. Biophysical analysis of interaction of lithium, sodium, potassium and cesium ions with plasma membranes isolated from HEK293 cells with the help of fluorescent probes indicated that monovalent ions interact, in low-affinity manner, with the polar, membrane-water interface of membrane bilayer. Key words: morphine, forebrain cortex, opioid receptors, G proteins, monovalent ions, plasma membrane, fluorescence spectroscopy.
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