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Studium post translačních modifikací fosducinu / Study of the posttrans lation al modifications of phosducinŠimůnek, Jiří January 2016 (has links)
The aim of this diploma thesis was to study the role of posttranslational modifications of phosducin and their role in the interaction with the 14-3-3 protein as well as the influence of the complex formation on these modifications. Phosducin is a 33kDa protein commonly present in photoreceptor cells of the retina as well as other tissues. Despite many experiments, its physiological functions are still elusive. It has been speculated that fosducin plays an important regulatory role in visual phototransduction pathway, regulation of blood pressure and expression of G-proteins. The phosducin function is regulated through binding to the 14-3-3 protein, a regulatory protein involved in many biochemical processes. Phosducins binding to 14-3-3 protein requires phosphorylation of two serine residues Ser-54 and Ser-73 within the N-terminal domain of phosducin. However, the role of the 14-3-3 protein binding in the regulation of phosducin function is still unclear. In this diploma thesis proteins 14-3-3ζ∆C and phosducin (mutation Q52K) were successfully expressed and purified. The effect of the complex formation on phosducin posttranslational modifications was investigated using limited proteolysis and dephosphorylation. These experiments revealed that the complex formation significantly slowed down both...
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Mechanismus regulace funkce fosducinu / The mechanism of the regulation of phosducin functionKacířová, Miroslava January 2016 (has links)
This dissertation is focused on 30 kDa protein phosducin (Pdc) and on the regulation of its function through the interaction with 28 kDa adaptor protein 14-3-3. These two proteins participate in G-protein signal transduction pathways, especially in the process of light signal transduction. It is assumed that Pdc binds to the Gtβγ complex of G-protein called transducin and through this interaction it inhibits the reassociation of Gtβγ with Gtα thus reducing the visual signal transfer. This process is thought to participate in a long- term light adaptation. The regulation of Pdc function is further regulated by its phosphorylation and subsequent binding to the 14-3-3 protein. It has been speculated that the 14-3-3 binding plays a key role in the inhibition of the interaction between phosphorylated Pdc (Pdc-PP) and Gtβγ. The formation of the 14-3-3/Pdc-PP complex leads to the reassociation of Gtβγ with Gtα and consequently to the amplification of visual signal transfer. Nevertheless, the mechanism by which the 14-3-3 protein binding inhibits the interaction between Pdc and Gtβγ remains elusive. The main aims of this dissertation were: (i) to investigate the structure of Pdc in its apo-state (in the absence of the binding partner) and in the complex with 14-3-3, and (ii) to suggest the mechanism of the...
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Studium úlohy proteinů 14-3-3 v regulaci G-proteinové signalizace / Role of the 14-3-3 protein in the regulation of G-protein signalingŘežábková, Lenka January 2012 (has links)
Univerzita Karlova v Praze Přírodovědecká fakulta Studijní program: Fyzikální chemie Mgr. Lenka Řežábková Studium úlohy proteinů 14-3-3 v regulaci G-proteinové signalizace Role of the 14-3-3 proteins in the regulation of G-protein signaling Disertační práce Školitel: doc. RNDr. Tomáš Obšil, Ph.D. Konzultanti: doc. RNDr. Petr Heřman, CSc. doc. RNDr. Jaroslav Večeř, CSc. Praha, 2012 Abstract The 14-3-3 family of phosphoserine/phosphothreonine-binding proteins dynamically regulates the activity of their binding partners in various signaling pathways that control diverse physiological and pathological processes such as signal transduction, metabolic pathways, cell cycle and apoptosis. More than 300 different cellular proteins from diverse eukaryotic organisms have been described as binding partners for the 14-3-3 proteins. During my Ph.D., I was particularly interested in the role of 14-3-3 proteins in the regulation of G protein signaling pathway. The 14-3-3 proteins affect the G protein signaling via the interaction with negative regulators of G protein cascade - the RGS proteins and phosducin. I employed both biochemical and biophysical approaches to understand how the activity and function of RGS3/14-3-3 and phosducin/14-3-3 complexes are regulated. I solved the low-resolution solution structure of...
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Effect of Melatonin and Dopamine in Site Specific Phosphorylation of Phosducin in Intact RetinaNkemdirim, Arinzechukwu Okere 31 August 2005 (has links) (PDF)
Phosducin (Pdc) is a 28 kDa binding partner for the G protein beta gamma subunit dimer (G-beta-gamma) found abundantly in the photoreceptor cells of the retina and pineal gland. In the retina, light-dependent changes in cAMP and Ca2+ control the phosphorylation of Pdc at serine 73 and 54, respectively, which in turn controls the binding of Pdc to G protein beta gamma subunit dimer . G protein beta gamma subunit dimer binding has been proposed to facilitate light-driven transport of G protein beta gamma subunit dimer from the site of phototransduction in the outer segment of the photoreceptor cell to the inner segment, thereby decreasing light sensitivity and contributing to the process of light adaptation. Dopamine and melatonin are neuromodulators whose concentrations in the retina vary reciprocally during the circadian cycle, with dopamine high during the day and melatonin high during the night. Together, they control numerous aspects of light and dark adaptation in the retina. In this study, we have investigated the possible roles of dopamine and melatonin in regulating Pdc phosphorylation. Using phosphorylation-site specific antibodies to serines 54 and 73, we show that dopamine decreases the phosphorylation of both sites. This decrease is blocked by D4 receptor antagonists and pertussis toxin, indicating that dopamine causes a decrease in photoreceptor cell cAMP and Ca2+ concentration via the D4 receptor coupled to the Gi protein. Conversely, melatonin increases the phosphorylation of both S54 and S73, most likely via the inhibition of dopamine synthesis. These results demonstrate that dopamine and melatonin control the phosphorylation state of phosducin by changing the concentration of cAMP and Ca2+ in photoreceptor cells, and they suggest that dopamine and melatonin may contribute to the light-induced movement of the photoreceptor G protein by regulating Pdc phosphorylation.
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Role of molecular chaperones in G protein B5-Regulator of G protein signaling dimer assembly and G protein By dimer specificityHowlett, Alyson Cerny 02 April 2009 (has links) (PDF)
In order for G protein signaling to occur, the G protein heterotrimer must be assembled from its nascent polypeptides. The most difficult step in this process is the formation of the Gβγ dimer from the free subunits since both are unstable in the absence of the other. Recent studies have shown that phosducin-like protein (PhLP1) works as a co-chaperone with the cytosolic chaperonin complex (CCT) to fold Gβ and mediate its interaction with Gγ. However, these studies did not address questions concerning the scope of PhLP1 and CCT-mediated Gβγ assembly, which are important questions given that there are four Gβs that form various dimers with 12 Gγs and a 5th Gβ that dimerizes with the four regulator of G protein signaling (RGS) proteins of the R7 family. The data presented in Chapter 2 shows that PhLP1 plays a vital role in the assembly of Gγ2 with all four Gβ1-4 subunits and in the assembly of Gβ2 with all twelve Gγ subunits, without affecting the specificity of the Gβγ interactions. The results of Chapter 3 show that Gβ5-RGS7 assembly is dependent on CCT and PhLP1, but the apparent mechanism is different from that of Gβγ. PhLP1 seems to stabilize the interaction of Gβ5 with CCT until Gβ5 is folded, after which it is released to allow Gβ5 to interact with RGS7. These findings point to a general role for PhLP1 in the assembly of all Gβγ combinations, and suggest a CCT-dependent mechanism for Gβ5-RGS7 assembly that utilizes the co-chaperone activity of PhLP1 in a unique way. Chapter 4 discusses PhLP2, a recently discovered essential protein, and member of the Pdc family that does not play a role in G protein signaling. Several studies have indicated that PhLP2 acts as a co-chaperone with CCT in the folding of actin, tubulin, and several cell cycle and pro-apoptotic proteins. In a proteomics screen for PhLP2A interacting partners, α-tubulin, 14-3-3, elongation factor 1α, and ribosomal protein L3 were found. Further proteomics studies indicated that PhLP2A is a phosphoprotein that is phosphorylated by CK2 at threonines 47 and 52.
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Příprava a charakterizace vazebných partnerů fosducinu. / Preparation and characterization of binding partners of phosducin.Kylarová, Salome January 2013 (has links)
AABBSSTTRRAACCTT Phosducin (Pdc) is a highly conserved acidic phosphoprotein, which plays an important role in the regulation of G-protein signalization in intact retina. It binds to Gβγ dimer of heterotrimeric G-protein transducin thereby decreases the pool of available transducin resulting in modulation of signal. Function of phosducin is negatively regulated by its phosphorylation followed by interaction with the 14-3-3 protein. Besides this established way of regulation, we were interested in other putative interaction partners of phosducin, like SUG1 and CRX. SUG1 is a subunit of 26S proteasome with a large scale of biological functions, especially a degradation of many transription factors. Its role in regulation of phosducin is still unclear, but is probably involved in targeting of phosducin to 26S proteasome for its degradation. Subsequently, we prepared four different expression constructs of full-length protein in order to find the best expression and purification strategy. These results suggest that all purified fusion proteins of SUG1 form stable and soluble high molecular weight oligomers. This behaviour was confirmed by dynamic light scattering and analytical ultracentrifugation measurements. In addition, this observation is consistent with previous studies of its bacterial counterpart, PAN...
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The Role of Phosducin-like Protein and the Cytosolic Chaperonin CCT in G beta gamma dimer AssemblyHu, Ting 17 November 2005 (has links) (PDF)
Phosducin-like protein (PhLP), a G protein beta gamma subunit dimer binder and G protein signaling regulator, was suggested to regulate the activity of cytosolic chaperonin CCT by their high affinity interaction. In the present study, the three-dimensional structure of PhLP:CCT complex has been solved by cryoelectron microscopy. PhLP was found to bind only one of the chaperonin rings with both N- and C-terminal domains. It spans the central folding cavity of CCT and interacts with two opposite sides of the top apical region, inducing the constraining of the entry of the folding cavity. These findings support a putative role of PhLP as a co-chaperone similar to prefoldin. Docking studies with the atomic model of PhLP generated from several known structures of the homologous phosducin (Pdc) together with the immuno-EM studies have provided more details of the complex structure and predicted some regions of PhLP and the subunits of CCT involved in the interaction. Taking advantage of the fact that Pdc is highly homologous to PhLP but lack of binding to CCT, the regions of PhLP involved in the interaction with CCT were determined by testing various PhLP/Pdc chimeric proteins in the CCT binding assay. In the other part of this dissertation, the physiological role of PhLP in G protein signaling was investigated. Cellular expression of PhLP was blocked using RNA interference targeting PhLP. Together with overexpression of PhLP variants and kinetic studies of G protein beta gamma dimer formation, PhLP was determined to be a positive mediator of G protein signaling and essential for G protein beta gamma dimer expression and dimer formation. Phosphorylation of PhLP at serines 18—20 by protein kinase CK2 was required for G protein beta gamma dimer formation, while a high-affinity interaction of PhLP with CCT appeared unnecessary. Interestingly, G protein beta subunit was found to interact with CCT by co-immunoprecipitation and PhLP over-expression increased the binding of G protein beta subunit to CCT. These results suggest that PhLP and CCT act as co-chaperones in the folding and assembly of the G protein beta gamma subunit dimer by forming a ternary PhLP-Gbeta-CCT complex that is a necessary intermediate in the assembly process.
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The Role of Phosducin-like Protein as a Co-chaperone with the Cytosolic Chaperonin Complex in Assembly of the G Protein βγ Subunit DimerLudtke, Paul Jayson 30 March 2007 (has links) (PDF)
Phosducin-like protein (PhLP) has been shown to interact with the cytosolic chaperonin containing TCP-1 (CCT), and the βγ subunit dimer of heterotrimeric G proteins (Gβγ). Here we provide details obtained from cryo-electron microscopic and biochemical studies on the structure of the complex between the cytosolic chaperonin CCT and PhLP. Binding of PhLP to CCT occurs through only one of the two chaperonin rings, making multiple contacts with CCT through both its N- and C-terminal domains. In addition, we show that PhLP acts as a co-chaperonin along with CCT in mediating the assembly of the G protein βγ subunit and that assembly is dependant upon the phosphorylation of PhLP by the protein kinase CK2. Variants of PhLP lacking the CK2 phosphorylation sites, or variants with an inability to bind Gβγ block the assembly process and inhibit G protein signaling. PhLP forms a complex with CCT and nascent Gβ prior to the release of Gβγ from the ternary complex and subsequent association with the Gγ subunit to form the Gβγ dimer. In order to understand the mechanism of Gβγ dimer assembly and the role of PhLP phosphorylation in the assembly process, we provide here a method for the purification of the PhLP·CCT·Gβ ternary complex of sufficient purity for structural studies.
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Mechanism of G Protein Beta-Gamma Assembly Mediated by Phosducin-Like Protein 1Lai, Chun Wan Jeffrey 15 December 2011 (has links) (PDF)
G-protein coupled receptor signaling (GPCR) is essential for regulating a large variety of hormonal, sensory and neuronal processes in eukaryotic cells. Because the regulation of these physiological responses is critical, GPCR signaling pathways are carefully controlled at different levels within the cascade. Phosducin-like protein 1 (PhLP1) can bind the G protein βγ dimer and participate in GPCR signaling. Recent evidence has supported the concept that PhLP1 can serve as a co-chaperone of the eukaryotic cytosolic chaperonin complex CCT/TRiC to mediate G βγ assembly. Although a general mechanism of PhLP1-mediated G βγ assembly has been postulated, many of the details about this process are still missing. Structural analysis of key complexes that are important intermediates in the G βγ assembly process can generate snapshots that provide molecular details of the mechanism beyond current understanding. We have isolated two important intermediates in the assembly process, the Gβ1-CCT and PhLP1-Gβ1-CCT complexes assembled in vivo in insect cells, and have determined their structures by cryo-electron microscopy (cryo-EM). Structural analysis reveals that Gβ1, representing the WD40 repeat proteins which are a major class of CCT substrates, interacts specifically with the apical domain of CCTβ. Gβ1 binding experiments with several chimeric CCT subunits confirm a strong interaction of Gβ1 with CCTβ and map Gβ1 binding to α-Helix 9 and the loop between β-strands 6 and 7. These regions are part of a hydrophobic surface of the CCTβ apical domain facing the chaperonin cavity. Docking the Gβ molecule into the two 3D reconstructions (Gβ1-CCT and PhLP1-Gβ1-CCT) reveals that upon PhLP1 binding to Gβ1-CCT, the quasi-folded Gβ molecule is constricted to a more native state and shifted to an angle that can lead to the release of folded Gβ1 from CCT. Moreover, mutagenesis of the CCTβ subunit suggests that PhLP1 can interact with the tip of the apical domain of CCTβ subunit at residue S260, which is a downstream phosphorylation target site of RSK and S6K kinases from the Ras-MAPK and mTOR pathways. These results reveal a novel mechanism of PhLP1-mediated Gβ folding and its release from CCT. The next important step in testing the PhLP1-mediated Gβγ assembly hypothesis is to investigate the function of PhLP1 in vivo. We have prepared a rod-specific PhLP1 conditional knockout mouse in which the physiological consequences of the loss of PhLP1 functions have been characterized. The loss of PhLP1 has led to profound consequences on the ability of these rods to detect light as a result of a significant reduction in the expression of transducin (Gt) subunits. Expression of other G protein subunits as well as Gβ5-RGS9-1 complexes was also greatly decreased, yet all of this occurs without resulting in rapid degeneration of the photoreceptor cells. These results show for the first time the essential nature of PhLP1 for Gβγ and Gβ5-RGS dimer assembly in vivo, confirming results from cell culture and structural studies.
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Novel Phosducin-Like Protein Binding Partners: Exploring Chaperone and Tumor Suppressor Protein InteractionsGray, Amy Jetaun 08 March 2012 (has links) (PDF)
Many proteins cannot fold into their native state without the assistance of one or more molecular chaperones. Chaperonins are an essential class of chaperones that provide an isolated chamber for proteins to fold. CCT, a group II chaperonin found in eukaryotes assists in the folding of actins, tubulins, and many other cellular proteins. PhLP1 is a member of the phosducin protein family that assists CCT in the folding of Gβ and its subsequent assembly with Gγ. However, previous studies have not addressed the scope of PhLP1 and CCT-mediated Gβγ; assembly. The data presented in Chapter 2 shows that PhLP1 plays a vital role in the assembly of all Gγ subunits that form dimers with Gβ2 and the assembly of Gγ2 with Gβ1-4, without affecting the specificity of the Gβγ interactions. These findings suggest that PhLP1 has a general role for the assembly of all Gβγ combinations. Although the role of PhLP1 as a co-chaperone for Gβγ assembly has been established, other possible functions for PhLP1 either as a co-chaperone or otherwise are yet to be investigated. A known tumor suppressor protein, PDCD5, was found to interact with PhLP1 in a co-immunoprecipitation proteomics screen. The data presented in Chapter 3 show that PDCD5 binds PhLP1 indirectly through a ternary complex with CCT. Our results signify that the apoptotic function of PDCD5 is cytosolic, is phosphorylation dependent, and most likely involves CCT. Moreover, structural analysis suggests that over-expressed PDCD5 blocks β-actin from entering the CCT folding cavity, suggesting a co-chaperone role for PDCD5 in inhibiting or enhancing folding of yet-to-be determined CCT substrates. Compared to PhLP1, the functions of other members of the phosducin family, PhLP2A, PhLP2B, and PhLP3, are poorly understood. They have no role in G-protein signaling, but appear to assist CCT in the folding of actin, tubulin and proteins involved in cell cycle progression. Chapter 4 investigates the possibility of PhLP2 and/or PhLP3 acting as co-chaperones in the folding and assembly of actins and tubulins. In addition, another mediator of cellular signaling, 14-3-3ε, was found to interact with PhLP2A in a phosphorylation dependent manner and relieve the inhibition of β-actin folding caused by PhLP2A over-expression.
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