EC:2.5.1.18 - FACTA Search

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Query: EC:2.5.1.18 (glutathione S-transferase)
22,582 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The C2 domain is a conserved protein module present in various signal-transducing proteins. To investigate the function of the C2 domain of protein kinase Calpha (PKCalpha), we have generated a recombinant glutathione S-transferase-fused C2 domain from rat PKCalpha, PKC-C2. We found that PKC-C2 binds with high affinity (half-maximal binding at 0.6 microM) to lipid vesicles containing the negatively charged phospholipid phosphatidylserine. When expressed into COS and HeLa cells, most of the PKC-C2 was found at the plasma membrane, whereas when the cells were depleted of Ca2+ by incubation with EGTA and ionophore, the C2 domain was localized preferentially in the cytosol. Ca2+ titration was performed in vivo and the critical Ca2+ concentration ranged from 0.1 to 0.32 microM. We also identified, by site-directed mutagenesis, three aspartic residues critical for that Ca2+ interaction, namely Asp-187, Asp-246 and Asp-248. Mutation of these residues to asparagine, to abolish their negative charge, resulted in a domain expressed as the same extension as wild-type protein that could interact in vitro with neither Ca2+ nor phosphatidylserine. Overexpression of these mutants into COS and HeLa cells also showed that they cannot localize at the plasma membrane, as demonstrated by immunofluorescence staining and subcellular fractionation. These results suggest that the Ca2+-binding site might be involved in promoting the interaction of the C2 domain of PKCalpha with the plasma membrane in vivo.
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PMID:Determination of the calcium-binding sites of the C2 domain of protein kinase Calpha that are critical for its translocation to the plasma membrane. 989 96

Mammalian phosphatidylcholine-specific phospholipase D1 (PLD1) is a signal transduction-activated enzyme thought to function in multiple cell biological settings including the regulation of membrane vesicular trafficking. PLD1 is activated by the small G proteins, ADP-ribosylation factor (ARF) and RhoA, and by protein kinase C-alpha (PKC-alpha). This stimulation has been proposed to involve direct interaction and to take place at a distinct site in PLD1 for each activator. In the present study, we employed the yeast two-hybrid system to attempt to identify these sites. Successful interaction of ARF and PKC-alpha with PLD1 was not achieved, but a C-terminal fragment of human PLD1 (denoted "D4") interacted with the active mutant of RhoA, RhoAVal-14. Deletion of the CAAX box from RhoAVal-14 decreased the strength of the interaction, suggesting that lipid modification of RhoA is important for efficient binding to PLD1. The specificity of the interaction was validated by showing that the PLD1 D4 fragment interacts with glutathione S-transferase-RhoA in vitro in a GTP-dependent manner and that it associates with RhoAVal-14 in COS-7 cells, whereas the N-terminal two-thirds of PLD1 does not. Finally, we show that recombinant D4 peptide inhibits RhoA-stimulated PLD1 activation but not ARF- or PKC-alpha-stimulated PLD1 activation. These results conclusively demonstrate that the C-terminal region of PLD1 contains the RhoA-binding site and suggest that the ARF and PKC interactions occur elsewhere in the protein.
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PMID:Interaction of the small G protein RhoA with the C terminus of human phospholipase D1. 1003 81

Protein kinase C is known to play a role in cell cycle regulation in both lower and higher eucaryotic cells. Since mutations in yeast proteins involved in cell cycle regulation can often be rescued by the mammalian homolog and since significant conservation exists between PKC-signalling pathways in yeast and mammalian cells, cell cycle regulation by mammalian PKC isoforms may be effectively studied in a simpler genetically-accessible model system such as Saccharomyces cerevisiae. With this objective in mind, we transfected S. cerevisiae cells with a plasmid (pYECepsilon) coding for the expression of murine protein kinase C epsilon (PKCepsilon) under the control of a galactose-inducible promoter. Unlike mock-transfected cells, yeast cells transformed with pYECepsilon expressed, in a galactose-dependent manner, an 89 kDa protein that was recognized by a human PKCepsilon antibody. Extracts from these pYECepsilon-transfected cells could phosphorylate a PKCepsilon substrate peptide in a phospholipid/phorbol ester-dependent manner. Moreover, this catalytic activity could be inhibited by a fusion protein in which the regulatory domain of murine PKCepsilon was fused in frame with GST (GST-Repsilon), further confirming the successful expression of murine PKCepsilon. Induction of PKCepsilon expression by galactose in cells transformed with pYECepsilon increased Ca++ uptake by the cells approximately 5-fold and resulted in a dramatic inhibition of cell growth in glycerol. However, when glucose was used as the carbon source, PKCepsilon expression had no effect on cell growth. This was in contrast to what was observed upon bovine PKCalpha or PKCbeta-I expression in yeast, where expression of these PKC isoforms strongly and moderately inhibited growth in glucose, respectively. Visualization of the cells by phase contrast microscopy indicated that murine PKCepsilon expression in the presence of glycerol resulted in a significant increase in the number of yeast cells exhibiting very small buds. Since overall growth of the cells was dramatically decreased, the data suggests that PKCepsilon expression potently inhibits the progression of yeast cells through the cell cycle after the initiation of budding. In addition, a small amount of the PKCepsilon-expressing yeast cells (1-2%) exhibited gross alterations in cell morphology and defects in both chromosome segregation and septum formation. This suggests that for those cells which do complete DNA synthesis, murine PKCepsilon expression may nevertheless inhibit yeast cell growth by retarding and/or imparing cell division. Taken together, the data suggests murine PKCepsilon expression potently reduces the growth of yeast cells in a carbon source-dependent fashion by affecting progression through multiple points within the cell cycle. This murine PKCepsilon-expressing yeast strain may serve as a very useful tool in the elucidation of mechanism(s) by which external environmental signals (possibly through specific PKC isoforms) regulate cell cycle progression in both yeast and mammalian cells.
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PMID:Carbon source-dependent regulation of cell growth by murine protein kinase C epsilon expression in Saccharomyces cerevisiae. 1004 86

The results presented here demonstrate that protein kinase D (PKD) and PKCeta transiently coexpressed in COS-7 cells form complexes that can be immunoprecipitated from cell lysates using specific antisera to PKD or PKCeta. The presence of PKCeta in PKD immune complexes was initially detected by in vitro kinase assays which reveal the presence of an 80-kDa phosphorylated band in addition to the 110-kDa band corresponding to autophosphorylated PKD. The association between PKD and PKCeta was further verified by Western blot analysis and peptide phosphorylation assays that exploited the distinct substrate specificity between PKCs and PKD. By the same criteria, PKD formed complexes only very weakly with PKCepsilon, and did not bind PKCzeta. When PKCeta was coexpressed with PKD mutants containing either complete or partial deletions of the PH domain, both PKCeta immunoreactivity and PKC activity in PKD immunoprecipitates were sharply reduced. In contrast, deletion of an amino-terminal portion of the molecule, either cysteine-rich region, or the entire cysteine-rich domain did not interfere with the association of PKD with PKCeta. Furthermore, a glutathione S-transferase-PKDPH fusion protein bound preferentially to PKCeta. These results indicate that the PKD PH domain can discriminate between closely related structures of a single enzyme family, e.g. novel PKCs epsilon and eta, thereby revealing a previously undetected degree of specificity among protein-protein interactions mediated by PH domains.
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PMID:The pleckstrin homology domain of protein kinase D interacts preferentially with the eta isoform of protein kinase C. 1009 95

Recent studies have documented direct interaction between 14-3-3 proteins and key molecules in signal transduction pathways like Ras, Cbl, and protein kinases. In T cells, the 14-3-3tau isoform has been shown to associate with protein kinase C theta and to negatively regulate interleukin-2 secretion. Here we present data that 14-3-3tau interacts with protein kinase C mu (PKCmu), a subtype that differs from other PKC members in structure and activation mechanisms. Specific interaction of PKCmu and 14-3-3tau can be shown in the T cell line Jurkat by immunocoprecipitiation and by pulldown assays of either endogenous or overexpressed proteins using PKCmu-specific antibodies and GST-14-3-3 fusion proteins, respectively. Using PKCmu deletion mutants, the 14-3-3tau binding region is mapped within the regulatory C1 domain. Binding of 14-3-3tau to PKCmu is significantly enhanced upon phorbol ester stimulation of PKCmu kinase activity in Jurkat cells and occurs via a Cbl-like serine containing consensus motif. However, 14-3-3tau is not a substrate of PKCmu. In contrast 14-3-3tau strongly down-regulates PKCmu kinase activity in vitro. Moreover, overexpression of 14-3-3tau significantly reduced phorbol ester induced activation of PKCmu kinase activity in intact cells. We therefore conclude that 14-3-3tau is a negative regulator of PKCmu in T cells.
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PMID:Protein kinase C mu is negatively regulated by 14-3-3 signal transduction proteins. 1009

Here we report an interaction between AMPA receptor subunits and a single PDZ domain-containing protein called PICK1 which is known to bind protein kinase C alpha (PKC alpha). The interaction occurs within the last ten amino acid residues containing a novel PDZ binding motif (E S V/I K I) of the short C-terminal alternative splice variants of AMPA receptor subunits. No interaction occurs with the corresponding long splice variants which do not contain the E S V/I K I motif. The PDZ domain of PICK1 is required for the interaction and the mutation of a single amino acid in this region (Lys-27 to Glu) prevents interaction between PICK1 and GluR2 in the yeast two-hybrid assay. A similar mutation has been reported to prevent the binding of PICK1 to PKC alpha indicating that the same domain of PICK1 binds both PKC alpha and GluRs. Flag-tagged PICK1 is retained by a glutathione S-transferase (GST) fusion of the C-terminal of GluR2 (GST-ct-GluR2; short splice variant) but not by GST-ct-GluR1 (long splice variant). Recombinant full length GluR2 is coimmunoprecipitated with flag-PICK1 using an anti-flag antibody and flag-PICK1 is coimmunoprecipitated with an N-terminal directed anti-GluR2 antibody. Transient expression of both proteins in COS cells reveals colocalization and an altered pattern of distribution for each protein from when they are expressed individually. This novel interaction provides a possible regulatory mechanism to specifically modulate distinct splice variants and may be involved in targeting the phosphorylation of short form GluRs by PKC alpha.
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PMID:The protein kinase C alpha binding protein PICK1 interacts with short but not long form alternative splice variants of AMPA receptor subunits. 1034 Mar 1

By interaction cloning (yeast two-hybrid system) using the catalytic domain of protein kinase Czeta (PKCzeta) as bait, we cloned a human full-length cDNA with 62% nucleotide homology to the A6 protein recently cloned and characterized by Beeler et al. [Beeler, J.F., LaRochelle, W.J., Chedid, M., Tronick, S.R. & Aaronson, S. A. (1994) Mol. Cell. Biol. 14, 982-988]. The deduced amino acid sequence (349 amino acids) of the A6-related protein (A6rp) contained potential actin-binding sites and ATP-binding sites. We also cloned the murine homolog of A6rp. Human A6rp was expressed in an in-vitro transcriptional/translational system with an apparent molecular mass of 40 kDa and as a glutathione S-transferase (GST) fusion protein in bacteria. A polyclonal anti-(A6rp) was raised in rabbits and used for the identification of A6rp by immunoblotting. A6rp was found to be expressed at the mRNA and the protein levels in all cells and tissues investigated. GST-A6rp was phosphorylated by PKCzeta but not significantly by other PKC isoenzymes. Moreover, it was phosphorylated by casein kinase 2 and most effectively by the tyrosine kinase Src. In contrast to GST-A6rp, GST-A6 was also phosphorylated by PKC isoforms other than PKCzeta and strongly by CK2, but just weakly by Src. In contrast to the results of Beeler et al. on beta-galactosidase-A6, we were unable to demonstrate autokinase activity or tyrosine phosphorylation of either GST-A6 or GST-A6rp. In accordance with the potential ATP-binding sites, both proteins were able to bind ATP.
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PMID:Cloning, expression and characterization of an A6-related protein. 1040 62

Removal of atypical PKC blocks NGF-induced differentiation of PC12 cells.1 We now examine the consequences that overexpression of atypical PKCs had upon NGF responses. PC12 cells were stably transfected with either PKC-iota or PKC-zeta. Overexpression of atypical PKCs markedly enhanced NGF- induced neurite outgrowth as well as enhanced NGF-stimulated JNK kinase. Cotransfection of HA-JNK1 along with increasing concentrations of PKC-iota, resulted in dose-dependent phosphorylation of GST c-Jun (1 - 79). NGF treatment of PC12 cells resulted in activation of NF-kappaB. In comparison, overexpression of atypical PKC-iota was by itself sufficient to activate NF-kappaB and shift the kinetics of NGF-induced kappaB activity. Furthermore, transfection of full-length antisense PKC-iota blocked basal and NGF-stimulated NF-kappaB. Differentiated and undifferentiated PC12 cells overexpressing atypical PKC-iota were protected from serum deprivation-induced cell death. Collectively, these findings demonstrate that atypical PKC-iota lies in a pathway that regulates NF-kappaB and contributes to both neurotrophin-mediated differentiation and survival signaling.
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PMID:Overexpression of atypical PKC in PC12 cells enhances NGF-responsiveness and survival through an NF-kappaB dependent pathway. 1046 49

Granulocyte macrophage colony stimulating factor (GM-CSF), interleukin-3 (IL-3) and interleukin-5 (IL-5 belong to a family of cytokines that regulate proliferation, differentiation and function of haematopoietic cells. Their receptor consists of a ligand specific alpha-chain and a signal transducing beta-chain (betac). While, the role of phosphotyrosine residues in the betac as mediators of downstream signalling cascades has been established, little is known about non-phosphotyrosine mediated events. To identify proteins interacting with betac, we screened a yeast two-hybrid library with the intracellular domain of betac. We found that RACK1, a molecule associating with activated PKC, PLCgamma and Src kinases, associated with the membrane proximal region of betac in both yeast two-hybrid, immunoprecipitation and GST-pull-down assays. The association of RACK1 was constitutive, demonstrating no alteration upon cellular stimulation. Furthermore, upon stimulation of cells with IL-5 or PMA, a complex of betac and PKCbeta was found. Together, these findings suggest a novel role for RACK1 as a possible adapter molecule associating with the intracellular domain of cytokine receptors.
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PMID:Association of RACK1 and PKCbeta with the common beta-chain of the IL-5/IL-3/GM-CSF receptor. 1049 Aug 50

Endothelin-1 (ET-1) can stimulate insulin-responsive glucose transporter (GLUT4) translocation in 3T3-L1 adipocytes (Wu-Wong, J. R., Berg, C. E., Wang, J., Chiou, W. J., and Fissel, B. (1999) J. Biol. Chem. 274, 8103-8110), and in the current study, we have evaluated the signaling pathway leading to this response. First, we inhibited endogenous Galpha(q/11) function by single-cell microinjection using anti-Galpha(q/11) antibody or RGS2 protein (a GTPase activating protein for Galpha(q)) followed by immunostaining to quantitate GLUT4 translocation in 3T3-L1 adipocytes. ET-1-stimulated GLUT4 translocation was markedly decreased by 70 or 75% by microinjection of Galpha(q/11) antibody or RGS2 protein, respectively. Pretreatment of cells with the Galpha(i) inhibitor (pertussis toxin) or microinjection of a Gbetagamma inhibitor (glutathione S-transferase-beta-adrenergic receptor kinase (GST-BARK)) did not inhibit ET-1-induced GLUT4 translocation, indicating that Galpha(q/11 )mediates ET-1 signaling to GLUT4 translocation. Next, we found that ET-1-induced GLUT4 translocation was inhibited by the phosphatidylinositol (PI) 3-kinase inhibitors wortmannin or LY294002, but not by the phospholipase C inhibitor U-73122. ET-1 stimulated the PI 3-kinase activity of the p110alpha subunit (5.5-fold), and microinjection of anti-p110alpha or PKC-lambda antibodies inhibited ET-stimulated GLUT4 translocation. Finally, we found that Galpha(q/11) formed immunocomplexes with the type-A endothelin receptor and the 110alpha subunit of PI 3-kinase and that ET-1 stimulation enhances tyrosine phosphorylation of Galpha(q/11). These results indicate that: 1) ET-1 signaling to GLUT4 translocation is dependent upon Galpha(q/11) and PI 3-kinase; and 2) Galpha(q/11) can transmit signals from the ET(A) receptor to the p110alpha subunit of PI 3-kinase, as does insulin, subsequently leading to GLUT4 translocation.
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PMID:Endothelin-1-induced GLUT4 translocation is mediated via Galpha(q/11) protein and phosphatidylinositol 3-kinase in 3T3-L1 adipocytes. 1055 59

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