EC:2.5.1.18 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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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 cheA gene of Escherichia coli encodes two proteins from in-frame tandem translation start sites. The long form of CheA (CheA(L)) is the histidine kinase responsible for phosphorylating the response regulator, CheY. The short form of CheA (CheA(S)) is identical in domain structure to CheA(L) except that it is missing the first 97 amino acids. Reduced CheA(S) bound to and enhanced the activity of the phosphatase of phospho-CheY, CheZ. Oxidized CheA(S) was unable to interact with CheZ. Oxidized CheA(S) formed covalent dimers, whereas CheA(L) did not. This property was believed to be the result of an intermolecular disulfide bond. The CheA proteins contain three cysteine residues, one of which likely lies within the CheZ binding region of CheA(S) and is exposed to solvent. We identified the CheZ binding domain of CheA(S) by testing the various fragments of CheA(S) that contain cysteine residues for CheZ binding activity in an ELISA-based CheA(S)-CheZ binding assay. Fragments of CheA(S) lacking the truncated P1 domain of CheA(S) ('P1) were unable to bind CheZ. We also found that a fusion of the first 42 amino acids of CheA(S) ('P1 domain) to GST bound CheZ and enhanced its activity. The interaction between the GST-CheA[98-139] fusion protein and CheZ was dependent on the accessibility of a cysteine residue (Cys-120) located in the 'P1 domain.
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PMID:The accessibility of cys-120 in CheA(S) is important for the binding of CheZ and enhancement of CheZ phosphatase activity. 1517 Mar 28

Our laboratory is interested in understanding the regulation of NADPH oxidase activity in human monocyte/macrophages. Protein kinase C (PKC) is reported to be involved in regulating the phosphorylation of NADPH oxidase components in human neutrophils; however, the regulatory roles of specific isoforms of PKC in phosphorylating particular oxidase components have not been determined. In this study calphostin C, an inhibitor for both novel PKC (including PKCdelta, -epsilon, -theta;, and -eta) and conventional PKC (including PKCalpha and -beta), inhibited both phosphorylation and translocation of p47phox, an essential component of the monocyte NADPH oxidase. In contrast, GF109203X, a selective inhibitor of classical PKC and PKCepsilon, did not affect the phosphorylation or translocation of p47phox, suggesting that PKCdelta, -theta;, or -eta is required. Furthermore, rottlerin (at doses that inhibit PKCdelta activity) inhibited the phosphorylation and translocation of p47phox. Rottlerin also inhibited O2 production at similar doses. In addition to pharmacological inhibitors, PKCdelta-specific antisense oligodeoxyribonucleotides were used. PKCdelta antisense oligodeoxyribonucleotides inhibited the phosphorylation and translocation of p47phox in activated human monocytes. We also show, using the recombinant p47phox-GST fusion protein, that p47phox can serve as a substrate for PKCdelta in vitro. Furthermore, lysate-derived PKCdelta from activated monocytes phosphorylated p47phox in a rottlerin-sensitive manner. Together, these data suggest that PKCdelta plays a pivotal role in stimulating monocyte NADPH oxidase activity through its regulation of the phosphorylation and translocation of p47phox.
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PMID:Protein kinase C delta is required for p47phox phosphorylation and translocation in activated human monocytes. 1549 25

Toxoplasma gondii activates the NF-kappaB pathway in the infected host cell resulting in upregulation of pro-survival genes and prevention of apoptosis. Manipulation of the NF-kappaB cascade by T. gondii correlates with the localization of phosphorylated IkappaB at the parasitophorous vacuole membrane (PVM). This suggests a parasite-mediated event, involving the recruitment and activation of the host IkappaB kinase (IKK) complex, as has been observed with the related protozoan Theileria parva. In contrast to Theileria, confocal microscopy studies showed no apparent hijacking of IKKalpha, IKKbeta, or their activated phosphorylated forms at the T. gondii PVM. Remarkably, phosphorylation of IkappaBalpha at Ser 32/36 was observed at the PVM of T. gondii-infected IKKalpha-/-, IKKbeta-/- and IKKalpha/beta double-knockout (IKKalpha/beta-/-) fibroblasts, suggesting the involvement of a parasite kinase activity independent of host IKK. The presence of a putative T. gondii IkappaB kinase was examined by in vitro kinase assays using GST-IkappaBalpha constructs and protein extracts from both extracellular parasites and PVM fractions. Interestingly, an activity capable of phosphorylating IkappaBalpha at the critical Ser 32/36 sites was identified in parasite extracts, a property restricted to the IKK signalosome. Taken together, our data support the role for a T. gondii kinase involved in phosphorylation of host cell IkappaBalpha and suggest an unusual mechanism utilized by an intracellular pathogen capable of manipulating the NF-kappaB pathway.
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PMID:Detection of a novel parasite kinase activity at the Toxoplasma gondii parasitophorous vacuole membrane capable of phosphorylating host IkappaBalpha. 1567 38

PKB/Akt is a protein involved in control of apoptosis, proliferation and cellular metabolism, and it has been found to be activated in many cancers. Activation of PKB involves recruitment of the enzyme by its PH domain to the cell membrane, and phosphorylation at two residues, T308 and S473. To produce active PKB kinase from Escherichia coli, we constructed a derivative of PKB lacking the PH domain and mutated to glutamate at residues S124, T450 and the activating residue S473 (DeltaPH-PKB-EEE). DeltaPH-PKB-EEE was expressed in E. coli together with PDK1, the kinase responsible for phosphorylating PKB at T308, which was expressed as a GST-fusion. Full-length DeltaPH-PKB-EEE was obtained by using a double tag strategy: His6 at the N-terminus and FLAG at the C-terminus. The protein was purified by nickel affinity chromatography, followed by passage over an anti-FLAG column. The final purification step, anion exchange over a monoQ column, separated phosphorylated from unphosphorylated protein. Active recombinant PKB kinase was thus produced from E. coli, by a simple, reproducible procedure.
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PMID:Expression and purification of active PKB kinase from Escherichia coli. 1580 34

The active form of the positive transcription elongation factor b (P-TEFb) consists of cyclin T and the kinase Cdk9. P-TEFb stimulates transcription by phosphorylating the C-terminal domain of RNA polymerase II. It becomes inactivated when associated in a tetrameric complex with the abundant 7SK small nuclear RNA and the recently identified protein Hexim1. In this study, we identified a stable and soluble C-terminal domain (residues 255-359) in Hexim1 of 12.5-kDa size that binds the cyclin boxes of Cyclin T1. Functional assays in HeLa cells showed that this cyclin T-binding domain (TBD) is required for the binding of Hexim1 to P-TEFb and inhibition of transcriptional activity in vivo. Analytical gel filtration and GST pull-down experiments revealed that both full-length Hexim1 and the TBD are homodimers. Isothermal titration calorimetry yielded a weak multimer for the TBD with a multimerization constant of 1.3 x 10(3) m. The binding affinity between the TBD and cyclin T1 was analyzed with fluorescence spectroscopy methods, using a dansyl-based fluorescence label at position G257C. Equilibrium fluorescence titration and stopped flow fast kinetics yield a dissociation constant of 1.2 mum. Finally, we tested the effect of the HIV-1 Tat protein on the cyclin T1-TBD complex formation. GST pull-down experiments and size exclusion chromatography exhibit a mutually exclusive binding of the two effectors to cyclin T1. Our data suggest a model where HIV-1 Tat competes with Hexim1 for cyclin T1 binding, thus releasing P-TEFb from the inactive complex to stimulate the transcription of HIV-1 gene expression.
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PMID:Identification of a cyclin T-binding domain in Hexim1 and biochemical analysis of its binding competition with HIV-1 Tat. 1585 66

Phosphorylation can affect both the function and trafficking of GABA(A) receptors with significant consequences for neuronal excitability. Serine/threonine kinases can phosphorylate the intracellular loops between M3-4 of GABA(A) receptor beta and gamma subunits thereby modulating receptor function in heterologous expression systems and in neurons (1, 2). Specifically, CaMK-II has been demonstrated to phosphorylate the M3-4 loop of GABA(A) receptor subunits expressed as GST fusion proteins (3, 4). It also increases the amplitude of GABA(A) receptor-mediated currents in a number of neuronal cell types (5-7). To identify which substrate sites CaMK-II might phosphorylate and the consequent functional effects, we expressed recombinant GABA(A) receptors in NG108-15 cells, which have previously been shown to support CaMK-II modulation of GABA(A) receptors containing the beta3 subunit (8). We now demonstrate that CaMK-II mediates its effects on alpha1beta3 receptors via phosphorylation of Ser(383) within the M3-4 domain of the beta subunit. Ablation of beta3 subunit phosphorylation sites for CaMK-II revealed that for alphabetagamma receptors, CaMK-II has a residual effect on GABA currents that is not mediated by previously identified sites of CaMK-II phosphorylation. This residual effect is abolished by mutation of tyrosine phosphorylation sites, Tyr(365) and Tyr(367), on the gamma2S subunit, and by the tyrosine kinase inhibitor genistein. These results suggested that CaMK-II is capable of directly phosphorylating GABA(A) receptors and activating endogenous tyrosine kinases to phosphorylate the gamma2 subunit in NG108-15 cells. These findings were confirmed in a neuronal environment by expressing recombinant GABA(A) receptors in cerebellar granule neurons.
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PMID:Identification of the sites for CaMK-II-dependent phosphorylation of GABA(A) receptors. 1744 79

In this study, we have identified protein kinase A-interacting protein 1 (AKIP1) as a binding partner of NF-kappaB p65 subunit, and AKIP1 enhances the NF-kappaB-mediated gene expression. AKIP1 is a nuclear protein and known to interact with the catalytic subunit of PKA (PKAc). We identified AKIP1 by a yeast two-hybrid screen using the N terminus region of p65 as bait. The interaction between AKIP1 and p65 was confirmed by glutathione S-transferase pull-down assay in vitro and immunoprecipitation-Western blotting assay in vivo. We found that the PKAc was present in the AKIP1.p65 complex and enhanced the transcriptional activity of NF-kappaB by phosphorylating p65. In a transient luciferase assay, AKIP1 cotransfection efficiently increased the transcriptional activity of NF-kappaB induced by phorbol 12-myristate 13-acetate (PMA). When AKIP1 was knocked down by RNA interference, the PMA-mediated NF-kappaB-dependent gene expression was abolished, indicating a physiological role of AKIP1. We found that PKAc, which is maintained in an inactive form by binding to IkappaBalpha and NF-kappaB in resting cells, was activated by PMA-induced signaling and could phosphorylate p65. Overexpression of AKIP1 increased the PKAc binding to p65 and enhanced the PKAc-mediated phosphorylation of p65 at Ser-276. Interestingly, this p65 phosphorylation promoted nuclear translocation of p65 and enhanced NF-kappaB transcription. In fact, we observed that AKIP1 colocalized with p65 within the cells and appeared to retain p65 in nucleus. These findings indicate a positive role of AKIP1 in NF-kappaB signaling and suggest a novel mechanism by which AKIP1 augments the transcriptional competence of NF-kappaB.
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PMID:AKIP1 enhances NF-kappaB-dependent gene expression by promoting the nuclear retention and phosphorylation of p65. 1817 62

Expression of p21(Sdi1) downstream of p53 is essential for induction of cellular senescence, although cancer cell senescence can also occur in the p53 null condition. We report herein that senescence-associated phosphorylated extracellular signal-regulated protein kinases 1 and 2 (SA-pErk1/2) enhanced p21(Sdi1) transcription by phosphorylating Sp1 on Ser(59) downstream of protein kinase C (PKC) alpha. Reactive oxygen species (ROS), which was increased in cellular senescence, significantly activated both PKCalpha and PKCbetaI. However, PKCalpha, but not PKCbetaI, regulated ROS generation and cell proliferation in senescent cells along with activation of cdk2, proven by siRNAs. PKCalpha-siRNA also reduced SA-pErk1/2 expression in old human diploid fibroblast cells, accompanied with changes of senescence phenotypes to young cell-like. Regulation of SA-pErk1/2 was also confirmed by using catalytically active PKCalpha and its DN-mutant construct. These findings strongly suggest a new pathway to regulate senescence phenotypes by ROS via Sp1 phosphorylation between PKCalpha and SA-pErk1/2: employing GST-Sp1 mutants and MEK inhibitor analyses, we found that SA-pErk1/2 regulated Sp1 phosphorylation on the Ser(59) residue in vivo, but not threonine, in cellular senescence, which regulated transcription of p21(Sdi1) expression. In summary, PKCalpha, which was activated in senescent cells by ROS strongly activated Erk1/2, and the SA-pErk1/2 in turn phosphorylated Sp1 on Ser(59). Sp1-enhanced transcription of p21(Sdi1) resulted in regulation of cellular senescence in primary human diploid fibroblast cells.
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PMID:Phosphorylated extracellular signal-regulated protein kinases 1 and 2 phosphorylate Sp1 on serine 59 and regulate cellular senescence via transcription of p21Sdi1/Cip1/Waf1. 1931 49

A20 protein is a major component of the vaccinia virus replication complex. It binds to the DNA polymerase E9, the uracil DNA glycosylase D4 and the primase/helicase D5, three proteins that are essential for viral DNA synthesis. The identification of molecules able to interact with the replication complex and inhibit its activity is a promising strategy for the design of new anti-orthopoxvirus drugs. In this study, we used a yeast genetic approach to select, from combinatorial libraries, 8-mers peptide aptamers that specifically interact with A20. From this screen, we isolated five peptide aptamers whose binding to A20 was confirmed by a glutathione S-transferase (GST) pull-down assay. Among those, we determined that peptide aptamer 72 binds to a central domain on A20. Interestingly, this region of A20 was previously shown to be important for its function in DNA replication. We next showed that vaccinia virus DNA synthesis was impaired in cells constitutively expressing peptide aptamer 72 and that virus production was inhibited in those cells. Thus, peptide aptamer 72 may be a useful tool for the development of new compounds specifically targeting poxvirus replication.
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PMID:Inhibition of vaccinia virus replication by peptide aptamers. 1942 4

Overexpression, genetic amplification and mutations of p21-activated kinase 4 (PAK4) were found in a variety of human cancers. PAK4 regulated actin cytoskeleton reorganization by phosphorylating LIMK1 and promoted cancer cells migration. Using yeast two-hybrid screen, we identified a novel PAK4 binding protein, DGCR6L, which was associated with cancer cell metastasis. We confirmed PAK4 binding to the DGCR6L specifically by GST pull-down assay, and found an association between endogenous PAK4 and DGCR6L by immunoprecipitation in mammalian cells. Furthermore, L115 of DGCR6L was the critical amino acid to bind 466-572aa in the very C-terminus of PAK4. Importantly, DGCR6L was required for the formation of PAK4-DGCR6L-beta-actin complex. Overexpressed DGCR6L promoted migration of AGS cells mediated by PAK4, whereas knock-down of DGCR6L markedly inhibited the migration of those cells. Moreover, DGCR6L (L115V), which did not bind to PAK4, lost the ability to promote AGS cells migration. DGCR6L colocalized with PAK4 or F-actin and enhanced the phosphorylation level of LIMK1 and cofilin in a dose dependent manner. Taken together, our results demonstrated that DGCR6L, a novel PAK4 interacting protein, regulated PAK4-mediated migration of human gastric cancer cells via LIMK1.
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PMID:DGCR6L, a novel PAK4 interaction protein, regulates PAK4-mediated migration of human gastric cancer cell via LIMK1. 1977 28

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