EC:2.7.11.13 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.7.11.13 (protein kinase C)
49,245 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The VHL (von Hippel-Lindau) tumour-suppressor protein forms a multi-protein complex [VCB (pVHL-elongin C-elongin B)-Cul-2 (Cullin-2)] with elongin C, elongin B, Cul-2 and Rbx1, acting as a ubiquitin-ligase (E3) and directing proteasome-dependent degradation of targeted proteins. The alpha-subunit of Hif1alpha (hypoxia-inducible factor 1alpha) is the principal substrate for the VCB-Cul-2 complex; however, other substrates such as aPKC (atypical protein kinase C) have been reported. In the present study, we show with FRET (fluorescence resonance energy transfer) analysis measured by FLIM (fluorescence lifetime imaging microscopy) that PKCdelta and pVHL (VHL protein) interact directly in cells. This occurs through the catalytic domain of PKCdelta (residues 432-508), which appears to interact with two regions of pVHL, residues 113-122 and 130-154. Despite this robust interaction, analysis of the PMA-induced proteasome-dependent degradation of PKCdelta in different RCC (renal cell carcinoma) lines (RCC4, UMRC2 and 786 O) shows that there is no correlation between the degradation of PKCdelta and the presence of active pVHL. Thus, in contrast with aPKC, PKCdelta is not a conventional substrate of the ubiquitin-ligase complex, VCB-Cul-2, and the observed interaction between these two proteins must underlie a distinct signalling output.
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PMID:The von Hippel-Lindau tumour-suppressor protein interaction with protein kinase Cdelta. 1666 86

Cholangiocytes are exposed to high concentrations of bile acids at their apical membrane. A selective transporter for bile acids, the Apical Sodium Bile Acid Cotransporter (ASBT) (also referred to as Ibat; gene name Slc10a2) is localized on the cholangiocyte apical membrane. On the basolateral membrane, four transport systems have been identified (t-ASBT, multidrug resistance (MDR)3, an unidentified anion exchanger system and organic solute transporter (Ost) heteromeric transporter, Ostalpha-Ostbeta. Together, these transporters unidirectionally move bile acids from ductal bile to the circulation. Bile acids absorbed by cholangiocytes recycle via the peribiliary plexus back to hepatocytes for re-secretion into bile. This recycling of bile acids between hepatocytes and cholangiocytes is referred to as the cholehepatic shunt pathway. Recent studies suggest that the cholehepatic shunt pathway may contribute in overall hepatobiliary transport of bile acids and to the adaptation to chronic cholestasis due to extrahepatic obstruction. ASBT is acutely regulated by an adenosine 3', 5'-monophosphate (cAMP)-dependent translocation to the apical membrane and by phosphorylation-dependent ubiquitination and proteasome degradation. ASBT is chronically regulated by changes in gene expression in response to biliary bile acid concentration and inflammatory cytokines. Another potential function of cholangiocyte ASBT is to allow cholangiocytes to sample biliary bile acids in order to activate intracellular signaling pathways. Bile acids trigger changes in intracellular calcium, protein kinase C (PKC), phosphoinositide 3-kinase (PI3K), mitogen-activated protein (MAP) kinase and extracellular signal-regulated protein kinase (ERK) intracellular signals. Bile acids significantly alter cholangiocyte secretion, proliferation and survival. Different bile acids have differential effects on cholangiocyte intracellular signals, and in some instances trigger opposing effects on cholangiocyte secretion, proliferation and survival. Based upon these concepts and observations, the cholangiocyte has been proposed to be the principle target cell for bile acids in the liver.
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PMID:Bile acid interactions with cholangiocytes. 1677 12

Activation of protein kinase C (PKC) by phorbol 12-myristate 13-acetate (PMA) triggers cellular signals that lead to the activation of the transcription factor NF-kappaB (nuclear factor kappaB) in various cell types. In addition to NF-kappaB activation by short-time PMA treatment, here we report that the prolonged exposure of human colonic cancer epithelial cells treated with PMA can also lead to a persistent inhibition of NF-kappaB activation. PMA selectively causes the degradation of IkappaB kinases (IKKs) including IKK-gamma and IKK-beta, and subsequent inhibition of tumor necrosis factor (TNF) induced IKK and NF-kappaB activation in human colon cancer cell line HCT-116, but not in other gastrointestinal tract cells. The use of Ro-318220 and GO-6983, general PKC inhibitors as well as MG-132, a proteasome-specific inhibitor, abrogated PMA-induced degradation of IKK-gamma and recovered the activation of IKK by TNF, suggesting that IKK complex is predominantly degraded by the proteasome pathway in a PKC-dependent manner. We also found that IKK-gamma strongly associates with heat shock protein 90 (Hsp90) in HCT-116 cells, and that this interaction was dramatically reduced after exposure to PMA. Furthermore, high levels of Hsp90 expression and enhanced association with IKK were observed in human colon cancer tissues. Taken together, these results suggest that long-term activation of PKC by PMA inhibits NF-kappaB system in case of colon cancer cells by disrupting the interaction of IKK-gamma with Hsp90, which may represent a novel regulatory mechanism of PKC-dependent cellular differentiation and limited proliferation of colonic epithelial cells.
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PMID:Sustained activation of protein kinase C downregulates nuclear factor-kappaB signaling by dissociation of IKK-gamma and Hsp90 complex in human colonic epithelial cells. 1677 32

Targeted therapies focus on signaling pathways in cancer cells and other molecular processes involved in oncogenesis. Recent approaches affect the following major groups: the epidermal growth factor receptor (EGFR)-family, angiogenesis, the eicosanoid pathway, the PKC/ Ras/ MAPK pathway, the proteasome and inducers of apoptosis. Numerous phase I and II trials have provided promising results and recently, anti-EGFR and anti-VEGF treatments have proven their efficacy in phase III trials. However, others failed in phase III settings (e.g. PKC- and matrix metalloproteinase inhibitors) and it is a moot point, whether patients have been selected properly. The huge amount of new medications raises questions like when to use which strategy in which sequence. The successful implementation of targeted agents into clinical routine will depend on the verification of sufficient predictive markers, allowing their economically reasonable usage. In the current review the up-to-date knowledge concerning targeted therapies in NSCLC is summarized and their therapeutical potential is discussed.
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PMID:Targeted therapies in non-small cell lung cancer: proven concepts and unfulfilled promises. 1684 20

Antigenic peptides presented on MHC class I molecules to cytotoxic T-cells are generated in the cytosol by the 20S proteasome. Two activators PA28-alpha and PA28-beta, which are inducible by interferon-gamma (IFN-gamma), activate the latent 20S proteasome, thus playing an important role in the processing of MHC class I antigen. Molecular properties and function in the MHC class I antigen processing of PA28 have been well studied and documented in mammals while little is known in fish. In the present study, we reported the cloning of a PA28-beta gene homologue from the spleen of large yellow croaker (Pseudosciana crocea), an economically important marine fish (LycPA28-beta). The full-length cDNA of LycPA28-beta is 1133 nucleotides (nt) encoding a protein of 245 amino acids (aa), with a putative molecular weight of 27.7 kDa. The deduced protein shares 76, 69, 61, 60, 59, 57 and 57% sequence identity to sequences found in zebrafish, flounder, pig, rat, mouse, cattle and human, respectively. The deduced LycPA28-beta contains a PA28-beta subunit-specific insert in the region corresponding to the KEKE motif of the known PA28-alpha (Region B), a conserved activation loop (Region C) and a highly homologous C-terminal region among all three PA28 subunits (Region E), and a characteristic proline-rich motif (Region A) and a potential protein kinase C recognition site (Region D). Western blot analysis of various tissues indicated that LycPA28-beta was constitutively expressed in kidney, liver, spleen and intestine, and weakly expressed in muscle tissue, but not detected in gills, heart and brain. The LycPA28-beta expression was significantly up-regulated in kidney, liver, spleen, intestine and muscle tissues, and also induced in gills after 72 h of treatment with a viral micmic, polyinosinic polycytidynic acid (poly I:C). The transcriptional analysis of LycPA28-beta and MHC class I alpha-chain (alpha-chain) and beta(2)-microglobulin (beta(2)m) in spleens of poly I:C-induced large yellow croaker was further performed by RT-PCR. The results showed that the expression of LycPA28-beta and class I alpha-chain and beta(2)m genes was coordinately up-regulated by poly I:C, suggesting that induction of the MHC class I antigen processing and presentation pathway may be required for the antiviral immune response triggered poly I:C in large yellow croaker.
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PMID:Molecular cloning of proteasome activator PA28-beta subunit of large yellow croaker (Pseudosciana crocea) and its coordinated up-regulation with MHC class I alpha-chain and beta 2-microglobulin in poly I:C-treated fish. 1690 44

While the role of the ubiquitin-proteasome system (UPS) in regulating cellular processes continues to expand, the elucidation of its role in cardiac disease is just beginning. The UPS regulates pivotal processes at all levels of cardiac biology: from membrane-associated ion channels and receptors to downstream signaling intermediates and transcription factors. Moreover, the role of the UPS in maintaining cardiac protein quality control is emerging, as exemplified by its multiple interactions with the cardiac sarcomere and role in familial cardiomyopathies. The diversity of UPS regulation lies in E3 ligases, which specifically recognize targets and direct the ubiquitination process. In the context of disease, E3 ligase expression affects the severity of disease in both ischemia reperfusion injury and cardiac hypertrophy in vivo by modulating signaling intermediates. In ischemia-reperfusion injury, the activities of CHIP and MDM2 (both with E3 ligase activity) profoundly affect apoptosis regulation and severity of disease. In cardiac hypertrophy, Atrogin1 and MuRF1 attenuate cardiac hypertrophy by interacting with calcineurin and PKCepsilon, respectively. Additionally, MuRF1 and MDM2 interact with sarcomeric proteins (cTnI and Tcap, respectively) which may prove to be mechanisms by which hypertrophy is attenuated or protein quality modulated. All of these exciting new findings, however, must be taken in the context of disease regulation of the UPS components themselves. Key UPS components (e.g. ubiquitin, E1, E2, E3, proteasome) are themselves transcriptionally regulated in cardiac disease. Our understanding of the precise nature by which the UPS regulates key biological functions in cardiac disease has just begun.
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PMID:Into the heart: the emerging role of the ubiquitin-proteasome system. 1694 2

p21(cip1) inhibits S phase entry by binding to cyclin-cdk2 (cyclin-dependent kinase-2) complexes. The levels of p21(cip1) are rapidly induced after mitogenic stimulation of quiescent fibroblasts and then down-regulate as the cells reach late G(1) phase and activate cyclin E-cdk2. In this study, we have shown that pharmacological inhibition of protein kinase C (PKC), expression of dominant negative PKCdelta, or knockdown of PKCdelta with small interfering RNA elevates p21(cip1) protein levels in mouse embryo fibroblasts. This effect is selective, post-transcriptional, and proteasome-dependent but distinct from previously identified post-transcriptional control mechanisms involving cyclin D1 and Skp2. PKCdelta inhibition results in a reduced entry into S phase, and this effect is not detected in p21(cip1)-null cells. Thus, post-transcriptional destabilization of p21(cip1) appears to be a major mitogenic effect of PKCdelta in fibroblasts.
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PMID:Post-transcriptional destabilization of p21cip1 by protein kinase C in fibroblasts. 1704 52

Several isoforms of protein kinase C (PKC) are degraded by the ubiquitin-proteasome pathway after phorbol ester-mediated activation. However, little is known about the ubiquitin ligase (E3) that targets activated PKCs. We recently showed that an E3 complex composed of HOIL-1L and HOIP (LUBAC) generates linear polyubiquitin chains and induces the proteasomal degradation of a model substrate. HOIL-1L has also been characterized as a PKC-binding protein. Here we show that LUBAC preferentially binds activated conventional PKCs and their constitutively active mutants. LUBAC efficiently ubiquitinated activated PKC in vitro, and degradation of activated PKCalpha was delayed in HOIL-1L-deficient cells. Conversely, PKC activation induced cleavage of HOIL-1L and led to downregulation of the ligase activity of LUBAC. These results indicate that LUBAC is an E3 for activated conventional PKC, and that PKC and LUBAC regulate each other for proper PKC signaling.
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PMID:Mutual regulation of conventional protein kinase C and a ubiquitin ligase complex. 1706 64

The diet-derived cancer preventive agent, curcumin, inhibits skin cancer cell proliferation and tumor formation. However, its effect on normal human keratinocyte differentiation, proliferation, and apoptosis has not been adequately studied. Involucrin (hINV) is a marker of keratinocyte differentiation and a useful model for the study of chemopreventive agent action. We show that curcumin suppresses the differentiation agent-dependent activation of hINV gene expression and that an AP1 transcription factor DNA binding site in the hINV gene is required for this regulation. A protein kinase C, Ras, MEKK1, MEK3 signaling cascade controls hINV expression by regulating AP1 factor level. Curcumin treatment inhibits the novel protein kinase C-, Ras-, and MEKK1-dependent activation of hINV promoter activity and reduces the differentiation agent-dependent increase in AP1 factor level and DNA binding. This reduction requires proteasome function. In addition, curcumin treatment reduces cell number, which is associated with a reduced cyclin and cdk1 levels. Curcumin treatment also suppresses the Bcl-xL level, leading to reduced mitochondrial membrane potential and increased cleavage of procaspases and poly(ADP-ribose) polymerase. These studies provide important insights regarding the mechanism whereby curcumin acts as a chemopreventive agent in normal human epidermis.
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PMID:Curcumin suppresses AP1 transcription factor-dependent differentiation and activates apoptosis in human epidermal keratinocytes. 1714 46

The aim of the present study was to gain a deeper insight into the cell signaling pathways involved in the neuroprotection/neurorescue activity of the major green tea polyphenol (-)-epigallocatechin-3-gallate (EGCG). EGCG (1 micro m) caused an immediate (30 min) down-regulation (approximately 40%) of Bad protein levels, and a more pronounced reduction after 24 h (55%) in the human neuroblastoma cell line SH-SY5Y. Co-treatment with EGCG and the protein synthesis inhibitor cycloheximide prominently shortened Bad half-life, with as little as 30% of the Bad protein content remaining after 2 h, suggesting an effect of EGCG on Bad protein degradation. Accordingly, the proteasome inhibitors MG-132 and lactacystin damped Bad down-regulation by EGCG. The general protein kinase C (PKC) inhibitor GF109203X, or the down-regulation of conventional and novel PKC isoforms, abolished EGCG-induced Bad decline. However, no inhibition was seen with the cell-permeable myristoylated pseudosubstrate inhibitor of the atypical PKCzeta isoform. The enforced expression of Bad for up to 72 h rendered the cells more susceptible to serum deprivation-induced cell death, whereas EGCG treatment significantly improved cell viability (up to 1.6-fold). The present study reveals a novel pathway in the neuroprotective mechanism of the action of EGCG, which involves a rapid PKC-mediated degradation of Bad by the proteasome.
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PMID:Green tea polyphenol (-) -epigallocatechin-3-gallate promotes the rapid protein kinase C- and proteasome-mediated degradation of Bad: implications for neuroprotection. 1715 30

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