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 exogenous addition of the catalytic subunit of cAMP-dependent protein kinase (PKA), cGMP-dependent protein kinase (PKG), or calmodulin (CaM) induced rapid phosphorylation of the ryanodine receptor (Ca2+ release channel) in canine cardiac microsomes treated with 1 mM [gamma-32P]ATP. Added protein kinase C (PKC) also phosphorylated the cardiac ryanodine receptor but at a relatively slow rate. The observed level of PKA-, PKG-, or PKC-dependent phosphorylation of the ryanodine receptor was comparable to the maximum level of [3H]ryanodine binding in cardiac microsomes, whereas the level of CaM-dependent phosphorylation was about 4 times greater. Phosphorylation by PKA, PKG, and PKC increased [3H]ryanodine binding in cardiac microsomes by 22 +/- 5, 17 +/- 4, and 15 +/- 9% (average +/- SD, n = 4-5), respectively. In contrast, incubation of microsomes with 5 microM CaM alone and 5 microM CaM plus 1 mM ATP decreased [3H]ryanodine binding by 38 +/- 14 and 53 +/- 15% (average +/- SD, n = 6), respectively. Phosphopeptide mapping and phosphoamino acid analysis provided evidence suggesting that PKA, PKG, and PKC predominantly phosphorylate serine residue(s) in the same phosphopeptide (peptide 1), whereas the endogenous CaM-kinase phosphorylates serine residue(s) in a different phosphopeptide (peptide 4). Photoaffinity labeling of microsomes with photoreactive 125I-labeled CaM revealed that CaM bound to a high molecular weight protein, which was immunoprecipitated by a monoclonal antibody against the cardiac ryanodine receptor. These results suggest that protein kinase-dependent phosphorylation and CaM play important regulatory roles in the function of the cardiac sarcoplasmic reticulum Ca2+ release channel.
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PMID:Regulation of the cardiac ryanodine receptor by protein kinase-dependent phosphorylation. 184 85

A computer-assisted sequence analysis of the ryanodine receptor pointed to a 15-residue peptide, "KC7", reported to have been purified from a proteolytic digest of the 565 kDa rabbit skeletal muscle protein. Sequence comparisons, however, showed that this peptide probably originated from a much smaller protein which copurified with the ryanodine receptor. Peptide KC7 (excluding its unknown N-terminal residue) was identical to the N-terminus of a 12 kDa immunophilin (immunosupressant-binding protein), human T-cell FK506- binding protein (FKBP), which has recently been identified as an inhibitor of protein kinase C. There was no other sequence similarity between FKBP and the ryanodine receptor. It is suggested that in vivo interaction of the ryanodine receptor and FKBP may play a role in the modulation of calcium release in muscle.
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PMID:Sequence analysis of the ryanodine receptor: possible association with a 12K, FK506-binding immunophilin/protein kinase C inhibitor. 187 49

Intracellular Ca2+ release channels are key players in the regulation of Ca2+ homeostasis. In the present study, we investigated the age-related changes of inositol 1,4,5-trisphosphate (IP3) receptor/Ca2+ release channel and ryanodine receptor/Ca2+ release channel in microsomes derived from either cerebellum or cerebrum cortex from male Wistar rats. A significant reduction (about 50%) in density of IP3 receptor/Ca2+ release channels was observed in cerebrum cortex, only, in 8- and 28-month old rats, whereas density and Kd of ryanodine binding sites were unaffected in both cerebellum and cerebrum microsomes. These findings, along with impairment of Ca(2+)-dependent protein kinase C phosphorylation of endogeneous substrates, point to coordinate, quantitative alterations of both targets of phosphoinositide metabolism, i.e., PKC and IP3 receptor, in the cerebrum cortex at least. The relevance of the present findings is discussed in relation to reported changes of neuronal Ca2+ homeostasis during aging.
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PMID:Inositol 1,4,5-trisphosphate receptor and ryanodine receptor in the aging brain of Wistar rats. 783 92

Activation of a calmodulin (CaM)-dependent protein kinase associated with rabbit skeletal-muscle sarcoplasmic reticulum (SR) results in the phosphorylation of polypeptides of 450, 360, 165, 105, 89, 60, 34 and 20 kDa. Radioligand-binding studies indicated that a membrane-bound 60 kDa polypeptide contained both CaM- and ATP-binding domains. Under renaturing conditions on nitrocellulose blots, the 60 kDa polypeptide of the membrane exhibited CaM-dependent autophosphorylation activity, suggesting that it was the CaM-dependent protein kinase of SR. Ca2+/CaM-independent autophosphorylation of polypeptides of 62 and 45 kDa was found to occur in the light SR, whereas the Ca2+/CaM-dependent autophosphorylation activity was enriched in the heavy SR. Both these kinase activities were absent from transverse tubules, although these membranes were enriched in CaM-binding polypeptides of 160, 100 and 80 kDa. In the absence of Ca2+, CaM bound to a 33 kDa polypeptide of the membrane. The purified ryanodine receptor was not phosphorylated by the purified CaM kinase, although it was a substrate for protein kinase C. Affinity-purified antibodies to brain CaM kinase II cross-reacted with the 60 kDa polypeptide in Western blots and immunoprecipitated the 60 kDa polypeptide, along with the 360, 105, 89, 34 and 20 kDa phosphoproteins, from Nonidet-P-40-solubilized SR membranes. Antibodies raised against the 60 kDa kinase polypeptide did not cross-react with the other phosphoproteins, suggesting that these polypeptides were distinct and unrelated. Subcellular distribution of the 60 kDa kinase indicated the specific association of the polypeptide with the junctional-face membrane of SR. The CaM-dependent incorporation of 32P into various membrane proteins was inhibited by the CaM kinase II fragment (290-309), with an IC50 value of 2 nM for the inhibition of incorporation into the 60 kDa kinase polypeptide. Recent studies [Wang and Best (1992) Nature (London) 359, 739-741] have shown that a CaM kinase activity intrinsic to the membrane can inactivate the Ca(2+)-release channel of skeletal muscle SR. Since our results demonstrate that the 60 kDa polypeptide of SR is a CaM-dependent protein kinase, we suggest that this kinase, through its associations, may be responsible for gating the Ca(2+)-release channel.
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PMID:A 60 kDa polypeptide of skeletal-muscle sarcoplasmic reticulum is a calmodulin-dependent protein kinase that associates with and phosphorylates several membrane proteins. 824 Mar 1

We previously found in single channel studies that ryanodine receptor (RyR) channel activity can be made insensitive to block by Mg2+ when terminal cisternae of sarcoplasmic reticulum, incorporated into planar bilayers, are treated with protein kinase A (PKA) or Ca2+/calmodulin dependent protein kinase type II (CamPK II), and then again made sensitive by treatment with protein phosphatases [Hain J. Nath S. Mayrleitner M. Fleischer S. Schindler H. (1994) Phosphorylation modulates the function of the calcium release channel of sarcoplasmic reticulum from skeletal muscle. Biophys. J., 67, 1823-1833]. In this study, modulation by protein kinases and phosphatases on net Ca2+ uptake by TC is presented. Phosphorylation of TC vesicles with PKA, CamPK II, or protein kinase C (PKC) reduced the calcium loading rate of TC vesicles 3-fold, 2.1-fold and 1.7-fold, respectively, measured in the presence of 1 mM MgCl2. There is no effect when AMP-PNP is substituted for ATP. Phosphorylation of the RyR was also measured by incorporation of [gamma-32P]-phosphate from ATP. A phosphorylation stoichiometry of 1.94 +/- 0.1 (32P/RyR) for PKA, 0.89 +/- 0.08 for CamPK II and 0.95 +/- 0.16 for PKC was obtained under these conditions. A study of the time dependence of phosphorylation with PKA and CamPK shows a direct correlation of reduction in calcium loading rate with increased phosphorylation of the ryanodine receptor. Treatment with protein phosphatase 1 enhanced the calcium loading rate again, after it was reduced by PKA phosphorylation. Investigation of the magnesium dependency shows that even at higher [Mg2+] (6 mM), PKA phosphorylated TC vesicles have a 2.3-fold reduced calcium loading rate indicating insensitivity to block by Mg2+.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Phosphorylation with protein kinases modulates calcium loading of terminal cisternae of sarcoplasmic reticulum from skeletal muscle. 852 60

Two types of ADP-ribosyl cyclase activity were distinguished in dog and rat cardiac muscles by measuring the enzymatic conversion of NGD (as an NAD analog) into the fluorescent product cyclic GDP-ribose in cardiac muscle subcellular fractions. Both types of activity were confined to membrane fractions isolated from microsomes by sucrose gradient centrifugation. One of the activities co-purified with fractions that were enriched in sarcolemma (SLM), as evidenced by immunodetection of the dihydropyridine receptor, while the other activity was found to co-precipitate with the sarcoplasmic reticulum (SR), that was identified on the basis of its immuno-staining with a ryanodine receptor monoclonal antibody. In certain aspects, the plasma membrane-bound ADP-ribosyl cyclase activity resembled the characteristics of CD38 or CD38-like proteins: it was sensitive to thiols and lectins and was recognized by a monoclonal anti CD38 antibody. The SR enzyme had apparently distinct properties, as it was insensitive to both thiols and lectins and was not recognized by the CD38 antibody. In addition, the SR-associated ADP-ribosyl cyclase was inhibited by endogenous protein kinase C (PKC)-dependent phosphorylation in both dog and rat cardiac SR. The PKC-modulated SR ADP-ribosyl cyclase we describe here might be a principal component of the signal transduction machinery that is responsible for regulation of the intracellular levels of cADPR.
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PMID:Sarcoplasmic reticulum-associated and protein kinase C-regulated ADP-ribosyl cyclase in cardiac muscle. 916 98

Signal transduction in gastric and intestinal smooth muscle is mediated by receptors coupled via distinct G proteins to various effector enzymes, including PI-specific PLC-beta 1 and PLC-beta 3, and phosphatidylcholine (PC)-specific PLC, PLD and PLA2. Activation of these enzymes is different in circular and longitudinal muscle cells, generating Ca(2+)-mobilizing (IP3, AA, cADPR) and other (DAG) messengers responsible for the initial and sustained phases of contraction, respectively. IP3-dependent Ca2+ release occurs only in circular muscle. Ca2+ mobilization in longitudinal muscle involves a cascade initiated by agonist-induced transient activation of PLA2 and formation of AA, AA-dependent depolarization of the plasma membrane and opening of voltage-sensitive Ca2+ channels. The influx of Ca2+ induces Ca2+ release by activating sarcoplasmic ryanodine receptor/Ca2+ channel and stimulates cADPR formation which enhances Ca(2+)-induced Ca2+ release. The initial [Ca2+]i transient in both muscle cell types results in Ca2+/calmodulin-dependent activation of MLC kinase, phosphorylation of MLC20 and interaction of actin and myosin. The sustained phase is mediated by a Ca(2+)-independent isoform of PKC, PKC-epsilon DAG for this process is generated by PLC- and PLD-mediated hydrolysis of PC. Relaxation is mediated by cAMP-and/or cGMP-dependent protein kinase which inhibit the initial [Ca2+]i transient and reduce the sensitivity of MLC kinase to [Ca2+]i. Relaxation induced by the main neurotransmitters, VIP and PACAP, involves two cascades, one of which reflects activation of adenylyl cyclase. A distinct cascade involves G-protein-dependent stimulation of Ca2+ influx leading to Ca2+/calmodulin-dependent activation of a constitutive eNOS in muscle cells; the generation of NO activates soluble guanylyl cyclase. The resultant activation of PKA and PKG is jointly responsible for muscle relaxation.
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PMID:Signal transduction in gastrointestinal smooth muscle. 921 27

Synaptic changes that underlie associative learning and memory begin with temporally related activity of two or more independent synaptic inputs to common postsynaptic targets. In turn, temporally related molecular events regulate cytosolic Ca2+ during progressively longer-lasting time domains. Associative learning behaviors of living animals have been correlated with changes of neuronal voltage-dependent K+ currents, protein kinase C-mediated phosphorylation and synthesis of the Ca2+ and GTP-binding protein, calexcitin (CE),and increased expression of the Ca2+-releasing ryanodine receptor (type II). These molecular events, some of which have been found to be dysfunctional in Alzheimer's disease, provide means of altering dendritic excitability and thus synaptic efficacy during induction, consolidation and storage of associative memory. Apparently, such stages of behavioral learning correspond to sequential differences of Ca2+ signaling that could occur in spatially segregated dendritic compartments distributed across brain structures, such as the hippocampus.
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PMID:Time domains of neuronal Ca2+ signaling and associative memory: steps through a calexcitin, ryanodine receptor, K+ channel cascade. 988 51

Local calcium transients ('Ca2+ sparks') are thought to be elementary Ca2+ signals in heart, skeletal and smooth muscle cells. Ca2+ sparks result from the opening of a single, or the coordinated opening of many, tightly clustered ryanodine receptor (RyR) channels in the sarcoplasmic reticulum (SR). In arterial smooth muscle, Ca2+ sparks appear to be involved in opposing the tonic contraction of the blood vessel. Intravascular pressure causes a graded membrane potential depolarization to approximately -40 mV, an elevation of arterial wall [Ca2+]i and contraction ('myogenic tone') of arteries. Ca2+ sparks activate calcium-sensitive K+ (KCa) channels in the sarcolemmal membrane to cause membrane hyperpolarization, which opposes the pressure induced depolarization. Thus, inhibition of Ca2+ sparks by ryanodine, or of KCa channels by iberiotoxin, leads to membrane depolarization, activation of L-type voltage-gated Ca2+ channels, and vasoconstriction. Conversely, activation of Ca2+ sparks can lead to vasodilation through activation of KCa channels. Our recent work is aimed at studying the properties and roles of Ca2+ sparks in the regulation of arterial smooth muscle function. The modulation of Ca2+ spark frequency and amplitude by membrane potential, cyclic nucleotides and protein kinase C will be explored. The role of local Ca2+ entry through voltage-dependent Ca2+ channels in the regulation of Ca2+ spark properties will also be examined. Finally, using functional evidence from cardiac myocytes, and histological evidence from smooth muscle, we shall explore whether Ca2+ channels, RyR channels, and KCa channels function as a coupled unit, through Ca2+ and voltage, to regulate arterial smooth muscle membrane potential and vascular tone.
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PMID:Ca2+ channels, ryanodine receptors and Ca(2+)-activated K+ channels: a functional unit for regulating arterial tone. 988 80

The tiny suprachiasmatic nucleus (SCN) of the hypothalamus plays a central role in the daily programming of organismic functions by regulating day-to-day oscillations of the internal milieu and synchronizing them to the changing cycles of day and night and of body state. This biological clock drives the daily expression of vital homeostatic functions as diverse as feeding, drinking, body temperature, and neurohormone secretion. It adaptively organizes these body functions into near-24-hour oscillations termed circadian rhythms. The SCN imposes temporal order 1) through generating output signals that relay time-of-day information, and 2) through gating its own sensitivity to incoming signals that adjust clock timing. Each of these properties, derived from the timebase of the SCN's endogenous near-24-hour pacemaker, persists when the SCN is maintained in a hypothalamic brain slice in vitro. Single-unit recording experiments demonstrate a spontaneous peak in the electrical activity of the ensemble of SCN neurons near midday. By utilizing this time of peak as a "pulse" of the clock, we have characterized a series of time domains, or windows of sensitivity, in which the SCN restricts its own sensitivity to stimuli that are capable of adjusting clock phase. Pituitary adenylyl cyclase-activating peptide (PACAP) and cAMP comprise agents that reset clock phase during the day time domain; both PACAP and membrane-permeable cAMP analogs cause phase advances only when applied during the day. In direct contrast to PACAP and cAMP, acetylcholine and cGMP analogs phase advance the clock only when applied during the night. Sensitivity to light and glutamate arises concomitant with sensitivity to acetylcholine and cGMP. Light and glutamate cause phase delays in the early night, by acting through elevation of intracellular Ca2+, mediated by activation of a neuronal ryanodine receptor. In late night, light and glutamate utilize a cGMP-mediated mechanism to induce phase advances. Finally, crepuscular domains, or dusk and dawn, are characterized by sensitivity to phase resetting by the pineal hormone, melatonin, acting through protein kinase C. Our findings indicate that the gates to both daytime and nighttime phase resetting lie beyond the level of membrane receptors; they point to critical gating within the cell, downstream from second messengers. The changing patterns of sensitivities in vitro demonstrate that the circadian clock controls multiple molecular gates at the intracellular level, to assure that they are selectively opened in a permissive fashion only at specific points in the circadian cycle. Discerning the molecular mechanisms that generate these changes is fundamental to understanding the integrative and regulatory role of the SCN in hypothalamic control of organismic rhythms.
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PMID:Suprachiasmatic nucleus: the brain's circadian clock. 1054 71

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