EC:2.7.11.1 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.7.11.1 (protein kinase)
81,284 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The relationship between NS protein phosphorylation and RNA polymerase activities was determined in nucleocapsids purified from vesicular stomatitis virus grown in BHK cells. Phosphate incorporation into endogenous NS protein under transcription conditions reached a maximum value of 0.06 mol/mol of NS within 20 to 30 min, while RNA synthesis remained linear for 90 min. Phosphate incorporation into NS increased further upon addition of kinase-free NS protein but not upon addition of nucleocapsid kinase (prepared as described below), indicating that cessation of NS phosphorylation under transcribing conditions was due to substrate exhaustion. When NS was phosphorylated with 32P, less than 8% of the radiolabel was lost during subsequent transcription, indicating that this phosphate did not turn over. Treatment of nucleocapsids with 5'-p-fluorosulfonylbenzoyl adenosine resulted in greater than 90% inhibition of NS phosphorylation but had no effect on RNA polymerase activity. Fast protein liquid (Superose-6) chromatography of a nucleocapsid (L + NS) fraction resulted in complete separation of the viral (L + NS) protein from NS-phosphorylating activity. The addition of this kinase-free (L + NS) fraction to a kinase-deficient N-RNA fraction reconstituted an active RNA polymerase containing less than 20% of the original NS-phosphorylating activity. These results demonstrate that NS-phosphorylating activity is unnecessary during vesicular stomatitis virus RNA synthesis and indicate that all of the protein kinase(s) present in purified nucleocapsids is probably of cellular rather than viral origin.
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PMID:Phosphorylation of NS protein by vesicular stomatitis virus nucleocapsids: lack of effect during RNA synthesis and separation of kinase from L protein. 216 40

1. Modulation of fast and slow Ca2+ channels of frog skeletal muscle by adrenaline (10(-6) to 10(-5) M) and cyclic AMP was investigated using intracellular voltage recordings in intact fibres and a voltage-clamp technique in cut fibres. 2. In tetraethylammonium (TEA), Cl(-)-free Ringer solution, adrenaline increased the maximum rate of rise of Ca2+ spikes by 85% and in a similar solution, peak slow Ca2+ current (ICa,s) by 51%. 3. Application of cyclic AMP to the cut ends of fibres, produced a relative increase of ICa,s of ca. 24%. The effect was maintained for ca. 2 h. 4. Changes in the time course of ICa,s were produced by adrenaline and cyclic AMP: the limiting values of time-to-peak current measured as a function of membrane potential were lower (ca. 41% in adrenaline and ca. 34% in cyclic AMP) than those found in control experiments. Also, ICa,s decayed faster in the presence of adrenaline or cyclic AMP. These changes can be explained by exhaustion of Ca2+ in the lumen of transverse tubular system and do not require the assumption of kinetic variations. 5. Fast Ca2+ currents (ICa,f) which could not be blocked by nifedipine were also recorded. Cyclic AMP greatly increased the amplitude of ICa,f but had no obvious effects on ICa,f kinetics. 6. Application of catalytic subunit of cyclic AMP-dependent protein kinase by diffusion or by pressure injection also increased the amplitude of ICa,s and ICa,f. Pressure injection brought about modifications in the time course of ICa,s that cannot be explained by depletion of Ca2+. 7. Mechanical experiments were performed on single fibres. Nominally Ca2+-free solutions prevented the development and the maintenance of positive inotropic effect of adrenaline on twitch tension. Development of twitch potentiation was dependent upon the frequency of stimulation. Adrenaline was practically ineffective if no stimulation was applied. 8. It is concluded that both populations of Ca2+ channels are modulated by adrenergic stimulation probably via cyclic AMP, and that twitch potentiation may be mediated by a Ca2+ entry through Ca2+ channels.
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PMID:Modulation of calcium channels of twitch skeletal muscle fibres of the frog by adrenaline and cyclic adenosine monophosphate. 245 39

Follicular cells from Xenopus oocytes offer a particularly interesting system to study ATP-sensitive K+ channels (KATP channels). In these cells, as in many other cell types, glibenclamide is a classical blocker of KATP channels. Metabolic inhibition with dinitrophenol (DNP) converts this inhibitory effect into an activation. Follicular cells treated with DNP keep their sensitivity to the KATP channel opener P1060, but this opening effect becomes insensitive to glibenclamide inhibition. Glibenclamide activation of KATP channels in DNP-treated follicular cells occurs with an EC50 of 3 microM. Glibenclamide activation is antagonized by blockers of KATP channels that do not belong to the sulfonylurea family, such as U-37883A, tedisamil, and LH 35. Other sulfonylureas display the same activating behavior as does glibenclamide in DNP-treated cells. Two of the properties of KATP channels in follicular cells are activation by cAMP through protein kinase A and inhibition by muscarinic effectors through protein kinase C activation. The stimulating effects of cAMP and glibenclamide in DNP-treated cells seem to be synergistic as are the cAMP and P1060 effects in control follicular cells. Glibenclamide-activated KATP channels in DNP-treated cells (conductance of 15 pS) are also inhibited by acetylcholine and by phorbol esters. The internal acidosis produced by metabolic exhaustion with DNP appears to be the key element in the conversion of glibenclamide from a blocker to an activator of KATP channels.
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PMID:Glibenclamide opens ATP-sensitive potassium channels in Xenopus oocyte follicular cells during metabolic stress. 770 Feb 56

To analyze the mechanisms of glycogen phosphorylase control in organs of the rainbow trout Oncorhynchus mykiss, activities of glycogen phosphorylase kinase (GPK) and cAMP-dependent protein kinase (PKA), as well as levels of cAMP, were quantified. The complete cascade for activating glycogen phosphorylase was present in trout organs and all components were activated in white skeletal muscle and liver during exhaustive swimming exercise. GPK and PKA showed the highest activities in the liver, being three- and four-fold higher than corresponding activities in white muscle. Exercise stimulated a 60% increase in GPK activity in the liver and a 40% rise in white muscle. Furthermore, the amount of active PKA rose from 12 to 21% in the liver and from 32 to 57% in white muscle after exhaustive exercise and the cellular levels of cAMP increased by 50% in the liver and 70% in white muscle of exercised fish. Other organs (heart, gill, brain, kidney) showed little or no change in these parameters as a result of exhaustive exercise. GPK activity in liver, muscle, and heart extracts was strongly stimulated by in vitro incubation with the catalytic subunit of mammalian PKA, activity rising by 6- to 7-fold in white muscle extracts and 2- to 2.6-fold in liver and heart extracts. This occurred in extracts from both control and exercised fish and suggested that even in fish exercised to exhaustion, the maximal enzymatic potential for activation of glycogenolysis was not expressed.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Control of glycogenolysis and effects of exercise on phosphorylase kinase and cAMP-dependent protein kinase in rainbow trout organs. 819 87

Cellular replicative senescence is a permanent growth arrest state that can be triggered by telomere shortening. The cyclin-dependent kinase (Cdk) inhibitor p21(CIP1/WAF1) (p21), encoded by the CDKN1A gene, is a critical cell cycle regulator whose expression increases as cells approach senescence. Although the pathways responsible for its up-regulation are not well understood, compelling evidence indicates that the upstream triggering event is telomere dysfunction. Studies of replicative senescence have been complicated by the asynchrony of its onset, which is caused by the continuous and stochastic variability in individual cell lifespans. In fact, the actual entry into senescence has never been observed in a single unperturbed cell. We report here a new in vitro human model system that allows entry into senescence to be monitored in real-time in individual viable cells. We used homologous recombination to generate non-immortalized fibroblast cells with the enhanced yellow fluorescence protein (EYFP) gene knocked into one CDKN1A gene copy, allowing promoter activity to be visualized as fluorescence intensity. Gamma irradiation, DNA-damaging drugs, expression of p14(ARF) or oncogenic Ras, and replicative exhaustion all resulted in elevated EYFP expression, demonstrating its proper control by physiological signalling circuits. Analysis by time-lapse microscopy of cultures approaching replicative senescence revealed that p21 levels rise abruptly in individual aging cells and remain elevated for extended periods of time.
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PMID:Real-time imaging of transcriptional activation in live cells reveals rapid up-regulation of the cyclin-dependent kinase inhibitor gene CDKN1A in replicative cellular senescence. 1467 32

The transcriptional program of yeast cells undergoes dramatic changes during the shift from fermentative growth to respiratory growth. A large part of this response is mediated by the stress responsive transcription factor Msn2. During glucose exhaustion, Msn2 is activated and concentrated in the nucleus. Simultaneously, Msn2 protein levels also drop significantly under this condition. Here we show that the decrease in Msn2 concentration is due to its increased degradation. Moreover, Msn2 levels are also reduced under chronic stress or low protein kinase A (PKA) activity, both conditions that cause a predominant nuclear localization of Msn2. Similar effects were found in msn5 mutant cells that block Msn2 nuclear export. To approximate the effect of low PKA activity on Msn2, we generated a mutant form with alanine substitutions in PKA phosphorylation sites. High expression of this Msn2 mutant is detrimental for growth, suggesting that the increased degradation of nuclear Msn2 might be necessary to adapt cells to low PKA conditions after the diauxic shift or to allow growth under chronic stress conditions.
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PMID:Nuclear localization destabilizes the stress-regulated transcription factor Msn2. 1550 60

In response to nutrient limitation, Saccharomyces cerevisiae cells enter into a non-proliferating state termed quiescence. This transition is associated with profound changes in gene expression patterns. The adenine deaminase encoding gene AAH1 is among the most precociously and tightly downregulated gene upon entry into quiescence. We show that AAH1 downregulation is not specifically due to glucose exhaustion but is a more general response to nutrient limitation. We also found that Aah1p level is tightly correlated to RAS activity indicating thus an important role for the protein kinase A pathway in this regulation process. We have isolated three deletion mutants, srb10, srb11 and saf1 (ybr280c) affecting AAH1 expression during post-diauxic growth and in early stationary phase. We show that the Srb10p cyclin-dependent kinase and its cyclin, Srb11p, regulate AAH1 expression at the transcriptional level. By contrast, Saf1p, a previously uncharacterized F-box protein, acts at a post-transcriptional level by promoting degradation of Aah1p. This post-transcriptional regulation is abolished by mutations affecting the proteasome or constant subunits of the SCF (Skp1-Cullin-F-box) complex. We propose that Saf1p targets Aah1p for proteasome-dependent degradation upon entry into quiescence. This work provides the first direct evidence for active degradation of proteins in quiescent yeast cells.
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PMID:Proteasome- and SCF-dependent degradation of yeast adenine deaminase upon transition from proliferation to quiescence requires a new F-box protein named Saf1p. 1667 11

Excessive copper concentrations, known to induce reactive oxygen species (ROS) formation, have been tested with respect to their effects on transcript abundance and related proteins involved in oxidative stress responses. The results show that the stromal photosynthetic functions were more ROS sensitive than the membrane-located reactions. The rbcL over-expression compensated for the damage only at 10 microM Cu, whereas the genetic stimulation of alpha-tocopherol biosynthesis led to the protection of membrane reactions up to 50-100 microM Cu. For this reason, the gradual growth drop of Chlamydomonas reinhardtii cultures observed under increasing Cu(2+) concentrations matched better with the loss of photosynthetic capacity than with those of photosynthetic quantum yields. According to Larcher's stress concept, the results allow the identification of gene markers for the alarm (rbcL), the hardening (FeSOD, VTE3) and the exhaustion [cyclin-dependent protein kinase (cdk), psbA] phases. These genes can be used to rapidly evaluate the state of oxidative stress in algae and putatively in other plant cells.
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PMID:Parallel analysis of transcript levels and physiological key parameters allows the identification of stress phase gene markers in Chlamydomonas reinhardtii under copper excess. 1708 Dec 40

Alterations in myocardial glucose metabolism are a key determinant of ischemia-induced depression of left ventricular mechanical function. Since myocardial glycogen is an important source of endogenous glucose, we compared the effects of ischemia on glucose uptake and utilization in isolated working rat hearts in which glycogen content was either replete (G replete, 114 micromol/g dry wt) or partially depleted (G depleted, 71 mumol/g dry wt). The effects of low-flow ischemia (LFI, 0.5 ml/min) on glucose uptake, glycogen turnover (glycogenolysis and glycogen synthesis), glycolysis, adenosine 5'-monophosphate-activated protein kinase (AMPK) activity, and GLUT4 translocation were measured. Relative to preischemic values, LFI caused a time-dependent reduction in glycogen content in both G-replete and G-depleted groups due to an acceleration of glycogenolysis (by 12-fold and 6-fold, respectively). In G-replete hearts, LFI (15 min) decreased glucose uptake (by 59%) and did not affect GLUT4 translocation. In G-depleted hearts, LFI also decreased initially glucose uptake (by 90%) and glycogen synthesis, but after 15 min, when glycogenolysis slowed due to exhaustion of glycogen content, glucose uptake increased (by 31%) in association with an increase in GLUT4 translocation. After 60 min of LFI, glucose uptake, glycogenolysis, and glycolysis recovered to near-preischemic values in both groups. LFI increased AMPK activity in a time-dependent manner in both groups (by 6-fold and 4-fold, respectively). Thus, when glycogen stores are replete before ischemia, ischemia-induced AMPK activation is not sufficient to increase glucose uptake. Under these conditions, an acceleration of glycogen degradation provides sufficient endogenous substrate for glycolysis during ischemia.
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PMID:Ischemia-induced activation of AMPK does not increase glucose uptake in glycogen-replete isolated working rat hearts. 1817 21

The role of cytokines in regulation of hematopoietic stem cells (HSCs) remains poorly understood. Herein we demonstrate that thrombopoietin (THPO) and its receptor, MPL, are critically involved in postnatal steady-state HSC maintenance, reflected in a 150-fold reduction of HSCs in adult Thpo(-/-) mice. Further, whereas THPO and MPL proved not required for fetal HSC expansion, HSC expansion posttransplantation was highly MPL and THPO dependent. The distinct role of THPO in postnatal HSC maintenance is accompanied by accelerated HSC cell-cycle kinetics in Thpo(-/-) mice and reduced expression of the cyclin-dependent kinase inhibitors p57(Kip2) and p19(INK4D) as well as multiple Hox transcription factors. Although also predicted to be an HSC viability factor, BCL2 failed to rescue the HSC deficiency of Thpo(-/-) mice. Thus, THPO regulates posttransplantation HSC expansion as well as the maintenance of adult quiescent HSCs, of critical importance to avoid postnatal HSC exhaustion.
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PMID:Critical role of thrombopoietin in maintaining adult quiescent hematopoietic stem cells. 1837 99

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