EC:3.6.1.3 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The purpose of this study was to see whether the receptor for cardiac glycosides might be localized upon or within the plasma membrane of digitalis-sensitive cells. Ouabain and digoxin were joined covalently to several large protein molecules. These macromolecular conjugates are too large to enter intact cells; consequently, any pharmacologic or biochemical effects which they display should arise from interaction with a cell surface receptor. Conjugates were tested in several cardiac glycoside-sensitive systems: (a), contractility response of isolated cardiac muscle; (b), active (86)Rb(+) uptake by red cells; (c), enzymatic activity of isolated myocardial microsomal (Na(+) + K(+))-activated adenosine triphosphatase (ATPase); and (d), enzymatic activity of solubilized red cell (Na(+) + K(+))-activated ATPase. Results demonstrated that in all of these systems, the macromolecular-glycoside conjugates were 100- to 1000-fold less active than the free glycosides. Careful chromatographic examination of the various conjugates revealed that they contained a small but persistent free cardiac glycoside contaminant. The amount of this species ranged from 0.1 to 1.0% of the total macromolecule-bound glycoside, and its presence fully explains the levels of biologic activity observed with the conjugates. To try to minimize steric factors which could interfere with glycoside-receptor interaction, digoxin and ouabain were also coupled to macromolecule via long, flexible polyamide side-chains. These extended chain conjugates, in which the cardiac glycoside potentially lay some 30 A removed from the surface of the macromolecule, also exhibited negligible digitalis-like effects when tested upon isolated cardiac muscle, red cell (86)Rb(+) uptake, and enzymatic activity of cardiac microsomal (Na(+) + K(+))-ATPase. However, the extended chain conjugates were fully active when examined with the solubilized red cell (Na(+) + K(+))-ATPase system. To further ensure that the chemical reactions used to couple macromolecule to glycoside did not inactivate the drug, all conjugates were subjected to extensive proteolytic digests exhibited full pharmacologic activity. Digoxin was also coupled to the tripeptide alanylglycylglycine, and the resulting conjugate was fully active. Taken together, these results suggest that if the receptor(s) for cardiac glycosides is associated with the plasma membrane, then it may lie deep within it.
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PMID:Studies on the localization of the cardiac glycoside receptor. 426 Jun 87

Insulin stimulated the uptake of 86Rb+ (a K+ analog) in rat adipocytes and increased the steady state concentration of intracellular potassium. Half-maximal stimulation occurred at an insulin concentration of 200 pM. Both basal- and insulin-stimulated 86Rb+ transport rates depended on the concentration of external K+, external Na+, and were 90% inhibited by 10(-3) M ouabain and 10(-3) M KCN, indicating that the hormone was activating the (Na+,K+)-ATPase. Insulin had no effect on the entry of 22Na+ or exit of 86Rb+. Kinetic analysis demonstrated that insulin acted by increasing the maximum velocity, Vmax, of 86Rb+ entry. Inhibition of the rate of Rb+ uptake by ouabain was best described by a biphasic inhibition curve. Scatchard analysis of ouabain binding to intact cells indicated binding sites with multiple affinities. Only the rubidium transport sites which exhibited a high affinity for ouabain were stimulated by insulin. Stimulation required insulin binding to an intact cell surface receptor, as it was reversible by trypsinization. We conclude that the uptake of 86Rb+ by the (Na+,K+)-ATPase is an insulin-sensitive membrane transport process in the fat cell.
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PMID:Insulin stimulation of (Na+,K+)-adenosine triphosphatase-dependent 86Rb+ uptake in rat adipocytes. 625 93

The time course of insulin activation of sodium and potassium ion activated adenosinetriphosphatase [(Na+,K+)ATPase] was studied in the rat adipocyte and was compared to activation of the glucose transporter. Under conditions in which the binding of insulin to its cell surface receptor was not rate limiting, a distinct time lag was apparent between insulin addition and stimulation of transport activity. At 37 degrees C, 40-50 s elapsed before an increase in Rb+ uptake [a measure of (Na+,K+)ATPase transport activity] or 2-deoxyglucose uptake could be observed. This lag time increased in an identical manner for both transport processes as the temperature was lowered to 23 degrees C. Addition of the insulinomimetic agent hydrogen peroxide also produced a lag time similar to that for insulin before activation of Rb+ and 2-deoxyglucose uptakes was detected. These data provide the first evidence of a discrete time lag involved during stimulation of the adipocyte (Na+,K+)ATPase. A model for the molecular mechanism of insulin activation of (Na+,K+)ATPase is presented that incorporates these results into the hypothesis of insulin mediated "translocation" of glucose transporters to the plasma membrane.
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PMID:Insulin activation of (Na+,K+)-adenosinetriphosphatase exhibits a temperature-dependent lag time. Comparison to activation of the glucose transporter. 630 47

Signal transduction in Dictyostelium for oriented movement and differentiation involves a fine tuning of the cytosolic Ca2+ concentration. We have previously shown that cAMP binding to the cell surface receptor elicits two cellular events: (i) to enhance Ca2+ entry across the plasma membrane; (ii) to increase Ca2+ uptake into Ca(2+)-sequestering organelles. Here we used permeabilised cells to show that cAMP-induced Ca2+ uptake in these cells was sensitive to the Ca2+ transport ATPase blocker 2,5-di-(tert-butyl)-1,4-hydroquinone (BHQ) and the vacuolar H(+)-ATPase inhibitor NBD-Cl. By contrast, bafilomycin A1 and vanadate, inhibitors of Ca2+ uptake into acidosomes in Dictyostelium, did not reduce the cAMP-induced Ca2+ uptake of permeabilised cells. GTP gamma S served as a tool to measure Ins(1,4,5)P3- (InsP3)-sensitive Ca2+ release. Following NBD-Cl or BHQ treatment Ca2+ release was reversibly inhibited. We conclude that the cAMP-controlled Ca2+ influx is directed into a NBD-Cl and BHQ-sensitive compartment, which comprises the InsP3-releasable pool. The acidosomal Ca2+ store seems to provide for additional Ca2+ if required.
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PMID:Evidence for two intracellular calcium pools in Dictyostelium: the cAMP-induced calcium influx is directed into a NBD-Cl- and 2,5-di-(tert-butyl)1,4-hydroquinone-sensitive pool. 822 1

The calcium-modulating cyclophilin ligand (CAML) protein activates Ca2+ influx signaling when overexpressed in Jurkat T cells. Although CAML appears to directly participate in Ca2+-dependent signaling initiated by the transmembrane activator and CAML interactor cell surface receptor, its mechanism of action is unknown. To address this issue, we have determined its membrane topology, subcellular localization, and ability to mobilize intracellular Ca2+ pools. Fractionation of cell extracts on discontinuous sucrose gradients and indirect immunofluorescence indicate that CAML co-localizes with sarcoplasmic/endoplasmic reticulum calcium/ATPase-2 and calreticulin at membrane-bound cytosolic vesicles. Limited trypsin digests indicate that the hydrophilic NH2-terminal domain of CAML is directed toward the cytoplasm. Functionally, CAML overexpression was shown to deplete thapsigargin-sensitive intracellular Ca2+ pools. These data suggest that CAML may initiate Ca2+ signaling through activation of a capacitative Ca2+ influx pathway.
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PMID:Co-localization of calcium-modulating cyclophilin ligand with intracellular calcium pools. 963 97

Cells require optimum protein synthetic activity in order to support cell proliferation, maintain homeostatic and metabolic integrity, and repair damage. Since growth depends on protein synthesis through ribosome biogenesis, the control of biosynthesis of ribosomes is necessarily a key element for control of growth. Nucleolin is a major nucleolar protein of exponentially growing eukaryotic cells, which is directly involved in the regulation of ribosome biogenesis and maturation. The highly conserved nucleolin contains three major domains through which it controls the organization of nucleolar chromatin, packaging of pre-RNA, rDNA transcription, and ribosome assembly. Numerous reports have implicated the involvement of nucleolin either directly or indirectly in the regulation of cell proliferation and growth, cytokinesis, replication, embryogenesis, and nucleogenesis. Nucleolin, an RNA binding protein, is also an autoantigen, a transcriptional repressor, and a switch region targeting factor. In addition, nucleolin exhibits autodegradation, DNA and RNA helicase activities, and DNA-dependent ATPase activity. An interesting aspect of nucleolin action is that it is a target for regulation by proteolysis, methylation, ADP-ribosylation, and phosphorylation by CKII, cdc2, PKC-xi, cyclic AMP-dependent protein kinase, and ecto-protein kinase. For these and other reasons, nucleolin is fundamental to the survival and proliferation of cells. Considerable progress has been made in recent years with the identification of new nucleolin binding proteins that may mediate these many nucleolin-dependent functions. Nucleolin also functions as a cell surface receptor, where it acts as a shuttling protein between cytoplasm and nucleus, and thus can even provide a mechanism for extracellular regulation of nuclear events. Exploration of the regulation of this multifaceted protein in a remarkable number of diverse functions is challenging.
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PMID:Molecular dissection of nucleolin's role in growth and cell proliferation: new insights. 1054 74

The proinsulin C-peptide has been held to be merely a by-product in insulin biosynthesis, but recent reports show that it elicits both molecular and physiological effects, suggesting that it is a hormonally active peptide. Specific binding of C-peptide to the plasma membranes of intact cells and to detergent-solubilised cells has been shown, indicating the existence of a cell surface receptor for C-peptide. C-peptide elicits a number of cellular responses, including Ca(2+) influx, activation of mitogen-activated protein (MAP) kinases, of Na(+),K(+)-ATPase, and of endothelial NO synthase. The pentapeptide EGSLQ, corresponding to the C-terminal five residues of human C-peptide, mimics several of the effects of the full-length peptide. The pentapeptide displaces cell membrane-bound C-peptide, elicits transient increase in intracellular Ca(2+) concentration and stimulates MAP kinase signalling pathways and Na(+),K(+)-ATPase. The Glu residue of the pentapeptide is essential for displacement of the full-length C-peptide, and free Glu can partly displace bound C-peptide, suggesting that charge interactions are important for receptor binding. Many C-peptide effects, such as phosphorylation of MAP-kinases ERK 1 and 2, stimulation of Na(+),K(+)-ATPase and increases in intracellular calcium concentrations are inhibited by pertussis toxin, supporting interaction of C-peptide with a G-protein-coupled receptor. However, all C-peptide effects cannot be explained in this manner, and it is possible that additional interactions are involved. Combined, the available observations show that C-peptide is biologically active and suggest a molecular model for its physiological effects.
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PMID:Molecular effects of proinsulin C-peptide. 1213 97

New results present C-peptide as a biologically active peptide hormone in its own right. Although C-peptide is formed from proinsulin and cosecreted with insulin, it is a separate entity with biochemical and physiological characteristics that differ from those of insulin. There is direct evidence of stereospecific binding of C-peptide to a cell surface receptor, which is different from those for insulin and other related hormones. The C-peptide binding site is most likely a G-protein-coupled receptor. The association constant for C-peptide binding is approximately 3 x 10(9) M(-1). Saturation of the binding occurs already at a concentration of about 1 nM, which explains why C-peptide effects are not observed in healthy subjects. Binding of C-peptide results in activation of Ca2+ and MAPK-dependent pathways and stimulation of Na+,K(+)-ATPase and eNOS activities. The latter 2 enzymes are both deficient in several tissues in type 1 diabetes. There is some evidence that C-peptide, and insulin may interact synergistically on the insulin signaling pathway. Clinical evidence suggests that replacement of C-peptide, together with regular insulin therapy, may be beneficial in patients with type 1 diabetes and serve to retard or prevent the development of long-term complications.
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PMID:Molecular and cellular effects of C-peptide--new perspectives on an old peptide. 1519 68

Activation of cell surface components has been implicated in the activation of downstream signaling cascade in response to UV irradiation, and yet the identity and the interaction of those components have been scantly documented. Accumulating evidence indicates that caveolae encapsulating caveolins is the location for those interactions. We found in cultured human keratinocytes that UV irradiation induced both caveolin-1 and EGFR phosphorylation. Filipin, a caveolae disruptive agent, inhibited UV-induced caveolin-1 activation. Na+-K+-ATPase catalyzes active transport of Na+ and K+ across plasma membrane of mammalian cells, inactivation of which has recently been shown to be involved in the activation of signal transduction pathways including MAP kinase cascade. We found in this study that UV inactivated Na+-K+-ATPase in time-dependent manner, Na+-K+-ATPase activity started to decrease 5 min post UV irradiation and reduced to 60% of its original activity within 1 h. Pretreatment with Flipin and MMP inhibitor recovered Na+-K+-ATPase activity lost by UV irradiation. ECIS analysis indicated that both EGF treatment and UV irradiation increased membrane electric activity which was inhibited by MMP inhibitor and Filipin. Further study showed that pretreatment of human keratinocytes with MMP inhibitor or Filipin inhibited UV-induced phosphorylation of p38 and JNK, which was however not observed in LnCap cells, a prostate cancer cell line lacking caveolin-1. UV irradiation also induced ectodomain shedding of HB-EGF in a time-dependent manner in keratinocytes. Collectively, we conclude that UV-induced MAP kinase activation is mediated by cell surface receptor activation due to the matrix activity and membrane caveolae function and inactivation of Na+-K+-ATPase.
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PMID:Extracellular matrix activity and caveolae events contribute to cell surface receptor activation that leads to MAP kinase activation in response to UV irradiation in cultured human keratinocytes. 1575 25

The multivesicular body (MVB) pathway functions in multiple cellular processes including cell surface receptor down-regulation and viral budding from host cells. An important step in the MVB pathway is the correct sorting of cargo molecules, which requires the assembly and disassembly of endosomal sorting complexes required for transport (ESCRTs) on the endosomal membrane. Disassembly of the ESCRTs is catalyzed by ATPase associated with various cellular activities (AAA) protein Vps4. Vps4 contains a single AAA domain and undergoes ATP-dependent quaternary structural change to disassemble the ESCRTs. Structural and biochemical analyses of the Vps4 ATPase reaction cycle are reported here. Crystal structures of Saccharomyces cerevisiae Vps4 in both the nucleotide-free form and the ADP-bound form provide the first structural view illustrating how nucleotide binding might induce conformational changes within Vps4 that lead to oligomerization and binding to its substrate ESCRT-III subunits. In contrast to previous models, characterization of the Vps4 structure now supports a model where the ground state of Vps4 in the ATPase reaction cycle is predominantly a monomer and the activated state is a dodecamer. Comparison with a previously reported human VPS4B structure suggests that Vps4 functions in the MVB pathway via a highly conserved mechanism supported by similar protein-protein interactions during its ATPase reaction cycle.
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PMID:Structural characterization of the ATPase reaction cycle of endosomal AAA protein Vps4. 1794 47

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