Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.3.16 (calcineurin)
 17,112 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Calmodulin (CaM) mediates the Ca(2+)-dependent activation of many enzyme systems in accordance with its cellular localization. We have described previously a muscarinic receptor-mediated translocation of CaM from membranes into the cytosol of SK-N-SH human neuroblastoma cells. To explore the potential targets (CaM-binding proteins, CaMBP) for CaM upon translocation, a photoreactive CaM derivative was introduced into living SK-N-SH cells using a scrape-loading technique. Scrape-loading incorporated rhodamine isothiocyanate-labeled CaM with an efficiency of 38%. CaM-diazopyruvamide (CaM-DAP), a Ca(2+)-dependent and CaM-specific probe, was also introduced into the cells. The muscarinic agonist carbachol stimulated a translocation of CaM from membranes into cytosol in CaM-DAP-loaded SK-N-SH cells. Upon photochemical cross-linking, cross-linked adducts of CaM-CaMBP were detected by immunoblotting with anti-CaM antibody. Carbachol stimulated increased photoaffinity labeling of three proteins with relative adduct molecular masses of 70, 120, and 180 kDa. The time course of labeling for the 70- and 120-kDa adducts showed maximal increased by 15-30 min. The 180-kDa adduct displayed a slower time course of maximal labeling, with increases maintained for 2-4 h. Subtracting the molecular mass of CaM, carbachol stimulated binding to CaMBPs of 55, 105, and 163 kDa. Predominant cellular CaMBP were identified using a biotinylated CaM overlay procedure. Western blot analysis indicated the expression of specific CaM-dependent enzymes such as calcineurin, phosphodiesterase, the beta-isoform (rat brain) of CaM kinase II, and Ca(2+)-ATPase. Numerous cytoskeletal CaMBP were expressed such as microtubule-associated protein-2, spectrin, tubulin, caldesmon, adducin, and neuromodulin. Of the CaMBP expressed, phosphodiesterase, calcineurin, caldesmon, and adducin cross-linked with CaM-DAP in the loaded SK-N-SH cells. Carbachol stimulated the time-dependent CaM-DAP labeling of calcineurin and adducin. This study demonstrates the novel incorporation of a photoreactive CaM derivative into living cells, as well as muscarinic receptor-activated CaM-DAP interaction with several cellular CaMBP. We postulate that carbachol-stimulated CaM translocation in SK-N-SH cells may affect the activity of CaM-dependent enzymes and may alter aspects of cytoskeletal function.
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PMID:Carbachol stimulates binding of a photoreactive calmodulin derivative to calmodulin-binding proteins in intact SK-N-SH human neuroblastoma cells. 155 1

In an effort to characterize the second messenger system for LH release, we have previously identified five calmodulin-binding proteins in rat gonadotropes of Mr greater than 205,000, 200,000, 135,000, 60,000, and 52,000. In the present study, we have used a calmodulin overlayer assay combined with Western blotting to determine the molecular identity of three calmodulin-binding proteins in rat gonadotropes: the alpha subunit of spectrin (Mr greater than 205,000), caldesmon (Mr 84,000), and the alpha subunit of calcineurin (Mr 60,000). The Mr greater than 205,000 and Mr 60,000 components or rat pituitary which bind calmodulin are immunoreactive with spectrin and calcineurin antisera, respectively. Rat pituitary also contains an Mr 84,000 component, which is immunoreactive with polyclonal sera and monoclonal antibody raised to chicken gizzard caldesmon (Mr 150,000). Like caldesmon from other sources, the Mr 84,000 component remains soluble after heat treatment and preferentially binds either filamentous actin or calmodulin, depending on the Ca2+ concentration. The three calmodulin-binding proteins were localized specifically in gonadotropes using indirect immunofluorescence microscopy or by Western-blotting cell fractions enriched for gonadotropes. After differential centrifugation of pituitary homogenate, spectrin immunoreactivity was found associated with the nuclear and secretory granule fractions, whereas caldesmon immunoreactivity was seen in the cytosolic fraction and calcineurin in the cytosolic and nuclear fractions. Although the precise role for these proteins remains unknown, the apparent requirement for calmodulin and the small number of calmodulin-binding proteins in the gonadotrope suggest their involvement in mediating GnRH actions.
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PMID:Specific identification and subcellular localization of three calmodulin-binding proteins in the rat gonadotrope: spectrin, caldesmon, and calcineurin. 184 52

Calmodulin (CaM) serves as an intracellular Ca2+ receptor in the gonadotrope and appears to mediate GnRH-stimulated gonadotropin release. Recently we have specifically identified three CaM binding proteins of the gonadotrope as calcineurin, caldesmon, and spectrin. Caldesmon (identified by seven polyclonal and a monoclonal antibody, as well as by functional characteristics) appears to be a CaM-regulated, F-actin binding, protein. This 84,000 mol wt component (CaD84) is heat stable and cosediments with F-actin in the absence of Ca2+. In the presence of Ca2+ (greater than 1 microM) this protein disassociates from F-actin and reassociates with calmodulin. We have prepared an antibody which blocks the caldesmon-actin interaction. In the present study, we have loaded this antibody into cells to prevent the (re-)association of caldesmon with F-actin. This treatment synergistically augments the ability of GnRH and other secretogogues (maitotoxin, phorbol myristyl acetate) to stimulate gonadotropin release from the pituitary. This finding, along with the previous observations that GnRH provokes a sufficient rise in intracellular Ca2+ to allow CaM to redistribute and bind proteins which it regulates, suggests a role for caldesmon in GnRH-stimulated gonadotropin release from the pituitary.
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PMID:Caldesmon: a bifunctional (calmodulin and actin) binding protein which regulates stimulated gonadotropin release. 190 32

Caldesmon is a major calmodulin- and actin-binding protein of smooth muscle which interacts with calmodulin in a Ca2+-dependent manner or with actin in a Ca2+-independent manner. Isolated caldesmon is capable of inhibiting the actin-activated Mg2+-ATPase of smooth-muscle myosin, suggesting a possible physiological role for caldesmon in regulating the contractile state of smooth-muscle. Caldesmon can be phosphorylated in vitro by a co-purifying Ca2+/calmodulin-dependent protein kinase and dephosphorylated by a protein phosphatase, both of which are present in smooth muscle. We investigated further the phosphorylation of caldesmon and the effects which phosphorylation has on the functional properties of the protein. The kinetics of caldesmon phosphorylation were similar whether the caldesmon substrate was free or bound to actin, actin/tropomyosin or thin filaments. Caldesmon containing endogenous kinase activity was rapidly phosphorylated (to approx. 1 mol of Pi/mol of caldesmon in 5 min) when reconstituted with actin, myosin, tropomyosin, calmodulin and myosin light-chain kinase in the presence of Ca2+ and MgATP2-. Under conditions in which unphosphorylated caldesmon showed substantial inhibition of the actin-activated myosin Mg2+-ATPase, no inhibition was observed with phosphorylated caldesmon. This was the case whether caldesmon was phosphorylated before addition to the actomyosin Mg2+-ATPase system, or phosphorylation was allowed to take place during the ATPase reaction. Binding studies revealed maximal binding of 1 mol of unphosphorylated caldesmon/9.5 mol of actin and 1 mol of phosphorylated caldesmon/11.7 mol of actin. All the bound phosphorylated caldesmon could be released by Ca2+/calmodulin, with half-maximal release at 0.11 microM-Ca2+, whereas only 62% of the bound unphosphorylated caldesmon could be removed, with half-maximal release at 0.16 microM-Ca2+. However, under conditions in which inhibition of actomyosin Mg2+-ATPase activity by non-phosphorylated but not by phosphorylated caldesmon was observed, both forms of caldesmon would remain bound to the thin filament. These observations suggest a possible mechanism whereby caldesmon phosphorylation may prevent its inhibitory action on the actomyosin Mg2+-ATPase.
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PMID:The effects of phosphorylation of smooth-muscle caldesmon. 282 3

Smooth muscle contraction is regulated primarily by the reversible phosphorylation of myosin by myosin light chain kinase. Secondary mechanisms that might modulate contractility are phosphorylation-dephosphorylation of myosin light chain kinase and thin-filament proteins, caldesmon and calponin. Purification of several protein phosphatases that are active toward myosin light chains and (or) myosin and heavy meromyosin from smooth muscles has been reported. All the cytosolic turkey gizzard smooth muscle phosphatases, termed SMP-I, -II, -III, and -IV, dephosphorylate myosin light chains rapidly, but only SMP-III and -IV are active toward myosin and heavy meromyosin, suggesting that SMP-III and -IV might be directly involved in the relaxation of smooth muscle. SMP-III and -IV exhibit properties typical of type 1 protein phosphatases following tryptic digestion. These enzymes appear to share structural similarity with myofibrillar phosphatase PP1M. Purified calponin phosphatase and caldesmon phosphatase from chicken gizzards are structurally and immunologically identical with SMP-I, a type 2A protein phosphatase. SMP-I dephosphorylates calponin faster than it does caldesmon, and has much higher activity toward these substrates than SMP-II, -III, and -IV. Thus, one role for SMP-I might be to regulate the activities of caldesmon and calponin. Since SMP-I is active toward myosin light chain kinase, it might also modulate this enzyme.
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PMID:Smooth muscle phosphatases: structure, regulation, and function. 776 89

The 55 kDa regulatory subunit of Drosophila protein phosphatase 2A is located in the cytoplasm at all cell cycle stages, by the criterion of immunofluorescence. We are unable to detect significant change in protein phosphatase activity during the nuclear division cycle of syncytial embryos. However, cell cycle function of the enzyme is suggested by the mitotic defects exhibited by two Drosophila mutants, aar1 and twinsP, defective in the gene encoding the 55 kDa subunit. The reduced levels of the 55 kDa subunit correlate with the loss of protein phosphatase 2A-like, okadaic acid-sensitive phosphatase activity of brain extracts against caldesmon and histone H1 phosphorylated by p34cdc2/cyclin B kinase, but not against phosphorylase a. Thus the mitotic defects of aar1 and twinsP are likely to result from the lack of dephosphorylation of specific substrates by protein phosphatase 2A.
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PMID:Drosophila mutants in the 55 kDa regulatory subunit of protein phosphatase 2A show strongly reduced ability to dephosphorylate substrates of p34cdc2. 784 74

Caldesmon phosphatase was identified in chicken gizzard smooth muscle by using as substrates caldesmon phosphorylated at different sites by protein kinase C, Ca2+/calmodulin-dependent protein kinase II and cdc2 kinase. Most (approximately 90%) of the phosphatase activity was recovered in the cytosolic fraction. Gel filtration after (NH4)2SO4 fractionation of the cytosolic fraction revealed a single major peak of phosphatase activity which coeluted with calponin phosphatase [Winder, Pato and Walsh (1992) Biochem. J. 286, 197-203] and myosin LC20 phosphatase. Further purification of caldesmon phosphatase was achieved by sequential chromatography on columns of DEAE-Sephacel, omega-amino-octyl-agarose, aminopropyl-agarose and thiophosphorylated myosin LC20-Sepharose. A single peak of caldesmon phosphatase activity was detected at each step of the purification. The purified phosphatase was identified as SMP-I [Pato and Adelstein (1980) J. Biol. Chem. 255, 6535-6538] by subunit composition (three subunits, of 60, 55 and 38 kDa) and Western blotting using antibodies against the holoenzyme which recognize all three subunits and antibodies specific for the 38 kDa catalytic subunit. SMP-I is a type 2A protein phosphatase [Pato, Adelstein, Crouch, Safer, Ingebritsen and Cohen (1983) Eur. J. Biochem. 132, 283-287; Winder et al. (1992), cited above]. Consistent with the conclusion that SMP-I is the major caldesmon phosphatase of smooth muscle, purified SMP-I from turkey gizzard dephosphorylated all three phosphorylated forms of caldesmon, whereas SMP-II, -III and -IV were relatively ineffective. Kinetic analysis of dephosphorylation by chicken gizzard SMP-I of the three phosphorylated caldesmon species and calponin phosphorylated by protein kinase C indicates that calponin is a significantly better substrate of SMP-I than are any of the three phosphorylated forms of caldesmon. We therefore suggest that caldesmon phosphorylation in vivo can be maintained after kinase inactivation due to slow dephosphorylation by SMP-I, whereas calponin and myosin are rapidly dephosphorylated by SMP-I and SMP-III/SMP-IV respectively. This may have important functional consequences in terms of the contractile properties of smooth muscle.
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PMID:Smooth-muscle caldesmon phosphatase is SMP-I, a type 2A protein phosphatase. 839 39

Okadaic acid (2 nM) inhibited by 80-90% the protein phosphatase activities in diluted extracts of rat liver, human fibroblasts, and Xenopus eggs acting on three substrates (high mobility group protein-I(Y), caldesmon and histone H1) phosphorylated by a cyclin-dependent protein kinase (CDK) suggesting that a type-2A phosphatase was responsible for dephosphorylating each protein. This result was confirmed by anion exchange chromatography of rat liver and Xenopus extracts, which demonstrated that the phosphatases acting on these substrates coeluted with the two major species of protein phosphatase 2A, termed PP2A1 and PP2A2. When matched for activity toward glycogen phosphorylase, PP2A1 was five- to sevenfold more active than PP2A2 and 35-fold to 70-fold more active than the free catalytic subunit (PP2Ac) toward the three CDK-labeled substrates. Protein phosphatases 1, 2B, and 2C accounted for a negligible proportion of the activity toward each substrate under the assay conditions examined. The results suggest that PP2A1 is the phosphatase that dephosphorylates a number of CDK substrates in vivo and indicate that the A and B subunits that are associated with PP2Ac in PP2A1 accelerate the dephosphorylation of CDK substrates, while suppressing the dephosphorylation of most other proteins. The possibility that PP2A1 activity is regulated during the cell cycle is discussed.
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PMID:Protein phosphatase 2A1 is the major enzyme in vertebrate cell extracts that dephosphorylates several physiological substrates for cyclin-dependent protein kinases. 840 Apr 54

We studied the Ca(2+)-capture ability of follicular dendritic cells (FDCs) in tonsillar secondary lymphoid follicles (LFs) and the expression of six Ca(2+)-binding proteins (CBPs), caldesmon, S-100 protein, calcineurin, calbindin-D, calmodulin, and annexin VI in LFs of various lymphoid tissues and caldesmon and S-100 protein in neoplastic follicles of follicular lymphomas. First, Ca(2+)-capture cytochemistry revealed extensive Ca(2+) capture in the nuclei and cytoplasm of FDCs, but little or none in follicular lymphocytes. All six CBPs were localized immunohistochemically in the LFs and were always present in the basal light zone. Immunoelectron microscopic staining of FDCs was classified into two patterns: caldesmon was distributed in the peripheral cytoplasm like a belt; S-100 protein, calcineurin, calbindin-D, and calmodulin were distributed diffusely in the cytosol. Annexin VI was, however, negative on FDCs. Immunocytochemistry also demonstrated CBP-positive FDCs within FDC-associated clusters isolated from germinal centers. In situ hybridization revealed diffuse calmodulin mRNA expression throughout the secondary LFs. These data indicate that the CBPs examined may regulate Ca(2+) in the different subcellular sites of FDCs, and the roles of CBPs may be heterogeneous. We also investigated the distribution of caldesmon and S-100 protein in follicular lymphomas on paraffin-embedded tissue sections. FDCs within grades I and II neoplastic follicles clearly expressed caldesmon, but not S-100 protein, except a part of grade II neoplastic follicles. FDCs within grade III follicles showed no caldesmon, but frequently expressed S-100 protein. These results demonstrate that the caldesmon and S-100 protein staining patterns of grade I follicular lymphomas are different from those of grade III follicular lymphomas and suggest that FDC networks in grade I neoplastic follicles may be similar to those in the light zone within non-neoplastic follicles, FDC networks in grade III neoplastic follicles may be similar to those in dark and basal light zones within non-neoplastic follicles, and grade II follicles may be intermediate between grade I and grade III follicles.
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PMID:Differential expression of Ca(2+)-binding proteins on follicular dendritic cells in non-neoplastic and neoplastic lymphoid follicles. 1048 24

The calcineurin-mediated pathway is involved in skeletal and cardiac hypertrophy and vascular development in vivo, but the relationship between this pathway and the phenotype of smooth muscle cells (SMCs) remains unknown. Using visceral SMCs in culture as a model system of differentiated SMCs, we investigated the role of the calcineurin-mediated pathway in maintaining the differentiated phenotype of SMCs, which depends on the insulin-like growth factor (IGF-I)-triggered activation of the phosphatidylinositol 3-kinase (PI3-K)/protein kinase B (PKB(Akt)) pathway. Treatment with calcineurin inhibitors, cyclosporin A or FK506, or the forced expression of the natural calcineurin inhibitor, CAIN, induced SMC dedifferentiation. Notably, suppression of the promoter activities of the SMC molecular markers caldesmon and alpha1 integrin by blocking the PI3-K/PKB(Akt) pathway was rescued by the forced expression of constitutively active calcineurin Aalpha, suggesting that the calcineurin-mediated pathway is critical for maintaining the differentiated phenotype of SMCs and works downstream of the PI3-K/PKB(Akt) pathway.
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PMID:Calcineurin-mediated pathway involved in the differentiated phenotype of smooth muscle cells. 1253 43


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