Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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) is a 148-residue regulatory calcium-binding protein that activates a wide range of target proteins and enzymes. Calcium-saturated CaM has a bilobal structure, and each domain has an exposed hydrophobic surface region where target proteins are bound. These two "active sites" of calmodulin are remarkably rich in Met residues. Here we have biosynthetically substituted (up to 90% incorporation) the unnatural amino acids ethionine (Eth) and norleucine (Nle) for the nine Met residues of CaM. The substituted proteins bind in a calcium-dependent manner to hydrophobic matrices and a synthetic peptide, encompassing the CaM-binding domain of myosin light-chain kinase (MLCK). Infrared and circular dichroism spectroscopy show that there are essentially no changes in the secondary structure of these proteins compared to wild-type CaM (WT-CaM). One- and two-dimensional NMR studies of the Eth-CaM and Nle-CaM proteins reveal that, while the core of the proteins is relatively unaffected by the substitutions, the two hydrophobic interaction surfaces adjust to accommodate the Eth and Nle residues. Enzyme activation studies with MLCK show that Eth-CaM and Nle-CaM activate the enzyme to 90% of its maximal activity, with little changes in dissociation constant. For calcineurin only 50% activation was obtained, and the K(D) for Nle-CaM also increased 3.5-fold compared with WT-CaM. These data show that the "active site" Met residues of CaM play a distinct role in the activation of different target enzymes, in agreement with site-directed mutagenesis studies of the Met residues of CaM.
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PMID:Substitution of the methionine residues of calmodulin with the unnatural amino acid analogs ethionine and norleucine: biochemical and spectroscopic studies. 1021 Jan 90

The polyps of Cassiopea andromeda produce spindle shaped, freely swimming buds which do not develop a head (a mouth opening surrounded by tentacles) and a foot (a sticky plate at the opposite end) until settlement to a suited substrate. The buds, therewith, look very similar to the planula larvae produced in sexual reproduction. With respect to both, buds and planulae, several peptides and the phorbolester TPA have been found to induce the transformation into a polyp. Here it is shown that cantharidin, a serine/threonine protein phosphatase inhibitor, induces head and foot formation in buds very efficiently in a 30 min treatment, the shortest yet known efficient treatment. Some resultant polyps show malformations which indicate that a bud is ordinary polyp tissue in which preparatory steps of head and foot formation mutually block each other from proceeding. Various compounds related to the transfer of methyl groups have been shown to affect head and foot formation in larvae of the hydrozoon Hydractinia echinata. These compounds including methionine, homocysteine, trigonelline, nicotinic acid and cycloleucine are shown to also interfere with the initiation of the processes which finally lead to head and foot formation in buds of Cassiopea andromeda.
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PMID:The protein phosphatase inhibitor cantharidin induces head and foot formation in buds of Cassiopea andromeda (Rhizostomae, Scyphozoa). 1021 82

Even among young, healthy individuals, there is more than a 10-fold variation in insulin sensitivity; however, taken in combination, all the known modifiers of insulin sensitivity - including obesity and a variety of environmental factors - explain less than one third of this variation. It is possible that genetic factors could account for the bulk of the variance observed, and hence play a major role in the development of impaired insulin sensitivity, ie insulin resistance. From the genetic point of view, insulin resistance is thought to be due to the inheritance of a number of mutations in a variety of genes. Three complementary approaches have been applied in the search for mutations: mutational analysis of candidate genes; linkage analysis of candidate genes or chromosomal regions for insulin resistance in familial type 2 diabetes; and random genome mapping with quantitative trait loci (QTL) analysis. Mutational analysis of the insulin signalling cascade has identified a glycine-arginine (Gly-Arg) substitution at codon 972 of the insulin receptor substrate-1 (IRS-1) gene with a carrier prevalence of 9% among Caucasians. Expression of this variant in 32-D cells is associated with a significant (20-30%) impairment of insulin-stimulated PI3-kinase activity, as well as reduced binding of IRS-1 to the p85 regulatory subunit of PI3-kinase. Genotype/phenotype studies stratified according to body mass index (BMI) indicate that obese subjects who are heterozygous for the mutant allele have a 50% decrease in insulin sensitivity, compared with wild-type obese subjects. This suggests that there may be an interaction between the mutant allele and obesity, such that, in the presence of obesity, the mutant variant may aggravate the obesity-associated insulin resistance. Mutational analysis has also shown that homozygous carriers of a codon Met 326 Ile mutation in the p85 subunit of phosphatidylinositol-3 (PI3)-kinase (about 2% of the Caucasian population) have lower glucose tolerance, glucose effectiveness. A further Asp to Tyr polymorphism has been identified at codon 905 of the gene encoding the regulatory subunit of glycogen-associated protein phosphatase-1 (PP1G). Individuals who are heterozygous for this polymorphism constitute 18% of the Caucasian population and appear to exhibit both tissue-specific and pathway-specific insulin resistance. It is likely that inherited insulin resistance will eventually prove to be related to subtle mutations in many such genes of the insulin signalling network and the numerous genetic components controlling energy metabolism.
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PMID:Genetics of insulin resistance. 1032 50

Okadaic acid (OKA), a potent and specific inhibitor of protein serine/threonine phosphatases 1 and 2A, induced the accumulation of NADH-glutamate synthase (GOGAT) mRNA within 4 h in rice (Oryza sativa L.) cell cultures. In contrast to the transient accumulation of NADH-GOGAT mRNA by NH(4)(+), OKA caused a continuous accumulation for at least 24 h. The induction of NADH-GOGAT mRNA by OKA was not inhibited in the presence of methionine sulfoximine, which inhibited the NH(4)(+)-induced accumulation of mRNA. These results suggest that the OKA-sensitive protein phosphatase is involved in the regulation of NADH-GOGAT gene expression and probably plays a role in the signal transduction pathway downstream from NH(4)(+), although a signal transduction pathway other than that of nitrogen sensing could be responsible. Nuclear run-on assays demonstrated that the accumulation of NADH-GOGAT mRNA induced by the supply of either NH(4)(+) or OKA was mainly regulated at the transcription level. OKA effects were synergistic to the NH(4)(+)-induced expression of the NADH-GOGAT gene. In the presence of K-252a, a protein kinase inhibitor, the accumulation of NADH-GOGAT mRNA induced by either NH(4)(+) or OKA was reduced. The possible roles of protein phosphatases in the regulation of NADH-GOGAT gene expression are discussed.
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PMID:Okadaic Acid Mimics Nitrogen-Stimulated Transcription of the NADH-Glutamate Synthase Gene in Rice Cell Cultures. 1055 28

The calcium/calmodulin-dependent activation of nitric-oxide synthase (NOS) and its production of nitric oxide (NO) play a key regulatory role in plant and animal cell function. SCaM-1 is a plant calmodulin (CaM) isoform that is 91% identical to mammalian CaM (wild type CaM (wtCaM)) and a selective competitive antagonist of NOS (Cho, M. J., Vaghy, P. L., Kondo, R., Lee, S. H., Davis, J. P., Rehl, R., Heo, W. D., and Johnson, J. D. (1998) Biochemistry 37, 15593-15597). We have used site-directed mutagenesis to show that a point mutation, involving the substitution of valine for methionine at position 144, is responsible for SCaM-1's inhibition of mammalian NOS. An M144V mutation in wild type CaM produced a mutant (M144V) which exhibited nearly identical inhibition of NOS's NO production and NADPH oxidation, with a similar K(i) (approximately 15 nM) as SCaM-1. A V144M back mutation in SCaM-1 significantly restored its ability to activate NOS's catalytic functions. The length of the hydrophobic amino acid side chain at position 144 appears to be critical for NOS activation, since M144L and M144F activated NOS while M144V and M144C did not. Despite their competitive antagonism of NOS, M144V, like SCaM-1, exhibited a similar dose-dependent activation of phosphodiesterase and calcineurin as wtCaM. SCaM-1 and M144V produced greater inhibition of NOS's oxygenase domain function (NO production) than its reductase domain functions (NADPH oxidation and cytochrome c reduction). Thus, CaM's methionine 144 plays a critical role the activation of NOS, presumably by influencing the function of NOS's oxygenase domain.
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PMID:A point mutation in a plant calmodulin is responsible for its inhibition of nitric-oxide synthase. 1059 8

Homocysteine is causally associated with birth defects such as spina bifida, and with premature vascular disease. We have investigated the effects of homocysteine on a cell-cell interaction in a fundamental eukaryotic system, the free-living ciliate Tetrahymena. Exogenously added homocysteine inhibits cell pairing in a dose-dependent manner. These effects are exacerbated by adenosine, which by itself has little demonstrable influence on pairing. S-adenosylhomocysteine (SAH) is a product of the reaction between adenosine and homocysteine, and is an inhibitor of methyl transferases. We therefore predicted that protein methylation would be significantly inhibited by homocysteine. A direct test of that hypothesis involved a demonstration that incorporation of an isotopically labeled methyl group from methionine into proteins was significantly reduced by homocysteine. The undermethylated proteins are of low molecular weight, and might correspond to known methylatable signaling proteins. We show that vanadate, an inhibitor of protein phosphatase, also inhibits cell pairing, and that the effects of vanadate and homocysteine are additive. This is the first demonstration that methylation and possibly phosphorylation play a regulatory role in cell-cell interactions in ciliates.
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PMID:Cell pairing and methylation in Tetrahymena thermophila are altered by exogenous homocysteine. 1072 73

Blue light-induced oxygen uptake of the colorless mutant of Chlorella kessleri (No. 9.80) was 30-40% higher in the presence of exogenous glycine than in its absence. None of the other amino acids tested had this effect. Moreover, mutant cells in which glutamine synthetase was inhibited by methionine sulphoximine, accumulated approximately 65% more ammonium ions under blue irradiation in the presence of exogenous glycine than in its absence. The protein kinase C inhibitors, staurosporine or K252a, reduced the enhancement of oxygen uptake by approximately 40%. The present results indicate that blue light-dependent deamination of endogenous glycine might be a prerequisite for enhanced oxygen uptake in Chlorella. This blue light-induced oxygen uptake was not influenced by the inhibitors of protein phosphatase, calyculin A or okadaic acid. On the contrary, calyculin A and okadaic acid had a marked effect on the acidification of the suspension medium and nitrate uptake induced by blue light in Chlorella cells. The different responses to the inhibitors of protein kinase and phosphatase suggest the presence of different pathways among the blue light signal transduction operating on oxygen uptake, acidification of the medium and nitrate uptake in Chlorella.
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PMID:Oxygen uptake, acidification of medium and nitrate uptake induced by blue light in nitrate-starved Chlorella cells. 1084 68

A tobacco cDNA (NtSLT1, for Nicotiana tabacum sodium- and lithium-tolerant) was isolated by functional complementation of the salt-sensitive phenotype of a calcineurin (CaN)-deficient yeast mutant (cnb delta, regulatory subunit null). CaN is a Ca2+/calmodulin-dependent type 2B protein phosphatase that regulates Na+ homeostasis in yeast. This phosphatase modulates plasma membrane K+/Na+ selectivity through the activation of high-affinity K+ transport, and increaseses extracellular Na+ efflux by activation and transcriptional induction of the Na+/Li+ translocating P-type ATPase encoded by ENA1. Expression of N-terminally truncated NtSLT1 (Met-304), but not full-length protein, suppressed salt sensitivity of cnb1. Truncated NtSLT1 also increased salt tolerance of wild-type yeast, indicating functional sufficiency. NtSLT1 encodes a protein of yet unknown function but experimentation in yeast confirms it as a salt tolerance determinant. The Arabidopsis thaliana orthologue, AtSLT1, also suppressed salt sensitivity of cnb delta but only when expressed without the N-terminus (Met-301), suggesting that this region of the proteins from these evolutionarily diverse plant species contains an autoinhibitory domain. NtSLT1 enhanced transcription of the CaN-dependent ENA1 gene promoter and compensated the salt sensitivity of a mutant deficient in TCN1--a transcription factor that is activated by CaN and then induces ENA1 expression. NtSLT1 partially suppressed the salt sensitivity of ena1-4 indicating that NtSLT1 has both ENA-dependent and independent functions. NtSLT1 suppressed spk1 hal4 (SPK1/HAL4 which encodes a serine-threonine kinase that regulates TRK1-2 transporters to have high K+/Na+ selectivity) but not ena1-4 trk1-2 implicating the ENA-independent function to be through TRK1-2. Together, these results implicate SLT1 as a signal regulatory molecule that mediates salt tolerance by modulating Na+ homeostasis.
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PMID:Tobacco and Arabidiopsis SLT1 mediate salt tolerance of yeast. 1135 67

A gene, TIF2, was identified as corresponding to the translation initiation factor eIF4A and when overexpressed it confers lithium tolerance in galactose medium to Saccharomyces cerevisiae. Incubation of yeast with 6 mm LiCl in galactose medium leads to inhibition of [(35)S]methionine incorporation. By polysome analysis we show that translation is inhibited by lithium at the initiation step, accumulating 80 S monosomes. We further show by immunoblot analysis that when cells are incubated with lithium eIF4A does not sediment with ribosomal subunits. Overexpression of TIF2 overcomes inhibition of protein synthesis and restores its sedimentation with the initiation complex. In vivo, eIF4A is induced by lithium stress. We have shown previously that lithium is highly toxic to yeast when grown in galactose medium mainly due to inhibition of phosphoglucomutase, an enzyme responsible for the entry of galactose into glycolysis. We show that conditions that revert inhibition of phosphoglucomutase also revert inhibition of protein synthesis. Interestingly, glucose starvation leads to loss of polysomes but not to dissociation of eIF4A from the preinitiation complexes. Overexpression of SIT4, a protein phosphatase related to the TOR kinase pathway, reverts inhibition of protein synthesis by lithium and association of eIF4A with the initiation complex.
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PMID:The initiation factor eIF4A is involved in the response to lithium stress in Saccharomyces cerevisiae. 1194 May 96

The role of elongation factor (EF)-2 phosphorylation in the regulation of pancreatic beta-cell protein synthesis by glucose was investigated in the INS-1-derived cell line 832/13. Incubation of cells in media containing 1 mm glucose resulted in a progressive increase in EF-2 phosphorylation that was maximal by 1-2 h. Readdition of 10 mm glucose promoted a rapid dephosphorylation of EF-2 that was complete in 10 min and maintained over the ensuing 2 h. Similar results were obtained using primary rat islets or Min-6 insulinoma cells. The glucose effect in 832/13 cells was replicated by addition of pyruvate or alpha-ketocaproate, but not 2-deoxyglucose, suggesting that mitochondrial metabolism was required. Accordingly, glucose-mediated dephosphorylation of EF-2 was completely blocked by the mitochondrial respiratory antagonists antimycin A and oligomycin. The hyperglycemic effect was not mimicked by incubation of cells in 100 nm insulin, 30 mm potassium chloride, or 0.25 mm diazoxide, indicating that insulin secretion and/or depolarization of beta cells was not required. The locus of the high glucose effect appeared to be protein phosphatase-2A, the principal phosphatase acting on EF-2. Protein phosphatase-2A activity was stimulated by glucose addition to 832/13 cells, but neither protein phosphatase-1 nor calmodulin kinase III (EF-2 kinase) activity was affected under these conditions. The slower rephosphorylation of EF-2 during the transition from high to low glucose may involve effects on EF-2 kinase activity. Addition of 5-aminoimidazole-4-carboxamide 1-beta-d-ribofuranoside in high glucose led to a marked stimulation of EF-2 phosphorylation, consistent with the possibility that increased AMP kinase activity in low glucose stimulates EF-2 kinase. In parallel with the effects on EF-2 dephosphorylation, addition of high glucose to 832/13 cells markedly increased the incorporation of [(35)S]methionine into total protein. Taken together, these results suggest that modulation of extracellular glucose impacts protein translation rate in beta cells at least in part through regulation of the elongation step, via phosphorylation/dephosphorylation of EF-2.
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PMID:Glucose regulates EF-2 phosphorylation and protein translation by a protein phosphatase-2A-dependent mechanism in INS-1-derived 832/13 cells. 1264 53


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