EC:2.7.11.1 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Target Concepts:

Query: EC:2.7.11.1 (protein kinase)
81,284 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Transcription of the CTT1 (catalase T) gene of Saccharomyces cerevisiae is controlled by oxygen via heme, by nutrients via cAMP and by heat shock. Nitrogen limitation triggers a rapid, cycloheximide-insensitive derepression of the gene. Residual derepression in a cAMP-nonresponsive mutant with attenuated protein kinase activity (bcy1 tpk1w tpk2 tpk3) demonstrates the existence of an alternative, cAMP-independent nutrient signaling mechanism. Deletion analysis using CTT1-lacZ fusion genes revealed the contribution of multiple control elements to derepression, not all of which respond to the cAMP signal. A positive promoter element responding to negative control by cAMP was inactivated by deletion of a DNA region between base pairs -340 and -364. Upstream fragments including this element confer negative cAMP control to a LEU2-lacZ fusion gene. Northern analysis of CTT1 expression in the presence or absence of heme, in RAS2+ (high cAMP) and ras2 mutant (low cAMP) strains and in cells grown at low temperature (23 degrees C) and in heat-shocked cells (37 degrees C) shows that CTT1 is only induced to an appreciable extent when at least two of the three factors contributing to its expression (oxidative stress signaled by heme, nutrient starvation (low cAMP) and heat stress) activate the CTT1 promoter.
...
PMID:Negative regulation of transcription of the Saccharomyces cerevisiae catalase T (CTT1) gene by cAMP is mediated by a positive control element. 184 76

Previous studies have established that the Escherichia coli protein kinase/phosphatase nitrogen regulator II (NRII also known as NtrB) becomes autophosphorylated on a histidine residue when incubated with ATP. We show that the major site at which NRII was autophosphorylated was contained within a peptide consisting of amino acid residues 136-142 of NRII, and thus probably corresponds to His-139. A minor site of phosphorylation, accounting for about 2% of the phosphate in NRII-P, was found in a peptide that corresponds to residues 158-169.
...
PMID:Identification of the site of autophosphorylation of the bacterial protein kinase/phosphatase NRII. 201 2

Fission yeast cell division is initiated by the cdc2/cdc13-cyclin protein kinase which in its catalytically active state comprises the mitotic inducer. During interphase the cdc2/cyclin complex is assembled in an inactive state that requires cdc25+ gene function for M-phase activation. The cdc25+ product, a 76 kd phosphoprotein, is shown to oscillate in abundance during the cell cycle, reaching a peak at G2/M, and to be sensitive to nitrogen starvation. The level of cdc25 is subject to feedback regulation involving both cdc25 and cdc2.
...
PMID:Fission yeast cdc25 is a cell-cycle regulated protein. 217 10

The developmental programme of fission yeast brings about a transition from mitotic cell division to the dormant state of ascospores. In response to nitrogen starvation, two cells of opposite mating type conjugate to form a diploid zygote, which then undergoes meiosis and sporulation. This differentiation process is characterized by a transcriptional induction of the mating-type genes. Conjugation can also be induced in pat1-ts mutants by a shift to a semi-permissive temperature. The pat1 gene encodes a protein kinase, which also functions further downstream in the developmental pathway controlling entry into meiosis. We have analysed transcriptional induction of mating-type genes in various strains--with and without a pat1-ts allele. In wild-type cells of P-mating type derepression occurs in two rounds. First, the mat1-Pc gene is induced in response to nitrogen starvation. Mutants in the map1 gene are defective in this process. In the following step the mat1-Pm gene is expressed in response to a pheromone signal generated by cells of M mating type. Both these controls are derepressed in the pat1-ts mutant at semipermissive temperature. Previous work has established that expression of the mating-type genes in the zygote leads to complete loss of pat1 protein kinase activity causing entry into meiosis. Thus, pat1 can promote its own inactivation. We suggest a model according to which a stepwise inactivation of pat1 leads to sequential derepression of the processes of conjugation and meiosis.
...
PMID:The pat1 protein kinase controls transcription of the mating-type genes in fission yeast. 232 19

In Saccharomyces cerevisiae, lack of nutrients triggers a pleiotropic response characterized by accumulation of storage carbohydrates, early G1 arrest, and sporulation of a/alpha diploids. This response is thought to be mediated by RAS proteins, adenylate cyclase, and cyclic AMP (cAMP)-dependent protein kinases. This study shows that expression of the S. cerevisiae gene coding for a cytoplasmic catalase T (CTT1) is controlled by this pathway: it is regulated by the availability of nutrients. Lack of a nitrogen, sulfur, or phosphorus source causes a high-level expression of the gene. Studies with strains with mutations in the RAS-cAMP pathway and supplementation of a rca1 mutant with cAMP show that CTT1 expression is under negative control by a cAMP-dependent protein kinase and that nutrient control of CTT1 gene expression is mediated by this pathway. Strains containing a CTT1-Escherichia coli lacZ fusion gene have been used to isolate mutants with mutations in the pathway. Mutants characterized in this investigation fall into five complementation groups. Both cdc25 and ras2 alleles were identified among these mutants.
...
PMID:Control of Saccharomyces cerevisiae catalase T gene (CTT1) expression by nutrient supply via the RAS-cyclic AMP pathway. 254 66

Bacteria continuously adapt to changes in their environment. Responses are largely controlled by signal transduction systems that contain two central enzymatic components, a protein kinase that uses adenosine triphosphate to phosphorylate itself at a histidine residue and a response regulator that accepts phosphoryl groups from the kinase. This conserved phosphotransfer chemistry is found in a wide range of bacterial species and operates in diverse systems to provide different regulatory outputs. The histidine kinases are frequently membrane receptor proteins that respond to environmental signals and phosphorylate response regulators that control transcription. Four specific regulatory systems are discussed in detail: chemotaxis in response to attractant and repellent stimuli (Che), regulation of gene expression in response to nitrogen deprivation (Ntr), control of the expression of enzymes and transport systems that assimilate phosphorus (Pho), and regulation of outer membrane porin expression in response to osmolarity and other culture conditions (Omp). Several additional systems are also examined, including systems that control complex developmental processes such as sporulation and fruiting-body formation, systems required for virulent infections of plant or animal host tissues, and systems that regulate transport and metabolism. Finally, an attempt is made to understand how cross-talk between parallel phosphotransfer pathways can provide a global regulatory curcuitry.
...
PMID:Protein phosphorylation and regulation of adaptive responses in bacteria. 255 36

The subcellular localization of protein kinase C in unstimulated human neutrophils and neutrophils stimulated by phorbol-myristate-acetate (PMA), 1-oleoyl-2-acetyl-rac-glycerol (OAG), and ionomycin was investigated in subcellular fractions obtained by nitrogen cavitation and Percoll density gradient centrifugation. Protein kinase C was found to be localized mainly in the cytosol in unstimulated cells, whereas significant translocation to fractions containing the plasma membrane was observed after stimulation by PMA, OAG, and ionomycin. At the same time, phospholipid-insensitive protein kinase activity appeared in the cytosol and the plasma membrane fractions. To determine whether binding of protein kinase C occurred to the plasma membrane or to intracellular membranes that had translocated to the plasma membrane, we investigated the ability of isolated azurophil, specific and secretory granules, and plasma membrane vesicles to bind protein kinase C in response to addition of PMA and OAG. Only fractions containing plasma membranes and secretory granules were able to bind protein kinase C. The observation explains the selective activation of plasma membrane structures by protein kinase C.
...
PMID:Translocation of protein kinase C to subcellular fractions of human neutrophils. 271 84

A method for the cryogenic storage of the cAMP-dependent protein kinase from bovine cardiac muscle is described. The catalytic parameters, kcat, KM, and kcat/KM are used to assess the activity of the enzyme both prior and subsequent to the freeze-thaw cycle. The enzyme is stored in cryogenic vials at -196 degrees C in liquid nitrogen. Complete retention of catalytic activity is dependent upon a rapid and efficient freeze-thaw cycle and the use of morpholinepropanesulfonic acid as the buffer. In addition, this buffer appears to eliminate the KCl- or NaCl-induced damage typically observed for enzymes stored at low temperature in phosphate buffer. As a result, morpholinepropanesulfonic acid may prove to be a more appropriate cryopreservation buffer than phosphate when the presence of salt is required for enzyme solubility or stability.
...
PMID:Cryopreservation of the cyclic 3',5'-adenosine monophosphate-dependent protein kinase from bovine cardiac muscle. 273 19

Mutations in the SRA1 or SRA3 gene eliminate the requirement for either RAS gene (RAS1 or RAS2) in Saccharomyces cerevisiae. We cloned SRA1 and SRA3 and determined their DNA sequences. SRA1 encodes the regulatory subunit of the cyclic AMP (cAMP)-dependent protein kinase and therefore is identical to REG1 and BCY1. This gene is not essential, but its deletion confers many traits: reduction of glycogen accumulation, temperature sensitivity, reduced growth rate on maltose and sucrose, inability to grow on galactose and nonfermentable carbon sources, and nitrogen starvation intolerance. SRA3 is homologous to protein kinases that phosphorylate serine and threonine and likely encodes the catalytic subunit of the cAMP-dependent protein kinase. The wild-type SRA3 gene either triplicated in the chromosome or on episomal, low-copy plasmids behaves like spontaneous dominant SRA3 mutations by suppressing ras2-530 (RAS2::LEU2 disruption), cdc25, and cdc35 mutations. These findings indicate that the yeast RAS genes are dispensable if there is constitutive cAMP-dependent protein kinase activity.
...
PMID:Characterization of Saccharomyces cerevisiae genes encoding subunits of cyclic AMP-dependent protein kinase. 282

The NTRC protein (ntrC product) of enteric bacteria activates transcription of nitrogen-regulated genes by a holoenzyme form of RNA polymerase that contains the ntrA product (sigma 54) as sigma factor. Although unmodified NTRC will bind to DNA, it must be phosphorylated to activate transcription. Both phosphorylation and dephosphorylation of NTRC occur in the presence of the NTRB protein (ntrB product). We here demonstrate rigorously that it is the NTRB protein that is a protein kinase by showing that NTRB can phosphorylate itself, whereas NTRC cannot. Phosphorylated NTRC (NTRC-P) is capable of autodephosphorylation with a first-order rate constant of 0.14-0.19 min-1 (t 1/2 of 5.0-3.6 min) at 37 degrees C. In addition, there is regulated dephosphorylation of NTRC-P. By contrast to the autophosphatase activity, regulated dephosphorylation requires three components in addition to NTRC-P: the PII regulatory protein, NTRB, and ATP. NTRC is phosphorylated within its amino-terminal domain, which is conserved in one partner of a number of two-component regulatory systems in a wide variety of eubacteria. A purified amino-terminal fragment of NTRC (approximately equal to 12.5 kDa) is sufficient for recognition by NTRB and is autodephosphorylated at the same rate as the native protein.
...
PMID:Protein kinase and phosphoprotein phosphatase activities of nitrogen regulatory proteins NTRB and NTRC of enteric bacteria: roles of the conserved amino-terminal domain of NTRC. 283 25

<< Previous 1 2 3 4 5 6 7 8 9 10 Next >>