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:2.7.13.3 (histidine kinase)
2,405 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Taz1 is a hybrid receptor in the Escherichia coli cytoplasmic membrane, consisting of the N-terminal ligand binding domain of Tar (a chemoreceptor for aspartate) and the C-terminal signaling domain of EnvZ (an osmosensor). The binding of aspartate to an extra cytoplasmic domain induces the transmembrane signal to the cytoplasmic signaling domain. The signaling domain functioning as a protein kinase evokes a response by transferring a phosphate from an intracellular histidine to OmpR. This domain also encodes an OmpR-specific phosphatase whose action is crucial in completing the OmpR phosphorylation cycle. Phosphorylated OmpR acts as a transcriptional activator for the ompC gene. A number of mutations were introduced into the signaling domain in conserved sequences of the prokaryotic histidine kinase family. All Taz1 mutants lost the ability to both autophosphorylate the histidine residue and transfer the phosphate to OmpR. These mutated receptors were unable to activate ompC-lacZ expression. However, ompC-lacZ was able to be activated by complementation of Taz1 mutants. In some combinations, two different defective Taz1 mutants could restore both OmpR kinase and phosphatase activities when co-expressed. In other combinations only kinase activity was restored. Aspartate-inducible ompC-lacZ expression was restored only in the former cases, while in the latter cases ompC-lacZ expression became constitutive. These results indicate that the kinase activity is essential to activate ompC expression while the phosphatase activity is required to regulate ompC gene expression in a ligand-dependent manner.
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PMID:Requirement of both kinase and phosphatase activities of an Escherichia coli receptor (Taz1) for ligand-dependent signal transduction. 838 84

Eukaryotic cellular proteins contain phosphohistidine. To search for protein histidine phosphatases, protein histidine kinase from Saccharomyces cerevisiae was used to phosphorylate histone H4 on histidine at position 75 in the H4 amino acid sequence. Incubation of the phosphorylated histone H4 with either protein phosphatase 1, 2A, or 2C resulted in extensive removal of phosphate from the phosphorylated histone. Thus, protein phosphatases 1, 2A, and 2C are histidine phosphatases as well as serine/threonine phosphatases. Calcium/calmodulin-regulated protein phosphatase (protein phosphatase 2B) did not remove phosphate from phosphohistidine. The histidine phosphatase reaction was tested for a magnesium requirement and effects of inhibitor-1 and okadaic acid. In all cases, the protein phosphatases behaved as they do in their serine/threonine phosphatase activity. Extracts of the yeast, S. cerevisiae, contain protein histidine phosphatase activity. Quantitative measurement of phosphatase activity shows that the activity against phosphohistidine is a major activity of protein phosphatases 1, 2A, and 2C.
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PMID:Protein phosphatases 1, 2A, and 2C are protein histidine phosphatases. 839 6

Pseudomonas solanacearum, an important wilt pathogen of many plants, produces several extracellular proteins (EXPs) and extracellular polysaccharides (EPSs) that contribute to its virulence. Using TnphoA mutagenesis, we discovered a new gene, vsrB, that when inactivated causes a major reduction in the virulence and production of an EPS. Analysis of eps::lacZ reporters showed that vsrB is required for maximal expression (transcription) of eps, whose products are required for production of EPS I, a major virulence determinant. Analysis of EXPs in culture supernatants revealed that inactivation of vsrB also causes reduced production of two major EXPs, with molecular masses of 28 and 97 kDa, and a simultaneous 15-fold increase in levels of another EXP, PglA endopolygalacturonase. The vsrB gene was cloned from a P. solanacearum genomic library by complementation of the nonmucoid phenotype of the vsrB::TnphoA mutant and then subcloned on a 2.4-kb DNA fragment. TnphoA fusion analysis and subcellular localization of the vsrB gene product in Escherichia coli maxicells suggest that it is a ca. 60-kDa transmembrane protein. The nucleotide sequence of the 2.4-kb DNA fragment was determined, and a 638-amino-acid open reading frame was found for VsrB. A search of the GenBank data base found that the central part of VsrB has homology with the histidine kinase domain of sensors in the two-component regulator family, while the C terminus has homology with the phosphate receiver domain of response regulators in the same family. Genetic analysis suggests that the receiver domain is not required for vsrB function.
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PMID:vsrB, a regulator of virulence genes of Pseudomonas solanacearum, is homologous to sensors of the two-component regulator family. 840 89

EnvZ of Escherichia coli is a transmembrane histidine kinase belonging to the family of two-component signal transducing systems prevalent in prokaryotes and recently discovered in eukaryotes. In response to changes in medium osmolarity EnvZ regulates the level of phosphorylated OmpR, its conjugate response-regulating transcription factor for ompF and ompC genes. EnvZ has dual opposing enzymatic activities; OmpR-phosphorylase (kinase) and phospho-OmpR-dephosphorylase (phosphatase). The osmotic signal is proposed to regulate the ratio of the kinase to the phosphatase activities of EnvZ to modulate the level of OmpR phosphorylation. In this work we used a COOH-terminal fragment of a previously identified kinase-/phosphatase+ EnvZ mutant (EnvZ-N347D) to demonstrate that the phosphoryl group on phospho-OmpR is transferred back to EnvZ to the same histidine residue (His243) that is utilized for the autokinase reaction by the wild type protein. Phospho-EnvZ-N347D thus formed could also transfer its phosphoryl group back to OmpR. The phosphotransfer reaction from phospho-OmpR to EnvZ.N347D was inhibited by ADP while Mg2+ ions stimulated the dephosphorylation reaction, resulting in release of inorganic phosphate. These results indicate that the energy levels of phosphoryl groups on OmpR and EnvZ are very similar and that the phosphatase reaction in the EnvZ.N347D mutant involves a reversal of the phosphotransfer reaction from EnvZ to OmpR using the identical His243 residue.
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PMID:Reverse phosphotransfer from OmpR to EnvZ in a kinase-/phosphatase+ mutant of EnvZ (EnvZ.N347D), a bifunctional signal transducer of Escherichia coli. 857 33

A mutant which failed to complete development was isolated from a population of cells that had been subjected to insertional mutagenesis using restriction enzyme-mediated integration. The disrupted gene, dhkA, encodes the conserved motifs of a histidine kinase as well as the response regulator domain. It is likely that the histidine in DhkA is autophosphorylated and the phosphate passed to one or more response regulators. Such two-component systems function in a variety of bacterial signal transduction pathways and have been characterized recently in yeast and Arabidopsis. In Dictyostelium, we found that DhkA functions both in the regulation of prestalk gene expression and in the control of the terminal differentiation of prespore cells.
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PMID:A two-component histidine kinase gene that functions in Dictyostelium development. 867 Aug 94

In Escherichia coli the histidine kinase sensor protein, EnvZ, undergoes autophosphorylation and subsequently phosphorylates the regulatory protein, OmpR. Modulation of the levels of OmpR-phosphate controls the differential expression of ompF and ompC. While the phosphotransfer reaction between EnvZ and OmpR has been extensively studied, the domains involved in the sensing function of EnvZ are not well understood. We have used a comparative approach to study the sensing function of EnvZ. During our search of numerous bacteria we found that the symbiotic/pathogenic bacterium Xenorhabdus nematophilus contained the operon encoding both ompR and envZ. Nucleotide sequence analysis revealed that EnvZ of X. nematophilus (EnvZX.n.) is composed of 342 amino acid residues, which is 108 residues shorter than EnvZ of E. coli (EnvZE.c.). Amino acid sequence comparison showed that the cytoplasmic domains of the EnvZ molecules shared 57% sequence identity. In contrast, the large hydrophilic periplasmic domain of EnvZE.c. was absent in EnvZX.n., and was replaced by a shorter hydrophobic region. Although the periplasmic domains had diverged extensively, envZX.n. was able to complement a delta envZ strain of E. coli. OmpF and OmpC were differentially produced in response to changes in medium osmolarity in this strain. Further genetic analysis established that heterologous phosphorylation between EnvZX.n. and OmpR of E. coli (OmpRE.c.) accounted for the complementation of the delta envZ strain. In addition we show that the OmpR molecules of X. nematophilus and E. coli share 78% amino acid sequence identity. These results indicate that the EnvZ protein of X. nematophilus was able to sense these changes in the osmolarity of the growth environment and properly regulate the levels of OmpR-phosphate in E. coli.
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PMID:Molecular analysis of the two-component genes, ompR and envZ, in the symbiotic bacterium Xenorhabdus nematophilus. 880 19

An osmosensing mechanism in the budding yeast (Saccharomyces cerevisiae) involves both a two-component signal transducer (Sln1p, Ypd1p and Ssk1p) and a MAP kinase cascade (Ssk2p/Ssk22p, Pbs2p, and Hog1p). The transmembrane protein Sln1p contains an extracellular sensor domain and cytoplasmic histidine kinase and receiver domains, whereas the cytoplasmic protein Ssk1p contains a receiver domain. Ypd1p binds to both Sln1p and Ssk1p and mediates the multistep phosphotransfer reaction (phosphorelay). This phosphorelay system is initiated by the autophosphorylation of Sln1p at His576. This phosphate is then sequentially transferred to Sln1p-Asp-1144, then to Ypd1p-His64, and finally to Ssk1p-Asp554. We propose that the multistep phosphorelay mechanism is a universal signal transduction apparatus utilized both in prokaryotes and eukaryotes.
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PMID:Yeast HOG1 MAP kinase cascade is regulated by a multistep phosphorelay mechanism in the SLN1-YPD1-SSK1 "two-component" osmosensor. 880 22

PhoB is a response-regulator protein from Escherichia coli that controls an adaptive response to limiting phosphate. It is activated by autophosphorylation of a conserved aspartate residue within its regulatory domain. Its primary phospho-donor is its cognate histidine kinase PhoR; however, it also becomes phosphorylated when incubated with acetylphosphate. To further characterize its activation, PhoB was considered to be an acetylphosphatase whose enzymatic mechanism involves a phospho-enzyme intermediate. The kinetic constants for autophosphorylation were determined using 32P-and fluorescence-based assays and indicated that PhoB has a K(m) for acetylphosphate of between 7 and 8 mM. These constants are not consistent with an in vivo role for acetylphosphate in the normal control of the Pho regulon. In addition, when PhoB was phosphorylated by acetylphosphate it eluted from a high-performance liquid chromatography (HPLC) size-exclusion column in two peaks. The larger form of PhoB eluted from the column in a similar manner to a chemically cross-linked dimer of PhoB. The smaller form of PhoB is a monomer. Phosphorylated PhoB bound pho-box DNA approximately 10 times tighter than PhoB. These observations show that PhoB forms a dimer when phosphorylated and suggest that the characteristics of activated PhoB result from its dimerization.
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PMID:The activation of PhoB by acetylphosphate. 880 68

Three signalling pathways lead to activation of the phosphate (Pho) regulon by phosphorylation of the response-regulator PhoB in Escherichia coli. One pathway responds to the extracellular inorganic phosphate (PI) level and leads to activation by the Pi sensor kinase, PhoR. The other two pathways are Pi independent and are apparent in the absence of PhoR. One Pi-independent pathway responds to the level of an unknown catabolite and leads to activation by the catabolite regulatory sensor kinase, CreC (originally called PhoM); the other Pi-independent pathway responds to acetyl phosphate and leads to activation by a process requiring acetyl phosphate. Here we show that activation of PhoB by acetyl phosphate can require the sensor kinase EnvZ. Accordingly, we propose that the in vivo activation of PhoB by acetyl phosphate (and perhaps other two-component response-regulators as well) probably always requires a certain kinase that can vary depending upon the growth conditions.
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PMID:Involvement of the sensor kinase EnvZ in the in vivo activation of the response-regulator PhoB by acetyl phosphate. 889 16

In Escherichia coli, EnvZ senses changes in the osmotic conditions of the growth environment and controls the phosphorylated state of the regulatory protein, OmpR. OmpR-phosphate regulates the expression of the porin genes, ompF and ompC. To investigate the role of the periplasmic domain of EnvZ in sensing of osmolarity signals, portions of this domain were deleted. Cells containing the EnvZ mutant proteins were able to regulate normally the production of OmpF and OmpC in response to changes in osmolarity. The periplasmic domain of EnvZ was also replaced with the non-homologous periplasmic domain of the histidine kinase PhoR of Bacillus subtilis. Osmoregulation of OmpF and OmpC production in cells containing the PhoR-EnvZ hybrid protein was indistinguishable from that in cells containing wild-type EnvZ. Identical results were obtained with an envZ-pta/ack strain, which could not synthesize acetyl phosphate. Thus, acetyl phosphate was not involved in the regulation of ompF and ompC observed in this study. These results indicate that the periplasmic domain of EnvZ is not essential for sensing of osmolarity signals.
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PMID:Re-examination of the role of the periplasmic domain of EnvZ in sensing of osmolarity signals in Escherichia coli. 893 25


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