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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)
In the Escherichia coli chemotaxis system, a family of chemoreceptors in the cytoplasmic membrane binds stimulatory ligands and regulates the activity of an associated
histidine kinase
CheA to modulate swimming behaviour and thereby cause a net migration towards attractants and away from repellents. The chemoreceptors themselves have been shown to be predominantly dimeric, but in the presence of the kinase CheA plus an
adapter protein
, CheW, much higher order structures have been observed. Recent results indicate that transmembrane signalling occurs within receptor clusters rather than through isolated dimers. We propose that the mechanism involves receptor arrays where binding of ligands at the outside surface of the membrane affects lateral packing interactions that cause perturbations in the organization of the signalling array at the opposing surface of the membrane. Results with receptor chimeras as well as findings with tyrosine kinase receptors suggest that this mechanism may represent a common theme in membrane receptor function.
...
PMID:Stimulus response coupling in bacterial chemotaxis: receptor dimers in signalling arrays. 982 12
The chemotaxis receptor for aspartate, Tar, generates responses by regulating the activity of an associated
histidine kinase
, CheA. Tar is composed of an extracellular sensory domain connected by a transmembrane sequence to a cytoplasmic signaling domain. The cytoplasmic domain fused to a leucine zipper dimerization domain forms soluble active ternary complexes with CheA and an
adapter protein
, CheW. The kinetics of kinase activity within these complexes compared to CheA alone indicate approximately a 50% decrease in the KM for ATP and a 100-fold increase in the Vmax. A truncated CheA construct that lacks the phosphoaccepting H-domain and the CheY/CheB-binding domain forms an activated ternary complex that is similar to the one formed by the full-length CheA protein. The Vmax of H-domain phosphorylation by this complex is enhanced approximately 60-fold, the KM for ATP decreased to 50%, and the KM for H-domain decreased to 20% of the values obtained with the same CheA construct in the absence of receptor and CheW. The kinetic data support a mechanism of CheA regulation that involves perturbation of an equilibrium between an inactive form where the H-domain is loosely bound and an active form where the H-domain is tightly associated with the CheA active site and properly positioned for phosphotransfer. The data are consistent with an asymmetric mechanism of CheA activation [Levit, M., Liu, I., Surette, M. G., and Stock, J. B. (1996) J. Biol. Chem. 271, 32057-32063] wherein only one phosphoaccepting domain of CheA at a time can interact with an active center within a CheA dimer.
...
PMID:Mechanism of CheA protein kinase activation in receptor signaling complexes. 1035 Apr 84
Appressorium formation plays a critical role in Magnaporthe oryzae. Mst50 is an
adapter protein
of the Mst11-Mst7-Pmk1 cascade that is essential for appressorium formation. To further characterize its functions, affinity purification was used to identify Mst50-interacting proteins (MIPs) in this study. Two of the MIPs are Mst11 and Mst7 that are known to interact with Mst50 for Pmk1 activation. Surprisingly, two other MIPs are Mck1 and Mkk2 that are the upstream kinases of the Mps1 pathway. Domain deletion analysis showed that the sterile alpha-motif of Mst50 but not the Ras-association domain was important for its interaction with Mck1 and responses to cell wall and oxidative stresses. The mst50 mutant was reduced in Mps1 activation under stress conditions. MIP11 encodes a RACK1 protein that also interacted with Mck1. Deletion of MIP11 resulted in defects in cell wall integrity, Mps1 phosphorylation and plant infection. Furthermore, Mst50 interacted with
histidine kinase
Hik1, and the mst50 mutant was reduced in Osm1 phosphorylation. These results indicated that Mst50 is involved in all three MAPK pathways in M. oryzae although its functions differ in each pathway. Several MIPs are conserved hypothetical proteins and may be involved in responses to various signals and crosstalk among signaling pathways.
...
PMID:MST50 is involved in multiple MAP kinase signaling pathways in Magnaporthe oryzae. 2824 40
Twitching motility-mediated biofilm expansion occurs via coordinated, multi-cellular collective behaviour to allow bacteria to actively expand across surfaces. Type-IV pili (T4P) are cell-associated virulence factors which mediate twitching motility via rounds of extension, surface attachment and retraction. The Chp chemosensory system is thought to respond to environmental signals to regulate the biogenesis, assembly and twitching motility function of T4P. In other well characterised chemosensory systems, methyl-accepting chemotaxis proteins (MCPs) feed environmental signals through a CheW
adapter protein
to the
histidine kinase
CheA to modulate motility. The
Pseudomonas aeruginosa
Chp system has an MCP PilJ and two CheW adapter proteins, PilI and ChpC, that likely interact with the
histidine kinase
ChpA to feed environmental signals into the system. In the current study we show that ChpC is involved in the response to host-derived signals serum albumin, mucin and oligopeptides. We demonstrate that these signals stimulate an increase in twitching motility, as well as in levels of 3'-5'-cyclic adenosine monophosphate (cAMP) and surface-assembled T4P. Interestingly, our data shows that changes in cAMP and surface piliation levels are independent of ChpC but that the twitching motility response to these environmental signals requires ChpC. Furthermore, we show that protease activity is required for the twitching motility response of
P. aeruginosa
to environmental signals. Based upon our data we propose a model whereby ChpC feeds these environmental signals into the Chp system, potentially via PilJ or another MCP, to control twitching motility. PilJ and PilI then modulate T4P surface levels to allow the cell to continue to undergo twitching motility. Our study is the first to link environmental signals to the Chp chemosensory system and refines our understanding of how this system controls twitching motility-mediated biofilm expansion in
P. aeruginosa
.
...
PMID:ChpC controls twitching motility-mediated expansion of
Pseudomonas aeruginosa
biofilms in response to serum albumin, mucin and oligopeptides. 3247 53
