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)

In the heme-based oxygen sensor protein FixL, conformational changes induced by oxygen binding to the heme sensor domain regulate the activity of a neighboring histidine kinase, eventually restricting expression of specific genes to hypoxic conditions. The conserved arginine 220 residue is suggested to play a key role in the signal transduction mechanism. To obtain detailed insights into the role of this residue, we replaced Arg(220) by histidine (R220H), glutamine (R220Q), glutamate (R220E), and isoleucine (R220I) in the heme domain FixLH from Bradyrhizobium japonicum. These mutations resulted in dramatic changes in the O(2) affinity with K(d) values in the order R220I < R220Q < wild type < R220H. For the R220H and R220Q mutants, residue 220 interacts with the bound O(2) or CO ligands, as seen by resonance Raman spectroscopy. For the oxy-adducts, this H-bond modifies the pi acidity of the O(2) ligand, and its strength is correlated with the back-bonding-sensitive nu(4) frequency, the k(off) value for O(2) dissociation, and heme core-size conformational changes. This effect is especially strong for the wild-type protein where Arg(220) is, in addition, positively charged. These observations strongly suggest that neither strong ligand fixation nor the displacement of residue 220 into the heme distal pocket are solely responsible for the reported heme conformational changes associated with kinase activity regulation, but that a significant decrease of the heme pi(*) electron density because of strong back-bonding toward the oxygen ligand also plays a key role.
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PMID:Role of arginine 220 in the oxygen sensor FixL from Bradyrhizobium japonicum. 1571 Oct 13

Rhizobia directly regulate the expression of genes required for symbiotic nitrogen fixation in response to oxygen concentration via the sensor protein FixL. The N-terminal PAS domain of FixL contains a histidine-coordinated heme and regulates the activity of its effector domain, a C-terminal histidine kinase, in response to binding of oxygen and other ligands at the heme. To further investigate ligand-induced inhibition of FixL, we have determined the crystal structures of the heme domain in both the deoxy state and bound to carbon monoxide, a weak inhibitor of FixL kinase activity. Structures collected at room temperature are presented in each state from two crystallographic space groups at 1.8 and 2 A resolution. These structures reveal displacement of the residues of the H(beta) and I(beta) strands by Leu236 upon CO binding, and this structural change propagates more than 15 A to a region of the structure implicated in signal transduction in PAS proteins. Displacement of residues Ile215, Ile216, and Gly217 in the FG loop is also evident, accompanied by the movement of heme propionate 6 upon change in iron ligation. CO binding increases the temperature factors in the FG loop of the protein and disorders the side chain of Arg206, a conserved residue involved in the FG loop switch mechanism. We relate these results to structural changes in other PAS sensor domains and their involvement in catalytic control.
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PMID:Crystal structures of deoxy and CO-bound bjFixLH reveal details of ligand recognition and signaling. 1577 89

FixL proteins are bacterial heme-containing signal transduction proteins responsible for sensing the O(2) concentration in the organism's environment. In Sinorhizobium meliloti FixL is a protein histidine kinase that, together with its response regulator FixJ, constitute an oxygen-sensitive switch for regulation of the organism's nitrogen fixation and microaerobic respiration genes. The O(2) sensitivity of the switch is such that it transitions during the process of symbiosis in alfalfa roots. Bradyrhizobium japonicum FixL similarly regulates microaerobic and anaerobic respiration genes during symbiosis in soybean roots. FixLs responds to low oxygen concentrations with increased autophosphorylation activity of their kinase domains. The phosphorylated FixL provides a phosphoryl group to FixJ within a FixLJ complex. The phosphorylated FixJs are transcriptionally active toward their target genes. The FixL kinase domain is inhibited when the heme in FixL is oxygenated. Kinetic and thermodynamic studies of ligand binding to both ferrous and ferric FixLs have shown a generally low affinity for ligands relative to myoglobins. These relatively low ligand affinities are attributable almost completely to diminished rates of ligand binding. The heme and its environment in liganded and unliganded FixLs have been characterized by UV-visible spectroscopy, resonance Raman spectroscopy, EXAFS, and X-ray crystallography. These studies have revealed that in the purified proteins, the heme is converted from a six-coordinate low spin state to a five-coordinate high spin state upon O(2) release. Comparisons of spectroscopic and structural characteristics of deoxyFixL with oxyFixL, met-FixL-CN, FixL-CO, and FixL-NO complexes indicate that distal affects in the heme pocket are, at least in part, responsible for communicating the ligation state of the heme to the kinase domain. The mechanisms by which ligand binding events are communicated from the heme to the kinase domain involves propagation and/or amplification of the ligation-coupled conformational transitions of the heme and its immediate protein environment. More recently, time-resolved experiments examining the nonequilibrium, ligand-coupled dynamics initiated by O(2), CO, and NO photolysis from the corresponding FixL complexes have begun to shed light on the landscape of the switching coordinate. Current thinking and understanding of the mechanism for signal transduction in the FixLJ systems are discussed in the context of these physical investigations.
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PMID:Insights into heme-based O2 sensing from structure-function relationships in the FixL proteins. 1581 14

Principles of modular design are evident in signaling networks that detect and integrate a given signal and, depending on the organism in which the network module is present, transduce this signal to affect different metabolic or developmental pathways. Here we report a global transcriptional analysis of an oxygen sensory/signaling network in Caulobacter crescentus consisting of the sensor histidine kinase FixL, its cognate response regulator FixJ, the transcriptional regulator FixK, and the kinase inhibitor FixT. It is known that in rhizobial bacteria these proteins form a network that regulates transcription of genes required for symbiotic nitrogen fixation, anaerobic and microaerobic respiration, and hydrogen metabolism under hypoxic conditions. We have identified a positive feedback loop in this network and present evidence that the negative feedback regulator, FixT, acts to inhibit FixL by mimicking a response regulator. Overall, the core circuit topology of the Fix network is conserved between the rhizobia and C. crescentus, a free-living aerobe that cannot fix nitrogen, respire anaerobically, or metabolize hydrogen. In C. crescentus, the Fix network is required for normal cellular growth during hypoxia and controls expression of genes encoding four distinct aerobic respiratory terminal oxidases and multiple carbon and nitrogen metabolic enzymes. Thus, the Fix network is a conserved sensory/signaling module whose transcriptional output has been adapted to the unique physiologies of C. crescentus and the nitrogen-fixing rhizobia.
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PMID:Conserved modular design of an oxygen sensory/signaling network with species-specific output. 1591 51

The enteric pathogen Salmonella enterica is exposed to a number of stressful environments during its life cycle within and outside its various hosts. During intestinal colonisation Salmonella is successively exposed to acid pH in the stomach, to the detergent-like activity of bile, to decreasing oxygen supply, to the presence of multiple metabolites produced by the normal gut microflora and finally it is exposed to cationic antimicrobial peptides present on the surface of epithelial cells. There are four major regulators controlling relevant stress responses in Salmonella, namely RpoS, PhoPQ, Fur and OmpR/EnvZ. Except for Fur, inactivation of genes encoding the other stress regulators results in attenuated virulence and such mutants can therefore be considered as vaccine candidates. In contrast, a decrease in oxygen supply monitored by Fnr and ArcAB, or oxidative stress controlled by OxyR and SoxRS is not regarded as a stress associated with host colonisation since inactivation of either of these systems does not result in reductions in colonisation. The role of quorum-sensing through luxS and sdiA is also considered as a regulator of virulence and colonisation.
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PMID:Salmonella stress management and its relevance to behaviour during intestinal colonisation and infection. 1602 58

Over the last two decades, the biochemistry and genetics of dimethylsulfoxide (DMSO) and trimethylamine-N-oxide (TMAO) respiration has been characterised, particularly in Escherichia coli marine bacteria of the genus Shewanella and the purple phototrophic bacteria, Rhodobacter sphaeroides and R. capsulatus. All of the enzymes (or catalytic subunits) involved the final step in DMSO and TMAO respiration contain a pterin molybdenum cofactor and are members of the DMSO reductase family of molybdoenzymes. In E. coli, the dimethylsulfoxide reductase (DmsABC) can be purified from membranes as a complex, which exhibits quinol-DMSO oxidoreductase activity. The enzyme is anchored to the membrane via the DmsC subunit and its catalytic subunit DmsA is now considered to face the periplasm. Electron transfer to DmsA involves the DmsB subunit, which is a polyferredoxin related to subunits found in other molybdoenzymes such as nitrate reductase and formate dehydrogenase. A characteristic of the DmsAB-type DMSO reductase is its ability to reduce a variety of S- and N-oxides. E. coli contains a trimethylamine-N-oxide reductase (TorA) that is highly specific for N-oxides. This enzyme is located in the periplasm and is connected to the quinone pool via a membrane-bound penta-haem cytochrome (TorC). DorCA in purple phototrophic bacteria of the genus Rhodobacter is very similar to TorCA with the critical difference that DorA catalyses reduction of both DMSO and TMAO. It is known as a DMSO reductase because the S-oxide is the best substrate. Crystal structures of DorA and TorA have revealed critical differences at the Mo active site that may explain the differences between substrate specificity between the two enzymes. DmsA, TorA and DorA possess a "twin arginine" N-terminal signal sequence consistent with their secretion via the TAT secretory system and not the Sec system. The enzymes are secreted with their bound prosthetic groups: this take place in the cytoplasm and the biogenesis involves a chaperone protein, which is cognate for each enzyme. Expression of the DMSO and TMAO respiratory operons is induced in response to a fall in oxygen tension. dmsABC expression is positively controlled by the oxygen-responsive transcription factor, Fnr and ModE, a transcription factor that binds molybdate. In contrast, torCAD expression is not under Fnr- or ModE-control but is dependent upon a sensor histidine kinase-response regulator pair, TorSR, which activate gene expression under conditions of low oxygen tension in the presence of N- or S-oxide. Regulation of dorCDA expression is similar to that seen for torCAD but it appears that the expression of the sensor histidine kinase-response regulator pair, DorSR is regulated by Fnr and there is an additional tier of regulation involving the ModE-homologue MopB, molybdate and the transcription factor DorX. Analysis of microbial genomes has revealed the presence of dms and tor operons in a wide variety of bacteria and in some archaea and duplicate dms and tor operons have been identified in E. coli. Challenges ahead will include the determination of the significance of the presence of the dms operon in bacterial pathogens and the determination of the significance of DMSO respiration in the global turnover of marine organo-sulfur compounds.
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PMID:Microbial dimethylsulfoxide and trimethylamine-N-oxide respiration. 1622 80

BjFixL from Bradyrhizobium japonicum is a heme-based oxygen sensor implicated in the signaling cascade that enables the bacterium to adapt to fluctuating oxygen levels. Signal transduction is initiated by the binding of O(2) to the heme domain of BjFixL, resulting in protein conformational changes that are transmitted to a histidine kinase domain. We report structural changes of the heme and its binding pocket in the Fe(II) deoxy and Fe(III) met states of the wild-type BjFixLH oxygen sensor domain and four mutants of the highly conserved residue arginine 220. UV-visible, electron paramagnetic resonance, and resonance Raman spectroscopies all showed that the heme iron of the R220H mutant is unexpectedly six-coordinated at physiological pH in the Fe(III) state but undergoes pH- and redox-dependent coordination changes. This behavior is unprecedented for FixL proteins, but is reminiscent of another oxygen sensor from E. coli, EcDos. All mutants in their deoxy states are five-coordinated Fe(II), although we report rupture of the residue 220-propionate 7 interaction and structural modifications of the heme conformation as well as propionate geometry and flexibility. In this work, we conclude that part of the structural reorganization usually attributed to O(2) binding in the wild-type protein is in fact due to rupture of the Arg220-P7 interaction. Moreover, we correlate the structural modifications of the deoxy Fe(II) states with k(on) values and conclude that the Arg220-P7 interaction is responsible for the lower O(2) and CO k(on) values reported for the wild-type protein.
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PMID:Functional implications of the propionate 7-arginine 220 interaction in the FixLH oxygen sensor from Bradyrhizobium japonicum. 1647 96

Photoactivation of hypericin is known to generate reactive oxygen species and induce phototoxic effects. However, modulation of the cellular antioxidant defense would influence the extent and severity of the photodynamic effects. We have previously shown that hypericin-mediated photodynamic therapy (PDT) induced a significant reduction of Glutathione S-transferase activity. In this study, we investigated the phototoxic effects of hypericin-mediated PDT in nasopharyngeal cancer (NPC) in vitro and analyzed the expression of metallothionein (MT), a family of potential free radical scavengers. HK1 NPC cells were subjected to PDT treatment in vitro, and the effects on cell death were analyzed by flow cytometry (using propidium iodide and Annexin V staining) and transmission electron microscopy. The expression profile of MT-1E and MT-2A isoforms (the only functional MT isoforms expressed in HK1 NPC cells) were determined by quantitative real-time RT-PCR. The results showed that hypericin PDT induced necrotic cell death as evidenced by the absence of a subdiploid peak and decreased Annexin-V fluorescence. Ultrastructural examination verified the presence of cell necrosis. There was a significant up-regulation of MT-1E and MT-2A isoforms six hours following PDT, with an approximately 50-fold rise in the expression level of MT-1E and a 15-fold increase of MT-2A. Hence, despite the up-regulation of MT, cells still succumbed to PDT-induced necrosis. It appears that the oxidative stress induced by PDT overwhelmed the antioxidant defense mechanism such as the alteration of MT levels in tumor cells.
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PMID:Differential up-regulation of metallothionein isoforms in well-differentiated nasopharyngeal cancer cells in vitro by photoactivated hypericin. 1708 67

Fungal pathogens of humans require molecular oxygen for several essential biochemical reactions, yet virtually nothing is known about how they adapt to the relatively hypoxic environment of infected tissues. We isolated mutants defective in growth under hypoxic conditions, but normal for growth in normoxic conditions, in Cryptococcus neoformans, the most common cause of fungal meningitis. Two regulatory pathways were identified: one homologous to the mammalian sterol-response element binding protein (SREBP) cholesterol biosynthesis regulatory pathway, and the other a two-component-like pathway involving a fungal-specific hybrid histidine kinase family member, Tco1. We show that cleavage of the SREBP precursor homolog Sre1-which is predicted to release its DNA-binding domain from the membrane-occurs in response to hypoxia, and that Sre1 is required for hypoxic induction of genes encoding for oxygen-dependent enzymes involved in ergosterol synthesis. Importantly, mutants in either the SREBP pathway or the Tco1 pathway display defects in their ability to proliferate in host tissues and to cause disease in infected mice, linking for the first time to our knowledge hypoxic adaptation and pathogenesis by a eukaryotic aerobe. SREBP pathway mutants were found to be a hundred times more sensitive than wild-type to fluconazole, a widely used antifungal agent that inhibits ergosterol synthesis, suggesting that inhibitors of SREBP processing could substantially enhance the potency of current therapies.
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PMID:A link between virulence and homeostatic responses to hypoxia during infection by the human fungal pathogen Cryptococcus neoformans. 1731 42

The FixL protein of Bradyrhizobium japonicum is a dimeric oxygen sensor responsible for initiating regulation of transcription of genes encoding proteins involved in nitrogen fixation and oxidative stress. It consists of an N-terminal heme-bound PAS domain, denoted bjFixLH, and a C-terminal histidine kinase domain whose enzymatic activity depends on the ligation state of the heme. To investigate the molecular basis for this dependence and the dynamics associated with conversion between ligated and unligated states, we have conducted time-resolved Laue diffraction studies of CO recombination in bjFixLH. Time-dependent difference Fourier maps from 1 micros to 10 ms after photolysis of the heme-CO bond show movement of the side chain of Leu236 and the H and I beta-strands into the ligand binding pocket formerly occupied by CO. Long-range conformational changes are evident in the protein, driven by relaxation of steric interactions between the bound ligand and amino acid side chains and/or changes in heme stereochemistry. These structural changes fully reverse as CO rebinds to the heme. Spectroscopic measurements of CO recombination kinetics in bjFixLH crystals relate the behavior of crystalline bjFixLH to solution and provide a framework for our time-resolved crystallographic experiments. Analysis of the time-dependent difference Fourier maps by singular value decomposition reveals that only one significant singular value accounts for the data. Thus only two structural states are present, the photolyzed and the CO-bound states. The first left singular vector represents the difference in density between these two states and shows features common to difference maps calculated from the static CO and deoxy states. The first right singular vector represents the time course of this difference density and agrees well with the CO recombination kinetics measured spectroscopically. We refine the structure of the photolyzed state present in the early-microsecond time range and find that it does not differ significantly in conformation from static, deoxy bjFixLH. Thus, structural relaxation from CO-bound to deoxy bjFixLH is complete in less than 1 micros.
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PMID:Time-resolved crystallographic studies of the heme domain of the oxygen sensor FixL: structural dynamics of ligand rebinding and their relation to signal transduction. 1738 95


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