Polar accumulation of the metabolic sensory histidine kinases DcuS and CitA in Escherichia coli

Scheu, Patrick D.; Sdorra, Sven; Liao, Yun-Feng; Wegner, M.; Basché, Thomas; Unden, Gottfried; Erker, Wolfgang

doi:10.1099/mic.0.2008/018614-0

Cited by 20 publications

(33 citation statements)

References 37 publications

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“…3B, lanes 2 to 5) showed an approximately 8-to 10-fold increase in the content of DcuS (Fig. 3B) (37). But again, all samples with detectable DcuS contained DcuS of the 61-kDa, the 120-kDa, and the major 240-kDa form, and there was no overproportional increase for the high-M r forms of DcuS with increasing induction of DcuS.…”

Section: Resultsmentioning

confidence: 97%

“…The fusions were placed on different plasmids within E. coli cells. In the DcuS-YFP fusion (encoded by pMW407), the DcuS protein is still functional in sensing and signal transduction in vivo (Table 2), and the YFP protein shows normal fluorescence (37). The DcuS-CFP fusion protein (encoded by pMW408) was tested in a similar way for the functionality of DcuS.…”

Section: Resultsmentioning

confidence: 99%

“…3B). E. coli containing the low-copy-number DcuS CysϪ expression plasmid pMW967 was induced for increasing levels of DcuS CysϪ by increasing the levels of the inducer (0 to 333 M arabinose), as described earlier (37). The proteins from the cell homogenate were subjected to SDS-PAGE and analyzed for DcuS by immunoblotting.…”

Section: Resultsmentioning

confidence: 99%

“…The FRET studies were performed with DcuS fused to the CFP or YFP derivative of the GFP protein or with DcuS labeled chemically with fluorescent dyes. DcuS forms stable fusion proteins with CFP or YFP, as tested earlier by immunoblotting (37). For quantitative and reproducible analysis of FRET efficiency, a method described by Gordon et al (12) was extended.…”

Section: Resultsmentioning

confidence: 99%

“…The dcuS-YFP fusion (pMW407) was constructed and cloned into pBAD30 as described previously (37). The dcuS-CFP fusion was constructed in the same way, whereas the ECFP gene was amplified from plasmid pECFP (Clontech) and dcuS-CFP was finally cloned from pMW386 via XbaI into pBAD18-Kan.…”

Section: Methodsmentioning

confidence: 99%

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Oligomeric Sensor Kinase DcuS in the Membrane of Escherichia coli and in Proteoliposomes: Chemical Cross-linking and FRET Spectroscopy

et al. 2010

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DcuS is the membrane-integral sensor histidine kinase of the DcuSR two-component system inThe DcuSR (dicarboxylate uptake sensor and regulator) system of Escherichia coli is a typical two-component system consisting of a membranous sensor kinase (DcuS) and a cytoplasmic response regulator (DcuR) (11,26,48). DcuS responds to C 4 -dicarboxylates like fumarate, malate, or succinate (19). In the presence of the C 4 -dicarboxlates, the expression of the genes of anaerobic fumarate respiration (dcuB, fumB, and frdABCD) and of aerobic C 4 -dicarboxylate uptake (dctA) is activated. DcuS is a histidine protein kinase composed of two transmembrane helices with an intermittent sensory PAS domain in the periplasm (PAS P ) that was also termed the PDC domain (for PhoQ/DcuS/DctB/CitA domain or fold) (7,20,32,48). The second transmembrane helix is followed by a cytoplasmic PAS domain (PAS C ) and the C-terminal transmitter domain. PAS C functions in signal transfer from transmembrane helix 2 (TM2) to the kinase domain (9). The C-terminal part of the transmitter domain consists of a catalytic or HATPase (histidine kinase/ATPase) subdomain for autophosphorylation of DcuS (16). The N-terminal part of the transmitter contains two conserved ␣-helical regions, including a conserved His residue which is the site for autophosphorylation. The ␣-helices serve in dimerization and form a four-helix bundle in the kinase dimer (dimerization and histidine phosphotransfer [DHp] domain) (25,35,42,44).The dimeric sensor kinases have been supposed to phosphorylate mutually, by the catalytic domain of one monomer, the His residue of the partner monomer (10). The oligomeric state of the membrane-bound sensor kinases EnvZ and VirA was also deduced from in vivo complementation studies (31,46). In addition, signal transduction across the membrane and along cytoplasmic PAS domains appears to be a mechanical process requiring oligomeric proteins (9, 40). Therefore, His kinases are supposed to be dimeric in the functional state, but a higher oligomeric state has not been tested and is conceivable. Only a limited number of membrane-bound sensor kinases have been studied for their oligomerization in their membrane-bound state. Thus, the oligomeric state of the KdpD and TorS sensor kinases of E. coli have been shown to prevail in the detergent-solubilized state as oligomers, presumably dimers (14, 29). There was indirect information that functional DcuS is a dimer as well. Purified DcuS shows kinase activity only after reconstitution into liposomes, and phosphorylation is stimulated by C 4 -dicarboxylates (16,19). Detergentsolubilized DcuS, on the other hand, shows no kinase activity,

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Section: Resultsmentioning

confidence: 97%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Oligomeric Sensor Kinase DcuS in the Membrane of Escherichia coli and in Proteoliposomes: Chemical Cross-linking and FRET Spectroscopy

et al. 2010

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The cytoplasmic PAS_C domain of the sensor kinase DcuS of Escherichia coli: role in signal transduction, dimer formation, and DctA interaction

et al. 2013

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The cytoplasmic PASC domain of the fumarate responsive sensor kinase DcuS of Escherichia coli links the transmembrane to the kinase domain. PASC is also required for interaction with the transporter DctA serving as a cosensor of DcuS. Earlier studies suggested that PASC functions as a hinge and transmits the signal to the kinase. Reorganizing the PASC dimer interaction and, independently, removal of DctA, converts DcuS to the constitutive ON state (active without fumarate stimulation). ON mutants were categorized with respect to these two biophysical interactions and the functional state of DcuS: type I-ON mutations grossly reorganize the homodimer, and decrease interaction with DctA. Type IIA-ON mutations create the ON state without grossly reorganizing the homodimer, whereas interaction with DctA is decreased. The type IIB-ON mutations were neither in PASC/PASC, nor in DctA/DcuS interaction affected, similar to fumarate activated wild-typic DcuS. OFF mutations never affected dimer stability. The ON mutations provide novel mechanistic insight: PASC dimerization is essential to silence the kinase. Reorganizing the homodimer and its interaction with DctA activate the kinase. The study suggests a novel ON homo-dimer conformation (type IIB) and an OFF conformation for PASC. Type IIB-ON corresponds to the fumarate induced wild-type conformation, representing an interesting target for structural biology.

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Cooperation of Secondary Transporters and Sensor Kinases in Transmembrane Signalling

Unden

Wörner

Monzel

2016

Advances in Microbial Physiology

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Polar accumulation of the metabolic sensory histidine kinases DcuS and CitA in Escherichia coli

Cited by 20 publications

References 37 publications

Oligomeric Sensor Kinase DcuS in the Membrane of Escherichia coli and in Proteoliposomes: Chemical Cross-linking and FRET Spectroscopy

Oligomeric Sensor Kinase DcuS in the Membrane of Escherichia coli and in Proteoliposomes: Chemical Cross-linking and FRET Spectroscopy

The cytoplasmic PAS_C domain of the sensor kinase DcuS of Escherichia coli: role in signal transduction, dimer formation, and DctA interaction

Cooperation of Secondary Transporters and Sensor Kinases in Transmembrane Signalling

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Polar accumulation of the metabolic sensory histidine kinases DcuS and CitA in Escherichia coli

Cited by 20 publications

References 37 publications

Oligomeric Sensor Kinase DcuS in the Membrane of Escherichia coli and in Proteoliposomes: Chemical Cross-linking and FRET Spectroscopy

Oligomeric Sensor Kinase DcuS in the Membrane of Escherichia coli and in Proteoliposomes: Chemical Cross-linking and FRET Spectroscopy

The cytoplasmic PASC domain of the sensor kinase DcuS of Escherichia coli: role in signal transduction, dimer formation, and DctA interaction

Cooperation of Secondary Transporters and Sensor Kinases in Transmembrane Signalling

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The cytoplasmic PAS_C domain of the sensor kinase DcuS of Escherichia coli: role in signal transduction, dimer formation, and DctA interaction