Structural plasticity and catalysis regulation of a thermosensor histidine kinase

Albanesi, Daniela; Martín, Mariana; Trajtenberg, F.; Mansilla, María C.; Haouz, Ahmed; Alzari, Pedro M.; Mendoza, Diego de; Buschiazzo, Alejandro

doi:10.1073/pnas.0906699106

Cited by 162 publications

(303 citation statements)

References 36 publications

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“…Intragenic complementation results described above for both NarX and NarQ homodimers are compatible only with the intermolecular autophosphorylation mechanism (Yang & Inouye, 1991), in accordance with the structural and biochemical data for DesK (Albanesi et al, 2009;Trajtenberg et al, 2010). This highlights the substantial differences in detail for reaction mechanisms employed by the two transmitter sequence families (Huynh et al, 2010).…”

Section: Narx and Narq Sensors Undergo Intermolecular Autophosphorylasupporting

confidence: 66%

“…Structural analysis and cross-linking experiments document intermolecular sensor autophosphorylation (Albanesi et al, 2009;Trajtenberg et al, 2010), even though its DHp domain loop is left-handed (Ashenberg et al, 2013). However, unlike the HisKA (HPK1-4) family DHp domains described above, the DesK DHp domain is in the distinct HisKA_3 (HPK7) family together with NarX and NarQ (Grebe & Stock, 1999).…”

Section: Narx and Narq Sensors Undergo Intermolecular Autophosphorylamentioning

confidence: 99%

“…The NarX DHp domain model (Fig. 1a) was constructed in SWISS-MODEL (Bordoli et al, 2009), and is based on the X-ray structure of the homologous DesK sensor (Albanesi et al, 2009), PDB accession number 3EHJ.…”

Section: Methodsmentioning

confidence: 99%

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Sensor–response regulator interactions in a cross-regulated signal transduction network

2015

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Two-component signal transduction involves phosphoryl transfer between a histidine kinase sensor and a response regulator effector. The nitrate-responsive two-component signal transduction systems in Escherichia coli represent a paradigm for a cross-regulation network, in which the paralogous sensor-response regulator pairs, NarX-NarL and NarQ-NarP, exhibit both cognate (e.g. NarX-NarL) and non-cognate (e.g. NarQ-NarL) interactions to control output. Here, we describe results from bacterial adenylate cyclase two-hybrid (BACTH) analysis to examine sensor dimerization as well as interaction between sensor-response regulator cognate and non-cognate pairs. Although results from BACTH analysis indicated that the NarX and NarQ sensors interact with each other, results from intragenic complementation tests demonstrate that they do not form functional heterodimers. Additionally, intragenic complementation shows that both NarX and NarQ undergo intermolecular autophosphorylation, deviating from the previously reported correlation between DHp (dimerization and histidyl phosphotransfer) domain loop handedness and autophosphorylation mode. Results from BACTH analysis revealed robust interactions for the NarX-NarL, NarQ-NarL and NarQ-NarP pairs but a much weaker interaction for the NarX-NarP pair. This demonstrates that asymmetrical cross-regulation results from differential binding affinities between different sensor-regulator pairs. Finally, results indicate that the NarL effector (DNA-binding) domain inhibits NarX-NarL interaction. Missense substitutions at receiver domain residue Ser-80 enhanced NarX-NarL interaction, apparently by destabilizing the NarL receiver-effector domain interface.

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Section: Narx and Narq Sensors Undergo Intermolecular Autophosphorylasupporting

confidence: 66%

Section: Narx and Narq Sensors Undergo Intermolecular Autophosphorylamentioning

confidence: 99%

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Sensor–response regulator interactions in a cross-regulated signal transduction network

2015

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“…Most systems consist of a sensor protein that exerts both positive and negative control on a cognate response regulator. Well-studied examples include nitrate regulation by NarXNarL, general nitrogen regulation by NtrB-NtrC (also termed NRII-NRI), osmoregulation by EnvZ-OmpR (1), and membrane fluidity regulation by DesK-DesR (2).…”

mentioning

confidence: 99%

“…Wellstudied examples of HisKA_3 members include E. coli NarX; Mycobacterium tuberculosis DosS and DosT, which control dormancy (18); Staphylococcus aureus VraS, which mediates cellenvelope stress response (19); and Bacillus subtilis DesK with available transmitter module X-ray structures (2,16).…”

mentioning

confidence: 99%

Conserved mechanism for sensor phosphatase control of two-component signaling revealed in the nitrate sensor NarX

Huynh¹,

Noriega

Stewart

2010

Proc. Natl. Acad. Sci. U.S.A.

124

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Two-component signal transduction mediates a wide range of phenotypes in microbes and plants. The sensor transmitter module controls the phosphorylation state of the cognate-responseregulator receiver domain. Whereas the two-component autokinase and phosphotransfer reactions are well-understood, the mechanism by which sensors accelerate the rate of phosphoresponse regulator dephosphorylation, termed "transmitter phosphatase activity," is unknown. We identified a conserved DxxxQ motif adjacent to the phospho-accepting His residue in the HisKA_3 subfamily of two-component sensors. We used site-specific mutagenesis to make substitutions for these conserved Gln and Asp residues in the nitrate-responsive NarX sensor and analyzed function both in vivo and in vitro. Results show that the Gln residue is critical for transmitter phosphatase activity, but is not essential for autokinase or phosphotransfer activities. The documented role of an amide moiety in phosphoryl group hydrolysis suggests an analogous catalytic function for this Gln residue in HisKA_3 members. Results also indicate that the Asp residue is important for both autokinase and transmitter phosphatase activities. Furthermore, we noted that sensors of the HisKA subfamily exhibit an analogous E/DxxT/N motif, the conserved Thr residue of which is critical for transmitter phosphatase activity of the EnvZ sensor. Thus, twocomponent sensors likely use similar mechanisms for receiver domain dephosphorylation.histidine kinase | DHp domain | DesK

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Transmembrane Signal Transduction in Two‐Component Systems: Piston, Scissoring, or Helical Rotation?

Gushchin

Gordeliy

2017

BioEssays

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Allosteric and transmembrane (TM) signaling are among the major questions of structural biology. Here, we review and discuss signal transduction in four-helical TM bundles, focusing on histidine kinases and chemoreceptors found in two-component systems. Previously, piston, scissors, and helical rotation have been proposed as the mechanisms of TM signaling. We discuss theoretically possible conformational changes and examine the available experimental data, including the recent crystallographic structures of nitrate/nitrite sensor histidine kinase NarQ and phototaxis system NpSRII:NpHtrII. We show that TM helices can flex at multiple points and argue that the various conformational changes are not mutually exclusive, and often are observed concomitantly, throughout the TM domain or in its part. The piston and scissoring motions are the most prominent motions in the structures, but more research is needed for definitive conclusions.

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Structural plasticity and catalysis regulation of a thermosensor histidine kinase

Cited by 162 publications

References 36 publications

Sensor–response regulator interactions in a cross-regulated signal transduction network

Sensor–response regulator interactions in a cross-regulated signal transduction network

Conserved mechanism for sensor phosphatase control of two-component signaling revealed in the nitrate sensor NarX

Transmembrane Signal Transduction in Two‐Component Systems: Piston, Scissoring, or Helical Rotation?

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