Two‐component signaling in the AAA+ ATPase DctD: binding Mg<sup>2+</sup>and BeF<sub>3</sub>selects between alternative dimeric states of the receiver domain

Park, Sungdae; Meyer, Matthew; Jones, Arthur C.; Yennawar, Hemant P.; Yennawar, Neela H.; Nixon, B. Tracy

doi:10.1096/fj.02-0395fje

Cited by 66 publications

(96 citation statements)

References 45 publications

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“…N-terminus insertions producing constitutively active proteins were found at the interface between the N-and C-terminal domains, and in adjoining loops and helices. These insertions presumably activated WspR via disruption of the interface between the two domains, a mechanism common to many responseregulator activation mechanisms (Eldridge et al, 2002;Park et al, 2002;Muchova et al, 2004). A comparison of the domain interaction surfaces of four full-length, two-domain response-regulator crystal structures (Robinson et al, 2003) suggests that the activation mechanisms of the different proteins, NarL (Baikalov et al, 1996), CheB (Djordjevic et al, 1998), DrrD (Buckler et al, 2002) and DrrB (Robinson et al, 2003), vary with the extent of their interdomain interfaces.…”

Section: Discussionmentioning

confidence: 99%

The structure–function relationship of WspR, a Pseudomonas fluorescens response regulator with a GGDEF output domain

et al. 2007

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The GGDEF response regulator WspR couples the chemosensory Wsp pathway to the overproduction of acetylated cellulose and cell attachment in the Pseudomonas fluorescens SBW25 wrinkly spreader (WS) genotype. Here, it is shown that WspR is a diguanylate cyclase (DGC), and that DGC activity is elevated in the WS genotype compared to that in the ancestral smooth (SM) genotype. A structure-function analysis of 120 wspR mutant alleles was employed to gain insight into the regulation and activity of WspR. Firstly, 44 random and defined pentapeptide insertions were produced in WspR, and the effects determined using assays based on colony morphology, attachment to surfaces and cellulose production. The effects of mutations within WspR were interpreted using a homology model, based on the crystal structure of Caulobacter crescentus PleD. Mutational analyses indicated that WspR activation occurs as a result of disruption of the interdomain interface, leading to the release of effector-domain repression by the N-terminal receiver domain. Quantification of attachment and cellulose production raised significant questions concerning the mechanisms of WspR function. The conserved RYGGEEF motif of WspR was also subjected to mutational analysis, and 76 single amino acid residue substitutions were tested for their effects on WspR function. The RYGGEEF motif of WspR is functionally conserved, with almost every mutation abolishing function.

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Section: Discussionmentioning

confidence: 99%

The structure–function relationship of WspR, a Pseudomonas fluorescens response regulator with a GGDEF output domain

et al. 2007

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“…It is not surprising therefore that many RRs utilize the α4-β5-α5 face for regulatory protein-protein interactions, the affinities of which are altered by phosphorylation. These interactions form the basis for a variety of different inter-and intramolecular regulatory mechanisms such as the binding of CheY-P to FliM 59 and CheZ, 60 the formation of homodimers of phosphorylated FixJ, 46 the alternation between different dimeric states in DctD, 61,62 and the inhibitory contacts between the unphosphorylated regulatory and effector domains of NarL 27 and CheB. 28 An analysis of residue conservation at the α4-β5-α5 face of the three major subfamilies of RR transcription factors (OmpR/PhoB, NarL/FixJ, and NtrC/DctD) revealed important differences that distinguish the OmpR/PhoB subfamily from the others.…”

Section: The α4-β5-α5 Facementioning

confidence: 99%

“…Interestingly, in the NtrC/ DctD subfamily, which lacks conservation in the α4-β5-α5 face, different members have been shown to use distinctly different surfaces of the regulatory domain for multimerization. 61 Another notable feature of the OmpR/PhoB subfamily is that in the inactive state the DNA recognition helix of the effector domain is freely exposed to the solvent 33,34 making it readily available for DNA binding in contrast to other RRs in which the functional regions of the effector domains are occluded by the unphosphorylated regulatory domains. 27,28 Taking into account these marked differences, it is hypothesized that members of the OmpR/PhoB subfamily use a common mechanism of regulation by dimerization.…”

Section: A Common Mechanism Of Regulation By Dimerizationmentioning

confidence: 99%

Structural Analysis and Solution Studies of the Activated Regulatory Domain of the Response Regulator ArcA: A Symmetric Dimer Mediated by the α4-β5-α5 Face

Toro-Roman

Mack²,

Stock

2005

Journal of Molecular Biology

119

137

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SUMMARYEscherichia coli react to changes from aerobic to anaerobic conditions of growth using the ArcAArcB two-component signal transduction system. This system, in conjunction with other proteins, regulates the respiratory metabolic pathways in the organism. ArcA is a member of the OmpR/ PhoB subfamily of response regulator transcription factors that are known to regulate transcription by binding in tandem to target DNA direct repeats. It is still unclear in this subfamily how activation by phosphorylation of the regulatory domain of response regulators stimulates DNA binding by the effector domain and how dimerization and domain orientation, as well as intra-and intermolecular interactions, affect this process. In order to address these questions we have solved the crystal structure of the regulatory domain of ArcA in the presence and absence of the phosphoryl analog, BeF 3 − . In the crystal structures, the regulatory domain of ArcA forms a symmetric dimer mediated by the α4-β5-α5 face of the protein and involving a number of residues that are highly conserved in the OmpR/PhoB subfamily. It is hypothesized that members of this subfamily use a common mechanism of regulation by dimerization. Additional biophysical studies were employed to probe the oligomerization state of ArcA, as well as its individual domains, in solution. The solution studies show the propensity of the individual domains to associate into oligomers larger than the dimer observed for the intact protein, and suggest that the C-terminal DNA-binding domain also plays a role in oligomerization.

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“…In their inactive states these proteins are usually dimers that bind to pairs of tandem sites in the enhancer elements. Upon activation via the regulatory domains, they oligomerize into ATPase-active rings that use the energy from ATP hydrolysis to physically remodel closed complexes of 54 holoenzyme and promoter DNA (Rombel et al 1998;Neuwald et al 1999;Chaney et al 2001;Lee et al 2003).Crystal or NMR structures are available for several isolated domains and truncation constructs of EBPs including NtrC, DctD, PspF, ZraR, and NtrC1 (Volkman et al 1995;Kern et al 1999;Pelton et al 1999;Meyer et al 2001;Park et al 2002;Hastings et al 2003;Lee et al 2003;Doucleff et al 2005;Rappas et al 2005;Sallai and Tucker 2005). Existing structural information on DctD and NtrC1 has been used to provide a model of how two-component signal transduction can regulate assembly of their AAA+ ATPase domains ), but this model fails to explain regulation in the closely related protein NtrC (40% sequence identity, 60% sequence similarity) Hastings et al 2003).…”

mentioning

confidence: 99%

The structural basis for regulated assembly and function of the transcriptional activator NtrC

Carlo¹,

Chen²,

Hoover³

et al. 2006

Genes Dev.

Self Cite

111

180

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In two-component signal transduction, an input triggers phosphorylation of receiver domains that regulate the status of output modules. One such module is the AAA+ ATPase domain in bacterial enhancer-binding proteins that remodel the 54 form of RNA polymerase. We report X-ray solution scattering and electron microscopy structures of the activated, full-length nitrogen-regulatory protein C (NtrC) showing a novel mechanism for regulation of AAA+ ATPase assembly via the juxtaposition of the receiver domains and ATPase ring. Accompanying the hydrolysis cycle that is required for transcriptional activation, we observed major order-disorder changes in the GAFTGA loops involved in 54 binding, as well as in the DNA-binding domains. The 54 holoenzyme form of RNA polymerase forms closed DNA complexes that open only with the help of enhancer-binding proteins (EBPs). For the nitrogen-regulatory protein C of enteric bacteria (NtrC), such activity starts a cascade of events that may ultimately lead to the activation of transcription for as much as 2% of the genome (Zimmer et al. 2000). Sequence analysis of >160054 -dependent transcriptional activators shows that in addition to their oligomerization/AAA+ ATPase domain, they also have a DNA-binding domain and a regulatory domain, which in 50% of cases is a twocomponent receiver domain (Bateman et al. 2004). The helix-turn-helix DNA-binding domain recognizes enhancer-like sequences between 100 and 150 bp upstream of the promoter. In their inactive states these proteins are usually dimers that bind to pairs of tandem sites in the enhancer elements. Upon activation via the regulatory domains, they oligomerize into ATPase-active rings that use the energy from ATP hydrolysis to physically remodel closed complexes of 54 holoenzyme and promoter DNA (Rombel et al. 1998;Neuwald et al. 1999;Chaney et al. 2001;Lee et al. 2003).Crystal or NMR structures are available for several isolated domains and truncation constructs of EBPs including NtrC, DctD, PspF, ZraR, and NtrC1 (Volkman et al. 1995;Kern et al. 1999;Pelton et al. 1999;Meyer et al. 2001;Park et al. 2002;Hastings et al. 2003;Lee et al. 2003;Doucleff et al. 2005;Rappas et al. 2005;Sallai and Tucker 2005). Existing structural information on DctD and NtrC1 has been used to provide a model of how two-component signal transduction can regulate assembly of their AAA+ ATPase domains ), but this model fails to explain regulation in the closely related protein NtrC (40% sequence identity, 60% sequence similarity) Hastings et al. 2003). Here we report both SAXS/WAXS (small-and wide-angle X-ray scattering) and EM (electron microscopy) structures of the full-length, activated form of NtrC from Salmonella typhimurium. Docking of atomic models for the individual domains into the structures reveals their organization within the activated ring and uncovers a novel mechanism for the use of two-compo-

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Two‐component signaling in the AAA+ ATPase DctD: binding Mg²⁺and BeF₃selects between alternative dimeric states of the receiver domain

Cited by 66 publications

References 45 publications

The structure–function relationship of WspR, a Pseudomonas fluorescens response regulator with a GGDEF output domain

The structure–function relationship of WspR, a Pseudomonas fluorescens response regulator with a GGDEF output domain

Structural Analysis and Solution Studies of the Activated Regulatory Domain of the Response Regulator ArcA: A Symmetric Dimer Mediated by the α4-β5-α5 Face

The structural basis for regulated assembly and function of the transcriptional activator NtrC

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Two‐component signaling in the AAA+ ATPase DctD: binding Mg2+and BeF3selects between alternative dimeric states of the receiver domain

Cited by 66 publications

References 45 publications

The structure–function relationship of WspR, a Pseudomonas fluorescens response regulator with a GGDEF output domain

The structure–function relationship of WspR, a Pseudomonas fluorescens response regulator with a GGDEF output domain

Structural Analysis and Solution Studies of the Activated Regulatory Domain of the Response Regulator ArcA: A Symmetric Dimer Mediated by the α4-β5-α5 Face

The structural basis for regulated assembly and function of the transcriptional activator NtrC

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Product

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Two‐component signaling in the AAA+ ATPase DctD: binding Mg²⁺and BeF₃selects between alternative dimeric states of the receiver domain