Adaptation Mechanism of the Aspartate Receptor:  Electrostatics of the Adaptation Subdomain Play a Key Role in Modulating Kinase Activity

Starrett, Diane J.; Falke, Joseph J.

doi:10.1021/bi048089z

Cited by 58 publications

(113 citation statements)

References 44 publications

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“…A recent study showed that electrostatic repulsion between negative charges on the surface of the subdomain modulates the packing between the adjacent helices of the two subunits within the homodimer, thereby regulating kinase activity (69). Covalent modification of the receptor adaptation sites is believed to modulate this electrostatic interaction in the same way, because methylation or amidation of the adaptation sites decreases the electrostatic repulsion between subunits, thereby stabilizing the helix interactions and activating the kinase.…”

Section: Discussionmentioning

confidence: 99%

Evidence that the Adaptation Region of the Aspartate Receptor Is a Dynamic Four-Helix Bundle: Cysteine and Disulfide Scanning Studies

2005

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The aspartate receptor is one of the ligand-specific, homodimeric chemoreceptors that detects extracellular attractants and triggers the chemotaxis pathway of Escherichia coli and Salmonella typhimurium. This receptor regulates the activity of the histidine kinase CheA, which forms a kinetically stable complex with the receptor cytoplasmic domain. An atomic four-helix bundle model has been constructed for this domain, which is functionally subdivided into the signaling and adaptation subdomains. The proposed four-helix bundle structure of the signaling subdomain, which binds CheA, is fully supported by experimental evidence. Much less evidence is available to test the four-helix bundle model of the adaptation subdomain, which possesses covalent adaptation sites and docking surfaces for adaptation enzymes. The present study focuses on a putative helix near the C terminus of the adaptation subdomain. To probe the structural and functional features of positions G467-A494 in this C-terminal region, a cysteine and disulfide scanning approach has been employed. Measurement of the chemical reactivities of scanned cysteines reveals an α-helical periodicity of exposed and buried residues, confirming α-helical secondary structure and mapping out a buried packing face. The effects of cysteine substitutions on activity in vivo and in vitro highlight the functional importance of the helix, especially its buried face. A scan for disulfide bond formation between symmetric pairs of engineered cysteines reveals promiscuous collisions between subunits, indicating the presence of significant thermal dynamics. A scan for functional disulfides reveals lockon and signal-retaining disulfide bonds formed between symmetric pairs of cysteines at buried positions, indicating that the buried face of the helix lies near the subunit interface of the homodimer in the equilibrium structures of both the apo and aspartate-bound states where it plays a critical role in kinase regulation. These results strongly support the existing four-helix bundle model of the adaptation subdomain structure. A mechanistic model is proposed in which a signal is transmitted through the adaptation subdomain by a change in supercoiling of the four-helix bundle.The mechanism of signal transduction by which cell-surface receptors regulate cytoplasmic kinases is an issue of central importance in signaling biology. Some receptors activate their appropriate kinases by dimerization, but others trigger kinase activation by transmembrane conformational changes. The latter class includes a large superfamily of cell-surface receptors that regulate cytoplasmic histidine kinases in prokaryotic and eukaryotic two-component signaling pathways (1,2). An important subfamily of this histidine kinase-coupled receptor superfamily is responsible for regulating the thermo-, photo-, osmo-, redox-, and chemotaxis pathways of a wide variety of prokaryotic organisms (3-5). These taxis receptors, comprising a group of over 2000 homologues (6), exhibit regions of high conservation in ...

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Section: Discussionmentioning

confidence: 99%

Evidence that the Adaptation Region of the Aspartate Receptor Is a Dynamic Four-Helix Bundle: Cysteine and Disulfide Scanning Studies

2005

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“…In addition, the adaptation region is highly anionic and is regulated by an electrostatic mechanism involving the adaptation site glutamates and several other anionic side-chains lining the subunit-subunit interface [58]. Covalent neutralization of an interfacial anion by methyl esterification or amidation stabilizes the interface and activates kinase, whereas simultaneous neutralization of all anions locks the receptor in the kinaseactivating state [58] Conformational signaling in the protein interaction region, where the kinase interacts, remains poorly understood. However, like the adaptation region, its subunit interface seems to be crucial for signal transmission because many 'lock-on' mutations occur at interfacial locations [54,59].…”

Section: Signaling In the Kinase Control Modulementioning

confidence: 99%

“…The other is tilting of dimers relative to the central trimer axis, detected by changes in dimer-to-dimer FRET [47,48]. In principle, such macroscopic transitions could be driven by changes in supercoiling, or supercoiling-dependent flexibility of the four-helix bundle of the kinase control module [46,58]. By triggering changes in inter-dimer distances or contacts, macroscopic transitions could have an important role in the strong positive signaling cooperativity between dimers, within or between trimers.…”

Section: Macroscopic Transitions In the Trimer-of-dimersmentioning

confidence: 99%

“…However, considerable evidence indicates that changes at the subunitsubunit interface within the kinase control module are important in signaling [56][57][58]. This contrasts with the transmembrane sensing domain, in which signaling movements occur between the two helices in a single subunit and the subunit interface is static [49].…”

Section: Signaling In the Kinase Control Modulementioning

confidence: 99%

“…In the otherwise dynamic kinase control module, stabilization of inter-subunit packing by disulfide bonds or amino acid replacements can lock the receptor to a kinase-on state, implying that attractant-generated, kinase-inhibiting signals shift or destabilize the subunit interface via mechanical forces [54,57]. In addition, the adaptation region is highly anionic and is regulated by an electrostatic mechanism involving the adaptation site glutamates and several other anionic side-chains lining the subunit-subunit interface [58]. Covalent neutralization of an interfacial anion by methyl esterification or amidation stabilizes the interface and activates kinase, whereas simultaneous neutralization of all anions locks the receptor in the kinaseactivating state [58] Conformational signaling in the protein interaction region, where the kinase interacts, remains poorly understood.…”

Section: Signaling In the Kinase Control Modulementioning

confidence: 99%

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Bacterial chemoreceptors: high-performance signaling in networked arrays

Hazelbauer

Falke

Parkinson

2008

Trends in Biochemical Sciences

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588

804

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Chemoreceptors are crucial components in the bacterial sensory systems that mediate chemotaxis. Chemotactic responses exhibit exquisite sensitivity, extensive dynamic range and precise adaptation. The mechanisms that mediate these high-performance functions involve not only actions of individual proteins but also interactions among clusters of components, localized in extensive patches of thousands of molecules. Recently, these patches have been imaged in native cells, important features of chemoreceptor structure and on-off switching have been identified, and new insights have been gained into the structural basis and functional consequences of higher order interactions among sensory components. These new data suggest multiple levels of molecular interactions, each of which contribute specific functional features and together create a sophisticated signaling device. High-performance signaling in bacterial chemotaxisThe high-performance chemotaxis signaling system of Escherichia coli (Box 1) involves a limited number of components but notable sophistication [1][2][3][4]. This system has become a paradigm for molecular characterization of biological signaling mechanisms. Transmembrane chemoreceptors, known as methyl-accepting chemotaxis proteins (MCPs), direct cell locomotion by regulating the histidine kinase CheA; CheA phosphorylates a response regulator, which in turn controls the rotational direction of the flagellar motor. Chemotactic sensitivity and the range of signal detection are regulated by adaptational modification of chemoreceptors via reversible glutamyl methylation. The resulting interplay between motor control and sensory adaptation produces directed motile behavior. E. coli chemoreceptors are the most extensively studied representatives of the MCP super-family, central components of homologous systems that mediate tactic responses [5,6] across the phylogenetic diversity of bacteria and archaea [7].In E. coli chemotaxis proteins cluster in membrane-associated patches [8]. Interaction within patches is thought to contribute to notable features of the signaling system: high sensitivity, wide dynamic range, extensive cooperativity and precise adaptation. Delineating the molecular mechanisms underlying these features will require knowledge of structures of the components, complexes and higher order arrays. In addition it will require definition of organization at the multiple levels of interaction among signaling components and an understanding of the changes in components and their interactions that mediate signaling at each level. In the past few years, notable progress has been made toward acquiring the NIH Public Access NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author Manuscript information and insights necessary for understanding these molecular mechanisms. This review describes that progress. Here we follow the lead of most investigators in the area, and do not distinguish between studies of first cousins E. coli and Salmonella enterica serovar Typhimurium. Thus, referenc...

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Transmembrane Signaling

and

Neiditch

2009

Bacterial Signaling

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Adaptation Mechanism of the Aspartate Receptor: Electrostatics of the Adaptation Subdomain Play a Key Role in Modulating Kinase Activity

Cited by 58 publications

References 44 publications

Evidence that the Adaptation Region of the Aspartate Receptor Is a Dynamic Four-Helix Bundle: Cysteine and Disulfide Scanning Studies

Evidence that the Adaptation Region of the Aspartate Receptor Is a Dynamic Four-Helix Bundle: Cysteine and Disulfide Scanning Studies

Bacterial chemoreceptors: high-performance signaling in networked arrays

Transmembrane Signaling

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