Structure-function relationships in the HAMP and proximal signaling domains of the aerotaxis receptor Aer

Aer, the Escherichia coli aerotaxis receptor, faces the cytoplasm, where the PAS (Per-ARNT-Sim)-flavin adenine dinucleotide (FAD) domain senses redox changes in the electron transport system or cytoplasm. PAS-FAD interacts with a HAMP (histidine kinase, adenylyl cyclase, methyl-accepting protein, and phosphatase) domain to form an input-output module for Aer signaling. In this study, the structure of the Aer HAMP and proximal signaling domains was probed to elucidate structure-function relationships important for signaling. Aer residues 210 to 290 were individually replaced with cysteine and then cross-linked in vivo. The results confirmed that the Aer HAMP domain is composed of two α-helices separated by a structured loop. The proximal signaling domain consisted of two α-helices separated by a short undetermined structure. The Af1503 HAMP domain from Archaeoglobus fulgidus was recently shown to be a four-helix bundle. To test whether the Af1503 HAMP domain is a prototype for the Aer HAMP domain, the latter was modeled using coordinates from Af1503. Several findings supported the hypothesis that Aer has a four-helix HAMP structure: (i) cross-linking independently identified the same residues at the dimer interface that were predicted by the model, (ii) the rate of cross-linking for residue pairs was inversely proportional to the β-carbon distances measured on the model, and (iii) clockwise lesions that were not contiguous in the linear Aer sequence were clustered in one region in the folded HAMP model, defining a potential site of PAS-HAMP interaction during signaling. In silico modeling of mutant Aer proteins indicated that the four-helix HAMP structure was important for Aer stability or maturation. The significance of the HAMP and proximal signaling domain structure for signal transduction is discussed.     

Functional Suppression of HAMP Domain Signaling Defects in the E. coli Serine Chemoreceptor

HAMP domains play key signaling roles in many bacterial receptor proteins. The four-helix HAMP bundle of the homodimeric Escherichia coli serine chemoreceptor (Tsr) interacts with an adjoining four-helix sensory adaptation bundle to regulate the histidine autokinase CheA bound to the cytoplasmic tip of the Tsr molecule. The adaptation helices undergo reversible covalent modifications that tune the stimulus-responsive range of the receptor: unmodified E residues promote kinase-off output, and methylated E residues or Q replacements at modification sites promote kinase-on output. We used mutationally imposed adaptational modification states and cells with various combinations of the sensory adaptation enzymes, CheR and CheB, to characterize the signaling properties of mutant Tsr receptors that had amino acid replacements in packing layer 3 of the HAMP bundle and followed in vivo CheA activity with an assay based on Förster resonance energy transfer. We found that an alanine or a serine replacement at HAMP residue I229 effectively locked Tsr output in a kinase-on state, abrogating chemotactic responses. A second amino acid replacement in the same HAMP packing layer alleviated the I229A and I229S signaling defects. Receptors with the suppressor changes alone mediated chemotaxis in adaptation-proficient cells but exhibited altered sensitivity to serine stimuli. Two of the suppressors (S255E and S255A) shifted Tsr output toward the kinase-off state, but two others (S255G and L256F) shifted output toward a kinase-on state. The alleviation of locked-on defects by on-shifted suppressors implies that Tsr-HAMP has several conformationally distinct kinase-active output states and that HAMP signaling might involve dynamic shifts over a range of bundle conformations.     

The mechanisms of HAMP-mediated signaling in transmembrane receptors

HAMP domains mediate signal transduction in over 7500 enzyme-coupled receptors represented in all kingdoms of life. The HAMP domain of the putative archaeal receptor Af1503 has a parallel, dimeric, four-helical coiled coil structure, but with unusual core packing, related to canonical packing by concerted axial rotation of the helices. This has led to the gearbox model for signal transduction, whereby the alternate packing modes correspond to signaling states. Here we present structures of a series of Af1503 HAMP variants. We show that substitution of a conserved small side chain within the domain core (A291) for larger residues induces a gradual transition in packing mode, involving both changes in helix rotation and bundle shape, which are most prominent at the C-terminal, output end of the domain. These are correlated with activity and ligand response in vitro and in vivo by incorporating Af1503 HAMP into mycobacterial adenylyl cyclase assay systems.     

Genetic analysis of the HAMP domain of the Aer aerotaxis sensor localizes flavin adenine dinucleotide-binding determinants to the AS-2 helix

HAMP domains are signal transduction domains typically located between the membrane anchor and cytoplasmic signaling domain of the proteins in which they occur. The prototypical structure consists of two helical amphipathic sequences (AS-1 and AS-2) connected by a region of undetermined structure. The Escherichia coli aerotaxis receptor, Aer, has a HAMP domain and a PAS domain with a flavin adenine dinucleotide (FAD) cofactor that senses the intracellular energy level. Previous studies reported mutations in the HAMP domain that abolished FAD binding to the PAS domain. In this study, using random and site-directed mutagenesis, we identified the distal helix, AS-2, as the component of the HAMP domain that stabilizes FAD binding. AS-2 in Aer is not amphipathic and is predicted to be buried. Mutations in the sequence coding for the contiguous proximal signaling domain altered signaling by Aer but did not affect FAD binding. The V264M residue replacement in this region resulted in an inverted response in which E. coli cells expressing the mutant Aer protein were repelled by oxygen. Bioinformatics analysis of aligned HAMP domains indicated that the proximal signaling domain is conserved in other HAMP domains that are not involved in chemotaxis or aerotaxis. Only one null mutation was found in the coding sequence for the HAMP AS-1 and connector regions, suggesting that these are not active signal transduction sites. We consider a model in which the signal from FAD is transmitted across a PAS-HAMP interface to AS-2 or the proximal signaling domain.     

Mechanism of regulation of receptor histidine kinases

Bacterial transmembrane receptors regulate an intracellular catalytic output in response to extracellular sensory input. To investigate the conformational changes that relay the regulatory signal, we have studied the HAMP domain, a ubiquitous intracellular module connecting input to output domains. HAMP forms a parallel, dimeric, four-helical coiled coil, and rational substitutions in our model domain (Af1503 HAMP) induce a transition in its interhelical packing, characterized by axial rotation of all four helices (the gearbox signaling model). We now illustrate how these conformational changes are propagated to a downstream domain by fusing Af1503 HAMP variants to the DHp domain of EnvZ, a bacterial histidine kinase. Structures of wild-type and mutant constructs are correlated with ligand response in vivo, clearly associating them with distinct signaling states. We propose that altered recognition of the catalytic domain by DHp, rather than a shift in position of the phospho-accepting histidine, forms the basis for regulation of kinase activity.     

Structure of the conserved HAMP domain in an intact, membrane-bound chemoreceptor: a disulfide mapping study

The HAMP domain is a conserved motif widely distributed in prokaryotic and lower eukaryotic organisms, where it is often found in transmembrane receptors that regulate two-component signaling pathways. The motif links receptor input and output modules and is essential to receptor structure and signal transduction. Recently, a structure was determined for a HAMP domain isolated from an unusual archeal membrane protein of unknown function [Hulko, M., et al. (2006) Cell 126, 929-940]. This study uses cysteine and disulfide chemistry to test this archeal HAMP model in the full-length, membrane-bound aspartate receptor of bacterial chemotaxis. The chemical reactivities of engineered Cys residues scanned throughout the aspartate receptor HAMP region are highly correlated with the degrees of solvent exposure of corresponding positions in the archeal HAMP structure. Both domains are homodimeric, and the individual subunits of both domains share the same helix-connector-helix organization with the same helical packing faces. Moreover, disulfide mapping reveals that the four helices of the aspartate receptor HAMP domain are arranged in the same parallel, four-helix bundle architecture observed in the archeal HAMP structure. One detectable difference is the packing of the extended connector between helices, which is not conserved. Finally, activity studies of the aspartate receptor indicate that contacts between HAMP helices 1 and 2' at the subunit interface play a critical role in modulating receptor on-off switching. Disulfide bonds linking this interface trap the receptor in its kinase-activating on-state, or its kinase inactivating off-state, depending on their location. Overall, the evidence suggests that the archeal HAMP structure accurately depicts the architecture of the conserved HAMP motif in transmembrane chemoreceptors. Both the on- and off-states of the aspartate receptor HAMP domain closely resemble the archeal HAMP structure, and only a small structural rearrangement occurs upon on-off switching. A model incorporating HAMP into the full receptor structure is proposed.     

Aer on the inside looking out: paradigm for a PAS-HAMP role in sensing oxygen, redox and energy

Aer, the Escherichia coli aerotaxis (oxygen-sensing) receptor, is representative of a small class of receptors that face the cytoplasm in bacteria. Instead of sensing oxygen directly, Aer detects redox changes in the electron transport system or cytoplasm when the bacteria enter or leave a hypoxic microniche. As a result, Aer sensing also enables bacteria to avoid environments where carbon deficiency, unfavourable reduction potential or other insults would limit energy production. An FAD-binding PAS domain is the sensor for Aer and a HAMP domain interacts with the PAS domain to form an input-output module for signal transduction. By analogy to the first solution structure of an isolated HAMP domain from Archaeoglobus, Aer HAMP is proposed to fold into a four-helix bundle that rotates between a signal-on and signal-off conformation. Aer is the first protein in which a PAS-HAMP input-output module has been investigated. The structure and signal transduction mechanism of Aer is providing important insights into signalling by PAS and HAMP domains.     

Interactions between the PAS and HAMP domains of the Escherichia coli aerotaxis receptor Aer

The Escherichia coli energy-sensing Aer protein initiates aerotaxis towards environments supporting optimal cellular energy. The Aer sensor is an N-terminal, FAD-binding, PAS domain. The PAS domain is linked by an F1 region to a membrane anchor, and in the C-terminal half of Aer, a HAMP domain links the membrane anchor to the signaling domain. The F1 region, membrane anchor, and HAMP domain are required for FAD binding. Presumably, alterations in the redox potential of FAD induce conformational changes in the PAS domain that are transmitted to the HAMP and C-terminal signaling domains. In this study we used random mutagenesis and intragenic pseudoreversion analysis to examine functional interactions between the HAMP domain and the N-terminal half of Aer. Missense mutations in the HAMP domain clustered in the AS-2 alpha-helix and abolished FAD binding to Aer, as previously reported. Three amino acid replacements in the Aer-PAS domain, S28G, A65V, and A99V, restored FAD binding and aerotaxis to the HAMP mutants. These suppressors are predicted to surround a cleft in the PAS domain that may bind FAD. On the other hand, suppression of an Aer-C253R HAMP mutant was specific to an N34D substitution with a predicted location on the PAS surface, suggesting that residues C253 and N34 interact or are in close proximity. No suppressor mutations were identified in the F1 region or membrane anchor. We propose that functional interactions between the PAS domain and the HAMP AS-2 helix are required for FAD binding and aerotactic signaling by Aer.     

PAS/poly-HAMP signalling in Aer-2, a soluble haem-based sensor

Poly-HAMP domains are widespread in bacterial chemoreceptors, but previous studies have focused on receptors with single HAMP domains. The Pseudomonas aeruginosa chemoreceptor, Aer-2, has an unusual domain architecture consisting of a PAS-sensing domain sandwiched between three N-terminal and two C-terminal HAMP domains, followed by a conserved kinase control module. The structure of the N-terminal HAMP domains was recently solved, making Aer-2 the first protein with resolved poly-HAMP structure. The role of Aer-2 in P. aeruginosa is unclear, but here we show that Aer-2 can interact with the chemotaxis system of Escherichia coli to mediate repellent responses to oxygen, carbon monoxide and nitric oxide. Using this model system to investigate signalling and poly-HAMP function, we determined that the Aer-2 PAS domain binds penta-co-ordinated b-type haem and that reversible signalling requires four of the five HAMP domains. Deleting HAMP 2 and/or 3 resulted in a kinase-off phenotype, whereas deleting HAMP 4 and/or 5 resulted in a kinase-on phenotype. Overall, these data support a model in which ligand-bound Aer-2 PAS and HAMP 2 and 3 act together to relieve inhibition of the kinase control module by HAMP 4 and 5, resulting in the kinase-on state of the Aer-2 receptor.     

Biphasic control logic of HAMP domain signalling in the Escherichia coli serine chemoreceptor

HAMP domains mediate input-output communication in many bacterial signalling proteins. To explore the dynamic bundle model of HAMP signalling (Zhou et al., Mol. Microbiol. 73: 801, 2009), we characterized the signal outputs of 118 HAMP missense mutants of the serine chemoreceptor, Tsr, by flagellar rotation patterns. Receptors with proline or charged amino acid replacements at critical hydrophobic packing residues in the AS1 and AS2 HAMP helices had locked kinase-off outputs, indicating that drastic destabilization of the Tsr-HAMP bundle prevents kinase activation, both in the absence and presence of the sensory adaptation enzymes, CheB and CheR. Attractant-mimic lesions that enhance the structural stability of the HAMP bundle also suppressed kinase activity, demonstrating that Tsr-HAMP has two kinase-off output states at opposite extremes of its stability range. HAMP mutants with locked-on kinase outputs appeared to have intermediate bundle stabilities, implying a biphasic relationship between HAMP stability and kinase activity. Some Tsr-HAMP mutant receptors exhibited reversed output responses to CheB and CheR action that are readily explained by a biphasic control logic. The findings of this study provide strong support for a three-state dynamic bundle model of HAMP signalling in Tsr, and possibly in other bacterial transducers as well.     

Conserved residues in the HAMP domain define a new family of proposed bipartite energy taxis receptors

HAMP domains, found in many bacterial signal transduction proteins, generally transmit an intramolecular signal between an extracellular sensory domain and an intracellular signaling domain. Studies of HAMP domains in proteins where both the input and output signals occur intracellularly are limited to those of the Aer energy taxis receptor of Escherichia coli, which has both a HAMP domain and a sensory PAS domain. Campylobacter jejuni has an energy taxis system consisting of the domains of Aer divided between two proteins, CetA (HAMP domain containing) and CetB (PAS domain containing). In this study, we found that the CetA HAMP domain differs significantly from that of Aer in the predicted secondary structure. Using similarity searches, we identified 55 pairs of HAMP/PAS proteins encoded by adjacent genes in a diverse group of microorganisms. We propose that these HAMP/PAS pairs form a new family of bipartite energy taxis receptors. Within these proteins, we identified nine residues in the HAMP domain and proximal signaling domain that are highly conserved, at least three of which are required for CetA function. Additionally, we demonstrated that CetA contributes to the invasion of human epithelial cells by C. jejuni, while CetB does not. This finding supports the hypothesis that members of HAMP/PAS pairs possess the capacity to act independently of each other in cellular traits other than energy taxis.     

HAMP domain-mediated signal transduction probed with a mycobacterial adenylyl cyclase as a reporter

HAMP domains, ～55 amino acid motifs first identified in histidine kinases, adenylyl cyclases, methyl-accepting chemotaxis proteins, and phosphatases, operate as signal mediators in two-component signal transduction proteins. A bioinformatics study identified a coevolving signal-accepting network of 10 amino acids in membrane-delimited HAMP proteins. To probe the functionality of this network we used a HAMP containing mycobacterial adenylyl cyclase, Rv3645, as a reporter enzyme in which the membrane anchor was substituted by the Escherichia coli chemotaxis receptor for serine (Tsr receptor) and the HAMP domain alternately with that from the protein Af1503 of the archaeon Archaeoglobus fulgidus or the Tsr receptor. In a construct with the Tsr-HAMP, cyclase activity was inhibited by serine, whereas in a construct with the HAMP domain from A. fulgidus, enzyme activity was not responsive to serine. Amino acids of the signal-accepting network were mutually swapped between both HAMP domains, and serine signaling was examined. The data biochemically tentatively established the functionality of the signal-accepting network. Based on a two-state gearbox model of rotation in HAMP domain-mediated signal propagation, we characterized the interaction between permanent and transient core residues in a coiled coil HAMP structure. The data are compatible with HAMP rotation in signal propagation but do not exclude alternative models for HAMP signaling. Finally, we present data indicating that the connector, which links the α-helices of HAMP domains, plays an important structural role in HAMP function.     

Mutational analysis of the connector segment in the HAMP domain of Tsr, the Escherichia coli serine chemoreceptor

HAMP domains are approximately 50-residue motifs, found in many bacterial signaling proteins, that consist of two amphiphilic helices joined by a nonhelical connector segment. The HAMP domain of Tsr, the serine chemoreceptor of Escherichia coli, receives transmembrane input signals from the periplasmic serine binding domain and in turn modulates output signals from the Tsr kinase control domain to elicit chemotactic responses. We created random amino acid replacements at each of the 14 connector residues of Tsr-HAMP to identify those that are critical for Tsr function. In all, we surveyed 179 connector missense mutants and identified three critical residues (G235, L237, and I241) at which most replacements destroyed Tsr function and another important residue (G245) at which most replacements impaired Tsr function. The region surrounding G245 tolerated 1-residue deletions and insertions of up to 10 glycines, suggesting a role as a relatively nonspecific, flexible linker. The critical connector residues are consistent with a structural model of the Tsr-HAMP domain based on the solution structure of an isolated thermophile HAMP domain (M. Hulko, F. Berndt, M. Gruber, J. U. Linder, V. Truffault, A. Schultz, J. Martin, J. E. Schultz, A. N. Lupas, and M. Coles, Cell 126:929-940, 2006) in which G235 defines a critical turn at the C terminus of the first helix and L237 and I241 pack against the helices, perhaps to stabilize alternative HAMP signaling conformations. Most I241 lesions locked Tsr signal output in the kinase-on mode, implying that this residue is responsible mainly for stabilizing the kinase-off signaling state. In contrast, lesions at L237 resulted in a variety of aberrant output patterns, suggesting a role in toggling output between signaling states.     

Mutational analysis of a conserved signal-transducing element: the HAMP linker of the Escherichia coli nitrate sensor NarX

The HAMP linker, a predicted structural element observed in sensor proteins from all domains of life, is proposed to transmit signals between extracellular sensory input domains and cytoplasmic output domains. HAMP (histidine kinase, adenylyl cyclase, methyl-accepting chemotaxis protein, and phosphatase) linkers are located just inside the cytoplasmic membrane and are projected to form two short amphipathic alpha-helices (AS-1 and AS-2) joined by an unstructured connector. The presumed helices are comprised of hydrophobic residues in heptad repeats, with only three positions exhibiting strong conservation. We generated missense mutations at these three positions and throughout the HAMP linker in the Escherichia coli nitrate sensor kinase NarX and screened the resulting mutants for defective responses to nitrate. Most missense mutations in this region resulted in a constitutive phenotype mimicking the ligand-bound state, and only one residue (a conserved Glu before AS-2) was essential for HAMP linker function. We also scanned the narX HAMP linker with an overlapping set of seven-residue deletions. Deletions in AS-1 and the connector resulted in constitutive phenotypes. Two deletions in AS-2 resulted in a novel reversed response phenotype in which the response to ligand was the opposite of that seen for the narX(+) strain. These observations are consistent with the proposed HAMP linker structure, show that the HAMP linker plays an active role in transmembrane signal transduction, and indicate that the two amphipathic alpha-helices have different roles in signal transduction.     

Two Distinct States of the HAMP Domain from Sensory Rhodopsin Transducer Observed in Unbiased Molecular Dynamics Simulations

HAMP domain is a ubiquitous module of bacterial and archaeal two-component signaling systems. Considerable progress has been made recently in studies of its structure and conformational changes. However, the mechanism of signal transduction through the HAMP domain is not clear. It remains a question whether all the HAMPs have the same mechanism of action and what are the differences between the domains from different protein families. Here, we present the results of unbiased molecular dynamics simulations of the HAMP domain from the archaeal phototaxis signal transducer NpHtrII. Two distinct conformational states of the HAMP domain are observed, that differ in relative position of the helices AS1 and AS2. The longitudinal shift is roughly equal to a half of an α-helix turn, although sometimes it reaches one full turn. The states are closely related to the position of bulky hydrophobic aminoacids at the HAMP domain core. The observed features are in good agreement with recent experimental results and allow us to propose that the states detected in the simulations are the resting state and the signaling state of the NpHtrII HAMP domain. To the best of our knowledge, this is the first observation of the same HAMP domain in different conformations. The simulations also underline the difference between AMBER ff99-SB-ILDN and CHARMM22-CMAP forcefields, as the former favors the resting state and the latter favors the signaling state.     

Topology and boundaries of the aerotaxis receptor Aer in the membrane of Escherichia coli

Escherichia coli chemoreceptors are type I membrane receptors that have a periplasmic sensing domain, a cytosolic signaling domain, and two transmembrane segments. The aerotaxis receptor, Aer, is different in that both its sensing and signaling regions are proposed to be cytosolic. This receptor has a 38-residue hydrophobic segment that is thought to form a membrane anchor. Most transmembrane prediction programs predict a single transmembrane-spanning segment, but such a topology is inconsistent with recent studies indicating that there is direct communication between the membrane flanking PAS and HAMP domains. We studied the overall topology and membrane boundaries of the Aer membrane anchor by a cysteine-scanning approach. The proximity of 48 cognate cysteine replacements in Aer dimers was determined in vivo by measuring the rate and extent of disulfide cross-linking after adding the oxidant copper phenanthroline, both at room temperature and to decrease lateral diffusion in the membrane, at 4 degrees C. Membrane boundaries were identified in membrane vesicles using 5-iodoacetamidofluorescein and methoxy polyethylene glycol 5000 (mPEG). To map periplasmic residues, accessible cysteines were blocked in whole cells by pretreatment with 4-acetamido-4'-maleimidylstilbene-2, 2' disulfonic acid before the cells were lysed in the presence of mPEG. The data were consistent with two membrane-spanning segments, separated by a short periplasmic loop. Although the membrane anchor contains a central proline residue that reaches the periplasm, its position was permissive to several amino acid and peptide replacements.     

Role of the F1 region in the Escherichia coli aerotaxis receptor Aer

In Escherichia coli, the aerotaxis receptor Aer is an atypical receptor because it senses intracellular redox potential. The Aer sensor is a cytoplasmic, N-terminal PAS domain that is tethered to the membrane by a 47-residue F1 linker. Here we investigated the function, topology, and orientation of F1 by employing random mutagenesis, cysteine scanning, and disulfide cross-linking. No native residue was obligatory for function, most deleterious substitutions had radically different side chain properties, and all F1 mutants but one were functionally rescued by the chemoreceptor Tar. Cross-linking studies were consistent with the predicted α-helical structure in the N-terminal F1 region and demonstrated trigonal interactions among the F1 linkers from three Aer monomers, presumably within trimer-of-dimer units, as well as binary interactions between subunits. Using heterodimer analyses, we also demonstrated the importance of arginine residues near the membrane interface, which may properly anchor the Aer protein in the membrane. By incorporating these data into a homology model of Aer, we developed a model for the orientation of the Aer F1 and PAS regions in an Aer lattice that is compatible with the known dimensions of the chemoreceptor lattice. We propose that the F1 region facilitates the orientation of PAS and HAMP domains during folding and thereby promotes the stability of the PAS and HAMP domains in Aer.     

Mutational analyses of HAMP helices suggest a dynamic bundle model of input–output signalling in chemoreceptors

To test the gearbox model of HAMP signalling in the Escherichia coli serine receptor, Tsr, we generated a series of amino acid replacements at each residue of the AS1 and AS2 helices. The residues most critical for Tsr function defined hydrophobic packing faces consistent with a four-helix bundle. Suppression patterns of helix lesions conformed to the predicted packing layers in the bundle. Although the properties and patterns of most AS1 and AS2 lesions were consistent with both proposed gearbox structures, some mutational features specifically indicate the functional importance of an x-da bundle over an alternative a-d bundle. These genetic data suggest that HAMP signalling could simply involve changes in the stability of its x-da bundle. We propose that Tsr HAMP controls output signals by modulating destabilizing phase clashes between the AS2 helices and the adjoining kinase control helices. Our model further proposes that chemoeffectors regulate HAMP bundle stability through a control cable connection between the transmembrane segments and AS1 helices. Attractant stimuli, which cause inward piston displacements in chemoreceptors, should reduce cable tension, thereby stabilizing the HAMP bundle. This study shows how transmembrane signalling and HAMP input–output control could occur without the helix rotations central to the gearbox model.     

HAMP domain structural determinants for signalling and sensory adaptation in Tsr,the Escherichia coli serine chemoreceptor

HAMP domains mediate input–output transactions in many bacterial signalling proteins. To clarify the mechanistic logic of HAMP signalling, we constructed Tsr‐HAMP deletion derivatives and characterized their steady‐state signal outputs and sensory adaptation properties with flagellar rotation and receptor methylation assays. Tsr molecules lacking the entire HAMP domain or just the HAMP‐AS2 helix generated clockwise output signals, confirming that kinase activation is the default output state of the chemoreceptor signalling domain and that attractant stimuli shift HAMP to an overriding kinase‐off signalling state to elicit counter‐clockwise flagellar responses. Receptors with deletions of the AS1 helices, which free the AS2 helices from bundle‐packing constraints, exhibited kinase‐off signalling behaviour that depended on three C‐terminal hydrophobic residues of AS2. We conclude that AS2/AS2′ packing interactions alone can play an important role in controlling output kinase activity. Neither kinase‐on nor kinase‐off HAMP deletion outputs responded to sensory adaptation control, implying that out‐of‐range conformations or bundle‐packing stabilities of their methylation helices prevent substrate recognition by the adaptation enzymes. These observations support the previously proposed biphasic, dynamic‐bundle mechanism of HAMP signalling and additionally show that the structural interplay of helix‐packing interactions between HAMP and the adjoining methylation helices is critical for sensory adaptation control of receptor output.     

Delineating PAS‐HAMP interaction surfaces and signalling‐associated changes in the aerotaxis receptor Aer

The Escherichia coli aerotaxis receptor, Aer, monitors cellular oxygen and redox potential via FAD bound to a cytosolic PAS domain. Here, we show that Aer‐PAS controls aerotaxis through direct, lateral interactions with a HAMP domain. This contrasts with most chemoreceptors where signals propagate along the protein backbone from an N‐terminal sensor to HAMP. We mapped the interaction surfaces of the Aer PAS, HAMP and proximal signalling domains in the kinase‐off state by probing the solvent accessibility of 129 cysteine substitutions. Inaccessible PAS‐HAMP surfaces overlapped with a cluster of PAS kinase‐on lesions and with cysteine substitutions that crosslinked the PAS β ‐scaffold to the HAMP AS‐2 helix. A refined Aer PAS‐HAMP interaction model is presented. Compared to the kinase‐off state, the kinase‐on state increased the accessibility of HAMP residues (apparently relaxing PAS‐HAMP interactions), but decreased the accessibility of proximal signalling domain residues. These data are consistent with an alternating static‐dynamic model in which oxidized Aer‐PAS interacts directly with HAMP AS‐2, enforcing a static HAMP domain that in turn promotes a dynamic proximal signalling domain, resulting in a kinase‐off output. When PAS‐FAD is reduced, PAS interaction with HAMP is relaxed and a dynamic HAMP and static proximal signalling domain convey a kinase‐on output.