NORMAL GENOMIC

• Bjorkman AM, Dunten P, Sandgren MO, Dwarakanath VN, Mowbray SL
• Mutations that affect ligand binding to the Escherichia coli aspartate receptor: implications for transmembrane signaling.
• J Biol Chem. 2001; 276: 2808-15
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• Three arginine residues of the binding site of the Escherichia coli aspartate receptor contribute to its high affinity for aspartate (K(d) approximately 3 microm). Site-directed mutations at residue 64 had the greatest effect on aspartate binding. No residue could substitute for the native arginine; all changes resulted in an apparent K(d) of approximately 35 mm. These mutations had little impact on maltose responses. At residue Arg-69, a lysine substitution was least disruptive, conferring an apparent K(d) of 0.3 mm for aspartate. Results obtained for an alanine mutant were similar to those with cysteine and histidine mutants (K(d) approximately 5 mm) indicating that side chain size was not an important factor here. Proline and aspartate caused more severe defects, presumably for reasons related to conformation and charge. The impact of residue 69 mutations on the maltose response was small. Mutations at Arg-73 had similar effects on aspartate binding (K(d) 0.3-7 mm) but more severe consequences for maltose responses. Larger side chains resulted in the best aspartate binding, implying steric considerations are important here. Signaling in the mutant proteins was surprisingly robust. Given aspartate binding, signaling occurred with essentially wild-type efficiency. These results were evaluated in the context of available structural data.

• Kim KK, Yokota H, Kim SH
• Four-helical-bundle structure of the cytoplasmic domain of a serine chemotaxis receptor.
• Nature. 1999; 400: 787-92
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• The bacterial chemotaxis receptors are transmembrane receptors with a simple signalling pathway which has elements relevant to the general understanding of signal recognition and transduction across membranes, how signals are relayed between molecules in a pathway, and how adaptation to a persistent signal is achieved. In contrast to many mammalian receptors which signal by oligomerizing upon ligand binding, the chemotaxis receptors are dimeric even in the absence of their ligands, and their signalling does not depend on a monomer-dimer equilibrium. Bacterial chemotaxis receptors are composed of a ligand-binding domain, a transmembrane domain consisting of two helices TM1 and TM2, and a cytoplasmic domain. All known bacterial chemotaxis receptors have a highly conserved cytoplasmic domain, which unites signals from different ligand domains into a single signalling pathway to flagella motors. Here we report the crystal structure of the cytoplasmic domain of a serine chemotaxis receptor of Escherichia coli, which reveals a 200 A-long coiled-coil of two antiparallel helices connected by a 'U-turn'. Two of these domains form a long, supercoiled, four-helical bundle in the cytoplasmic portion of the receptor.

• Nishiyama S, Maruyama IN, Homma M, Kawagishi I
• Inversion of thermosensing property of the bacterial receptor Tar by mutations in the second transmembrane region.
• J Mol Biol. 1999; 286: 1275-84
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• The aspartate chemoreceptor Tar of Escherichia coli serves as a warm sensor that produces attractant and repellent signals upon increases and decreases in temperature, respectively. However, increased levels of methylation of the cytoplasmic domain of Tar resulting from aspartate binding convert Tar to a cold sensor with the opposite signaling behavior. Detailed analyses of the methylation sites, which are located in two separate alpha-helices (MH1 and MH2), have suggested that intra- and/or intersubunit interactions of MH1 and MH2 play a critical role in thermosensing. These interactions may be influenced by binding of aspartate, which could trigger some displacement of MH1 through the second transmembrane region (TM2). As an initial step toward understanding the role of TM2 in thermosensing, we have examined the thermosensing properties of 43 mutant Tar receptors with randomized TM2 sequences (residues 190-210). Among them, we identified one mutant receptor (Tar-I2) that functioned as a cold sensor in the absence of aspartate. This is the first example of attractant-independent inversion of thermosensing in Tar. Further analyses identified the minimal essential divergence from the wild-type Tar sequence (Q191V-W192R-Q193C) required for the inverted response. Thus, displacements of TM2 seem to influence the thermosensing function of Tar.

• Trammell MA, Falke JJ
• Identification of a site critical for kinase regulation on the central processing unit (CPU) helix of the aspartate receptor.
• Biochemistry. 1999; 38: 329-36
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• Ligand binding to the homodimeric aspartate receptor of Escherichia coli and Salmonella typhimurium generates a transmembrane signal that regulates the activity of a cytoplasmic histidine kinase, thereby controlling cellular chemotaxis. This receptor also senses intracellular pH and ambient temperature and is covalently modified by an adaptation system. A specific helix in the cytoplasmic domain of the receptor, helix alpha6, has been previously implicated in the processing of these multiple input signals. While the solvent-exposed face of helix alpha6 possesses adaptive methylation sites known to play a role in kinase regulation, the functional significance of its buried face is less clear. This buried region lies at the subunit interface where helix alpha6 packs against its symmetric partner, helix alpha6'. To test the role of the helix alpha6-helix alpha6' interface in kinase regulation, the present study introduces a series of 13 side-chain substitutions at the Gly 278 position on the buried face of helix alpha6. The substitutions are observed to dramatically alter receptor function in vivo and in vitro, yielding effects ranging from kinase superactivation (11 examples) to complete kinase inhibition (one example). Moreover, four hydrophobic, branched side chains (Val, Ile, Phe, and Trp) lock the kinase in the superactivated state regardless of whether the receptor is occupied by ligand. The observation that most side-chain substitutions at position 278 yield kinase superactivation, combined with evidence that such facile superactivation is rare at other receptor positions, identifies the buried Gly 278 residue as a regulatory hotspot where helix packing is tightly coupled to kinase regulation. Together, helix alpha6 and its packing interactions function as a simple central processing unit (CPU) that senses multiple input signals, integrates these signals, and transmits the output to the signaling subdomain where the histidine kinase is bound. Analogous CPU elements may be found in other receptors and signaling proteins.

• Butler SL, Falke JJ
• Cysteine and disulfide scanning reveals two amphiphilic helices in the linker region of the aspartate chemoreceptor.
• Biochemistry. 1998; 37: 10746-56
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• The transmembrane aspartate receptor of E. coli and S. typhimurium mediates cellular chemotaxis toward aspartate by regulating the activity of the cytoplasmic histidine kinase, CheA. Ligand binding results in transduction of a conformational signal through the membrane to the cytoplasmic domain where both kinase regulation and adaptation occur. Of particular interest is the linker region, E213 to Q258, which connects and transduces the conformational signal between the cytoplasmic end of the transmembrane signaling helix (alpha 4/TM2) and the major methylation helix of the cytoplasmic domain (alpha 6). This linker is crucial for stable folding and function of the homodimeric receptor. The present study uses cysteine and disulfide scanning mutagenesis to investigate the secondary structure and packing surfaces within the linker region. Chemical reactivity assays reveal that the linker consists of three distinct subdomains: two alpha-helices termed alpha 4 and alpha 5 and, between them, an ordered region of undetermined secondary structure. When cysteine is scanned through the helices, characteristic repeating patterns of solvent exposure and burial are observed. Activity assays, both in vivo and in vitro, indicate that each helix possesses a buried packing face that is crucial for proper receptor function. The interhelical subdomain is at least partially buried and is also crucial for proper receptor function. Disulfide scanning places helix alpha 4 distal to the central axis of the homodimer, while helix alpha 5 is found to lie at the subunit interface. Finally, sequence alignments suggest that all three linker subdomains are highly conserved among the large subfamily of histidine kinase-coupled sensory receptors that possess methylation sites for use in covalent adaptation.

• Chi YI, Yokota H, Kim SH
• Apo structure of the ligand-binding domain of aspartate receptor from Escherichia coli and its comparison with ligand-bound or pseudoligand-bound structures.
• FEBS Lett. 1997; 414: 327-32
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• The aspartate receptor from E. coli is a dimeric transmembrane-signaling protein that mediates chemotaxis behavior and is the most studied system among the chemotaxis receptors to understand the molecular mechanism for transmembrane signaling. However, there is an unresolved issue for the structural event which initiates the transmembrane signal upon binding to the ligand. Biochemical and genetic evidence implies an intrasubunit mechanism (monomeric model) whereas crystallographic evidence implies an intersubunit mechanism (dimeric model). Crystallographic evidence has been ambiguous because all the apo protein structures contained a pseudoligand sulfate, and a completely ligand-free structure has not been available thus far. Here we present the crystal structure of the ligand binding domain of the aspartate receptor free of the ligand aspartate or pseudoligand sulfate. The structural comparison of this structure with those of ligand-bound and pseudoligand-bound forms revealed that, on ligand or pseudoligand binding, the conformational change in the ligand-binding domain is relatively small, but there is a considerable rotation between two subunits, supporting the dimeric model.

• Le Moual H, Quang T, Koshland DE Jr
• Methylation of the Escherichia coli chemotaxis receptors: intra- and interdimer mechanisms.
• Biochemistry. 1997; 36: 13441-8
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• The mechanism(s) of methylation of the Escherichia coli chemotaxis receptors was analyzed by experiments involving the construction of a series of aspartate receptor variants. Truncation of five or more residues from the C-terminal end of the aspartate receptor, which prevents the methyltransferase from binding to the receptor, resulted in very low rates of methylation, indicating that the methyltransferase is activated by binding to the receptor. Coexpression of a receptor variant that is unmethylatable but able to C-terminally bind the methyltransferase resulted in much higher methylation rates for all of the truncated receptors. By preventing the possibility of subunit exchange between receptor variants, we showed that the truncated receptors were methylated via an interdimer mechanism. The interdimer methylation rates of the truncated receptors were found to be 3-fold lower than the methylation rate of the unaltered receptor, suggesting that intradimer methylation as well as interdimer methylation accounts for the methylation of the unaltered receptor. In addition, the presence of the cytoplasmic signaling proteins, which have been shown to cause receptor clustering, did not influence the rates of methylation.

• Danielson MA, Bass RB, Falke JJ
• Cysteine and disulfide scanning reveals a regulatory alpha-helix in the cytoplasmic domain of the aspartate receptor.
• J Biol Chem. 1997; 272: 32878-88
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• The transmembrane, homodimeric aspartate receptor of Escherichia coli and Salmonella typhimurium controls the chemotactic response to aspartate, an attractant, by regulating the activity of a cytoplasmic histidine kinase. The cytoplasmic domain of the receptor plays a central role in both kinase regulation and sensory adaptation, although its structure and regulatory mechanisms are unknown. The present study utilizes cysteine and disulfide scanning to probe residues Leu-250 through Gln-309, a region that contains the first of two adaptive methylation segments within the cytoplasmic domain. Following the introduction of consecutive cysteine residues by scanning mutagenesis, the measurement of sulfhydryl chemical reactivities reveals an alpha-helical pattern of exposed and buried positions spanning residues 270-309. This detected helix, termed the "first methylation helix," is strongly amphiphilic; its exposed face is highly anionic and possesses three methylation sites, while its buried face is hydrophobic. In vivo and in vitro assays of receptor function indicate that inhibitory cysteine substitutions are most prevalent on the buried face of the first methylation helix, demonstrating that this face is involved in a critical packing interaction. The buried face is further analyzed by disulfide scanning, which reveals three "lock-on" disulfides that covalently trap the receptor in its kinase-activating state. Each of the lock-on disulfides cross-links the buried faces of the two symmetric first methylation helices of the dimer, placing these helices in direct contact at the subunit interface. Comparative sequence analysis of 56 related receptors suggests that the identified helix is a conserved feature of this large receptor family, wherein it is likely to play a general role in adaptation and kinase regulation. Interestingly, the rapid rates and promiscuous nature of disulfide formation reactions within the scanned region reveal that the cytoplasmic domain of the full-length, membrane-bound receptor has a highly dynamic structure. Overall, the results demonstrate that cysteine and disulfide scanning can identify secondary structure elements and functionally important packing interfaces, even in proteins that are inaccessible to other structural methods.

• Chen X, Koshland DE Jr
• Probing the structure of the cytoplasmic domain of the aspartate receptor by targeted disulfide cross-linking.
• Biochemistry. 1997; 36: 11858-64
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• Applying the technique of targeted disulfide cross-linking to the cytoplasmic domain of the aspartate receptor of Salmonella typhimurium indicates a generally alpha-helical conformation of the linker region, and a close juxtaposition and a parallel alignment at the interface between the two subunits in the linker region. This conclusion is supported by the results from the Fourier transform of the hydrophobicity values of the amino acid sequences. Aspartate binding in the periplasmic domain causes a closer juxtaposition of the two subunits in the cytoplasmic domain, as indicated by the more rapid disulfide cross-linking on addition of aspartate.

• Kolodziej AF, Tan T, Koshland DE Jr
• Producing positive, negative, and no cooperativity by mutations at a single residue located at the subunit interface in the aspartate receptor of Salmonella typhimurium.
• Biochemistry. 1996; 35: 14782-92
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• Site-directed mutagenesis of the aspartate receptor of Salmonella typhimurium (Tars) at serine 68, a residue located within the aspartate binding pocket and at the subunit interface, identified this residue as an allosteric switch in this receptor. Substitutions at this position can affect both the type and degree of binding cooperativity observed. Negative cooperativity is observed in the wild-type receptor (nH = 0.7 +/- 0.1) and is maintained by the mutations S68C (nH = 0.8 +/- 0.02), S68V (nH = 0.9 +/- 0.05), and S68D (half-of-the-sites). Binding at only half of the sites was detectable in the S68D mutant, an extreme form of negative cooperativity. No cooperativity (nH = 1.0 +/- 0.03) was observed in the mutant S68A. Positive cooperativity was generated by the substitutions S68T (nH = 1.2 +/- 0.09), S68L (nH = 1.2 +/- 0.1), S68N (nH = 1.3 +/- 0.2), and S68I (nH = 1.4 +/- 0.2). Binding measurements indicated that the substitutions S68Q, S68E, and S68F decrease affinity of the first ligand binding 500-fold, 7000-fold, and 1600-fold, respectively.

• Baumgartner JW, Hazelbauer GL
• Mutational analysis of a transmembrane segment in a bacterial chemoreceptor.
• J Bacteriol. 1996; 178: 4651-60
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• Trg is a member of a family of receptors that mediates chemotaxis by Escherichia coli. Its transmembrane domain is a loose four-helix bundle consisting of two helices from each of the two identical subunits. This domain mediates transmembrane signaling through a conformational change in which the second transmembrane segment (TM2) is thought to move relative to TM1, but mutational analysis of TM2 by cysteine scanning had identified only a few positions at which substitutions perturbed function or induced signaling. Thus, we performed mutational analysis by random mutagenesis and screening. Among 42 single-residue substitutions in TM2 that detectably altered function, 16 had drastic effects on receptor activity. These substitutions defined a helical face of TM2. This functionally important surface was directed into the protein interior of the transmembrane domain, where TM2 faces the helices or the other subunit. The functionally perturbing substitutions did not appear to cause general disruption of receptor structure but rather had more specific effects, altering aspects of transmembrane signaling. An in vivo assay of signaling identified some substitutions that reduced and others that induced signaling. These two classes were distributed along adjacent helical faces in a pattern that strongly supports the notion that conformational signaling involves movement between TM2 and TM1 and that signaling is optimal when stable interactions are maintained across the interface between the homologous helices in the transmembrane domain. Our mutational analysis also revealed a striking tolerance of the chemoreceptor for substitutions, including charged residues, usually considered to be disruptive of transmembrane segments.

• Chervitz SA, Falke JJ
• Molecular mechanism of transmembrane signaling by the aspartate receptor: a model.
• Proc Natl Acad Sci U S A. 1996; 93: 2545-50
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• The aspartate receptor of bacterial chemotaxis is representative of a large class of membrane-spanning receptors found in prokaryotic and eukaryotic organisms. These receptors, which regulate histidine kinase pathways and possess two putative transmembrane helices per subunit, appear to control a wide variety of cellular processes. The best characterized subgroup of the two-helix receptor class is the homologous family of chemosensory receptors from Escherichia coli and Salmonella typhimurium, including the aspartate receptor. This receptor binds aspartate, an attractant, in the periplasmic compartment and undergoes an intramolecular, transmembrane conformational change, thereby modulating the autophosphorylation rate of a bound histidine kinase in the cytoplasm. Here, we analyze recent results from x-ray crystallographic, solution 19F NMR, and engineered disulfide studies probing the aspartate-induced structural change within the periplasmic and transmembrane regions of the receptor. Together, these approaches provide evidence that aspartate binding triggers a "swinging-piston" displacement of the second membrane-spanning helix, which is proposed to communicate the signal across the bilayer.

• Yeh JI, Biemann HP, Prive GG, Pandit J, Koshland DE Jr, Kim SH
• High-resolution structures of the ligand binding domain of the wild-type bacterial aspartate receptor.
• J Mol Biol. 1996; 262: 186-201
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• The high-resolution structures of the wild-type periplasmic domain of the bacterial aspartate receptor have been determined in the absence and presence of bound aspartate to 1.85 and 2.2 A resolution, respectively. As we reported earlier, in the refined structure of the complexed form of the crosslinked cysteine mutant receptor, the binding of the aspartate at the first site was mediated through four bridging water molecules while the second site showed an occupant electron density that best fit a sulfate group, which was present in the crystallization solution at high concentration. In the wild-type periplasmic domain structure two aspartate residues are bound per dimer, but with different occupancies. There exists a "strong" aspartate-binding site whose binding is again mediated by four water molecules while the second site contains aspartate whose B-factor is about 10% higher, signifying weaker binding. The interaction between the second, "weaker" aspartate with the three ligand-binding arginine side-chains is slightly different from the first site. The major difference is that there are three water molecules mediating the binding of aspartate at the second site, whereas in the first site there are four bridging water molecules. The fact that aspartate-complexed crystals of the wild-type were grown with a large excess aspartate while the cross-linked crystals were grown with equal molar aspartate may explain the difference in the stoichiometry observed. The conservation of the four bridging water molecules in the strong aspartate site of both the cross-linked and wild-type periplasmic domain may reflect an important binding motif. The periplasmic domain in the apo form is a symmetrical dimer, in which each of the subunits is equivalent, and the two aspartate binding sites are identical. Upon the binding of aspartate, the subunits are no longer symmetrical. The main difference between the aspartate-bound and unbound forms is in a small, rigid-body rotation between the subunits within a dimer. The rotation is similar in both direction and magnitude in the crosslinked and wild-type periplasmic domains. The presence of the second aspartate in the wild-type structure does not make any additional rotation compared to the single-site binding. The conservation of the small angular change in vitro suggests that the inter-subunit rotation may have relevance to the understanding of the mechanism of transmembrane signal transduction in vivo.

• Gardina PJ, Manson MD
• Attractant signaling by an aspartate chemoreceptor dimer with a single cytoplasmic domain.
• Science. 1996; 274: 425-6
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• Signal transduction across cell membranes often involves interactions among identical receptor subunits, but the contribution of individual subunits is not well understood. The chemoreceptors of enteric bacteria mediate attractant responses by interrupting a phosphotransfer circuit initiated at receptor complexes with the protein kinase CheA. The aspartate receptor (Tar) is a homodimer, and oligomerized cytoplasmic domains stimulate CheA activity much more than monomers do in vitro. Intragenic complementation was used to show in Escherichia coli that heterodimers containing one full-length and one truncated Tar subunit mediated responses to aspartate in the presence of full-length Tar homodimers that could not bind aspartate. Thus, a Tar dimer containing only one cytoplasmic domain can initiate an attractant (inhibitory) signal, although it may not be able to stimulate kinase activity of CheA.

• Hughson AG, Hazelbauer GL
• Detecting the conformational change of transmembrane signaling in a bacterial chemoreceptor by measuring effects on disulfide cross-linking in vivo.
• Proc Natl Acad Sci U S A. 1996; 93: 11546-51
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• Transmembrane signaling by bacterial chemoreceptors is thought to involve relative movement among the four transmembrane helices of the homodimer. We assayed that movement by measuring effects of ligand occupancy on rates of oxidative cross-linking between cysteines introduced into neighboring helices of the transmembrane domain of chemoreceptor Trg from Escherichia coli. Measurements were done on chemoreceptors in their native environment, intact cells that were motile and chemotactically responsive. Receptor occupancy did not appear to cause drastic rearrangement of the four-helix structure since, among 67 cysteine pairs tested, the same 19 exhibited oxidative cross-linking in the presence or absence of saturating chemoattractant. However, occupancy did cause subtle changes that were detected as effects on rates of cross-linking. Among the seven disulfides appropriate for measurements of initial rates of formation, ligand occupancy had significant and different effects on all three cross-links that connected the two helices within a subunit but had minimal effects on the four that spanned the packing interface between subunits. This constitutes direct evidence that the conformational change of transmembrane signaling involves significant movement within a subunit and minimal movement between subunits, a pattern deduced from several previous studies and now documented directly. Among possible modes of movement between the two helices of a subunit, axial sliding of one helix relative to the other was the conformational change that best accounted for the observed effects on cross-linking.

• Shapiro MJ, Panomitros D, Koshland DE Jr
• Interactions between the methylation sites of the Escherichia coli aspartate receptor mediated by the methyltransferase.
• J Biol Chem. 1995; 270: 751-5
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• Mutations made at and near the methylation sites of the Escherichia coli aspartate receptor were found to affect the methylation rates of the remaining methylation sites. The results supported a model in which the methyltransferase enzyme contacts a residue seven amino acids to the C terminus of a site being methylated. The presence of a negatively charged residue at that position inhibits methylation, whereas a neutral residue has no effect. Methylation sites in the wild type receptor may also influence the methylation of other sites which are 7 residues away through a physical contact with the methyltransferase.

• Chervitz SA, Falke JJ
• Lock on/off disulfides identify the transmembrane signaling helix of the aspartate receptor.
• J Biol Chem. 1995; 270: 24043-53
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• The aspartate receptor of the bacterial chemotaxis pathway regulates the autophosphorylation rate of a cytoplasmic histidine kinase in response to ligand binding. The transmembrane signal, which is transmitted from the periplasmic aspartate-binding domain to the cytoplasmic regulatory domain, is carried by an intramolecular conformational change within the homodimeric receptor structure. The present work uses engineered cysteines and disulfide bonds to probe the nature of this conformational change, focusing in particular on the role of the second transmembrane alpha-helix. Altogether 26 modifications, consisting of 13 cysteine pairs and the corresponding disulfide bonds, have been introduced into the contacts between the second transmembrane helix and adjacent helices. The effects of these modifications on the transmembrane signal have been quantified by in vitro assays which measure (i) ligand binding, (ii) receptor-mediated regulation of kinase activity, and (iii) receptor methylation. All three parameters are observed to be highly sensitive to perturbations of the second transmembrane helix. In particular, 13 of the 26 modifications (6 cysteine pairs and 7 disulfides) significantly increase or decrease aspartate affinity, while 15 of the 26 modifications (6 cysteine pairs and 10 disulfides) destroy transmembrane kinase regulation. Importantly, 3 of the perturbing disulfides are found to lock the receptor in the "on" or "off" signaling state by covalently constraining the second transmembrane helix, demonstrating that it is possible to use engineered disulfides to lock the signaling function of a receptor protein. A separate aspect of the study probes the thermal motions of the second transmembrane helix: 4 disulfides designed to trap large amplitude twisting motions are observed to disrupt function but form readily, suggesting that the helix is mobile. Together the results support a model in which the second transmembrane helix is a mobile signaling element responsible for communicating the transmembrane signal.

• Jeffery CJ, Koshland DE Jr
• A single hydrophobic to hydrophobic substitution in the transmembrane domain impairs aspartate receptor function.
• Biochemistry. 1994; 33: 3457-63
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• Many transmembrane receptors, such as the insulin, EGF, and bacterial chemotaxis receptors, have only one or a few transmembrane domains connecting an extracellular ligand-binding domain to a cytoplasmic signaling domain. The general belief is that the transmembrane domains in these receptors have no specific sequence requirements as long as they are hydrophobic and long enough to span the membrane as an alpha-helix. To test this model, we constructed mutants in the aspartate receptor. This receptor is a dimer with two transmembrane domains per subunit. Amino acid substitutions can be made at several positions in the second transmembrane domain, which connects the periplasmic aspartate-binding domain to the cytoplasmic signaling domain, and the receptor remains functional. However, a single substitution of one hydrophobic residue for another can impair receptor function in methylation and swarm plate assays. These results suggest that the second transmembrane domain may pack against the other transmembrane domains in the receptor and small changes in this packing can affect the function of the receptor.

• Danielson MA, Biemann HP, Koshland DE Jr, Falke JJ
• Attractant- and disulfide-induced conformational changes in the ligand binding domain of the chemotaxis aspartate receptor: a 19F NMR study.
• Biochemistry. 1994; 33: 6100-9
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• The isolated ligand binding domain of the chemotaxis aspartate receptor is the focus of the present study, which both (a) identifies structural regions involved in the attractant-induced conformational change and (b) investigates the kinetic parameters of attractant binding. To analyze the attractant-induced conformational change within the homodimeric domain, 19F NMR is used to monitor six para-fluorophenylalanine (4-F-Phe) positions within each identical subunit of the homodimer. The binding one molecule of aspartate to the homodimer perturbs three of the 4-F-Phe resonances significantly: 4-F-Phe150 in the attractant binding site, 4-F-Phe107 located 26 A from the site, and 4-F-Phe180 at a distance of 40 A from the site. Comparison of the frequency shifts triggered by aspartate and glutamate reveals that these attractants generate different conformations in the vicinity of the attractant site but trigger indistinguishable long-range conformational effects at distant positions. This long-range conformational change is specific for attractant binding, since formation of the Cys36-Cys36' disulfide bond or the nonphysiological binding of 1,10-phenanthroline to an aromatic pocket distal to the attractant site each yield conformational changes which are significantly more localized. The attractant-triggered perturbations detected at 4-F-Phe107 and 4-F-Phe180 indicate that the structural change includes an intrasubunit component communicated through the domain to its C-terminal region, which, in the full-length receptor, continues through the membrane as the second membrane-spanning helix. It would thus appear that the transmembrane signal is transmitted through this helix.(ABSTRACT TRUNCATED AT 250 WORDS)

• Kim SH
• "Frozen" dynamic dimer model for transmembrane signaling in bacterial chemotaxis receptors.
• Protein Sci. 1994; 3: 159-65
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• The crystal structures of the ligand binding domain of a bacterial aspartate receptor suggest a simple mechanism for transmembrane signaling by the dimer of the receptor. On ligand binding, one domain rotates with respect to the other, and this rotational motion is proposed to be transmitted through the membrane to the cytoplasmic domains of the receptor.

• Jeffery CJ, Koshland DE Jr
• Three-dimensional structural model of the serine receptor ligand-binding domain.
• Protein Sci. 1993; 2: 559-66
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• Computer-based homology modeling techniques were used to construct a three-dimensional model of the Escherichia coli serine receptor ligand-binding domain based on the crystal structure of the Salmonella typhimurium aspartate receptor and the sequence homology between the two receptors. Residues that have been found in mutagenesis studies to be necessary for serine binding are located in a proposed serine-binding site. Several other mutations that affect swimming behavior require relatively small shifts in alpha-carbon positions in the model to give a minimized structure, suggesting that small changes in receptor conformation can affect the signaling state of the receptor.

• Yeh JI, Biemann HP, Pandit J, Koshland DE, Kim SH
• The three-dimensional structure of the ligand-binding domain of a wild-type bacterial chemotaxis receptor. Structural comparison to the cross-linked mutant forms and conformational changes upon ligand binding.
• J Biol Chem. 1993; 268: 9787-92
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• The three-dimensional structures of the ligand-binding domain of the wild-type Salmonella typhimurium aspartate receptor have been determined in the absence (apo) and presence of bound aspartate (complex) and compared to a cross-linked mutant containing a cysteine at position 36 which does not change signaling behavior of the intact receptor. The structures of the wild-type forms were determined in order to assess the effects of cross-linking on the structure and its influence on conformational changes upon ligand binding. As in the case of the cross-linked mutant receptor, the non-cross-linked ligand-binding domain is dimeric and is composed of 4-alpha-helical bundle monomer subunits related by a crystallographic 2-fold axis in the unbound form and by a non-crystallographic axis in the aspartate-bound form. A comparative study between the non-cross-linked and cross-linked structures has led to the following observations: 1) The long N-terminal helices of the individual subunits in the cross-linked structures are bent toward each other to accommodate the disulfide bond. 2) The rest of the subunit conformation is very similar to that of the wild-type. 3) The intersubunit angle of the cross-linked apo structure is larger by about 13 degrees when compared to the wild-type apo structure. 4) The nature and magnitude of the aspartate-induced conformational changes in the non-cross-linked wild-type structures are very similar to those of the cross-linked structures.

• Scott WG et al.
• Refined structures of the ligand-binding domain of the aspartate receptor from Salmonella typhimurium.
• J Mol Biol. 1993; 232: 555-73
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• The aspartate receptor is a transmembrane-signalling protein that mediates chemotaxis behaviour in bacteria. Aspartate receptors in Salmonella typhimurium and Escherichia coli exist as dimers of two subunits in the presence as well as in the absence of aspartate. We have previously reported the three-dimensional structures of the external ligand-binding domain of the S. typhimurium aspartate receptor with and without bound aspartate. The external or periplasmic region of the aspartate receptor is a dimer of four-alpha-helical bundle subunits; a single aspartate molecule binds to one of two sites residing at the subunit interface, increasing the affinity of the subunits for one another. Here we report the results of a detailed analysis of the aspartate receptor ligand-binding domain structure (residues 25 to 188). The dimer interface between the twofold related subunits consists primarily of contacts mediated by the side-chains of the N-terminal helix of each four-alpha-helical bundle subunit. The N-terminal helices pack approximately 20 degrees from parallel as an approximate coiled-coil super-secondary structure. We have refined aspartate receptor ligand-binding domain structures in the presence and in the absence of a bound aromatic compound, 1,10-phenanthroline, to 2.2 A and 2.3 A resolution, respectively, as well as crystal structures in the presence of specifically bound Au(I), Hg(II) and Pt(IV) complex ions at 2.4 A, 3.0 A and 3.3 A resolution, respectively. The possible biological relevance of the aromatic ligand-binding site and the metal ion-binding sites is discussed. The dimer of four-alpha-helical bundle subunits composing the periplasmic region of the S. typhimurium aspartate receptor provides a basis for understanding the results of mutational analyses performed on related chemotaxis transmembrane receptors. The crystal structure analysis provides an explanation for the way in which mutations in the E. coli aspartate receptor affect its binding to the periplasmic maltose-binding protein and how mutations in the more distantly related E. coli Trg chemotaxis receptor affect its binding to the periplasmic ribose and glucose-galactose binding proteins.

• Kim SH, Prive GG, Yeh J, Scott WG, Milburn MV
• A model for transmembrane signaling in a bacterial chemotaxis receptor.
• Cold Spring Harb Symp Quant Biol. 1992; 57: 17-24

• Lynch BA, Koshland DE Jr
• The fifth Datta Lecture. Structural similarities between the aspartate receptor of bacterial chemotaxis and the trp repressor of E. coli. Implications for transmembrane signaling.
• FEBS Lett. 1992; 307: 3-9
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• A high resolution structure of the N-terminal ligand-binding domain of the aspartate receptor which mediates aspartate chemotaxis in Salmonella typhimurium has recently been reported. A least-squares superposition of the alpha-amino nitrogen, alpha-carbon, beta-carbon, and alpha-carboxylate carbon of the aspartate bound to the aspartate receptor onto the equivalent atoms in the tryptophan bound to the trp repressor provides evidence for similarity between key parts of the active sites that bind to the alpha-amino and alpha-carboxylates of the respective ligands. Because the N-terminal domain of the aspartate receptor and the trp repressor also share other structural similarities, we hypothesize that the similarity between the aspartate receptor and the trp repressor derives from a similarity in ligand-induced conformational changes at the active sites of these proteins. This hypothesis also implies that an important signaling event in the aspartate receptor occurs through tertiary conformational changes within a single subunit.

• Milligan DL, Koshland DE Jr
• Intrasubunit signal transduction by the aspartate chemoreceptor.
• Science. 1991; 254: 1651-4
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• Receptors that transmit signals across cell membranes are typically composed of multiple subunits. To test whether subunit interactions are required for transmembrane signaling by the bacterial aspartate receptor, dimers were constructed with (i) two full-length subunits, (ii) one full-length subunit and one subunit lacking the cytoplasmic domain, or (iii) one full-length subunit and one subunit lacking both the cytoplasmic and the transmembrane domains. Methylation of the cytoplasmic domain of all three receptor constructs was stimulated by the binding of aspartate. These findings demonstrate that transmembrane signaling does not require interactions between cytoplasmic or transmembrane domains of adjacent subunits and suggest that signaling occurs via conformational changes transduced through a single subunit.

• Lynch BA, Koshland DE Jr
• Disulfide cross-linking studies of the transmembrane regions of the aspartate sensory receptor of Escherichia coli.
• Proc Natl Acad Sci U S A. 1991; 88: 10402-6
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• The Escherichia coli aspartate receptor, a dimer of identical subunits, has two transmembrane regions (TM1, residues 7-30; TM2, residues 189-212) of 24 residues each. To study the relative placement and orientation of the regions, cysteine residues were introduced individually into the center of each: at positions 17, 18, and 19 in TM1; and at positions 198, 199, 200, and 201 in TM2. Based on the patterns of disulfide cross-linking observed between subunits in the mutant receptors, there appears to be close contact between the TM1 and TM1' regions at the dimer interface but no such direct interaction between the TM2 and TM2' regions. The cross-linking results are consistent with an alpha-helical structure extending across the transmembrane region up through at least residue 36, which lies on the periplasmic side of TM1. The ability of an 18-18' cross-linked dimer to transmit an aspartate-induced transmembrane signal is also supportive of such an extended helix. The changes in relative rates of disulfide cross-linking provide experimental evidence of a conformational change transmitted through the transmembrane domain during signaling. Once formed, disulfides between the transmembrane regions are unusually resistant to reduction by low molecular weight thiols in the presence of denaturants like SDS. These targeted disulfide cross-links can be used to reveal structural and dynamic aspects of protein function.

• Milligan DL, Koshland DE Jr
• Site-directed cross-linking. Establishing the dimeric structure of the aspartate receptor of bacterial chemotaxis.
• J Biol Chem. 1988; 263: 6268-75
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• Cysteine residues introduced at specific locations in the aspartate receptor of Salmonella typhimurium provide anchor points for cross-linking and serve as chemical markers for structural studies of this oligomeric receptor. These markers have been used to measure the rate of subunit exchange between oligomeric receptors and to show that ligand binding inhibits this exchange. The cysteine-containing receptors can be oxidatively cross-linked to completion within the oligomeric receptor, indicating that the receptor has an even number of subunits. Based on this observation, a technique has been developed that can be used to determine the oligomeric structure of proteins under a variety of experimental conditions. The technique involves the measurement of the effect of dilution by "cysteineless" receptor subunits on cross-linking and reveals that the aspartate receptor is dimeric in detergent solution, in a mixed-micelle system, and in reconstituted membrane vesicles. Binding of aspartate does not change the oligomeric structure of the receptor, indicating that transmembrane signaling occurs within an oligomeric receptor of constant size.

• Falke JJ, Koshland DE Jr
• Global flexibility in a sensory receptor: a site-directed cross-linking approach.
• Science. 1987; 237: 1596-600
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• The aspartate receptor of Escherichia coli and Salmonella typhimurium is a cell surface sensory transducer that binds extracellular aspartate and sends a transmembrane signal to the inside of the bacterium. The flexibility and allostery of this receptor was examined by placing sulfhydryl groups as potential cross-linking sites at targeted locations in the protein. Seven different mutant receptors were constructed, each containing a single cysteine residue at a different position in the primary structure. Intramolecular disulfide bond formation within oligomers of these mutant receptors is shown to trap structural fluctuations and to detect ligand-induced changes in structure. The results indicate that the receptor oligomer has a flexible, dynamic structure which undergoes a global change upon aspartate binding.