Chimeric Chemoreceptors in Escherichia coli: Signaling Properties of Tar-Tap and Tap-Tar Hybrids

The Tap (taxis toward peptides) receptor and the periplasmic dipeptide-binding protein (DBP) of Escherichia coli together mediate chemotactic responses to dipeptides. Tap is a low-abundance receptor. It is present in 5- to 10-fold-fewer copies than high-abundance receptors like Tar and Tsr. Cells expressing Tap as the sole receptor, even from a multicopy plasmid at 5- to 10-fold-overexpressed levels, do not generate sufficient clockwise (CW) signal to tumble and thus swim exclusively smoothly (run). To study the signaling properties of Tap in detail, we constructed reciprocal hybrids between Tap and Tar fused in the linker region between the periplasmic and cytoplasmic domains. The Tapr hybrid senses dipeptides and is a good CW-signal generator, whereas the Tarp hybrid senses aspartate but is a poor CW-signal generator. Thus, the poor CW signaling of Tap is a property of its cytoplasmic domain. Eighteen residues at the carboxyl terminus of high-abundance receptors, including the NWETF sequence that binds the CheR methylesterase, are missing in Tap. The Tart protein, created by removing these 18 residues from Tar, has diminished CW-signaling ability. The Tapl protein, made by adding the last 18 residues of Tar to the carboxyl terminus of Tap, also does not support CW flagellar rotation. However, Tart and Tapl cross-react well with antibody directed against the conserved cytoplasmic region of Tsr, whereas Tap does not cross-react with this antibody. Tap does cross-react, however, with antibody directed against the low-abundance chemoreceptor Trg. The hybrid, truncated, and extended receptors exhibit various levels of methylation. However, Tar and Tapl, which contain a consensus CheR-binding motif (NWETF) at their carboxyl termini, exhibit the highest basal levels of methylation, as expected. We conclude that no simple correlation exists between the abundance of a receptor, its methylation level, and its CW-signaling ability.     

Methylation-independent aerotaxis mediated by the Escherichia coli Aer protein

Aer is a membrane-associated protein that mediates aerotactic responses in Escherichia coli. Its C-terminal half closely resembles the signaling domains of methyl-accepting chemotaxis proteins (MCPs), which undergo reversible methylation at specific glutamic acid residues to adapt their signaling outputs to homogeneous chemical environments. MCP-mediated behaviors are dependent on two specific enzymes, CheR (methyltransferase) and CheB (methylesterase). The Aer signaling domain contains unorthodox methylation sites that do not conform to the consensus motif for CheR or CheB substrates, suggesting that Aer, unlike conventional MCPs, might be a methylation-independent transducer. Several lines of evidence supported this possibility. (i) The Aer protein was not detectably modified by either CheR or CheB. (ii) Amino acid replacements at the putative Aer methylation sites generally had no deleterious effect on Aer function. (iii) Aer promoted aerotactic migrations on semisolid media in strains that lacked all four of the E. coli MCPs. CheR and CheB function had no influence on the rate of aerotactic movements in those strains. Thus, Aer senses and signals efficiently in the absence of deamidation or methylation, methylation changes, methylation enzymes, and methyl-accepting chemotaxis proteins. We also found that chimeric transducers containing the PAS-HAMP sensing domain of Aer joined to the signaling domain and methylation sites of Tar, an orthodox MCP, exhibited both methylation-dependent and methylation-independent aerotactic behavior. The hybrid Aear transducers demonstrate that methylation independence does not emanate from the Aer signaling domain but rather may be due to transience of the cellular redox changes that are thought to trigger Aer-mediated behavioral responses.     

Purification of receptor protein Trg by exploiting a property common to chemotactic transducers of Escherichia coli

The methyl-accepting chemotactic transducers of Escherichia coli were found to bind strongly to Cibacron blue-Sepharose. Among potential elutants tested, only S-adenosylmethionine at moderate concentrations and NaCl at concentrations greater than 1.5 M caused dissociation of these detergent-solubilized transmembrane proteins from the dye. Release by S-adenosylmethionine may be a generalized effect rather than the result of a specific binding site for that compound on transducers. A truncated trg gene was created that coded for the carboxyl-terminal three-fifths of the transducer, which constitutes the cytoplasmic domain common to all four transducers in E. coli. This domain bound to Cibacron blue-Sepharose and was eluted in a pattern similar to that exhibited by intact Trg, indicating that interaction with the dye occurred in this conserved domain. Adherence to Cibacron blue and elution by high salt formed the core of an efficient purification scheme, developed for Trg but applicable to all transducers in E. coli and perhaps to methyl-accepting chemotaxis proteins in other species. Determination of the amino acid sequence at the beginning of purified Trg confirmed that it contained a longer hydrophilic segment at its amino terminus than other transducers of E. coli. The initial methionine of Trg is neither cleaved nor modified, in contrast to the Tar transducer in which the amino terminus was found previously to be blocked. Circular dichroic measurements of purified Trg indicated that the secondary structural organization of the protein is predominantly alpha-helix.     

Multiple covalent modifications of Trg, a sensory transducer of Escherichia coli

The sensory transducers of Escherichia coli are integral membrane proteins that mediate the tactic response of cells to chemical stimuli. Adaptation to environmental stimuli is correlated with methylation of the transducer proteins. Two transducer genes, tsr and tar, exhibit extensive homologies while no homology has been detected between a third transducer, trg, and those genes. The Tsr and Tar proteins have been shown to contain multiple sites for methylation as well as two sites for another modification that requires an active cheB gene product and is designated the CheB-dependent modification. In this study, covalent modifications of the Trg protein were characterized by analysis of tryptic peptides. We found that methylation occurred at several sites on the Trg protein and that the protein contained at least three sites for CheB-dependent modification, two of which were located on a tryptic peptide that contains both methionine and lysine. This tryptic peptide is analogous to the methionine- and lysine-containing methyl-accepting peptides isolated from the Tsr and Tar proteins and like those peptides may contain several methyl-accepting sites. We estimated the pKa of the group created by the CheB-dependent modification on the methionine- and lysine-containing peptide of Trg to be between pH 2.2 and 5.8. This result supports the idea that the CheB-dependent modification is an enzymatic deamidation of glutamine to glutamic acid.     

Evolution of chemotactic-signal transducers in enteric bacteria.

The methyl-accepting chemotactic-signal transducers of the enteric bacteria are transmembrane proteins that consist of a periplasmic receptor domain and a cytoplasmic signaling domain. To study their evolution, transducer genes from Enterobacter aerogenes and Klebsiella pneumoniae were compared with transducer genes from Escherichia coli and Salmonella typhimurium. There are at least two functional transducer genes in the nonmotile species K. pneumoniae, one of which complements the defect in serine taxis of an E. coli tsr mutant. The tse (taxis to serine) gene of E. aerogenes also complements an E. coli tsr mutant; the tas (taxis to aspartate) gene of E. aerogenes complements the defect in aspartate taxis, but not the defect in maltose taxis, of an E. coli tar mutant. The sequence was determined for 5 kilobases of E. aerogenes DNA containing a 3' fragment of the cheA gene, cheW, tse, tas, and a 5' fragment of the cheR gene. The tse and tas genes are in one operon, unlike tsr and tar. The cytoplasmic domains of Tse and Tas are very similar to those of E. coli and S. typhimurium transducers. The periplasmic domain of Tse is homologous to that of Tsr, but Tas and Tar are much less similar in this region. However, several short sequences are conserved in the periplasmic domains of Tsr, Tar, Tse, and Tas but not of Tap and Trg, transducers that do not bind amino acids. These conserved regions include residues implicated in amino-acid binding.     

Limited homology between trg and the other transducer proteins of Escherichia coli.

Transducers are transmembrane proteins that are central to the chemotactic system of Escherichia coli. The proteins transduce ligand recognition into an excitatory signal and function in adaptation as methyl-accepting proteins. The transducer genes tsr, tar, and tap have extensive homology with each other. However, previous studies revealed little indication of homology between those three transducer genes and a fourth gene, trg. We investigated the relationship between trg and the other genes by blot-hybridization experiments and the relationship between Trg and the other transducer proteins by immune precipitation and experiments with an antiserum raised to purified Trg protein. In experiments in which 35% mismatch would be tolerated, weak hybridization of trg was detected to a DNA fragment containing tar and tap but not to a fragment containing tsr. In experiments in which only 30% mismatch would be tolerated, no trg hybridization was apparent either to total chromosomal DNA or to DNA from hybrid plasmids carrying the other transducer genes. An anti-Trg serum formed immune precipitates with the Tsr and Tar proteins as well as with the Trg protein to which it was raised. We conclude that there is homology between Trg and the other transducer, but the homology is more limited than that shared among the other transducers. Furthermore, we found no indication of additional transducer genes closely related to trg. Thus, the trg gene is a somewhat distant cousin within a single transducer gene family of E. coli.     

Genetics of methyl-accepting chemotaxis proteins in Escherichia coli: cheD mutations affect the structure and function of the Tsr transducer

The tsr gene specifies a methyl-accepting membrane protein involved in chemotaxis to serine and several repellent compounds. We have characterized a special class of tsr mutations designated cheD which alter the signaling properties of the Tsr transducer. Unlike tsr null mutants, cheD strains are generally nonchemotactic, dominant in complementation tests, and exhibit a pronounced counterclockwise bias in flagellar rotation. Several lines of evidence showed that cheD mutations were alleles of the tsr gene. First, cheD mutations were mapped into the same deletion segments as conventional tsr mutations. Second, restriction site analysis of the transducing phage deletions used to construct the genetic map demonstrated that the endpoints of the deletion segments fell within the tsr coding sequence. Third, a number of the cheD mutants synthesized Tsr proteins with slight changes in electrophoretic mobility, consistent with alterations in Tsr primary structure. These mutant proteins were able to undergo posttranslational deamidation and methylation reactions in the same manner as wild-type Tsr protein; however, the steady-state level of Tsr methylation in cheD strains was very high. The methylation state of the Tar protein, another species of methyl-accepting protein in Escherichia coli, was also higher than normal in cheD strains, suggesting that the aberrant Tsr transducer in cheD mutants has a generalized effect on the sensory adaptation system of the cell. These properties are consistent with the notion that the Tsr protein of cheD mutants is locked in an excitatory signaling mode that both activates the sensory adaptation system and drowns out chemotactic signals generated by other transducer species. Further study of cheD mutations thus promises to reveal valuable information about the functional architecture of the Tsr protein and how this transducer controls flagellar behavior.     

Mutation plus amplification of a transducer gene disrupts general chemotactic behavior in Escherichia coli.

Transducers are transmembrane receptor proteins that generate intracellular signals on stimulation and participate in adaptation by appropriate changes in the level of methylation. The transducer mutation trg-21 conferred a Trg- phenotype and defective taxis to galactose and ribose but a normal response to other attractants when present in a single chromosomal copy. Amplification of trg-21 by a multicopy plasmid made host cells generally nonchemotactic. The dominant phenotype resulted from a strong counterclockwise rotational bias of flagellar motors in Che- cells. Apparently, the Trg21 transducer sends a continuous counterclockwise signal to flagella independent of tactic stimulation. It appears that the cell has a homeostatic capacity that is sufficient to compensate for the effect of mutant transducers produced from a single chromosomal copy of trg-21, but the capacity is exceeded in cells that have multiple copies of the gene. The Trg21 protein did not have a significant effect on methylesterase activity, indicating that the two global effects of a stimulated transducer, that is, on flagellar rotation and on modification enzymes, can occur independently. The mutant protein exhibited essentially normal turnover of methyl groups but had a drastic defect in deamidation which thus reduced the number of methyl-accepting sites. The trg-21 mutation substitutes a threonine for Ala-419. This alanine is a conserved residue in all sequenced transducers and is in a region of the carboxy-terminal domain in which homology among the transducers is very high. The Trg21 phenotype implicates this conserved region in the generation of the excitatory signal which is directed at the flagella.     

An Archaeal Aerotaxis Transducer Combines Subunit I Core Structures of Eukaryotic Cytochrome c Oxidase and Eubacterial Methyl-Accepting Chemotaxis Proteins

Signal transduction in the archaeon Halobacterium salinarum is mediated by three distinct subfamilies of transducer proteins. Here we report the complete htrVIII gene sequence and present analysis of the encoded primary structure and its functional features. HtrVIII is a 642-amino-acid protein and belongs to halobacterial transducer subfamily B. At the N terminus, the protein contains six transmembrane segments that exhibit homology to the heme-binding sites of the eukaryotic cytochrome c oxidase. The C-terminal domain has high homology with the eubacterial methyl-accepting chemotaxis protein. The HtrVIII protein mediates aerotaxis: a strain with a deletion of the htrVIII gene loses aerotaxis, while an overproducing strain exhibits stronger aerotaxis. We also demonstrate that HtrVIII is a methyl-accepting protein and demethylates during the aerotaxis response.     

Cloning of trg, a gene for a sensory transducer in Escherichia coli.

Clones of trg, a gene which codes for a chemotactic transducer, were isolated linked to ColE1 and pBR322 vectors. Studies with the hybrid plasmids demonstrated unequivocally that trg is the structural gene for methyl-accepting chemotaxis protein III. The Trg protein was found to be structurally complex, electrophoresing as a series of seven bands on high-resolution sodium dodecyl sulfate-polyacrylamide gels. The multiplicity of bands is a function of the activity of cheR, which codes for a methyltransferase, and of cheB, which codes for a demethylase. It appears that Trg, a quantitatively minor transducer, resembles the two major transducer proteins, Tsr and Tar, in that all three are multiply methylated and also multiply modified in a second way which requires an active cheB gene. However, preliminary analysis of the Trg protein indicated that it is significantly less related structurally to the Tsr or Tar protein than those two transducers are to each other. This implies that the features of multiple methylation and cheB-dependent modification are likely to be critical for the common physiological functions in chemotactic excitation and adaptation performed by all three transducers.     

A predictive computational model of the kinetic mechanism of stimulus-induced transducer methylation and feedback regulation through CheY in archaeal phototaxis and chemotaxis

Background  

Photo- and chemotaxis of the archaeon Halobacterium salinarum is based on the control of flagellar motor switching through stimulus-specific methyl-accepting transducer proteins that relay the sensory input signal to a two-component system. Certain members of the transducer family function as receptor proteins by directly sensing specific chemical or physical stimuli. Others interact with specific receptor proteins like the phototaxis photoreceptors sensory rhodopsin I and II, or require specific binding proteins as for example some chemotaxis transducers. Receptor activation by light or a change in receptor occupancy by chemical stimuli results in reversible methylation of glutamate residues of the transducer proteins. Both, methylation and demethylation reactions are involved in sensory adaptation and are modulated by the response regulator CheY.     

Aspartate taxis mutants of the Escherichia coli tar chemoreceptor.

The Tar protein of Escherichia coli belongs to a family of methyl-accepting inner membrane proteins that mediate chemotactic responses to a variety of compounds. These transmembrane signalers monitor the chemical environment by means of specific ligand-binding sites arrayed on the periplasmic side of the membrane, and in turn control cytoplasmic signals that modulate the flagellar rotational machinery. The periplasmic receptor domain of Tar senses two quite different chemoeffectors, aspartate and maltose. Aspartate is detected through direct binding to Tar molecules, whereas maltose is detected indirectly when complexed with the periplasmic maltose-binding protein. Saturating levels of either aspartate or maltose do not block behavioral responses to the other compound, indicating that the detection sites for these two attractants are not identical. We initiated structure-function studies of these chemoreceptor sites by isolating tar mutants which eliminate aspartate or maltose taxis, while retaining the ability to respond to the other chemoeffector. Mutants with greatly reduced aspartate taxis are described and characterized in this report. When present in single copy in the chromosome, these tar mutations generally eliminated chemotactic responses to aspartate and structurally related compounds, such as glutamate and methionine. Residual responses to these compounds were shifted to higher concentrations, indicating a reduced affinity of the aspartate-binding site in the mutant receptors. Maltose responses in the mutants ranged from 10 to 80% of normal, but had no detectable threshold shifts, indicating that these receptor alterations may have little effect on maltose detection sensitivity. The mutational changes in 17 mutants were determined by DNA sequence analysis. Each mutant exhibited a single amino acid replacement at residue 64, 69, or 73 in the Tar molecule. The wild-type Tar transducer contains arginines at all three of these positions, implying that electrostatic forces may play an important role in aspartate detection.     

Phenol sensing by Escherichia coli chemoreceptors: a nonclassical mechanism

The four transmembrane chemoreceptors of Escherichia coli sense phenol as either an attractant (Tar) or a repellent (Tap, Trg, and Tsr). In this study, we investigated the Tar determinants that mediate its attractant response to phenol and the Tsr determinants that mediate its repellent response to phenol. Tar molecules with lesions in the aspartate-binding pocket of the periplasmic domain, with a foreign periplasmic domain (from Tsr or from several Pseudomonas chemoreceptors), or lacking nearly the entire periplasmic domain still mediated attractant responses to phenol. Similarly, Tar molecules with the cytoplasmic methylation and kinase control domains of Tsr still sensed phenol as an attractant. Additional hybrid receptors with signaling elements from both Tar and Tsr indicated that the transmembrane (TM) helices and HAMP domain determined the sign of the phenol-sensing response. Several amino acid replacements in the HAMP domain of Tsr, particularly attractant-mimic signaling lesions at residue E248, converted Tsr to an attractant sensor of phenol. These findings suggest that phenol may elicit chemotactic responses by diffusing into the cytoplasmic membrane and perturbing the structural stability or position of the TM bundle helices, in conjunction with structural input from the HAMP domain. We conclude that behavioral responses to phenol, and perhaps to temperature, cytoplasmic pH, and glycerol, as well, occur through a general sensing mechanism in chemoreceptors that detects changes in the structural stability or dynamic behavior of a receptor signaling element. The structurally sensitive target for phenol is probably the TM bundle, but other behaviors could target other receptor elements.     

Conditional inversion of the thermoresponse in Escherichia coli.

Mutants in Escherichia coli having defects in one of the methyl-accepting chemotaxis proteins, Tsr protein, which is the chemoreceptor and transducer for L-serine, showed a reduced but similar type of thermoresponse compared with wild-type strains; the cells showed smooth swimming upon temperature increase and tumbling upon temperature decrease. However, when the mutant cells were adapted to attractants such as L-aspartate and maltose, which are specific to another methyl-accepting chemotaxis protein, Tar protein, the direction of the thermoresponse was found to be inverted; a temperature increase induced tumbling and a temperature decrease induced smooth swimming. Consistent with this, the mutant cells showed inverted changes in the methylation level of Tar protein upon temperature changes. Wild-type strains but not Tar protein-deficient mutants exhibited the inverted thermoresponse when the cells were simultaneously adapted to L-aspartate and L-serine, indicating that Tar protein has a key role in the inversion of the thermoresponse. Thus, besides Tsr protein, Tar protein has a certain role in thermoreception. A simple model for thermoreception and inversion of the thermoresponse is also discussed.     

Sensory transducers of E. coli are composed of discrete structural and functional domains

The tar and tsr genes of E. coli encode functionally analogous transducer proteins that mediate two distinct classes of chemotactic response. The tap gene lies adjacent to tar, and is thought to encode another transducer protein. We present here the complete nucleotide sequence of the tar-tap region of the E. coli genome, together with a comparative analysis of the sequences of the Tar, Tap, and Tsr proteins. The proteins appear to have a simple transmembrane structure consisting of an extracytoplasmic amino-terminal domain, a membrane-spanning domain, and an intracellular carboxy-terminal domain. The carboxy-terminal domains of three proteins possess highly homologous sequences and contain sites of methylation involved in sensory adaptation, while the amino-terminal sequences are only distantly related to one another, consistent with their serving as chemoreceptor domains that have diverged functionally.     

Signaling interactions between the aerotaxis transducer Aer and heterologous chemoreceptors in Escherichia coli

Aer, a low-abundance signal transducer in Escherichia coli, mediates robust aerotactic behavior, possibly through interactions with methyl-accepting chemotaxis proteins (MCP). We obtained evidence for interactions between Aer and the high-abundance aspartate (Tar) and serine (Tsr) receptors. Aer molecules bearing a cysteine reporter diagnostic for trimer-of-dimer formation yielded cross-linking products upon treatment with a trifunctional maleimide reagent. Aer also formed mixed cross-linking products with a similarly marked Tar reporter. An Aer trimer contact mutation known to abolish trimer formation by MCPs eliminated Aer trimer and mixed trimer formation. Trimer contact alterations known to cause epistatic behavior in MCPs also produced epistatic properties in Aer. Amino acid replacements in the Tar trimer contact region suppressed an epistatic Aer signaling defect, consistent with compensatory conformational changes between directly interacting proteins. In cells lacking MCPs, Aer function required high-level expression, comparable to the aggregate number of receptors in a wild-type cell. Aer proteins with clockwise (CW)-biased signal output cannot function under these conditions but do so in the presence of MCPs, presumably through formation of mixed signaling teams. The Tar signaling domain was sufficient for functional rescue. Moreover, CW-biased lesions did not impair aerotactic signaling in a hybrid Aer-Tar transducer capable of adjusting its steady-state signal output via methylation-dependent sensory adaptation. Thus, MCPs most likely assist mutant Aer proteins to signal productively by forming collaborative signaling teams. Aer evidently evolved to operate collaboratively with high-abundance receptors but can also function without MCP assistance, provided that it can establish a suitable prestimulus swimming pattern.     

Mutationally altered signal output in the Nart (NarX-Tar) hybrid chemoreceptor

Signal-transducing proteins that span the cytoplasmic membrane transmit information about the environment to the interior of the cell. In bacteria, these signal transducers include sensor kinases, which typically control gene expression via response regulators, and methyl-accepting chemoreceptor proteins, which control flagellar rotation via the CheA kinase and CheY response regulator. We previously reported that a chimeric protein (Nart) that joins the ligand-binding, transmembrane, and linker regions of the NarX sensor kinase to the signaling and adaptation domains of the Tar chemoreceptor elicits a repellent response to nitrate and nitrite. As with NarX, nitrate evokes a stronger response than nitrite. Here we show that mutations targeting a highly conserved sequence (the P box) in the periplasmic domain alter chemoreception by Nart and signaling by NarX similarly. In particular, the G51R substitution converts Nart from a repellent receptor into an attractant receptor for nitrate. Our results underscore the conclusion that the fundamental mechanism of transmembrane signaling is conserved between homodimeric sensor kinases and chemoreceptors. They also highlight the plasticity of the coupling between ligand binding and signal output in these systems.     

Rotational on-off switching of a hybrid membrane sensor kinase Tar-ArcB in Escherichia coli

Signal transduction in biological systems typically involves receptor proteins that possess an extracytosolic sensory domain connected to a cytosolic catalytic domain. Relatively little is known about the mechanism by which the signal is transmitted from the sensory site to the catalytic site. At least in the case of Tar (methyl-accepting chemotaxis protein for sensing aspartate) of Escherichia coli, vertical piston-like displacements of one transmembrane segment relative to the other within the monomer induced by ligand binding has been shown to modulate the catalytic activity of the cytosolic domain. The ArcB sensor kinase of E. coli is a transmembrane protein without a significant periplasmic domain. Here, we explore how the signal is conveyed to the catalytic site by analyzing the property of various Tar-ArcB hybrids. Our results suggest that, in contrast to the piston-like displacement that operates in Tar, the catalytic activity of ArcB is set by altering the orientation of the cytosolic domain of one monomer relative to the other in the homodimer. Thus, ArcB represents a distinct family of membrane receptor proteins whose catalytic activity is determined by rotational movements of the cytosolic domain.     

Chemotaxis proteins and transducers for aerotaxis in Pseudomonas aeruginosa

It was previously shown that the chemotaxis gene cluster 1 (cheYZABW) was required for chemotaxis. In this study, the involvement of the same cluster in aerotaxis is described and two transducer genes for aerotaxis are identified. Aerotaxis assays of a number of deletion-insertion mutants of Pseudomonas aeruginosa PAO1 revealed that the chemotaxis gene cluster 1 and cheR are required for aerotaxis. Mutant strains which contained deletions in the methyl-accepting chemotaxis protein-like genes tlpC and tlpG showed decreased aerotaxis. A double mutant deficient in tlpC and tlpG was negative for aerotaxis. TlpC has 45% amino acid identity with the Escherichia coli aerotactic transducer Aer. The TlpG protein has a predicted C-terminal segment with 89% identity to the highly conserved domain of the E. coli serine chemoreceptor Tsr. A hydropathy plot of TlpG indicated that hydrophobic membrane-spanning regions are missing in TlpG. A PAS motif was found in the N-terminal domains of TlpC and TlpG. On this basis, the tlpC and tlpG genes were renamed aer and aer-2, respectively. No significant homology other than the PAS motif was detected in the N-terminal domains between Aer and Aer-2.     

Ligand-specific activation of Escherichia coli chemoreceptor transmethylation

Adaptation in the chemosensory pathways of bacteria like Escherichia coli is mediated by the enzyme-catalyzed methylation (and demethylation) of glutamate residues in the signaling domains of methyl-accepting chemotaxis proteins (MCPs). MCPs can be methylated in trans, where the methyltransferase (CheR) molecule catalyzing methyl group transfer is tethered to the C terminus of a neighboring receptor. Here, it was shown that E. coli cells exhibited adaptation to attractant stimuli mediated through either engineered or naturally occurring MCPs that were unable to tether CheR as long as another MCP capable of tethering CheR was also present, e.g., either the full-length aspartate or serine receptor (Tar or Tsr). Methylation of isolated membrane samples in which engineered tethering and substrate receptors were coexpressed demonstrated that the truncated substrate receptors (trTsr) were efficiently methylated in the presence of tethering receptors (Tar with methylation sites blocked) relative to samples in which none of the MCPs had tethering sites. The effects of ligand binding on methylation were investigated, and an increase in rate was produced only with serine (the ligand specific for the substrate receptor trTsr); no significant change in rate was produced by aspartate (the ligand specific for the tethering receptor Tar). Although the overall efficiency of methylation was lower, receptor-specific effects were also observed in trTar- and trTsr-containing samples, where neither Tar nor Tsr possessed the CheR binding site at the C terminus. Altogether, the results are consistent with a ligand-induced conformational change that is limited to the methylated receptor dimer and does not spread to adjacent receptor dimers.