Characterization of Escherichia coli chemotaxis receptor mutants with null phenotypes

Axial helix rotation as a mechanism for signal regulation inferred from the crystallographic analysis of the E. coli serine chemoreceptor

Bacterial chemotaxis receptors are elongated homodimeric coiled-coil bundles, which transduce signals generated in an N-terminal sensor domain across 15-20nm to a conserved C-terminal signaling subdomain. This signal transduction regulates the activity of associated kinases, altering the behavior of the flagellar motor and hence cell motility. Signaling is in turn modulated by selective methylation and demethylation of specific glutamate and glutamine residues in an adaptation subdomain. We have determined the structure of a chimeric protein, consisting of the HAMP domain from Archaeoglobus fulgidus Af1503 and the methyl-accepting domain of Escherichia coli Tsr. It shows a 21nm coiled coil that alternates between two coiled-coil packing modes: canonical knobs-into-holes and complementary x-da, a variant form related to the canonical one by axial rotation of the helices. Comparison of the obtained structure to the Thermotoga maritima chemoreceptor TM1143 reveals that they adopt different axial rotation states in their adaptation subdomains. This conformational change is presumably induced by the upstream HAMP domain and may modulate the affinity of the chemoreceptor to the methylation-demethylation system. The presented findings extend the cogwheel model for signal transmission to chemoreceptors.

A possible degree of motional freedom in bacterial chemoreceptor cytoplasmic domains and its potential role in signal transduction

We describe an array of gaps in an antiparallel four-helix bundle structure, the cytoplasmic domains of bacterial chemoreceptors. For a given helix, the side chain interactions that define a helix's position are analyzed in terms of residue interfaces, the most important of which are a-a, g-g, d-d, g-d, and a-d. It was found that the interdigitation of the side groups does not entirely fill the space along the long axis of the structure, which results in a rather regular array of gaps. A simulated piston motion of helix CD1 along the helical axis direction by 1.2Å shows that 85% of the side chain interactions still satisfy Van der Waals criteria, while the remaining clashes could be avoided by small rotations of side chains. Therefore, two states could exist in the structure, related by a piston motion. Analysis of the crystal structure of a small four-helix bundle, the P1(short) domain of CheA in Thermotoga Maritima, reveals that the two coexisting states related by a 1.3-1.7Å piston motion are defined by the same mechanism. This two-state model is a plausible candidate mechanism for the long distance signal transduction in bacterial chemoreceptors and is qualitatively consistent with literature chemoreceptor mutagenesis results. Such a mechanism could exist in many other structures with interdigitating α-helices.

Liposome-mediated assembly of receptor signaling complexes

The reconstitution of membrane-associated protein complexes poses significant experimental challenges. The core signaling complex in the bacterial chemotaxis system is an illustrative example: The soluble cytoplasmic signaling proteins CheW and CheA bind to heterogeneous clusters of transmembrane receptor proteins, resulting in an assembly that exhibits cooperative kinase regulation. An understanding of the basis for the cooperativity inherent in the receptor/CheW/CheA interaction, as well as other membrane phenomena, can benefit from functional studies under defined conditions. To meet this need, a simple method was developed to assemble functional complexes on lipid membranes. The method employs a receptor cytoplasmic domain fragment (CF) with a histidine tag and liposomes that contain a Ni(2+) -chelating lipid. Assemblies of CF, CheW, and CheA form spontaneously in the presence of these liposomes, which exhibit the salient biochemical functions of kinase stimulation, cooperative regulation, and CheR-mediated receptor methylation. Although ligand binding phenomena cannot be studied directly with this approach, other factors that influence kinase stimulation and receptor methylation can be explored systematically, including receptor density and competition among stimulating and inhibiting receptor domains. The template-directed assembly of proteins leads to relatively well-defined samples that are amenable to analysis by a number of methods, including light scattering, electron microscopy, and fluorescence resonance energy transfer. The approach promises to be applicable to many systems involving membrane-associated proteins.

Phenotypic Suppression Methods for Analyzing Intra‐ and Inter‐Molecular Signaling Interactions of Chemoreceptors

The receptors that mediate chemotactic behaviors in E. coli and other motile bacteria and archaea are exquisite molecular machines. They detect minute concentration changes in the organism's chemical environment, integrate multiple stimulus inputs, and generate a highly amplified output signal that modulates the cell's locomotor pattern. Genetic dissection and suppression analyses have played an important role in elucidating the molecular mechanisms that underlie chemoreceptor signaling. This chapter discusses three examples of phenotypic suppression analyses of receptor signaling defects. (i) Balancing suppression can occur in mutant receptors that have biased output signals and involves second-site mutations that create an offsetting bias change. Such suppressors can arise in many parts of the receptor and need not involve directly interacting parts of the molecule. (ii) Conformational suppression within a mutant receptor molecule occurs through a mutation that directly compensates for the initial structural defect. This form of suppression should be highly dependent on the nature of the structural alterations caused by the original mutation and its suppressor, but in practice may be difficult to distinguish from balancing suppression without high-resolution structural information about the mutant and pseudorevertant proteins. (iii) Conformational suppression between receptor molecules involves correction of a functional defect in one receptor by a mutational change in a heterologous receptor with which it normally interacts. The suppression patterns exhibit allele-specificity with respect to the compensatory residue positions and amino acid side chains, a hallmark of stereospecific protein-protein interactions.

Competitive and cooperative interactions in receptor signaling complexes

In bacterial chemotaxis, clustered transmembrane receptors and the adaptor protein CheW regulate the kinase CheA. Receptors outnumber CheA, yet it is poorly understood how interactions among receptors contribute to regulation. To address this problem, receptor clusters were simulated using liposomes decorated with the cytoplasmic domains of receptors, which supported CheA binding and stimulation. Competitive and cooperative interactions were revealed through the use of known receptor signaling mutants, which were used in mixtures with the wild type domain. Competitive effects among the receptor domains sorted cleanly into two categories defined by either stronger or weaker interactions with CheA. Cooperative effects were also evident in CheA binding and activity. In the transition from the stimulating to the inhibiting states, both the cooperativity of the transition and the persistence of stimulation by the wild type domain increased with receptor modification, as in the intact receptor. We conclude that competitive and cooperative receptor interactions both contribute to CheA regulation and that liposome-mediated assembly is effective in addressing these general membrane phenomena.

Conformational suppression of inter-receptor signaling defects

Motile bacteria follow gradients of attractant and repellent chemicals with high sensitivity. Their chemoreceptors are physically clustered, which may enable them to function as a cooperative array. Although native chemoreceptor molecules are typically transmembrane homodimers, they appear to associate through their cytoplasmic tips to form trimers of dimers, which may be an important architectural element in the assembly and operation of receptor clusters. The five receptors of Escherichia coli that mediate most of its chemotactic and aerotactic behaviors have identical trimer contact residues and have been shown by in vivo crosslinking methods to form mixed trimers of dimers. Mutations at the trimer contact sites of Tsr, the serine chemoreceptor, invariably abrogate Tsr function, but some of those lesions (designated Tsr*) are epistatic and block the function of heterologous chemoreceptors. We isolated and characterized mutations (designated Tar()) in the aspartate chemoreceptor that restored function to Tsr* receptors. The suppressors arose at or near the Tar trimer contact sites and acted in an allele-specific fashion on Tsr* partners. Alone, many Tar() receptors were unable to mediate chemotactic responses to aspartate, but all formed clusters with varying efficiencies. Most of those Tar() receptors were epistatic to WT Tsr, but some regained Tar function in combination with a suppressible Tsr* partner. Tar()-Tsr* suppression most likely occurs through compensatory changes in the conformation or dynamics of a mixed receptor signaling complex, presumably based on trimer-of-dimer interactions. These collaborative teams may be responsible for the high-gain signaling properties of bacterial chemoreceptors.

Template-Directed Assembly of Receptor Signaling Complexes

Transmembrane receptors in the signaling pathways of bacterial chemotaxis systems influence cell motility by forming noncovalent complexes with the cytoplasmic signaling proteins to regulate their activity. The requirements for receptor-mediated activation of CheA, the principal kinase of the Escherichia coli chemotaxis signaling pathway, were investigated using self-assembled clusters of a receptor fragment (CF) derived from the cytoplasmic domain of the aspartate receptor, Tar. Histidine-tagged Tar CF was assembled on the surface of sonicated unilamellar vesicles via a lipid containing the nickel-nitrilotriacetic acid moiety as a headgroup. In the presence of the adaptor protein CheW, CheA bound to and was activated approximately 180-fold by vesicle-bound CF. The extent of CheA activation was found to be independent of the level of covalent modification on the CF. Instead, the stability of the complex increased significantly as the level of covalent modification increased. Surface-assembled CF was also found to serve as a substrate for receptor methylation in a reaction catalyzed by the receptor methyltransferase, CheR. Since neither CheA activation nor CF methylation was observed in comparable samples in the absence of vesicles, it is concluded that surface templating generates the organization among CF subunits required for biochemical activity.

CheA kinase and chemoreceptor interaction surfaces on CheW

Chemotactic responses of Escherichia coli to aspartic acid are initiated by a ternary protein complex composed of Tar (chemoreceptor), CheA (kinase), and CheW (a coupling protein that binds to both Tar and CheA and links their activities). We used a genetic selection based on the yeast two-hybrid assay to identify nine cheW point mutations that specifically disrupted CheW interaction with CheA but not with Tar. We sequenced these single point mutants and purified four of the mutant CheW proteins for detailed biochemical characterizations that demonstrated the weakened affinity of the mutant CheW proteins for CheA, but not for Tar. In the three-dimensional structure of CheW, the positions affected by these mutations cluster on one face of the protein, defining a potential binding interface for interaction of CheW with CheA. We used a similar two-hybrid approach to identify four mutation sites that disrupted CheW binding to Tar. Mapping of these "Tar-sensitive" mutation sites and those from previous suppressor analysis onto the structure of CheW defined an extended surface on a face of the protein that is adjacent to the CheA-binding surface and that may serve as an interface for CheW binding to Tar.

CheW binding interactions with CheA and Tar. Importance for chemotaxis signaling in Escherichia coli

The initial signaling events underlying the chemotactic response of Escherichia coli to aspartic acid occur within a ternary complex that includes Tar (an aspartate receptor), CheA (a protein kinase), and CheW. Because CheW can bind to CheA and to Tar, it is thought to serve as an adapter protein in this complex. The functional importance of CheW binding interactions, however, has not been investigated. To better define the role of CheW and its binding interactions, we performed biochemical characterization of six mutant variants of CheW. We examined the ability of the purified mutant CheW proteins to bind to CheA and Tar, to promote formation of active ternary complexes, and to support chemotaxis in vivo. Our results indicate that mutations which eliminate CheW binding to Tar (V36M) or to CheA (G57D) result in a complete inability to form active ternary complexes in vitro and render the CheW protein incapable of mediating chemotaxis in vivo. The in vivo signaling pathway can, however, tolerate moderate changes in CheW-Tar and CheW-CheA affinities observed with several of the mutants (G133E, G41D, and 154ocr). One mutant (R62H) provided surprising results that may indicate a role for CheW in addition to binding CheA/receptors and promoting ternary complex formation.

Hydrogen exchange reveals a stable and expandable core within the aspartate receptor cytoplasmic domain

Intensive study of bacterial chemoreceptors has not yet revealed how receptor methylation and ligand binding alter the interactions between the receptor cytoplasmic domain and the CheA kinase to control kinase activity. Both monomeric and dimeric forms of an Asp receptor cytoplasmic fragment have been shown to be highly dynamic, with a small core of slowly exchanging amide hydrogens (Seeley, S. K., Weis, R. M., and Thompson, L. K. (1996) Biochemistry 35, 5199-5206). Hydrogen exchange studies of the wild-type cytoplasmic fragment and an S461L mutant thought to mimic the kinase-inactivating state are used to investigate the relationship between the stable core and dimer dissociation. Our results establish that (i) decreasing pH stabilizes the dimeric state, (ii) the stable core is present also in the transition state for dissociation, and (iii) this core is expanded significantly by small changes in electrostatic and hydrophobic interactions. These kinase-inactivating changes stabilize both the monomeric and the dimeric states of the protein, which has interesting implications for the mechanism of kinase activation. We conclude that the cytoplasmic domain is a flexible region poised for stabilization by small changes in electrostatic and hydrophobic interactions such as those caused by methylation of glutamate residues and by ligand-induced conformational changes during signaling.

Chemotaxis receptors: a progress report on structure and function

Recent biochemical and structural studies have provided many new insights into the structure and function of bacterial chemoreceptors. Aspects of their ligand binding, conformational changes, and interactions with other members of the signaling pathway are being defined at the structural level. It is anticipated that the combined effort will soon provide a detailed, unified view of an entire response system.

Chemotactic adaptation is altered by changes in the carboxy-terminal sequence conserved among the major methyl-accepting chemoreceptors

In Escherichia coli and Salmonella typhimurium, methylation and demethylation of receptors are responsible for chemotactic adaptation and are catalyzed by the methyltransferase CheR and the methylesterase CheB, respectively. Among the chemoreceptors of these species, Tsr, Tar, and Tcp have a well-conserved carboxy-terminal motif (NWET/SF) that is absent in Trg and Tap. When they are expressed as sole chemoreceptors, Tsr, Tar, and Tcp support good adaptation, but Trg and Tap are poorly methylated and supported only weak adaptation. It was recently discovered that CheR binds to the NWETF sequence of Tsr in vitro. To examine the physiological significance of this binding, we characterized mutant receptors in which this pentapeptide sequence was altered. C-terminally-mutated Tar and Tcp expressed in a receptorless E. coli strain mediated responses to aspartate and citrate, respectively, but their adaptation abilities were severely impaired. Their expression levels and attractant-sensing abilities were similar to those of the wild-type receptors, but the methylation levels of the mutant receptors increased only slightly upon addition of attractants. When CheR was overproduced, both the adaptation and methylation profiles of the mutant Tar receptor became comparable to those of wild-type Tar. Furthermore, overproduction of CheR also enhanced adaptive methylation of wild-type Trg, which lacks the NWETF sequence, in the absence of any other chemoreceptor. These results suggest that the pentapeptide sequence facilitates effective adaptation and methylation by recruiting CheR.

Probing the structure of the cytoplasmic domain of the aspartate receptor by targeted disulfide cross-linking

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.

Oligomers of the cytoplasmic fragment from the Escherichia coli aspartate receptor dissociate through an unfolded transition state

The kinetic and equilibrium properties of a clustering process were studied as a function of temperature for two point mutants of a 31 kDa fragment derived from the cytoplasmic region of the Escherichia coli aspartate receptor (C-fragment), which were shown previously to have a greater tendency to form clusters relative to the wild-type C-fragment [Long, D. G., & Weis, R. M. (1992) Biochemistry 31, 9904-9911]. The clustering equilibria were different for the two C-fragments. Monomers of a serine-461 to leucine (S461L) mutant C-fragment were in equilibrium with dimers, while monomers of a S325L C-fragment were in equilibrium with trimers. The positive values for delta H degree, delta S degree, and delta Cp degree of dissociation estimated from a van't Hoff analysis, and the differences in the CD spectra of isolated monomers and oligomers, demonstrated that the monomers were less well-folded than the clustered forms. The oligomer dissociation rate exhibited a marked temperature dependence over the range from 4 to 30 degrees C and was remarkably slow at low temperatures; e.g. t1/2 of dimer dissociation for the S461L C-fragment was 85 h at 4 degrees C. The values for delta H degree +2, delta S degree +2, and delta Cp degree +2 derived from the temperature dependence of the dissociation rate were comparable to the corresponding parameters determined in a DSC study of C-fragment denaturation [Wu, J., Long, D. G., & Weis, R. M. (1995) Biochemistry 34, 3056-3065], which indicated that the transition state resembled thermally denatured C-fragment. Octyl glucoside accelerated the dissociation rate by 3-5-fold presumably by lowering the barrier to dissociation. This acceleration and the positive value of delta Cp degree +2 were interpreted as evidence for an increase in solvent accessible hydrophobic groups in the transition state. The molecular basis for the slow rate of dissociation is proposed to result from the conversion of intermolecular coiled coils in the oligomers to an intramolecular coiled coil in the monomer.

The cytoplasmic fragment of the aspartate receptor displays globally dynamic behavior

A number of cloned soluble fragments if the bacterial chemotaxis transmembrane receptors retain partial function. Prior studies of a fragment corresponding to the cytoplasmic domain (c-fragment) of the Escherichia coli aspartate receptor have correlated the signaling state of mutant receptors with the oligomerization state of the c-fragments: equilibria of smooth-swimming mutants are shifted toward oligomeric states; tumble mutants are shifted toward monomeric states [Long, D. G., & Weis, R. M. (1992) Biochemistry 31, 9904-9911]. We have applied several experimental probes of local and global structural flexibility to two signaling states, the wild-type (monomeric) and S461L smooth mutant (predominantly dimeric) c-fragments. Featureless near-UV CD spectra are observed, which indicate that the single Trp residue is in a symmetric environment (most likely averaged by fluctuations) and suggest that the C-termini of both proteins are highly mobile. Both proteins undergo extremely rapid proteolysis and enhance ANS fluorescence, which indicates that many sites are accessible to trypsin cleavage and hydrophobic sites are accessible to ANS binding. The global nature of the flexibility is demonstrated by 1H NMR studies. Lack of chemical shift dispersion suggests that fluctuations average the environments of side chains and backbone protons. Rapid exchange of 99% of the observable amide protons suggests that these fluctuations give high solvent accessibility to nearly the entire backbone. This evidence indicates that both monomeric and dimeric c-fragments are globally flexible proteins, with properties similar to "molten-globule" states. The significance of this flexibility depends on whether it is retained in functioning receptors: the c-fragment structure may lack important tertiary contacts, protein-protein interactions, or topological constraints needed to stabilize a nondynamic native structure, or the cytoplasmic domain of the native receptor may retain flexibility which may be modulated in the mechanism of transmembrane signaling.

Imitation of Escherichia coli aspartate receptor signaling in engineered dimers of the cytoplasmic domain

Transmembrane signaling by bacterial chemotaxis receptors appears to require a conformational change within a receptor dimer. Dimers were engineered of the cytoplasmic domain of the Escherichia coli aspartate receptor that stimulated the kinase CheA in vitro. The folding free energy of the leucine-zipper dimerization domain was harnessed to twist the dimer interface of the receptor, which markedly affected the extent of CheA activation. Response to this twist was attenuated by modification of receptor regulatory sites, in the same manner as adaptation resets sensitivity to ligand in vivo. These results suggest that the normal allosteric activation of the chemotaxis receptor has been mimicked in a system that lacks both ligand-binding and transmembrane domains. The most stimulatory receptor dimer formed a species of tetrameric size.

Sequences determining the cytoplasmic localization of a chemoreceptor domain

The Escherichia coli serine chemoreceptor (Tsr) is a protein with a simple topology consisting of two membrane-spanning sequences (TM1 and TM2) separating a large periplasmic domain from N-terminal and C-terminal cytoplasmic regions. We analyzed the contributions of several sequence elements to the cytoplasmic localization of the C-terminal domain by using chemoreceptor-alkaline phosphatase gene fusions. The principal findings were as follows. (i) The cytoplasmic localization of the C-terminal domain depended on TM2 but was quite tolerant of mutations partially deleting or introducing charged residues into the sequence. (ii) The basal level of C-terminal domain export was significantly higher in proteins with the wild-type periplasmic domain than in derivatives with a shortened periplasmic domain, suggesting that the large size of the wild-type domain promotes partial membrane misinsertion. (iii) The membrane insertion of deletion derivatives with a single spanning segment (TM1 or TM2) could be controlled by either an adjacent positively charged sequence or an adjacent amphipathic sequence. The results provide evidence that the generation of the Tsr membrane topology is an overdetermined process directed by an interplay of sequences promoting and opposing establishment of the normal structure.

Constitutively signaling fragments of Tsr, the Escherichia coli serine chemoreceptor

Tsr, the serine chemoreceptor of Escherichia coli, has two signaling modes. One augments clockwise (CW) flagellar rotation, and the other augments counterclockwise (CCW) rotation. To identify the portion of the Tsr molecule responsible for these activities, we isolated soluble fragments of the Tsr cytoplasmic domain that could alter the flagellar rotation patterns of unstimulated wild-type cells. Residues 290 to 470 from wild-type Tsr generated a CW signal, whereas the same fragment with a single amino acid replacement (alanine 413 to valine) produced a CCW signal. The soluble components of the chemotaxis phosphorelay system needed for expression of these Tsr fragment signals were identified by epistasis analysis. Like full-length receptors, the fragments appeared to generate signals through interactions with the CheA autokinase and the CheW coupling factor. CheA was required for both signaling activities, whereas CheW was needed only for CW signaling. Purified Tsr fragments were also examined for effects on CheA autophosphorylation activity in vitro. Consistent with the in vivo findings, the CW fragment stimulated CheA, whereas the CCW fragment inhibited CheA. CheW was required for stimulation but not for inhibition. These findings demonstrate that a 180-residue segment of the Tsr cytoplasmic domain can produce two active signals. The CCW signal involves a direct contact between the receptor and the CheA kinase, whereas the CW signal requires participation of CheW as well. The correlation between the in vitro effects of Tsr signaling fragments on CheA activity and their in vivo behavioral effects lends convincing support to the phosphorelay model of chemotactic signaling.

The carboxy-terminal portion of the CheA kinase mediates regulation of autophosphorylation by transducer and CheW

The CheA kinase is a central protein in the signal transduction network that controls chemotaxis in Escherichia coli. CheA receives information from a transmembrane receptor (e.g., Tar) and CheW proteins and relays it to the CheB and CheY proteins. The biochemical activities of CheA proteins truncated at various distances from the carboxy terminus were examined. The carboxy-terminal portion of CheA regulates autophosphorylation in response to environmental signals transmitted through Tar and CheW. The central portion of CheA is required for autophosphorylation and is also presumably involved in dimer formation. The amino-terminal portion of CheA was previously shown to contain the site of autophosphorylation and to be able to transfer the phosphoryl group to CheB and CheY. These studies further delineate three functional domains of the CheA protein.

Ligand occupancy mimicked by single residue substitutions in a receptor: transmembrane signaling induced by mutation

We used mixed, mutagenic oligonucleotides to create single amino acid substitutions in the bacterial chemoreceptor Trg. Mutagenesis was directed at a 20-residue segment of the periplasmic domain implicated in ligand recognition. Transmembrane signaling by the mutant receptors was assayed in vivo by monitoring adaptational covalent modification. Among 20 functionally altered but stable receptors there were two distinct signaling phenotypes. Insensitive receptors did not signal upon stimulation and thus appeared defective in productive ligand interaction. Mimicked-occupancy receptors exhibited transmembrane signaling without ligand. Many mimicked-occupancy receptors produced additional signaling upon ligand binding and in appropriate conditions mediated effective chemotaxis; most insensitive receptors did not. Like normal receptors with one binding site occupied, mimicked-occupancy proteins adapted to persistent transmembrane signaling by increased methylation and thus could respond to other stimuli. Signaling phenotypes were strikingly segregated by residue position. Substitutions mimicking ligand occupancy occurred in half the segment, and those creating insensitive phenotypes occurred in the other half. These observations could be related to the three-dimensional structure of the periplasmic domain of the Tar(s) chemoreceptor. Insensitive substitutions occurred near the distal end of helix 1, where bulky protein ligands could interact; occupancy-mimicking substitutions were on the same helix at positions buried in the subunit interface between helices 1 and 1'. Thus perturbation of the interface induced transmembrane signaling, implicating changes at that interface in signal transduction, a conclusion consistent with differences in crystal structures of unoccupied and ligand-occupied Tar(s).

Mechanism of maltose transport in Escherichia coli: transmembrane signaling by periplasmic binding proteins

Maltose transport across the cytoplasmic membrane of Escherichia coli is dependent on the presence of a periplasmic maltose-binding protein (MBP), the product of the malE gene. The products of the malF, malG, and malK genes form a membrane-associated complex that catalyzes the hydrolysis of ATP to provide energy for the transport event. Previously, mutants were isolated that had gained the ability to grow on maltose in the absence of MBP. After reconstitution of the transport complex into proteoliposomes, measurement of the ATPase activity of wild-type and mutant complexes in the presence and absence of MBP revealed that the wild-type complex hydrolyzed ATP rapidly only when MBP and maltose were both present. In contrast, the mutant complexes have gained the ability to hydrolyze ATP in the absence of maltose and MBP. The basal rate of hydrolysis by the different mutant complexes was directly proportional to the growth rate of that strain on maltose, a result indicating that the constitutive ATP hydrolysis and presumably the resultant cyclic conformational changes of the complex produce maltose transport in the absence of MBP. These results also suggest that ATP hydrolysis is not directly coupled to ligand transport even in wild-type cells and that one important function of MBP is to transmit a transmembrane signal, through the membrane-spanning MalF and MalG proteins, to the MalK protein on the other side of the membrane, so that ATP hydrolysis can occur.

Mutations in the MotA protein of Escherichia coli reveal domains critical for proton conduction

The MotA protein of Escherichia coli is an essential component of the torque-generating units that drive the flagellar rotary motor. A variety of evidence indicates that MotA is involved in transmembrane proton conduction. We have now mapped a number of MotA mutants, focusing primarily on those previously shown to be dominant. Fifty-six mutations (all dominant), each causing severe or complete impairment of function, were sequenced and found to correspond to 31 different alleles. All except two of these encoded amino acid substitutions clustered in four hydrophobic, presumably membrane-spanning segments, that together make up only one-third of the length of the polypeptide chain. In contrast, eight mutations (5 dominant), each causing only slight impairment of function (slow alleles), were sequenced and found to specify amino acid substitutions in three hydrophilic domains. The clustering of the mutations provides independent support for the suggestion that MotA is a transmembrane proton channel and places significant constraints on models for the molecular mechanism of ion conduction.

Mutant MotB proteins in Escherichia coli

The MotB protein of Escherichia coli is an essential component in each of eight torque generators in the flagellar rotary motor. Based on its membrane topology, it has been suggested that MotB might be a linker that fastens the torque-generating machinery to the cell wall. Here, we report the isolation and characterization of a number of motB mutants. As found previously for motA, many alleles of motB were dominant, as expected if MotB is a component of the motor. In other respects, however, the motB mutants differed from the motA mutants. Most of the mutations mapped to a hydrophilic, periplasmic domain of the protein, and nothing comparable to the slow-swimming alleles of motA, which show normal torque when tethered, was found. Some motB mutants retained partial function, but when tethered they produced subnormal torque, indicating that their motors contained only one or two functional torque generators. These results support the hypothesis that MotB is a linker.

The dynamics of protein phosphorylation in bacterial chemotaxis

The chemotaxis signal transduction pathway allows bacteria to respond to changes in concentration of specific chemicals (ligands) by modulating their swimming behavior. The pathway includes ligand binding receptors, and the CheA, CheY, CheW, and CheZ proteins. We showed previously that phosphorylation of CheY is activated in reactions containing receptor, CheW, CheA, and CheY. Here we demonstrate that this activation signal results from accelerated autophosphorylation of the CheA kinase. Evidence for a second signal transmitted by a ligand-bound receptor, which corresponds to inhibition of CheA autophosphorylation, is also presented. We postulate that CheA can exist in three forms: a "closed" form in the absence of receptor and CheW; an "open" form that results from activation of CheA by receptor and CheW; and a "sequestered" form in reactions containing ligand-bound receptor and CheW. The system's dynamics depends on the relative distribution of CheA among these three forms at any time.

Mutations that affect control of the methylesterase activity of CheB, a component of the chemotaxis adaptation system in Escherichia coli

Sensory adaptation by the chemotaxis system of Escherichia coli requires adjustments of the extent of methyl esterification of the chemotaxis receptor proteins. One mechanism utilized by E. coli to make such adjustments is to control the activity of CheB, the enzyme responsible for removing receptor methyl ester groups. Previous work has established the existence of a multicomponent signal transduction pathway that enables the chemotaxis receptor proteins to control the methylesterase activity in response to chemotactic stimuli. We isolated and characterized CheB mutants that do not respond normally to this control mechanism. In intact cells these CheB variants could not be activated in response to negative chemotaxis stimuli. Further characterization indicated that these CheB variants could not be phosphorylated by the chemotaxis protein kinase CheA. Disruption of the mechanism responsible for regulating methylesterase activity was also observed in cells carrying chromosomal deletions of either cheA or cheW as well as in cells expressing mutant versions of CheA that lacked kinase activity. These results provide further support for recent proposals that activation of the methylesterase activity of CheB involves phosphorylation of CheB by CheA. Furthermore, our findings suggest that CheW plays an essential role in enabling the chemotaxis receptor proteins to control the methylesterase activity, possibly by controlling the CheA-CheB phosphotransfer reaction.

The MotA protein of E. coli is a proton-conducting component of the flagellar motor

A number of mutants of motA, a gene necessary for flagellar rotation in E. coli, were isolated and characterized. Many mutations were dominant, owing to competition between functional and nonfunctional MotA for a limited number of sites on the flagellar motor. A new class of mutant was discovered in which flagellar torque is normal at low speeds but reduced at high speeds. Hydrogen isotope effects on these mutants indicate that MotA catalyzes proton transfer. We confirmed an earlier observation that overproduction of MotA leads to accumulation of the protein in the cytoplasmic membrane and to significant decreases in growth rate. When nonfunctional mutant variants of MotA were overproduced instead, they accumulated in the cytoplasmic membrane, but growth was not impaired. These results also suggest that MotA conducts protons. This was confirmed by measuring the proton permeabilities of vesicles containing wild-type or mutant MotA proteins.

Developmental bypass suppression of Myxococcus xanthus csgA mutations

The csgA mutations of Myxococcus xanthus (formerly known as spoC) inhibit sporulation as well as rippling, which involves ridges of cells moving in waves. Sporulating revertants of CsgA cells were isolated by direct selection, since spores are much more resistant to heat and ultrasonic treatment than are vegetative cells. The revertants fell into seven groups on the basis of phenotype and the chromosomal location of the suppressor alleles. Group 1 contained one allele that was a back mutation of the original csgA mutation. Group 2 contained two linked alleles that were unlinked to the csgA locus and restored fruiting-body formation, sporulation, and rippling. Group 3 revertants regained the ability to sporulate in fruiting bodies but not the ability to ripple. Revertants in groups 4 to 7 were able to sporulate but unable to form fruiting bodies or ripples. The suppressors were all found to be bypass suppressors even though they were not selected as such in most cases. The csgA mutation prevented expression of several developmentally regulated promoters, each fused to a lacZ reporter gene and assayed by beta-galactosidase production. In four of five suppressor groups (groups 4 to 7), expression of each of these csgA-dependent fusions was restored, which suggests that bypass suppression restores developmental gene expression near the point at which expression is disrupted in CsgA mutants. Bypass suppression did not restore production of C factor, and morphological manifestations of development such as rippling and fruiting-body formation were usually abnormal. One interpretation of these results is that C factor has multiple functions and few suppressors can compensate for all of them.

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.

Transmembrane signal transduction in bacterial chemotaxis involves ligand-dependent activation of phosphate group transfer

Signal transduction in Escherichia coli involves the interaction of transmembrane receptor proteins such as the aspartate receptor, Tar, and the products of four chemotaxis genes, cheA, cheY, cheW, and cheZ. It was previously shown that the cheA gene product is an autophosphorylating protein kinase that transfers phosphate to CheY, whereas the cheZ gene product acts as a specific CheY phosphatase. Here we report that the system can be reconstituted in vitro and receptor function can be coupled to CheY phosphorylation. Coupling requires the presence of the CheW protein, the appropriate form of the receptor, and the CheA and CheY proteins. Under these conditions the accumulation of CheY-phosphate is enhanced approximately 300-fold. This rate enhancement is seen in reactions using wild-type and "tumble" mutant receptors but not "smooth" mutant receptors. The increased accumulation of phosphoprotein was inhibited by micromolar concentrations of aspartate, using wild-type, but not tumble, receptors. These results provide evidence that the signal transduction pathway in bacterial chemotaxis involves receptor-mediated alteration of the levels of phosphorylated proteins. They suggest that CheW acts as the coupling factor between receptor and phosphorylation. The results also support the suggestion that CheY-phosphate is the tumble signal.

Transmembrane signaling by bacterial chemoreceptors: E. coli transducers with locked signal output

Methyl-accepting chemotaxis proteins (MCPs) function as transmembrane signalers in bacteria. We isolated and characterized mutants of the E. coli Tsr protein that produce output signals in the absence of overt stimuli and that are refractory to sensory adaptation. The properties of these "locked" transducers indicate that MCP molecules are capable of generating signals that actively augment clockwise and counter-clockwise rotation of the flagellar motors. Transitions between MCP signaling states can be influenced by amino acid replacements in many parts of the molecule, including the methylation sites, at least one of the two membrane-spanning segments, and a linker region connecting the receptor and signaling domains. These findings suggest that transmembrane signaling may involve direct propagation of conformational changes between the periplasmic and cytoplasmic portions of the MCP molecule.

N-terminal half of CheB is involved in methylesterase response to negative chemotactic stimuli in Escherichia coli

The chemotactic receptor-transducer proteins of Escherichia coli are responsible for directing the swimming behavior of cells by signaling for either straight swimming or tumbling in response to chemostimuli. The signaling states of these proteins are affected not only by the concentrations of various stimuli but also by the extent to which they have been methylated at specific glutamyl residues. The activities of a chemotaxis-specific methyltransferase (CheR) and a chemotaxis-specific methylesterase (CheB) are regulated in response to chemotactic stimuli to enable sensory adaptation to unchanging levels of stimuli by appropriately shifting the signaling states of the transducer proteins. For CheB this regulation involves a feedback loop that requires some of the components making up the chemotactic signal transduction machinery of the cell. This feedback loop causes the methylesterase activity of CheB to decrease transiently in response to attractant stimuli and to increase transiently in response to negative stimuli (repellent addition or attractant removal). In this report we demonstrate that the methylesterase response to negative stimuli involves the N-terminal half of the CheB protein, whereas the response to positive stimuli does not require this segment of the protein. Both aspects of the methylesterase response to positive stimuli does not require this segment of the protein. Both aspects of the methylesterase response require CheA. In addition, we demonstrate that mutant forms of CheB lacking methylesterase activity can adversely affect the swimming behavior and chemotactic ability of cells and can markedly diminish modulation of the wild-type methylesterase activity in response to negative stimuli. The significance of these results is discussed in relation to the recent demonstration of phosphoryl transfer from CheA to CheB (J. F. Hess, K. Oosawa, N. Kaplan, and M. I. Simon, Cell 53:79-87, 1988) and the discovery of sequence homology between the N-terminal half of CheB and CheY (A. Stock, D. E. Koshland, Jr., and J. Stock, Proc. Natl. Acad. Sci. USA 82:7989-7993, 1985).

Purification and characterization of the wild-type and mutant carboxy-terminal domains of the Escherichia coli Tar chemoreceptor

The carboxy-terminal half of the Escherichia coli Tar chemoreceptor protein was cloned into an overproducing plasmid with the transcription of the insert under the control of the strong hybrid tac promoter. Two dominant mutations in the tar gene, which result in "tumble-only" (tar-526) or "swim-only" (tar-529) phenotypes and which are postulated to produce proteins locked in specific signalling modes, were introduced separately onto the overproducing plasmid. After induction with isopropyl-beta-D-thiogalactopyranoside, cells containing the plasmids produced about 10% of their soluble cellular protein as the carboxy-terminal fragments. A scheme to purify the overproduced fragments was developed. Typical yields of pure fragment were 5, 30, and 20 mg per liter of induced culture for the wild type, 526 mutant, and 529 mutant, respectively. Fast-protein liquid chromatography-gel filtration analysis of the pure fragments showed that they all existed as oligomers (ca. 103,000 daltons), possibly trimers or tetramers (monomer size is 31,000 daltons). However, the 529 mutant fragment showed an additional oligomeric form (240,000 daltons) corresponding approximately to an octamer. When chromatographed in the presence of 1% octylglucoside, all three fragments showed an identical single oligomeric size of about 135,000 daltons. Further differences between the fragments such as ion-exchange behavior and susceptibility to degradation were found. Taken together, these results suggest that conformational differences between the 529 mutant fragment and the other fragments exist and that these differences may correlate with the phenotypic effects of the tar-529 mutation.

Maltose chemoreceptor of Escherichia coli: interaction of maltose-binding protein and the tar signal transducer

The maltose chemoreceptor in Escherichia coli consists of the periplasmic maltose-binding protein (MBP) and the Tar signal transducer, which is localized in the cytoplasmic membrane. We previously isolated strains containing malE mutations that cause specific defects in the chemotactic function of MBP. Four of these mutations have now been characterized by DNA sequence analysis. Two of them replace threonine at residue 53 of MBP with isoleucine (MBP-TI53), one replaces an aspartate at residue 55 with asparagine (MBP-DN55), and the fourth replaces threonine at residue 345 with isoleucine (MBP-TI345). The chemotactic defects of MBP-TI53 and MBP-DN55, but not of MBP-TI345, are suppressed by mutations in the tar gene. Of the tar mutations, the most effective suppressor (isolated independently three times) replaces Arg-73 of Tar with tryptophan. Two other tar mutations that disrupt the aspartate chemoreceptor function of Tar also suppress the maltose taxis defects associated with MBP-TI53 and MBP-DN55. One of these mutations introduces glutamine at residue 73 of Tar, the other replaces arginine at residue 69 of Tar with cysteine. These results suggest that regions of MBP that include residues 53 to 55 and residue 345 are important for the interaction with Tar. In turn, arginines at residues 69 and 73 of Tar must be involved in the recognition of maltose-bound MBP and/or in the production of the attractant signal generated by Tar in response to maltose-bound MBP.

Cloning of the C-terminal cytoplasmic fragment of the tar protein and effects of the fragment on chemotaxis of Escherichia coli

A gene encoding only the C-terminal portion of the receptor-transducer protein Tar of Escherichia coli was constructed. The gene product was detected and localized in the cytoplasmic fraction of the cell by immunoblotting with anti-Tar antibodies. The C-terminal fragments from wild-type and mutant tar genes were characterized in vivo. The C-terminal fragment generated from tar-526, a mutation that results in a dominant "tumble" phenotype, was found to be deamidated and methylated by the CheB and CheR proteins, respectively. The C-terminal fragment derived from a wild-type gene was poorly deamidated, and the C-terminal fragment derived from tar-529, a dominant mutant with a "smooth swimming" phenotype, was not apparently modified. Cells carrying the C-terminal fragment with the tar-526 mutation as the sole receptor-transducer protein showed a high frequency of tumbling and chemotaxis responses to changes in intracellular pH. These results suggest that the cytoplasmic C-terminal fragment of Tar retains some of the functions of the whole protein in vivo.

Mutants defective in bacterial chemotaxis show modified protein phosphorylation

To examine the correlation between CheA phosphorylation and bacterial chemotaxis, cheA mutations leading to defects in chemotaxis were mapped and characterized. Mutant CheA proteins were tested in vitro for phosphorylation and were grouped into four classes: nonphosphorylated, partially phosphorylated, phosphorylated but not dephosphorylated by CheB and CheY, and phosphorylated and dephosphorylated. Nearly all the mutants were found to be defective in an aspect of phosphorylation. Furthermore, the mutant phenotypes were found to cluster in different regions of the cheA gene. We suggest that the CheA protein has three functional domains: one for interaction with CheB and CheY, a second for regulating phosphorylation and controlling the stability of the protein, and a third for receiving input signals regulating CheA activity.

Protein phosphorylation is involved in bacterial chemotaxis

The nature of the biochemical signal that is involved in the excitation response in bacterial chemotaxis is not known. However, ATP is required for chemotaxis. We have purified all of the proteins involved in signal transduction and show that the product of the cheA gene is rapidly autophosphorylated, while some mutant CheA proteins cannot be phosphorylated. The presence of stoichiometric levels of two other purified components in the chemotaxis system, the CheY and CheZ proteins, induces dephosphorylation. We suggest that the phosphorylation of CheA by ATP plays a central role in signal transduction in chemotaxis.

Hybrid Escherichia coli sensory transducers with altered stimulus detection and signaling properties

The tar and tap loci of Escherichia coli encode methyl-accepting inner membrane proteins that mediate chemotactic responses to aspartate and maltose or to dipeptides. These genes lie adjacent to each other in the same orientation on the chromosome and have extensive sequence homology throughout the C-terminal portions of their coding regions. Many spontaneous deletions in the tar-tap region appear to be generated by recombination between these regions of homology, leading to gene fusions that produce hybrid transducer molecules in which the N terminus of Tar is joined to the C terminus of Tap. The properties of two such hybrids are described in this report. Although Tar and Tap molecules have homologous domain structures, these Tar-Tap hybrids exhibited defects in stimulus detection and flagellar signaling. Both hybrid transducers retained Tar receptor specificity, but had reduced detection sensitivity. This defect was correlated with the presence of the C-terminal methyl-accepting segment of Tap, which may have more methylation sites than its Tar counterpart, leading to elevated steady-state methylation levels in the hybrid molecules. One of the hybrids, which carried a more extensive segment from Tap, appeared to generate constitutive signals that locked the flagellar motors in a counterclockwise rotational mode. Changes in the methylation state of this transducer were ineffective in cancelling this aberrant signal. These findings implicate the conserved C-terminal domain of bacterial transducers in the generation or regulation of flagellar signals.

Reconstitution of signaling in bacterial chemotaxis

Strains missing several genes required for chemotaxis toward amino acids, peptides, and certain sugars were tethered and their rotational behavior was analyzed. Null strains (called gutted) were deleted for genes that code for the transducers Tsr, Tar, Tap, and Trg and for the cytoplasmic proteins CheA, CheW, CheR, CheB, CheY, and CheZ. Motor switch components were wild type, flaAII(cheC), or flaBII(cheV). Gutted cells with wild-type motors spun exclusively counterclockwise, while those with mutant motors changed their directions of rotation. CheY reduced the bias (the fraction of time that cells spun counterclockwise) in either case. CheZ offset the effect of CheY to an extent that varied with switch allele but did not change the bias when tested alone. Transducers also increased the bias in the presence of CheY but not when tested alone. However, cells containing transducers and CheY failed to respond to attractants or repellents normally detected in the periplasm. This sensitivity was restored by addition of CheA and CheW. Thus, CheY both enhances clockwise rotation and couples the transducers to the flagella. CheZ acts, at the level of the motor, as a CheY antagonist. CheA or CheW or both are required to complete the signal pathway. A model is presented that explains these results and is consistent with other data found in the literature.