Mutations in the aspartate receptor of Escherichia coli which affect aspartate binding

The effects of five mutations at arginines 64, 69, and 73 of the Tar protein were analyzed using swarm assays, aspartate binding in purified membranes, and methylation both in vitro and in vivo. The defects in the responses of these mutant receptors to aspartate were shown to be directly attributable to reduced binding of aspartate to the receptor rather than to defects in their signaling characteristics. Mutations at residues 64, 69, and 73 reduced aspartate binding by factors of greater than 10(-4), 10(-3), and 10(-2), respectively. Once aspartate was bound, the mutants exhibited normal signaling properties. No cooperativity was observed in the coupling of aspartate binding to methylation, indicating that the monomers of the receptor dimer act independently. The in vitro methylation system was thus shown to be an effective way of measuring aspartate binding constants and examining the functional integrity of the proteins. The maltose responses of the receptor proteins were affected slightly, or not at all, in an in vivo methylation assay. Two models for the roles of these arginine residues in receptor function are discussed.     

Structural analysis of bacterial chemotaxis proteins: components of a dynamic signaling system

Most motile bacteria are capable of directing their movement in response to chemical gradients, a behavior known as chemotaxis. The signal transduction system that mediates chemotaxis in enteric bacteria consists of a set of six cytoplasmic proteins that couple stimuli sensed by a family of transmembrane receptors to behavioral responses generated by the flagellar motors. Signal transduction occurs via a phosphotransfer pathway involving a histidine protein kinase, CheA, and a response regulator protein, CheY, that in its phosphorylated state, modulates the direction of flagellar rotation. Two auxiliary proteins, CheW and CheZ, and two receptor modification enzymes, methylesterase CheB and methyltransferase CheR, influence the flux of phosphoryl groups within this central pathway. This paper focuses on structural characteristics of the four signaling proteins (CheA, CheY, CheB, and CheR) for which NMR or x-ray crystal structures have been determined. The proteins are examined with respect to their signaling activities that involve reversible protein modifications and transient assembly of macromolecular complexes. A variety of data suggest conformational flexibility of these proteins, a feature consistent with their multiple roles in a dynamic signaling pathway.     

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.     

Tryptophan residues flanking the second transmembrane helix (TM2) set the signaling state of the Tar chemoreceptor

The chemoreceptors of Escherichia coli are homodimeric membrane proteins that cluster in patches near the cell poles. They convert environmental stimuli into intracellular signals that control flagellar rotation. The functional domains of a receptor are physically separated by the cell membrane. Chemoeffectors bind to the extracellular (periplasmic) domain, and the cytoplasmic domain mediates signaling and adaptation. These two domains communicate through the second transmembrane helix (TM2) that connects them. In the high-abundance receptors Tar and Tsr, TM2 is flanked by tryptophan residues, which should localize preferentially to the interfacial zone between the polar and hydrophobic layers of the phospholipid bilayer. To investigate the functional significance of the Trp residues that flank TM2 of Tar, we used site-directed mutagenesis to generate the W192A and W209A substitutions. The W192A protein retains full activity in vivo and in vitro, but it increases the K(i) for aspartate in the in vitro assay 3-fold. The W209A replacement eliminates receptor-mediated stimulation of CheA in vitro, and it leads to an increased level of adaptive methylation in vivo. This phenotype in some respects mimics the changes seen upon binding aspartate. Since the W209A substitution may cause the C-terminus of TM2 to protrude farther into the cytoplasm, these results reinforce the hypothesis that aspartate binding causes a similar displacement. Moving Trp to each position from residue 206 to residue 212 generated a wide variety of Tar signaling states that are generally consistent with the predictions of the piston model of transmembrane signaling. None of these receptors was completely locked in one signaling mode, although most showed pronounced signaling biases. Our findings suggest that the Trp residues flanking TM2, especially Trp-209, are important in setting the baseline activity and ligand sensitivity of the Tar receptor. We also conclude that the Tyr-210 residue plays at least an auxiliary role in this control.     

Phosphorylation by Protein Kinase C of the Muscarinic Acetylcholine Receptor

Muscarinic acetylcholine receptors purified from porcine cerebrum were phosphorylated by protein kinase C purified from the same tissue. More than 1 mol of phosphate was incorporated per mole of receptor, with both serine and threonine residues being phosphorylated. Neither the degree nor the rate of the phosphorylation was affected by the presence or absence of acetylcholine. GTP-sensitive high-affinity binding with acetylcholine was observed for muscarinic receptors reconstituted with GTP-binding proteins (Gi or Go), irrespective of whether muscarinic receptors or the GTP-binding proteins had been phosphorylated by protein kinase C or not. This indicates that the interaction between purified muscarinic receptors and purified GTP-binding proteins in vitro is not affected by their phosphorylation.     

The regulatory role of known tyrosine autophosphorylation sites of the insulin receptor kinase domain. An assessment by replacement with neutral and negatively charged amino acids.

Autophosphorylation of the insulin receptor has been previously documented to activate the phosphotransferase activity of the receptor from 20- to 200-fold. Biochemical studies have correlated activation of the receptor kinase with the autophosphorylation of tyrosines residues 1158, 1162, and 1163. To further assess the role of these 3 tyrosines in the activation process, we have studied the effect of their substitution with either the neutral amino acids phenylalanine or alanine or with the negatively charged amino acids aspartate and glutamate. In several other proteins, it has been shown that substitution of phosphorylated residues with negatively charged amino acids can mimic the phosphorylation state of the protein. In agreement with previous studies, tyrosines at positions 1162 and 1163 were found to be crucial in the kinase activation process. In contrast, mutant receptors with tyrosine 1158 changed to either phenylalanine or aspartate were still activated to the same extent as the wild-type receptor. An increased basal exogenous kinase activity was observed upon replacement of tyrosines 1162 and 1163 with, in increasing order of potency, aspartate = glutamate less than alanine = phenylalanine. These results indicate that phosphorylation of tyrosines 1162/1163 but not 1158 play a critical role in the activation of the receptor kinase and that the mechanism of activation of the receptor kinase by autophosphorylation is more complex than just an introduction of a cluster of negative charges in this region of the receptor. In addition, the finding of an increased basal kinase activity in receptors lacking tyrosines 1162 and 1163 could explain the reported ability of this receptor to mediate certain biological responses.     

Additive and independent responses in a single receptor: aspartate and maltose stimuli on the tar protein

The aspartate and maltose responses of E. coli are mediated through a single membrane receptor, yet the responses are independent and additive. Both stimuli cause methylation of the same 4 glutamic acid residues. More extensive methylation occurs when a cell that has adapted to one stimulus is exposed to the second, or when both stimuli are added simultaneously. The degree of methylation, as well as receptor migration on two-dimensional gels, demonstrates that only one type of protein is involved, rather than two different receptors arising from differential processing of a single gene. A conformational "push-pull" mechanism in which binding of stimulus and covalent modification, producing opposing stresses, can explain these diverse results.     

Receptor-specific desensitization with purified proteins. Kinase dependence and receptor specificity of beta-arrestin and arrestin in the beta 2-adrenergic receptor and rhodopsin systems.

Homologous desensitization of beta-adrenergic receptors, as well as adaptation of rhodopsin, are thought to be triggered by specific phosphorylation of the receptor proteins. However, phosphorylation alone seems insufficient to inhibit receptor function, and it has been proposed that the inhibition is mediated, following receptor phosphorylation, by the additional proteins beta-arrestin in the case of beta-adrenergic receptors and arrestin in the case of rhodopsin. In order to test this hypothesis with isolated proteins, beta-arrestin and arrestin were produced by transient overexpression of their cDNAs in COS7 cells and purified to apparent homogeneity. Their functional effects were assessed in reconstituted receptor/G protein systems using either beta 2-adrenergic receptors with Gs or rhodopsin with Gt. Prior to the assays, beta 2-receptors and rhodopsin were phosphorylated by their specific kinases beta-adrenergic receptor kinase (beta ARK) and rhodopsin kinase, respectively. beta-Arrestin was a potent inhibitor of the function of beta ARK-phosphorylated beta 2-receptors. Half-maximal inhibition occurred at a beta-arrestin:beta 2-receptor stoichiometry of about 1:1. More than 100-fold higher concentrations of arrestin were required to inhibit beta 2-receptor function. Conversely, arrestin caused half-maximal inhibition of the function of rhodopsin kinase-phosphorylated rhodopsin when present in concentrations about equal to those of rhodopsin, whereas beta-arrestin at 100-fold higher concentrations had little inhibitory effect. The potency of beta-arrestin in inhibiting beta 2-receptor function was increased over 10-fold following phosphorylation of the receptors by beta ARK, but was not affected by receptor phosphorylation using protein kinase A. This suggests that beta-arrestin plays a role in beta ARK-mediated homologous, but not in protein kinase A-mediated heterologous desensitization of beta-adrenergic receptors. It is concluded that even though arrestin and beta-arrestin are similar proteins, they display marked specificity for their respective receptors and that phosphorylation of the receptors by the receptor-specific kinases serves to permit the inhibitory effects of the "arresting" proteins by allowing them to bind to the receptors and thereby inhibit their signaling properties. Furthermore, it is shown that this mechanism of receptor inhibition can be reproduced with isolated purified proteins.     

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.     

Agonist-independent phosphorylation of purified cardiac muscarinic cholinergic receptors by protein kinase C

The results of several studies have suggested that muscarinic cholinergic receptors (mAChR) may be regulated by multiple pathways involving phosphorylation of the receptors. Previous studies have demonstrated that chick heart mAChR are phosphorylated by the beta-adrenergic receptor kinase (beta-AR kinase) in an agonist-dependent manner, and it has been suggested that this process may be linked to receptor desensitization. In this work, we present evidence that protein kinase C can phosphorylate the purified, reconstituted chick heart mAChR and can modify the interaction of the receptors with GTP binding proteins (G-proteins) that couple the receptors to effectors. Phosphorylation of the mAChR with protein kinase C occurred to an extent of approximately 5 mol of P/mol of receptor. Neither the rate nor the extent of the protein kinase C mediated phosphorylation of mAChR was agonist-dependent. Under the conditions tested, the initial rate of phosphorylation of the mAChR by protein kinase C was significantly more rapid than that obtained with the beta-AR kinase. At equilibrium, phosphorylation of mAChR by protein kinase C and beta-AR kinase was partially additive. The functional effects of protein kinase C mediated phosphorylation of the mAChR were assessed by comparing the abilities of purified G-proteins (Gi and Go) to reconstitute high-affinity agonist binding to phosphorylated and nonphosphorylated receptors. A significantly larger percentage of the receptors phosphorylated with protein kinase C exhibited G-protein-dependent high-affinity agonist binding, suggesting that phosphorylation of the receptors by protein kinase C modulates receptor function in a positive manner.(ABSTRACT TRUNCATED AT 250 WORDS)     

A protein methylation pathway in Chlamydomonas flagella is active during flagellar resorption

During intraflagellar transport (IFT), the regulation of motor proteins, the loading and unloading of cargo and the turnover of flagellar proteins all occur at the flagellar tip. To begin an analysis of the protein composition of the flagellar tip, we used difference gel electrophoresis to compare long versus short (i.e., regenerating) flagella. The concentration of tip proteins should be higher relative to that of tubulin (which is constant per unit length of the flagellum) in short compared with long flagella. One protein we have identified is the cobalamin-independent form of methionine synthase (MetE). Antibodies to MetE label flagella in a punctate pattern reminiscent of IFT particle staining, and immunoblot analysis reveals that the amount of MetE in flagella is low in full-length flagella, increased in regenerating flagella, and highest in resorbing flagella. Four methylated proteins have been identified in resorbing flagella, using antibodies specific for asymmetrically dimethylated arginine residues. These proteins are found almost exclusively in the axonemal fraction, and the methylated forms of these proteins are essentially absent in full-length and regenerating flagella. Because most cells resorb cilia/flagella before cell division, these data indicate a link between flagellar protein methylation and progression through the cell cycle.     

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

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

Photostimulation of a sensory rhodopsin II/HtrII/Tsr fusion chimera activates CheA-autophosphorylation and CheY-phosphotransfer in vitro

A chimeric fusion protein consisting of Natronomonas pharaonis sensory rhodopsin II (SRII), fused by a flexible linker to the two transmembrane helices of its cognate transducer protein, HtrII, followed by the HtrII membrane-proximal cytoplasmic fragment joined to the cytoplasmic domains of the Escherichia coli chemotaxis receptor Tsr, was expressed in E. coli. Purified fusion chimera protein reconstituted in liposomes binds to E. coli CheA kinase in the presence of the coupling protein CheW, and activates CheA autophosphorylation activity. CheA kinase activity is stimulated by photoexcitation of the SRII domain of the fusion protein, as shown by the wavelength-dependence of photostimulated phosphotransfer to the E. coli flagellar motor response regulator CheY in the purified in vitro liposomal system. Further confirming the fidelity of the in vitro system, increased and decreased levels of CheA activation in vitro result from overmethylated and undermethylated fusion protein purified from methylesterase and methyltransferase-deficient E. coli, respectively. Photoexcitation of the undermethylated fusion protein resulted in a 3-fold increase in phosphotransfer over that of the dark state. The results directly demonstrate the coupling of SRII photoactivated states to histidine kinase activity, previously predicted on the basis of sequence homologies of the haloarchaeal phototaxis system components to those of E. coli chemotaxis. The fusion chimera provides the first tool for in vitro measurement of photosignaling activity of SRII-HtrII molecular complexes.     

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.     

Focal adhesion kinase suppresses apoptosis by binding to the death domain of receptor-interacting protein

Tumor cells resist the apoptotic stimuli associated with invasion and metastasis by activating survival signals that suppress apoptosis. Focal adhesion kinase (FAK), a tyrosine kinase that is overexpressed in a variety of human tumors, mediates one of these survival signals. Attenuation of FAK expression in tumor cells results in apoptosis that is mediated by caspase 8- and FADD-dependent pathways, suggesting that death receptor pathways are involved in the process. Here, we report a functional link between FAK and death receptors. We have demonstrated that FAK binds to the death domain kinase receptor-interacting protein (RIP). RIP is a major component of the death receptor complex and has been shown to interact with Fas and tumor necrosis factor receptor 1 through its binding to adapter proteins. We have shown that RIP provides proapoptotic signals that are suppressed by its binding to FAK. We thus propose that FAK overexpression in human tumors provides a survival signal function by binding to RIP and inhibiting its interaction with the death receptor complex.     

Protein phosphorylation in the bacterial chemotaxis system

Bacterial chemotaxis involves the detection of changes in concentration of specific chemicals in the environment of the cell as a function of time. This process is mediated by a series of cell surface receptors that interact with and activate intracellular protein phosphorylation. Five cytoplasmic proteins essential for chemotaxis have been shown to be involved in a coupled system of protein phosphorylation. Ligand binding to cell surface receptors affects the rate of autophosphorylation of the CheA protein. In the absence of an attractant bound to receptor and in the presence of the CheW protein, the rate of CheA autophosphorylation is markedly increased. Phosphorylated CheA can transfer phosphate to the CheY or CheB proteins; phosphorylation of these "effector" proteins may increase their activity. The CheY protein is thought to regulate flagellar rotation and thus control swimming behavior. The CheB protein modifies the cell surface receptor and thus regulates receptor function. Finally, another chemotaxis protein, CheZ, acts to specifically dephosphorylate CheY-phosphate. This system shows marked similarity to the 2-component sensor-regulator systems found to control specific gene expression in a variety of bacteria.     

A free-energy-based stochastic simulation of the Tar receptor complex

We recently developed a stochastic-based program that allows individual molecules in a cell signalling pathway to be simulated. This program has now been used to model the Tar complex, a multimeric signalling complex employed by coliform bacteria. This complex acts as a solid-state computational cassette, integrating and disseminating information on the presence of attractants and repellents in the environment of the bacterium. In our model, the Tar complex exists in one of two conformations which differ in the rate at which they generate labile phosphate groups and hence signal to the flagellar motor. Individual inputs to the complex (aspartate binding, methylation at different sites, binding of CheB, CheR and CheY) are represented as binary flags, and each combination of flags confers a different free energy to the two conformations. Binding and catalysis by the complex are performed stochastically according to the complete set of known reactions allowing the swimming performance of the bacterium to be predicted.The assumption of two conformational states together with the use of free energy values allows us to bring together seemingly unrelated experimental parameters. Because of thermodynamic constraints, we find that the binding affinity for aspartate is linked to changes in phosphorylation activity. We estimate the pattern of Tar methylation and effective affinity constant of receptors over a range of aspartate levels. We also obtain evidence that both the methylating and demethylating enzymes must operate exclusively on one or other of the two conformations, and that sites of methylation of the complex are occupied in sequential order rather than independently. Detailed analysis of the response to aspartate reveals several quantitative discrepancies between simulated and experimental data which indicate areas for future research.     

Conversion of a bacterial warm sensor to a cold sensor by methylation of a single residue in the presence of an attractant

The aspartate chemoreceptor (Tar) of Escherichia coli also serves as a thermosensor, and it is very amenable to genetic and biochemical analysis of the thermosensing mechanism. Its thermosensing properties are controlled by reversible methylation of the cytoplasmic signalling/adaptation domain of the protein. The unmethylated and the fully methylated (aspartate-bound) receptors sense, as attractant stimuli, increases (warm sensor) and decreases (cold sensor) in temperature respectively. To learn more about the mechanism of thermosensing, we replaced the four methyl-accepting glutamyl residues with non-methylatable aspartyl residues in all possible combinations. In a strain defective in both methyltransferase (CheR) and methylesterase (CheB) activities, all of the mutant Tar proteins functioned as warm sensors. To create a situation in which all of the remaining glutamyl residues were methylated, we expressed the mutant proteins in a CheB-defective, CheR-overproducing strain. The fully glutamyl-methylated proteins were designed to mimic the full range of methylation states possible for wild-type Tar. Almost all of the methylated mutant receptors, including those with single glutamyl residues, were cold sensors in the presence of aspartate. Thus, binding of aspartate to Tar and methylation of its single glutamyl residue can invert its temperature-dependent signalling properties.     

Functional reconstitution of the Na(+)-driven polar flagellar motor component of Vibrio alginolyticus

The bacterial flagellar motor is a molecular machine that couples the influx of specific ions to the generation of the force necessary to drive rotation of the flagellar filament. Four integral membrane proteins, PomA, PomB, MotX, and MotY, have been suggested to be directly involved in torque generation of the Na(+)-driven polar flagellar motor of Vibrio alginolyticus. In the present study, we report the isolation of the functional component of the torque-generating unit. The purified protein complex appears to consist of PomA and PomB and contains neither MotX nor MotY. The PomA/B protein, reconstituted into proteoliposomes, catalyzed (22)Na(+) influx in response to a potassium diffusion potential. Sodium uptake was abolished by the presence of Li(+) ions and phenamil, a sodium channel blocker. This is the first demonstration of a purification and functional reconstitution of the bacterial flagellar motor component involved in torque generation. In addition, this study demonstrates that the Na(+)-driven motor component, PomA and PomB, forms the Na(+)-conducting channel.