Phosphorylation in halobacterial signal transduction.

Regulated phosphorylation of proteins has been shown to be a hallmark of signal transduction mechanisms in both Eubacteria and Eukarya. Here we demonstrate that phosphorylation and dephosphorylation are also the underlying mechanism of chemo- and phototactic signal transduction in Archaea, the third branch of the living world. Cloning and sequencing of the region upstream of the cheA gene, known to be required for chemo- and phototaxis in Halobacterium salinarium, has identified cheY and cheB analogs which appear to form part of an operon which also includes cheA and the following open reading frame of 585 nucleotides. The CheY and CheB proteins have 31.3 and 37.5% sequence identity compared with the known signal transduction proteins CheY and CheB from Escherichia coli, respectively. The biochemical activities of both CheA and CheY were investigated following their expression in E.coli, isolation and renaturation. Wild-type CheA could be phosphorylated in a time-dependent manner in the presence of [gamma-32P]ATP and Mg2+, whereas the mutant CheA(H44Q) remained unlabeled. Phosphorylated CheA was dephosphorylated rapidly by the addition of wild-type CheY. The mutant CheY(D53A) had no effect on phosphorylated CheA. The mechanism of chemo- and phototactic signal transduction in the Archaeon H.salinarium, therefore, is similar to the two-component signaling system known from chemotaxis in the eubacterium E.coli.     

Phosphorylation of three proteins in the signaling pathway of bacterial chemotaxis

Six cytoplasmic che gene products are required for signal transduction in bacterial chemotaxis, but the nature of their biochemical interactions is not known. We show that in vitro the CheA protein becomes autophosphorylated in the presence of ATP. In addition, the phosphate group on CheA can be rapidly transferred to CheB, a protein involved in adaptation to stimuli, or to CheY, a protein involved in the excitation response. The phosphorylation of CheB and CheY is transient; they readily dephosphorylate. We have also found that CheZ, a protein that appears to antagonize CheY function in vivo, accelerates the hydrolysis of the phosphate on CheY. These results suggest that signal transduction in bacterial chemotaxis may involve the flow of phosphate through a cascade of phosphorylated protein intermediates.     

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.     

Chemotactic signaling by an Escherichia coli CheA mutant that lacks the binding domain for phosphoacceptor partners

CheA is a multidomain histidine kinase for chemotaxis in Escherichia coli. CheA autophosphorylates through interaction of its N-terminal phosphorylation site domain (P1) with its central dimerization (P3) and ATP-binding (P4) domains. This activity is modulated through the C-terminal P5 domain, which couples CheA to chemoreceptor control. CheA phosphoryl groups are donated to two response regulators, CheB and CheY, to control swimming behavior. The phosphorylated forms of CheB and CheY turn over rapidly, enabling receptor signaling complexes to elicit fast behavioral responses by regulating the production and transmission of phosphoryl groups from CheA. To promote rapid phosphotransfer reactions, CheA contains a phosphoacceptor-binding domain (P2) that serves to increase CheB and CheY concentrations in the vicinity of the adjacent P1 phosphodonor domain. To determine whether the P2 domain is crucial to CheA's signaling specificity, we constructed CheADeltaP2 deletion mutants and examined their signaling properties in vitro and in vivo. We found that CheADeltaP2 autophosphorylated and responded to receptor control normally but had reduced rates of phosphotransfer to CheB and CheY. This defect lowered the frequency of tumbling episodes during swimming and impaired chemotactic ability. However, expression of additional P1 domains in the CheADeltaP2 mutant raised tumbling frequency, presumably by buffering the irreversible loss of CheADeltaP2-generated phosphoryl groups from CheB and CheY, and greatly improved its chemotactic ability. These findings suggest that P2 is not crucial for CheA signaling specificity and that the principal determinants that favor appropriate phosphoacceptor partners, or exclude inappropriate ones, most likely reside in the P1 domain.     

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.     

Chemotactic signaling by the P1 phosphorylation domain liberated from the CheA histidine kinase of Escherichia coli.

CheA is a histidine kinase central to the signal transduction pathway for chemotaxis in Escherichia coli. CheA autophosphorylates at His-48, with ATP as the phosphodonor, and then donates its phosphoryl groups to two aspartate autokinases, CheY and CheB. Phospho-CheY controls the flagellar motors, whereas phospho-CheB participates in sensory adaptation. Polypeptides encompassing the N-terminal P1 domain of CheA can be transphosphorylated in vitro by the CheA catalytic domain and yet have no deleterious effect on chemotactic ability when expressed at high levels in wild-type cells. To find out why, we examined the effects of a purified P1 fragment, CheA[1-149], on CheA-related signaling activities in vitro and devised in vivo assays for those same activities. Although readily phosphorylated by CheA[260-537], the CheA catalytic domain, CheA[1-149], was a poor substrate for transphosphorylation by full-length CheA molecules, implying that the resident P1 domain monopolizes the CheA catalytic center. CheA-H48Q, a nonphosphorylatable mutant, failed to transphosphorylate CheA[1-149], suggesting that phosphorylation of the P1 domain in cis may alleviate the exclusion effect. In agreement with these findings, a 40-fold excess of CheA[1-149] fragments did not impair the CheA autophosphorylation reaction. CheA[1-149] did acquire phosphoryl groups via reversible phosphotransfer reactions with CheB and CheY molecules. An H48Q mutant of CheA[1-149] could not participate in these reactions, indicating that His-48 is probably the substrate site. The low level of efficiency of these phosphotransfer reactions and the inability of CheA[1-149] to interfere with CheA autophosphorylation most likely account for the failure of liberated P1 domains to jam chemotactic signaling in wild-type cells. However, an excess of CheA[1-149] fragments was able to support chemotactic signaling by P1-deficient cheA mutants, demonstrating that CheA[1-149] fragments have both transphosphorylation and phosphotransfer capability in vivo.     

Phosphotransfer in Rhodobacter sphaeroides chemotaxis

The two-component sensing system controlling bacterial chemotaxis is one of the best studied in biology. Rhodobacter sphaeroides has a complex chemosensory pathway comprising two histidine protein kinases (CheAs) and eight downstream response regulators (six CheYs and two CheBs) rather than the single copies of each as in Escherichia coli. We used in vitro analysis of phosphotransfer to start to determine why R.sphaeroides has these multiple homologues. CheA(1) and CheA(2) contain all the key motifs identified in the histidine protein kinase family, except for conservative substitutions (F-L and F-I) within the F box of CheA(2), and both are capable of ATP-dependent autophosphorylation. While the K(m) values for ATP of CheA(1) and CheA(2) were similar to that of E.coli, the k(cat) value was three times lower, but similar to that measured for the related Sinorhizobium meliloti CheA. However, the two CheAs differed both in their ability to phosphorylate the various response regulators and the rates of phosphotransfer. CheA(2) phosphorylated all of the CheYs and both CheBs, whilst CheA(1) did not phosphorylate either CheB and phosphorylated only the response regulators encoded within its own genetic locus (CheY(1), CheY(2), and CheY(5)) and CheY(3). The dephosphorylation rates of the R.sphaeroides CheBs were much slower than the E.coli CheB. The dephosphorylation rate of CheY(6), encoded by the third chemosensory locus, was ten times faster than that of the E.coli CheY. However, the dephosphorylation rates of the remaining R.sphaeroides CheYs were comparable to that of E.coli CheY.     

Chemotaxis in Rhodobacter sphaeroides requires an atypical histidine protein kinase

Rhodobacter sphaeroides has a complex chemosensory system comprising two classic CheAs, two atypical CheAs, and eight response regulators (six CheYs and two CheBs). The classic CheAs, CheA(1) and CheA(2), have similar domain structures to Escherichia coli CheA, whereas the atypical CheAs, CheA(3) and CheA(4), lack some of the domains found in E. coli CheA. CheA(2), CheA(3), and CheA(4) are all essential for chemotaxis. Here we demonstrate that CheA(3) and CheA(4) are both unable to undergo ATP-dependent autophosphorylation, however, CheA(4) is able to phosphorylate CheA(3). The in vitro kinetics of this phosphorylation reaction were consistent with a reaction mechanism in which CheA(3) associates with a CheA(4) dimer forming a complex, CheA(3)A(4). To the best of our knowledge, CheA(3)A(4) is the first characterized histidine protein kinase where the subunits are encoded by distinct genes. Selective phosphotransfer was observed from CheA(3)-P to the response regulators CheY(1), CheY(6), and CheB(2). Using phosphorylation site and kinase domain mutants of CheA we show that phosphosignaling involving CheA(2), CheA(3), and CheA(4) is essential for chemotaxis in R. sphaeroides. Interestingly, CheA(3) was not phosphorylated in vitro by CheA(1) or CheA(2), although CheA(1) and CheA(2) mutants with defective kinase domains were phosphorylated by CheA(4). Because in vivo CheA(3) and CheA(4) localize to the cytoplasmic chemotaxis cluster, while CheA(2) localizes to the polar chemotaxis cluster, it is likely that the physical separation of CheA(2) and CheA(4) prevents unwanted cross-talk between these CheAs.     

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.     

Identification of a fourth cheY gene in Rhodobacter sphaeroides and interspecies interaction within the bacterial chemotaxis signal transduction pathway

The Escherichia coli chemotaxis signal transduction pathway has: CheA, a histidine protein kinase; CheW, a linker between CheA and sensory proteins; CheY, the effector; and CheZ, a signal terminator. Rhodobacter sphaeroides has multiple copies of these proteins (2 x CheA, 3 x CheW and 3 x CheY, but no CheZ). In this study, we found a fourth cheY and expressed these R. sphaeroides proteins in E. coli. CheA2 (but not CheA1) restored swarming to an E. coli cheA mutant (RP9535). CheW3 (but not CheW2) restored swarming to a cheW mutant of E. coli (RP4606). R. sphaeroides CheYs did not affect E. coli lacking CheY, but restored swarming to a cheZ strain (RP1616), indicating that they can act as signal terminators in E. coli. An E. coli CheY, which is phosphorylated but cannot bind the motor (CheY109KR), was expressed in RP1616 but had no effect. Overexpression of CheA2, CheW2, CheW3, CheY1, CheY3 and CheY4 inhibited chemotaxis of wild-type E. coli (RP437) by increasing its smooth-swimming bias. While some R. sphaeroides proteins restore tumbling to smooth-swimming E. coli mutants, their activity is not controlled by the chemosensory receptors. R. sphaeroides possesses a phosphorelay cascade compatible with that of E. coli, but has additional incompatible homologues.     

Proteomic mapping of a suppressor of non-chemotactic cheW mutants reveals that Helicobacter pylori contains a new chemotaxis protein

Bacterial chemotaxis is a colonization factor for the ulcer-causing pathogen Helicobacter pylori. H. pylori contains genes encoding the chemotaxis signalling proteins CheW, CheA and CheY; CheW couples chemoreceptors to the CheA kinase and is essential for chemotaxis. While characterizing a cheW mutant, we isolated a spontaneous, chemotactic variant (Che+). We determined that this phenotype was caused by a genetic change unlinked to the original cheW mutation. To locate the underlying Che+ mutation, we compared total protein profiles of the non-chemotactic mutant (cheW) with those from the cheW Che+ variant by two-dimensional differential in-gel electrophoresis. One protein was found only in the cheW Che+ variant. This protein was identified by MS/MS as HP0170, a hypothetical protein with no known function. DNA sequencing verified that hp0170 was mutated in the cheW Che+ suppressor, and deletion of this open reading frame in the cheW background nearly recapitulated the Che+ suppressor phenotype. Using hidden Markov models, we found that HP0170 is a remote homologue of E. coli CheZ. CheZ interacts with phosphorylated CheY and stimulates its autodephosphorylation. CheZ was not predicted to be present in epsilon-proteobacteria. We found that chemotaxis in the cheW Che+ suppressor depended on both cheY and cheA. We hypothesize that a small amount of phosphorylated CheY is generated via CheA in the cheW mutant, and this amount is sufficient to affect flagellar rotation when HP0170 is removed. Our results suggest that HP0170 is a remote homologue of CheZ, and that CheZ homologues are found in a broader range of bacteria than previously supposed.     

Cloning and characterization of chemotaxis genes in Pseudomonas aeruginosa

Two chemotaxis-defective mutants of Pseudomonas aeruginosa, designated PC3 and PC4, were selected by the swarm plate method after N-methyl-N'-nitro-N-nitrosoguanidine mutagenesis. These mutants were not complemented by the P. aeruginosa cheY and cheZ genes, which had been previously cloned (Masduki et al., J. Bacteriol., 177, 948-952, 1995). DNA sequences downstream of the cheY and cheZ genes were able to complement PC3 but not PC4. Sequence analysis of a 9.7-kb region directly downstream of the cheZ gene found three chemotaxis genes, cheA, cheB, and cheW, and seven unknown open reading frames (ORFs). The predicted translation products of the cheA, cheB, and cheW genes showed 33, 36, and 31% amino acid identity with Escherichia coli CheA, CheB, and CheW, respectively. Two of the unknown ORFs, ORF1 and ORF2, encoded putative polypeptides that resembled Bacillus subtilis MotA (40% amino acid identity) and MotB (34% amino acid identity) proteins, respectively. Although P. aeruginosa was found to have proteins similar to the enteric chemotaxis proteins CheA, CheB, CheW, CheY, and CheZ, the gene encoding a CheR homologue did not reside in the chemotaxis gene cluster. The P. aeruginosa cheR gene could be cloned by phenotypic complementation of the PC4 mutant. This gene was located at least 1,800 kb away from the chemotaxis gene cluster and encoded a putative polypeptide that had 32% amino acid identity with E. coli CheR.     

Control of transducer methylation levels in Escherichia coli: investigation of components essential for modulation of methylation and demethylation reactions.

During bacterial chemotaxis in Escherichia coli, adaptation is accomplished by reversible methylation of the transmembrane signal transducers. Methyl groups are added by the CheR protein in a slow response to attractants and removed by the CheB protein in response to repellents. The methylesterase activity of the CheB protein is modulated by a factor that is controlled in a global fashion throughout the cell. By controlling the level of expression of the cheR, cheB, and transducer genes with exogenous promoters on multicopy plasmids, we demonstrate that the modulating factor exists in stoichiometric concentrations relative to CheB protein and that the generation or efficacy of this factor requires the cheA and/or cheW gene products, suggesting that phosphorylation of the methylesterase by CheA may be involved in its global activation. We show that in the absence of any modulation of the CheB activity, the CheR methyltransferase activity is modulated in a local fashion at the transducers, most likely as a result of a conformational change in the transducer protein brought about by the binding of ligand, and does not require CheA or CheW.     

Sensory transduction in bacterial chemotaxis involves phosphotransfer between Che proteins

The CheA protein of the Salmonella typhimurium chemotaxis system is phosphorylated by ATP. Phospho-CheA transfers its phosphoryl group to a second chemotaxis protein, CheY. Unlike phospho-CheA, phospho-CheY is relatively unstable, rapidly decaying to phosphate and CheY. We propose that phosphorylation of CheY may play a role in its function as a tumble regulator to control motor behavior in response to attractant and repellent stimuli.     

Phosphorylation and binding interactions of CheY studied by use of Badan-labeled protein

In the chemotaxis signal transduction pathway of Escherichia coli, the response regulator protein CheY is phosphorylated by the receptor-coupled protein kinase CheA. Previous studies of CheY phosphorylation and CheY interactions with other proteins in the chemotaxis pathway have exploited the fluorescence properties of Trp(58), located immediately adjacent to the phosphorylation site of CheY (Asp(57)). Such studies can be complicated by the intrinsic fluorescence and absorbance properties of CheA and other proteins of interest. To circumvent these difficulties, we generated a derivative of CheY carrying a covalently attached fluorescent label that serves as a sensitive reporter of phosphorylation and binding events and that absorbs and emits light at wavelengths well removed from potential interference by other proteins. This labeled version of CheY has the (dimethylamino)naphthalene fluorophore from Badan [6-bromoacetyl-2-(dimethylamino)naphthalene] attached to the thiol group of a cysteine introduced at position 17 of CheY by site-directed mutagenesis. Under phosphorylating conditions (or in the presence of beryllofluoride), the fluorescence emission of Badan-labeled CheY(M17C) exhibited an approximately 10 nm blue shift and an approximately 30% increase in signal intensity at 490 nm. The fluorescence of Badan-labeled CheY(M17C) also served as a sensitive reporter of CheY-CheA binding interactions, exhibiting an approximately 50% increase in emission intensity in the presence of saturating levels of CheA. Compared to wild-type CheY, Badan-labeled CheY exhibited reduced ability to autodephosphorylate and could not interact productively with the phosphatase CheZ. However, with respect to autophosphorylation and interactions with CheA, Badan-CheY performed identically to wild-type CheY, allowing us to explore CheA-CheY phosphotransfer kinetics and binding kinetics without interference from the fluorescence/absorbance properties of CheA and ATP. These results provide insights into CheY interactions with CheA, CheZ, and other components of the chemotaxis signaling pathway.     

Mutational Analysis of the P1 Phosphorylation Domain in Escherichia coli CheA,the Signaling Kinase for Chemotaxis

The histidine autokinase CheA functions as the central processing unit in the Escherichia coli chemotaxis signaling machinery. CheA receives autophosphorylation control inputs from chemoreceptors and in turn regulates the flux of signaling phosphates to the CheY and CheB response regulator proteins. Phospho-CheY changes the direction of flagellar rotation; phospho-CheB covalently modifies receptor molecules during sensory adaptation. The CheA phosphorylation site, His-48, lies in the N-terminal P1 domain, which must engage the CheA ATP-binding domain, P4, to initiate an autophosphorylation reaction cycle. The docking determinants for the P1-P4 interaction have not been experimentally identified. We devised mutant screens to isolate P1 domains with impaired autophosphorylation or phosphotransfer activities. One set of P1 mutants identified amino acid replacements at surface-exposed residues distal to His-48. These lesions reduced the rate of P1 transphosphorylation by P4. However, once phosphorylated, the mutant P1 domains transferred phosphate to CheY at the wild-type rate. Thus, these P1 mutants appear to define interaction determinants for P1-P4 docking during the CheA autophosphorylation reaction.     

CheY3 of Borrelia burgdorferi is the key response regulator essential for chemotaxis and forms a long-lived phosphorylated intermediate

Spirochetes have a unique cell structure: These bacteria have internal periplasmic flagella subterminally attached at each cell end. How spirochetes coordinate the rotation of the periplasmic flagella for chemotaxis is poorly understood. In other bacteria, modulation of flagellar rotation is essential for chemotaxis, and phosphorylation-dephosphorylation of the response regulator CheY plays a key role in regulating this rotary motion. The genome of the Lyme disease spirochete Borrelia burgdorferi contains multiple homologues of chemotaxis genes, including three copies of cheY, referred to as cheY1, cheY2, and cheY3. To investigate the function of these genes, we targeted them separately or in combination by allelic exchange mutagenesis. Whereas wild-type cells ran, paused (flexed), and reversed, cells of all single, double, and triple mutants that contained an inactivated cheY3 gene constantly ran. Capillary tube chemotaxis assays indicated that only those strains with a mutation in cheY3 were deficient in chemotaxis, and cheY3 complementation restored chemotactic ability. In vitro phosphorylation assays indicated that CheY3 was more efficiently phosphorylated by CheA2 than by CheA1, and the CheY3-P intermediate generated was considerably more stable than the CheY-P proteins found in most other bacteria. The results point toward CheY3 being the key response regulator essential for chemotaxis in B. burgdorferi. In addition, the stability of CheY3-P may be critical for coordination of the rotation of the periplasmic flagella.     

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.     

Response regulation in bacterial chemotaxis

The signal transduction system that mediates bacterial chemotaxis allows cells to moduate their swimming behavior in response to fluctuations in chemical stimuli. Receptors at the cell surface receive information from the surroundings. Signals are then passed from the receptors to cytoplasmic chemotaxis components: CheA, CheW, CheZ, CheR, and CheB. These proteins function to regulate the level of phosphorylation of a response regulator designated CheY that interacts with the flagellar motor switch complex to control swimming behavior. The structure of CheY has been determined. Magnesium ion is essential for activity. The active site contains highly conserved Asp residues that are required for divalent metal ion binding and CheY phosphorylation. Another residue-at the active site, Lys109, is important in the phosphorylation-induced conformational change that facilitates communication with the switch complex and another chemotaxis component, CheZ. CheZ facilitates the dephosphorylation of phospho-CheY. Defects in CheY and CheZ can be suppressed by mutations in the flagellar switch complex. CheZ is thought to modulate the switch bias by varying the level of phospho-CheY. © 1993 Wiley-Liss, Inc.     

Rapid phosphotransfer to CheY from a CheA protein lacking the CheY-binding domain

The histidine protein kinase CheA plays a central role in the bacterial chemotaxis signal transduction pathway. Autophosphorylated CheA passes its phosphoryl group to CheY very rapidly (k(cat) approximately 750 s(-)(1)). Phospho-CheY in turn influences the direction of flagellar rotation. The autophosphorylation site of CheA (His(48)) resides in its N-terminal P1 domain. The adjacent P2 domain provides a high-affinity binding site for CheY, which might facilitate the phosphotransfer reaction by tethering CheY in close proximity to the phosphodonor located in P1. To explore the contribution of P2 to the CheA --> CheY phosphotransfer reaction in the Escherichia coli chemotaxis system, we examined the transfer kinetics of a mutant CheA protein (CheADeltaP2) in which the 98 amino acid P2 domain had been replaced with an 11 amino acid linker. We used rapid-quench and stopped-flow fluorescence experiments to monitor phosphotransfer to CheY from phosphorylated wild-type CheA and from phosphorylated CheADeltaP2. The CheADeltaP2 reaction rates were significantly slower and the K(m) value was markedly higher than the corresponding values for wild-type CheA. These results indicate that binding of CheY to the P2 domain of CheA indeed contributes to the rapid kinetics of phosphotransfer. Although phosphotransfer was slower with CheADeltaP2 (k(cat)/K(m) approximately 1.5 x 10(6) M(-)(1) s(-)(1)) than with wild-type CheA (k(cat)/K(m) approximately 10(8) M(-)(1) s(-)(1)), it was still orders of magnitude faster than the kinetics of CheY phosphorylation by phosphoimidazole and other small molecule phosphodonors (k(cat)/K(m) approximately 5-50 M(-)(1) s(-)(1)). We conclude that the P1 domain of CheA also makes significant contributions to phosphotransfer rates in chemotactic signaling.