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.     

Solution structure of a complex of the histidine autokinase CheA with its substrate CheY

In the bacterial chemotaxis two-component signaling system, the histidine-containing phosphotransfer domain (the "P1" domain) of CheA receives a phosphoryl group from the catalytic domain (P4) of CheA and transfers it to the cognate response regulator (RR) CheY, which is docked by the P2 domain of CheA. Phosphorylated CheY then diffuses into the cytoplasm and interacts with the FliM moiety of the flagellar motors, thereby modulating the direction of flagellar rotation. Structures of various histidine phosphotransfer domains (HPt) complexed with their cognate RR domains have been reported. Unlike the Escherichia coli chemotaxis system, however, these systems lack the additional domains dedicated to binding to the response regulators, and the interaction of an HPt domain with an RR domain in the presence of such a domain has not been examined on a structural basis. In this study, we used modern nuclear magnetic resonance techniques to construct a model for the interaction of the E. coli CheA P1 domain (HPt) and CheY (RR) in the presence of the CheY-binding domain, P2. Our results indicate that the presence of P2 may lead to a slightly different relative orientation of the HPt and RR domains versus those seen in such complex structures previously reported.     

Sensory transduction to the flagellar motor of Sinorhizobium meliloti

Molecular mechanisms that govern chemotaxis and motility in the nitrogen-fixing soil bacterium, Sinorhizobium meliloti, are distinguished from the well-studied taxis systems of enterobacteria by new features. (i) In addition to six transmembrane chemotaxis receptors, S. meliloti has two cytoplasmic receptor proteins, McpY (methyl-accepting chemotaxis protein) and IcpA (internal chemotaxis protein). (ii) The tactic response is mediated by two response regulators, CheY1 and CheY2, but no phosphatase, CheZ. Phosphorylated CheY2 (CheY2-P) is the main regulator of motor function, whereas CheY1 assumes the role of a 'sink' for phosphate that is shuttled from CheY2-P back to CheA. This phospho-transfer from surplus CheY2-P to CheA to CheY1 replaces CheZ phosphatase. (iii) S. meliloti flagella have a complex structure with three helical ribbons that render the filaments rigid and unable to undergo polymorphic transitions from right- to left-handedness. Flagella rotate only clockwise and their motors can increase and decrease rotary speed. Hence, directional changes of a swimming cell occur during slow-down, when several flagella rotate at different speed. Two novel motility proteins, the periplasmic MotC and the cytoplasmic MotD, are essential for motility and rotary speed variation. A model consistent with these data postulates a MotC-mediated gating of the energizing MotA-MotB proton channels leading to variations in flagellar rotary speed.     

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.     

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.     

Interaction of CheY2 and CheY2-P with the cognate CheA kinase in the chemosensory-signalling chain of Sinorhizobium meliloti

An unusual regulatory mechanism involving two response regulators, CheY1 and CheY2, but no CheZ phosphatase, operates in the chemotactic signalling chain of Sinorhizobium meliloti . Active CheY2-P, phosphorylated by the cognate histidine kinase, CheA, is responsible for flagellar motor control. In the absence of any CheZ phosphatase activity, the level of CheY2-P is quickly reset by a phospho-transfer from CheY2-P first back to CheA, and then to CheY1, which acts as a phosphate sink. In studying the mechanism of this phosphate shuttle, we have used GFP fusions to show that CheY2, but not CheY1, associates with CheA at a cell pole. Cross-linking experiments with the purified proteins revealed that both CheY2 and CheY2-P bind to an isolated P2 ligand-binding domain of CheA, but CheY1 does not. The dissociation constants of CheA–CheY2 and CheA–CheY2-P indicated that both ligands bind with similar affinity to CheA. Based on the NMR structures of CheY2 and CheY2-P, their interactions with the purified P2 domain were analysed. The interacting surface of CheY2 comprises its C-terminal β4-α4-β5-α5 structural elements, whereas the interacting surface of CheY2-P is shifted towards the loop connecting β5 and α5. We propose that the distinct CheY2 and CheY2-P surfaces interact with two overlapping sites in the P2 domain that selectively bind either CheY2 or CheY2-P, depending on whether CheA is active or inactive.     

Genetic analysis of the catalytic domain of the chemotaxis-associated histidine kinase CheA.

Escherichia coli cells express two forms of CheA, the histidine kinase associated with chemotaxis. The long form, CheA(L), plays a critical role in chemotactic signal transduction by phosphorylating two chemotaxis-associated response regulators, CheY and CheB. CheA(L) first autophosphorylates amino acid His-48 before its phosphoryl group is transferred to these response regulators. The short form, CheA(S), lacks the amino-terminal 97 amino acids of CheA(L) and therefore does not possess the site of phosphorylation. The centrally located transmitter domain of both forms of CheA contains four regions, called N, G1, F, and G2, highly conserved among histidine kinases of the family of two-component signal transduction systems. On the basis of sequence similarity to highly conserved regions of certain eukaryotic kinases, the G1 and G2 regions are purported to be involved in the binding and hydrolysis of ATP. We report here that alleles mutated in the G1, G2, or F region synthesize CheA variants that cannot autophosphorylate in vitro and which cannot support chemotaxis in vivo. We also show that in vitro, the nonphosphorylatable CheA(S) protein mediates transphosphorylation of a CheA(L) variant defective in both G1 and G2. In contrast, CheA(L) variants defective for either G1 or G2 mediate transphosphorylation of each other poorly, if at all. These results are consistent with a mechanism by which the G1 and G2 regions of one protomer of a CheA dimer form a unit that mediates transphosphorylation of the other protomer within that dimer.     

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.     

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.     

Divalent metal ion binding to the CheY protein and its significance to phosphotransfer in bacterial chemotaxis

Signal transduction in bacterial chemotaxis involves transfer of a phosphoryl group between the cytoplasmic proteins CheA and CheY. In addition to the established metal ion requirement for autophosphorylation of CheA, divalent magnesium ions are necessary for the transfer of phosphate from CheA to CheY. The work described here demonstrates via fluorescence studies that CheY contains a magnesium ion binding site. This site is a strong candidate for the metal ion site required to facilitate phosphotransfer from phospho-CheA to CheY. The diminished magnesium ion interaction with CheY mutant D13N and the lack of metal ion binding to D57N along with significant reduction in phosphotransfer to these two mutants are in direct contrast to the behavior of wild-type CheY. This supports the hypothesis that the acidic pocket formed by Asp13 and Asp57 is essential to metal binding and phosphotransfer activity. Metal ion is also required for the dephosphorylation reaction, raising the possibility that the phosphotransfer and hydrolysis reactions occur by a common metal-phosphoprotein transition-state intermediate. The highly conserved nature of the proposed metal ion binding site and site of phosphorylation within the large family of phosphorylated regulatory proteins that are homologous to CheY supports the hypothesis that all these proteins function by a similar catalytic mechanism.     

Identification of an anchor residue for CheA-CheY interactions in the chemotaxis system of Escherichia coli

Transfer of a phosphoryl group from autophosphorylated CheA (P-CheA) to CheY is an important step in the bacterial chemotaxis signal transduction pathway. This reaction involves CheY (i) binding to the P2 domain of P-CheA and then (ii) acquiring the phosphoryl group from the P1 domain. Crystal structures indicated numerous side chain interactions at the CheY-P2 binding interface. To investigate the individual contributions of the P2 side chains involved in these contacts, we analyzed the effects of eight alanine substitution mutations on CheA-CheY binding interactions. An F214A substitution in P2 caused ～1,000-fold reduction in CheA-CheY binding affinity, while Ala substitutions at other P2 positions had small effects (E171A, E178A, and I216A) or no detectable effects (H181A, D202A, D207A, and C213A) on binding affinity. These results are discussed in relation to previous in silico predictions of hot-spot and anchor positions at the CheA-CheY interface. We also investigated the consequences of these mutations for chemotaxis signal transduction in living cells. CheA(F214A) was defective in mediating localization of CheY-YFP to the large clusters of signaling proteins that form at the poles of Escherichia coli cells, while the other CheA variants did not differ from wild-type (wt) CheA (CheA(wt)) in this regard. In our set of mutants, only CheA(F214A) exhibited a markedly diminished ability to support chemotaxis in motility agar assays. Surprisingly, however, in FRET assays that monitored receptor-regulated production of phospho-CheY, CheA(F214A) (and each of the other Ala substitution mutants) performed just as well as CheA(wt). Overall, our findings indicate that F214 serves as an anchor residue at the CheA-CheY interface and makes an important contribution to the binding energy in vitro and in vivo; however, loss of this contribution does not have a large negative effect on the overall ability of the signaling pathway to modulate P-CheY levels in response to chemoattractants.     

Kinetic characterization of CheY phosphorylation reactions: comparison of P-CheA and small-molecule phosphodonors

In the chemotaxis system of Escherichia coli, phosphorylation of the CheY protein plays an important role in regulating the swimming pattern of the cell. In vitro, CheY can be phosphorylated either by phosphotransfer from phospho-CheA or by acquiring a phosphoryl group from any of a variety of small, high-energy phosphodonor molecules such as acetyl phosphate. Previous work explored the rapid kinetics of CheY phosphorylation by CheA. Here we extend that work and examine the kinetics of CheY phosphorylation by several small-molecule phosphodonors, including acetyl phosphate, benzoyl phosphate, carbamoyl phosphate, 2-methoxybenzoyl phosphate, and phosphoramidate. Our results indicate that these phosphodonors bind to CheY with relatively low affinity (Ks values ranging from 10 to 600 mM) and that the rate constant (kphos) for phosphotransfer at saturating phosphodonor concentrations is relatively slow (values ranging from 0.05 to 0.5 s-1). By contrast, under identical conditions, phosphorylation of CheY by phospho-CheA occurs much more rapidly (kphos approximately 800 s-1) and reflects CheY binding to phospho-CheA considerably more tightly (Ks approximately 60 microM) than it does to the small-molecule phosphodonors. In comparing CheA-mediated phosphorylation of CheY to small-molecule-mediated phosphorylation of CheY, the large difference in kphos values suggests that phospho-CheA makes significant contributions to the catalysis of CheY phosphorylation. The effects of pH and ionic strength on CheY phosphorylation kinetics were also investigated. For CheA-->CheY phosphotransfer, increasing ionic strength resulted in increased Ks values while kphos was unaffected. For CheY phosphorylation by small-molecule phosphodonors, increasing ionic strength resulted in decreasing Ks values and increasing kphos values. The significance of these effects is discussed in relation to the catalytic mechanism of CheY phosphorylation by phospho-CheA and small-molecule phosphodonors.     

Sinorhizobium meliloti CheA complexed with CheS exhibits enhanced binding to CheY1, resulting in accelerated CheY1 dephosphorylation

Retrophosphorylation of the histidine kinase CheA in the chemosensory transduction chain is a widespread mechanism for efficient dephosphorylation of the activated response regulator. First discovered in Sinorhizobium meliloti, the main response regulator CheY2-P shuttles its phosphoryl group back to CheA, while a second response regulator, CheY1, serves as a sink for surplus phosphoryl groups from CheA-P. We have identified a new component in this phospho-relay system, a small 97-amino-acid protein named CheS. CheS has no counterpart in enteric bacteria but revealed distinct similarities to proteins of unknown function in other members of the α subgroup of proteobacteria. Deletion of cheS causes a phenotype similar to that of a cheY1 deletion strain. Fluorescence microscopy revealed that CheS is part of the polar chemosensory cluster and that its cellular localization is dependent on the presence of CheA. In vitro binding, as well as coexpression and copurification studies, gave evidence of CheA/CheS complex formation. Using limited proteolysis coupled with mass spectrometric analyses, we defined CheA(163-256) to be the CheS binding domain, which overlaps with the N-terminal part of the CheY2 binding domain (CheA(174-316)). Phosphotransfer experiments using isolated CheA-P showed that dephosphorylation of CheY1-P but not CheY2-P is increased in the presence of CheS. As determined by surface plasmon resonance spectroscopy, CheY1 binds ～100-fold more strongly to CheA/CheS than to CheA. We propose that CheS facilitates signal termination by enhancing the interaction of CheY1 and CheA, thereby promoting CheY1-P dephosphorylation, which results in a more efficient drainage of the phosphate sink.     

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.     

Investigation of the role of electrostatic charge in activation of the Escherichia coli response regulator CheY

In a two-component regulatory system, an important means of signal transduction in microorganisms, a sensor kinase phosphorylates a response regulator protein on an aspartyl residue, resulting in activation. The active site of the response regulator is highly charged (containing a lysine, the phosphorylatable aspartate, two additional aspartates involved in metal binding, and an Mg(2+) ion), and introduction of the dianionic phosphoryl group results in the repositioning of charged moieties. Furthermore, substitution of one of the Mg(2+)-coordinating aspartates with lysine or arginine in the Escherichia coli chemotaxis response regulator CheY results in phosphorylation-independent activation. In order to examine the consequences of altered charge distribution for response regulator activity and to identify possible additional amino acid substitutions that result in phosphorylation-independent activation, we made 61 CheY mutants in which residues close to the site of phosphorylation (Asp57) were replaced by various charged amino acids. Most substitutions (47 of 61) resulted in the complete loss of CheY activity, as measured by the inability to support clockwise flagellar rotation. However, 10 substitutions, all introducing a new positive charge, resulted in the loss of chemotaxis but in the retention of some clockwise flagellar rotation. Of the mutants in this set, only the previously identified CheY13DK and CheY13DR mutants displayed clockwise activity in the absence of the CheA sensor kinase. The absence of negatively charged substitution mutants with residual activity suggests that the introduction of additional negative charges into the active site is particularly deleterious for CheY function. Finally, the spatial distribution of positions at which amino acid substitutions are functionally tolerated or not tolerated is consistent with the presently accepted mechanism of response regulator activation and further suggests a possible role for Met17 in signal transduction by 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.     

Divergent regulatory pathways control A and S motility in Myxococcus xanthus through FrzE, a CheA-CheY fusion protein

Myxococcus xanthus moves on solid surfaces by using two gliding motility systems, A motility for individual-cell movement and S motility for coordinated group movements. The frz genes encode chemotaxis homologues that control the cellular reversal frequency of both motility systems. One of the components of the core Frz signal transduction pathway, FrzE, is homologous to both CheA and CheY from the enteric bacteria and is therefore a novel CheA-CheY fusion protein. In this study, we investigated the role of this fusion protein, in particular, the CheY domain (FrzECheY). FrzECheY retains all of the highly conserved residues of the CheY superfamily of response regulators, including Asp709, analogous to phosphoaccepting Asp57 of Escherichia coli CheY. While in-frame deletion of the entire frzE gene caused both motility systems to show a hyporeversal phenotype, in-frame deletion of the FrzECheY domain resulted in divergent phenotypes for the two motility systems: hyperreversals of the A-motility system and hyporeversals of the S-motility system. To further investigate the role of FrzECheY in A and S motility, point mutations were constructed such that the putative phosphoaccepting residue, Asp709, was changed from D to A (and was therefore never subject to phosphorylation) or E (possibly mimicking constitutive phosphorylation). The D709A mutant showed hyperreversals for both motilities, while the D709E mutant showed hyperreversals for A motility and hyporeversal for S motility. These results show that the FrzECheY domain plays a critical signaling role in coordinating A and S motility. On the basis of the phenotypic analyses of the frzE mutants generated in this study, a model is proposed for the divergent signal transduction through FrzE in controlling and coordinating A and S motility in M. xanthus.     

Solution structures of the inactive and BeF3-activated response regulator CheY2

The chemotactic signalling chain to the flagellar motor of Sinorhizobium meliloti features a new type of response regulator, CheY2. CheY2 activated by phosphorylation (CheY2-P) controls the rotary speed of the flagellar motor (instead of reversing the sense of rotation), and it is efficiently dephosphorylated by phospho-retrotransfer to the cognate kinase, CheA. Here, we report the NMR solution structures of the Mg(2+)-complex of inactive CheY2, and of activated CheY2-BeF(3), a stable analogue of CheY2-P, to an overall root mean square deviation of 0.042 nm and 0.027 nm, respectively. The 14 kDa CheY2 protein exhibits a characteristic open (alpha/beta)(5) conformation. Modification of CheY2 by BeF(3)(-) leads to large conformational changes of the protein, which are in the limits of error identical with those observed by phosphorylation of the active-centre residue Asp58. In BeF(3)-activated CheY2, the position of Thr88-OH favours the formation of a hydrogen bond with the active site, Asp58-BeF(3), similar to BeF(3)-activated CheY from Escherichia coli. In contrast to E.coli, this reorientation is not involved in a Tyr-Thr-coupling mechanism, that propagates the signal from the incoming phosphoryl group to the C-terminally located FliM-binding surface. Rather, a rearrangement of the Phe59 side-chain to interact with Ile86-Leu95-Val96 along with a displacement of alpha4 towards beta5 is stabilised in S.meliloti. The resulting, activation-induced, compact alpha4-beta5-alpha5 surface forms a unique binding domain suited for specific interaction with and signalling to a rotary motor that requires a gradual speed control. We propose that these new features of response regulator activation, compared to other two-component systems, are the key for the observed unique phosphorylation, dephosphorylation and motor control mechanisms in S.meliloti.     

Analysis of ATP binding to CheA containing tryptophan substitutions near the active site

Signal transduction in the chemotaxis system of Escherichia coli involves an autophosphorylating protein histidine kinase, CheA. At the active site of CheA, phenylalanine residues 455 and 459 occupy positions near the ATP-binding pocket, immediately adjacent to one of the hinge regions of a loop that undergoes an ATP-induced conformational change ("lid closure") that has been characterized previously in X-ray crystal structures [Bilwes et al. (2001) Nat. Struct. Biol. 8, 353-360]. We generated versions of CheA carrying F455W and F459W replacements and investigated whether the fluorescence properties of the introduced tryptophan side chains were affected by nucleotide binding in a manner that would provide a signal for investigating the dynamics of active site events, such as ATP binding and lid closure. Our results indicate that CheA(F455W) is useful in this regard, but CheA(F459W) is not. CheA(F455W) retained full catalytic activity and exhibited easily monitored fluorescence changes upon binding nucleotide: we observed a 25-30% decrease in CheA(F455W) fluorescence emission intensity at 330 nm upon binding ATP in the absence of Mg(2+); in the presence of Mg(2+), the emission spectrum of the CheA(F455W):ATP complex was red-shifted by 5 nm and exhibited an increased intensity (approximately 20% higher at 345 nm relative to that of uncomplexed CheA(F455W)). Different fluorescence changes were observed when two ATP analogues (ADPNP and ADPCP) were used instead of ATP and when Mn(2+) or Ca(2+) was used in place of Mg(2+). We exploited the fluorescence changes induced by Mg(2+)-ATP to explore the kinetics and mechanism of nucleotide binding by CheA(F455W). In the absence of Mg(2+), binding appears to involve a simple one-step equilibrium (k(assn) = 0.7 microM(-1) s(-1) and k(dissn) = 270 s(-1) at 4 degrees C). In the presence of Mg(2+), the binding mechanism involves at least two steps: (i) rapid, relatively weak binding followed by (ii) a rapid, reversible step (k(forward) = 300 s(-1) and k(reverse) =15 s(-1) at 4 degrees C) that enhanced the overall affinity of the complex and generated an increase in W455 fluorescence. This second step could reflect a conformational change at the CheA active site, such as lid closure. These results provide the first insight into the dynamics of nucleotide binding and substrate-induced conformational changes at the active site of a protein histidine kinase.     

Localization of components of the chemotaxis machinery of Escherichia coli using fluorescent protein fusions

We prepared fusions of yellow fluorescent protein [the YFP variant of green fluorescent protein (GFP)] with the cytoplasmic chemotaxis proteins CheY, CheZ and CheA and the flagellar motor protein FliM, and studied their localization in wild-type and mutant cells of Escherichia coli. All but the CheA fusions were functional. The cytoplasmic proteins CheY, CheZ and CheA tended to cluster at the cell poles in a manner similar to that observed earlier for methyl-accepting chemotaxis proteins (MCPs), but only if MCPs were present. Co-localization of CheY and CheZ with MCPs was CheA dependent, and co-localization of CheA with MCPs was CheW dependent, as expected. Co-localization with MCPs was confirmed by immunofluorescence using an anti-MCP primary antibody. The motor protein FliM appeared as discrete spots on the sides of the cell. These were seen in wild-type cells and in a fliN mutant, but not in flhC or fliG mutants. Co-localization with flagellar structures was confirmed by immunofluorescence using an antihook primary antibody. Surprisingly, we did not observe co-localization of CheY with motors, even under conditions in which cells tumbled.