Mutational activation of CheA, the protein kinase in the chemotaxis system of Escherichia coli

Regulation of the chemotaxis histidine kinase CheA: A structural perspective

Bacteria sense and respond to their environment through a highly conserved assembly of transmembrane chemoreceptors (MCPs), the histidine kinase CheA, and the coupling protein CheW, hereafter termed "the chemosensory array". In recent years, great strides have been made in understanding the architecture of the chemosensory array and how this assembly engenders sensitive and cooperative responses. Nonetheless, a central outstanding question surrounds how receptors modulate the activity of the CheA kinase, the enzymatic output of the sensory system. With a focus on recent advances, we summarize the current understanding of array structure and function to comment on the molecular mechanism by which CheA, receptors and CheW generate the high sensitivity, gain and dynamic range emblematic of bacterial chemotaxis. The complexity of the chemosensory arrays has motivated investigation with many different approaches. In particular, structural methods, genetics, cellular activity assays, nanodisc technology and cryo-electron tomography have provided advances that bridge length scales and connect molecular mechanism to cellular function. Given the high degree of component integration in the chemosensory arrays, we ultimately aim to understand how such networked molecular interactions generate a whole that is truly greater than the sum of its parts. This article is part of a Special Issue entitled: Molecular biophysics of membranes and membrane proteins.

Regulatory Role of an Interdomain Linker in the Bacterial Chemotaxis Histidine Kinase CheA

The histidine kinase CheA plays a central role in signal integration, conversion, and amplification in the bacterial chemotaxis signal transduction pathway. The kinase activity is regulated in chemotaxis signaling complexes formed via the interactions among CheA's regulatory domain (P5), the coupling protein CheW, and transmembrane chemoreceptors. Despite recent advancements in the understanding of the architecture of the signaling complex, the molecular mechanism underlying this regulation remains elusive. An interdomain linker that connects the catalytic (P4) and regulatory domains of CheA may mediate regulatory signals from the P5-CheW-receptor interactions to the catalytic domain. To investigate whether this interdomain linker is capable of both activating and inhibiting CheA, we performed in vivo screens to search for P4-P5 linker mutations that result in different CheA autokinase activities. Several CheA variants were identified with kinase activities ranging from 30% to 670% of the activity of wild-type CheA. All of these CheA variants were defective in receptor-mediated kinase activation, indicating that the natural receptor-mediated signal transmission pathway was simultaneously affected by these mutations. The altered P4-P5 linkers were sufficient for making significant changes in the kinase activity even in the absence of the P5 domain. Therefore, the interdomain linker is an active module that has the ability to impose regulatory effects on the catalytic activity of the P4 domain. These results suggest that chemoreceptors may manipulate the conformation of the P4-P5 linker to achieve CheA regulation in the platform of the signaling complex.IMPORTANCE The molecular mechanism underlying kinase regulation in bacterial chemotaxis signaling complexes formed by the regulatory domain of the histidine kinase CheA, the coupling protein CheW, and chemoreceptors is still unknown. We isolated and characterized mutations in the interdomain linker that connects the catalytic and regulatory domains of CheA and found that the linker mutations resulted in different CheA autokinase activities in the absence and presence of the regulatory domain as well as a defect in receptor-mediated kinase activation. These results demonstrate that the interdomain linker is an active module that has the ability to impose regulatory effects on CheA activity. Chemoreceptors may manipulate the conformation of this interdomain linker to achieve CheA regulation in the platform of the signaling complex.

Structural and enzymatic insights into the ATP binding and autophosphorylation mechanism of a sensor histidine kinase

DesK is a sensor histidine kinase (HK) that allows Bacillus subtilis to respond to cold shock, triggering the adaptation of membrane fluidity via transcriptional control of a fatty acid desaturase. It belongs to the HK family HPK7, which includes the nitrogen metabolism regulators NarX/Q and the antibiotic sensor LiaS among other important sensor kinases. Structural information on different HK families is still scarce and several questions remain, particularly concerning the molecular features that determine HK specificity during its catalytic autophosphorylation and subsequent response-regulator phosphotransfer reactions. To analyze the ATP-binding features of HPK7 HKs and dissect their mechanism of autophosphorylation at the molecular level, we have studied DesK in complex with ATP using high resolution structural approaches in combination with biochemical studies. We report the first crystal structure of an HK in complex with its natural nucleotidic substrate. The general fold of the ATP-binding domain of DesK is conserved, compared with well studied members of other families. Yet, DesK displays a far more compact structure at the ATP-binding pocket: the ATP lid loop is much shorter with no secondary structural organization and becomes ordered upon ATP loading. Sequence conservation mapping onto the molecular surface, semi-flexible protein-protein docking simulations, and structure-based point mutagenesis allow us to propose a specific domain-domain geometry during autophosphorylation catalysis. Supporting our hypotheses, we have been able to trap an autophosphorylating intermediate state, by protein engineering at the predicted domain-domain interaction surface.

The CheZ binding interface of CheAS is located in alpha-helix E

Specific CheA-short (CheA(S)) residues, L123 and L126, were identified as critical for CheZ binding. In the CheA(S) 'P1-CheZ nuclear magnetic resonance structure, these residues form an interaction surface on alpha-helix E in the 'P1 domain. Both L123 and L126 are buried in CheA-long (CheA(L)), providing an explanation for why CheA(L) fails to bind CheZ.

Dynamic mechanism for the autophosphorylation of CheA histidine kinase: molecular dynamics simulations

The two-component system (TCS) is an important signal transduction component for most bacteria. This signaling pathway is mediated by histidine kinases via autophosphorylation between P1 and P4 domains. Taking chemotaxis protein CheA as a model of TCS, the autophosphorylation mechanism of the TCS histidine kinases has been investigated in this study by using a computational approach integrated homology modeling, ligand-protein docking, protein-protein docking, and molecular dynamics (MD) simulations. Four nanosecond-scale MD simulations were performed on the free P4 domain, P4-ATP, P4-TNPATP, and P1-P4-ATP complexes, respectively. Upon its binding to the binding pocket of P4 with a folded conformation, ATP gradually extends to an open state with help from a water molecule. Meanwhile, ATP forms two hydrogen bonds with His413 and Lys494 at this state. Because of the lower energy of the folded conformations, ATP shrinks back to its folded conformations, leading to the rupture of the hydrogen bond between ATP and Lys494. Consequently, Lys494 moves away from the pocket entrance, resulting in an open of the ATP lid of P4. It is the open state of P4 that can bind tightly to P1, where the His45 of P1 occupies a favorable position for its autophosphorylation from ATP. This indicates that ATP is not only a phosphoryl group donor but also an activator for CheA phosphorylation. Accordingly, a mechanism of the autophosphorylation of CheA is proposed as that the ATP conformational switch triggers the opening of the ATP lid of P4, leading to P1 binding tightly, and subsequently autophosphorylation from ATP to P1.

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.

A cytoplasmic coiled-coil domain is required for histidine kinase activity of the yeast osmosensor, SLN1

The yeast histidine kinase, Sln1p, is a plasma membrane-associated osmosensor that regulates the activity of the osmotic stress MAP kinase pathway. Changes in the osmotic environment of the cell influence the autokinase activity of the cytoplasmic kinase domain of Sln1p. Neither the nature of the stimulus, the mechanism by which the osmotic signal is transduced nor the manner in which the kinase is regulated is currently clear. We have identified several mutations located in the linker region of the Sln1 kinase (just upstream of the kinase domain) that cause hyperactivity of the Sln1 kinase. This region of histidine kinases is largely uncharacterized, but its location between the transmembrane domains and the cytoplasmic kinase domain suggests that it may have a potential role in signal transduction. In this study, we have investigated the Sln1 linker region in order to understand its function in signal transduction and regulation of Sln1 kinase activity. Our results indicate that the linker region forms a coiled-coil structure and suggest a mechanism by which alterations induced by osmotic stress influence kinase activity by altering the alignment of the phospho-accepting histidine with respect to the catalytic domain of the kinase.

Active site mutations in CheA, the signal-transducing protein kinase of the chemotaxis system in Escherichia coli

We investigated the functional roles of putative active site residues in Escherichia coli CheA by generating nine site-directed mutants, purifying the mutant proteins, and quantifying the effects of those mutations on autokinase activity and binding affinity for ATP. We designed these mutations to alter key positions in sequence motifs conserved in the protein histidine kinase family, including the N box (H376 and N380), the G1 box (D420 and G422), the F box (F455 and F459), the G2 box (G470, G472, and G474), and the "GT block" (T499), a motif identified by comparison of CheA to members of the GHL family of ATPases. Four of the mutant CheA proteins exhibited no detectable autokinase activity (Kin(-)). Of these, three (N380D, D420N, and G422A) exhibited moderate decreases in their affinities for ATP in the presence or absence of Mg(2+). The other Kin(-) mutant (G470A/G472A/G474A) exhibited wild-type affinity for ATP in the absence of Mg(2+), but reduced affinity (relative to that of wild-type CheA) in the presence of Mg(2+). The other five mutants (Kin(+)) autophosphorylated at rates slower than that exhibited by wild-type CheA. Of these, three mutants (H376Q, D420E, and F455Y/F459Y) exhibited severely reduced k(cat) values, but preserved K(M)(ATP) and K(d)(ATP) values close to those of wild-type CheA. Two mutants (T499S and T499A) exhibited only small effects on k(cat) and K(M)(ATP). Overall, these results suggest that conserved residues in the N box, G1 box, G2 box, and F box contribute to the ATP binding site and autokinase active site in CheA, while the GT block makes little, if any, contribution. We discuss the effects of specific mutations in relation to the three-dimensional structure of CheA and to binding interactions that contribute to the stability of the complex between CheA and Mg(2+)-bound ATP in both the ground state and the transition state for the CheA autophosphorylation reaction.

Histidine kinases and two-component signal transduction systems

The phosphorylation of histidine is the first step in many signal transduction cascades in bacteria, yeast and higher plants. The transfer of a very reactive phosphoryl group from phosphorylated histidine kinase to an acceptor is an essential step in many cellular signaling responses.

TNP-ATP and TNP-ADP as probes of the nucleotide binding site of CheA, the histidine protein kinase in the chemotaxis signal transduction pathway of Escherichia coli

The interaction of CheA with ATP has important consequences in the chemotaxis signal transduction pathway of Escherichia coli. This interaction results in autophosphorylation of CheA, a histidine protein kinase. Autophosphorylation of CheA sets in motion a chain of biochemical events that enables the chemotaxis receptor proteins to communicate with the flagellar motors. As a result of this communication, CheA allows the receptors to control the cell swimming pattern in response to gradients of attractant and repellent chemicals. To probe CheA interactions with ATP, we investigated the interaction of CheA with the fluorescent nucleotide analogues TNP-ATP [2'(3')-O-(2,4,6-trinitrophenyl)adenosine 5'-triphosphate] and TNP-ADP. Spectroscopic studies indicated that CheA bound TNP-ATP and TNP-ADP with high affinity (micromolar Kd values) and caused a marked enhancement of the fluorescence of the TNP moiety of these modified nucleotides. Analysis of titration experiments indicated a binding stoichiometry of two molecules of TNP-ATP (TNP-ADP) per CheA dimer and suggested that the two binding sites on the CheA dimer operate independently. Binding of TNP-ATP to CheA was inhibited by ATP, and analysis of this inhibition indicated that the CheA dimer binds 2 molecules of ATP. Competition experiments also indicated that CheA binds TNP-ATP considerably more tightly than it binds unmodified ATP. Binding of TNP-ADP to CheA was inhibited by ADP in a similar manner. TNP-ATP was not a substrate for CheA and served as a potent inhibitor of CheA autophosphorylation (Ki < 1 microM). The glycine-rich regions (G1 and G2) of CheA and other histidine protein kinases have been presumed to play important roles in ATP binding and/or catalysis of CheA autophosphorylation, although few experimental tests of these functional assignments have been made. Here, we demonstrate that a CheA mutant protein with Gly-->Ala substitutions in G1 and G2 has a markedly reduced affinity for ATP and ADP, as measured by Hummel-Dreyer chromatography. This mutant protein also bound TNP-ATP and TNP-ADP very poorly and had no detectable autokinase activity. Surprisingly, a distinct single-site substitution in G2 (Gly470-->Lys) had no observable effect on the affinity of CheA for ATP and ADP, despite the fact that it rendered CheA completely inactive as an autokinase. This mutant protein also bound TNP-ATP and TNP-ADP with affinities and stoichiometries that were indistinguishable from those observed with wild-type CheA. These results provide some preliminary insight into the possible functional roles of G1 and G2, and they suggest that TNP-nucleotides are useful tools for exploring the effects of additional mutations on the active site of CheA.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Mutational analysis of the linker region of EnvZ, an osmosensor in Escherichia coli

EnvZ, a transmembrane signal transducer, is composed of a periplasmic sensor domain, transmembrane domains, and a cytoplasmic signaling domain. Between the second transmembrane domain and the cytoplasmic signaling domain there is a linker domain consisting of approximately 50 residues. In this study, we investigated the functional role of the EnvZ linker domain with respect to signal transduction. Amino acid sequence alignment of linker regions among various bacterial signal transducer proteins does not show a high sequence identity but suggests a common helix 1-loop-helix 2 structure. Among several mutations introduced in the EnvZ linker region, it was found that hydrophobic-to-charged amino acid substitutions in helix 1 and helix 2 and deletions in helix 1, loop, and helix 2 (delta14, delta8, and delta7) resulted in constitutive OmpC expression. In the linker mutant EnvZ x delta7, both kinase and phosphatase activities were significantly reduced but the ratio of kinase to phosphatase activity increased, consistent with the constitutive OmpC expression. In contrast, the purified cytoplasmic fragment of EnvZ x delta7 possessed both kinase and phosphatase activities at levels similar to those of the cytoplasmic fragment of wild-type EnvZ. In addition, the linker mutations had no direct effect on EnvZ C-terminal dimerization. These results together with previous data suggest that the linker region is not directly involved in EnvZ enzymatic activities and that it may have a crucial role in propagating a conformational change to ensure correct positioning of two EnvZ molecules within a dimer during the transmembrane signaling.

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.

Active site interference and asymmetric activation in the chemotaxis protein histidine kinase CheA

The histidine protein kinase CheA is a multidomain protein that mediates stimulus-response coupling in bacterial chemotaxis. We have previously shown that the purified protein exhibits an equilibrium between inactive monomer and active dimer (Surette, M., Levit, M., Liu, Y., Lukat, G., Ninfa, E., Ninfa, A., and Stock, J. (1996) J. Biol. Chem. 271, 939-945). We report here a study of the kinetics of phosphorylation of the isolated phosphoacceptor domain of CheA catalyzed by the isolated catalytic domain of the protein. The reaction fits Michaelis-Menten kinetics (Km = 0.26 mM for ATP and 0. 10 mM for phosphoacceptor domain; kobs = 17 min-1). The catalytic domain exhibits the same equilibrium between inactive monomers and active dimers as the full-length CheA protein. Thus, CheA dimerization is an intrinsic property of this domain, independent of any other portion of the molecule and is required for its catalytic activity. In equimolar mixtures of full-length CheA and catalytic domain, homodimers and heterodimers are formed in equal concentration, indicating that all of the determinants for the dimerization are localized entirely on the catalytic domain. An analysis of the kinetics of phosphorylation catalyzed by CheA-catalytic domain heterodimers indicates half of the sites reactivity. The rate of CheA phosphorylation within this heterodimer is over 5-fold greater than that observed in CheA homodimers. The dramatic increase in activity within this asymmetric dimer raises the possibility that CheA activation by receptors involves a mechanism that directs catalysis to one active site while preventing interference from the other.

Modular structure of the Rhizobium meliloti DctB protein

To investigate the modular structure of the Rhizobium meliloti dicarboxylic acid sensor protein, DctB, three truncated DctB proteins (DctB4, DctB5 and DctB4G) were constructed, overproduced in Escherichia coli and purified. The DctB4G protein was composed of 446 amino acids of the DctB C-terminus and displayed strong autophosphorylation activity in vitro. This activity was sustained when a further 120 amino acids at the N-terminus of the polypeptide were deleted (DctB5). This protein which has an intact transmitter domain exhibits specific but inefficient phospho-transfer capabilities. Removal of 58 amino acids from the DctB4G C-terminus which included blocks F and G2 of the transmitter domain, rendered the resultant protein (DctB4) incompetent in autophosphorylation. Phosphorylation activity was restored to DctB4 through intramolecular complementation with DctB. Therefore, it would appear that the R. meliloti DctB protein is active as a dimer (or higher order oligomer). Furthermore, the intramolecular complementation experiments indicate that the amino acids 171-291, a predicted periplasmic stretch, play an important role in the dimerization process.

Bacterial chemotaxis: a field in motion

Many different types of studies are being combined to provide an increasingly detailed picture of the bacterial chemotaxis system. The structures of periplasmic receptors and a cytoplasmic response regulator, along with structures of domains of a membrane receptor, a receptor-modifying enzyme and a cytoplasmic histidine kinase, have been determined. These structures provide a basis for other work which is likely to open up new structural avenues.