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

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

Crystallographic snapshot of the Escherichia coli EnvZ histidine kinase in an active conformation

Sensor histidine kinases are important sensors of the extracellular environment and relay signals via conformational changes that trigger autophosphorylation of the kinase and subsequent phosphorylation of a response regulator. The exact mechanism and the regulation of this protein family are a matter of ongoing investigation. Here we present a crystal structure of a functional chimeric protein encompassing the entire catalytic part of the Escherichia coli EnvZ histidine kinase, fused to the HAMP domain of the Archaeoglobus fulgidus Af1503 receptor. The construct is thus equivalent to the full cytosolic part of EnvZ. The structure shows a putatively active conformation of the catalytic domain and gives insight into how this conformation could be brought about in response to sensory input. Our analysis suggests a sequential flip-flop autokinase mechanism.

Role of the Dc domain of the bacterial hook protein FlgE in hook assembly and function

The bacterial flagellar hook acts as a universal joint to smoothly transmit torque produced by the motor to the filament. The hook protein FlgE assembles into a 55 nm tubular structure with the help of the hook cap (FlgD). FlgE consists of four domains, D0, Dc, D1 and D2, arranged from the inner to the outer part of the tubular structure of the hook. The Dc domain contributes to the structural stability of the hook, but it is unclear how this Dc domain is responsible for the universal joint mechanism. Here, we carried out a deletion analysis of the FlgE Dc domain. FlgEΔ4/5 with deletion of residues 30 to 49 was not secreted into the culture media. FlgEΔ5 and FlgEΔ6 with deletions of residues 40 to 49 and 50 to 59, respectively, still formed hooks, allowing the export apparatus to export the hook-filament junction proteins FlgK and FlgL and flagellin FliC. However, these deletions inhibited the replacement of the FlgD hook cap by FlgK at the hook tip, thereby abolishing filament formation. Deletion of residues 50 to 59 significantly affected hook morphology. These results suggest that the Dc domain is responsible not only for hook assembly but also for FlgE export, the interaction with FlgK, and the polymorphic supercoiling mechanism of the hook.

Mechanism of regulation of receptor histidine kinases

Bacterial transmembrane receptors regulate an intracellular catalytic output in response to extracellular sensory input. To investigate the conformational changes that relay the regulatory signal, we have studied the HAMP domain, a ubiquitous intracellular module connecting input to output domains. HAMP forms a parallel, dimeric, four-helical coiled coil, and rational substitutions in our model domain (Af1503 HAMP) induce a transition in its interhelical packing, characterized by axial rotation of all four helices (the gearbox signaling model). We now illustrate how these conformational changes are propagated to a downstream domain by fusing Af1503 HAMP variants to the DHp domain of EnvZ, a bacterial histidine kinase. Structures of wild-type and mutant constructs are correlated with ligand response in vivo, clearly associating them with distinct signaling states. We propose that altered recognition of the catalytic domain by DHp, rather than a shift in position of the phospho-accepting histidine, forms the basis for regulation of kinase activity.

The mechanisms of HAMP-mediated signaling in transmembrane receptors

HAMP domains mediate signal transduction in over 7500 enzyme-coupled receptors represented in all kingdoms of life. The HAMP domain of the putative archaeal receptor Af1503 has a parallel, dimeric, four-helical coiled coil structure, but with unusual core packing, related to canonical packing by concerted axial rotation of the helices. This has led to the gearbox model for signal transduction, whereby the alternate packing modes correspond to signaling states. Here we present structures of a series of Af1503 HAMP variants. We show that substitution of a conserved small side chain within the domain core (A291) for larger residues induces a gradual transition in packing mode, involving both changes in helix rotation and bundle shape, which are most prominent at the C-terminal, output end of the domain. These are correlated with activity and ligand response in vitro and in vivo by incorporating Af1503 HAMP into mycobacterial adenylyl cyclase assay systems.

Flipping the switch: bringing order to flagellar assembly

The bacterial flagellum is a complex self-assembling nanomachine that contains its own type III protein export apparatus. Upon completion of early flagellar structure, this apparatus switches substrate specificity to export late structural subunits, thereby coupling sequential flagellar gene expression with flagellar assembly. The switch is achieved by a conformational change of the export apparatus component FlhB driven by the flagellar hook-length control protein FliK. Two basic models of FliK- and FlhB-based switching are currently being pursued, together with the investigation of another factor, Flk, which prevents premature export of late substrates. Here, we review in detail each of these three export switch components and present the current understanding of how they work in concert in the making of a flagellum.

Two parts of the T3S4 domain of the hook-length control protein FliK are essential for the substrate specificity switching of the flagellar type III export apparatus

The switch in export specificity of the type III flagellar protein export apparatus from rod/hook type to filament type is believed to occur upon completion of hook assembly by way of an interaction of the type III secretion substrate specificity switch (T3S4) domain of the hook-length control protein FliK, with the integral membrane export apparatus component FlhB. The T3S4 domain of FliK (FliKT3S4) consisting of amino acid residues 265-405 has an unstable and flexible conformation in its last 35 residues (FliKCT). To investigate the role of FliKT3S4 in substrate specificity switching, we studied the effect of deletions and point mutations within this domain and characterized suppressor mutations. Deletions of ten amino acid residues within the region of residues 301-350 and five amino acids of residues 401-405 abolished switching of export specificity. Site directed mutagenesis showed that highly conserved residues, Val302, Ile304, Leu335, Val401 and Ala405, are essential, and that the five C terminal residues (401-405) are restricted in conformation for the switching process. Suppressor mutant analysis of the fliK(S319Y) mutant, which produces extended hooks with filaments attached due to delayed switching, suggested that FliKT3S4 interacts with the C terminal half of the cytoplasmic domain of FlhB (FlhBC). We propose a two step binding model of FliKT3S4 and FlhBC, in which residues 301-350 of FliK bind to FlhBC upon hook assembly completion at about 55 nm, and then unfolded FliKCT binds to FlhBC to trigger the switch in substrate specificity.

FlhB Regulates Ordered Export of Flagellar Components via Autocleavage Mechanism

The bacterial flagellum is a predominantly cell-external super-macromolecular construction whose structural components are exported by a flagellum-specific export apparatus. One of the export apparatus proteins, FlhB, regulates the substrate specificity of the entire apparatus; i.e. it has a role in the ordered export of the two main groups of flagellar structural proteins such that the cell-proximal components (rod-/hook-type proteins) are exported before the cell-distal components (filament-type proteins). The controlled switch between these two export states is believed to be mediated by conformational changes in the structure of the C-terminal cytoplasmic domain of FlhB (FlhB(C)), which is consistently and specifically cleaved into two subdomains (FlhB(CN) and FlhB(CC)) that remain tightly associated with each other. The cleavage event has been shown to be physiologically significant for the switch. In this study, the mechanism of FlhB cleavage has been more directly analyzed. We demonstrate that cleavage occurs in a heterologous host, Saccharomyces cerevisiae, deficient in vacuolar proteinases A and B. In addition, we find that cleavage of a slow-cleaving variant, FlhB(C)(P270A), is stimulated in vitro at alkaline pH. We also show by analytical gel-filtration chromatography and analytical ultracentrifugation experiments that both FlhB(C) and FlhB(C)(P270A) are monomeric in solution, and therefore self-proteolysis is unlikely. Finally, we provide evidence via peptide analysis and FlhB cleavage variants that the tertiary structure of FlhB plays a significant role in cleavage. Based on these results, we propose that FlhB cleavage is an autocatalytic process.

Substrate specificity of type III flagellar protein export in Salmonella is controlled by subdomain interactions in FlhB

FlhB, an integral membrane protein, gates the type III flagellar export pathway of Salmonella. It permits export of rod/hook-type proteins before hook completion, whereupon it switches specificity to recognize filament-type proteins. The cytoplasmic C-terminal domain of FlhB (FlhBC) is cleaved between Asn-269 and Pro-270, defining two subdomains: FlhBCN and FlhBCC. Here, we show that subdomain interactions and cleavage within FlhB are central to substrate-specificity switching. We found that deletions between residues 216 and 240 of FlhBCN permitted FlhB cleavage but abolished function, whereas a deletion spanning Asn-269 and Pro-270 abolished both. The mutation N269A prevented cleavage at the FlhBCN-FlhBCC boundary. Cells producing FlhB(N269A) exported the same amounts of hook-capping protein as cells producing wild-type FlhB. However, they exported no flagellin, even when the fliC gene was being expressed from a foreign promoter to circumvent regulation of expression by FlgM, which is itself a filament-type substrate. Electron microscopy revealed that these cells assembled polyhook structures lacking filaments. Thus, FlhB(N269A) is locked in a conformation specific for rod/hook-type substrates. With FlhB(P270A), cleavage was reduced but not abolished, and cells producing this protein were weakly motile, exported reduced amounts of flagellin and assembled polyhook filaments.