Function of the conserved FHIPEP domain of the flagellar type III export apparatus,protein FlhA

The Type III flagellar protein export apparatus of bacteria consists of five or six membrane proteins, notably FlhA, which controls the export of other proteins and is homologous to the large family of FHIPEP export proteins. FHIPEP proteins contain a highly‐conserved cytoplasmic domain. We mutagenized the cloned Salmonella flhA gene for the 692 amino acid FlhA, changing a single, conserved amino acid in the 68‐amino acid FHIPEP region. Fifty‐two mutations at 30 positions mostly led to loss of motility and total disappearance of microscopically visible flagella, also Western blot protein/protein hybridization showed no detectable export of hook protein and flagellin. There were two exceptions: a D199A mutant strain, which produced short‐stubby flagella; and a V151L mutant strain, which did not produce flagella and excreted mainly un‐polymerized hook protein. The V151L mutant strain also exported a reduced amount of hook‐cap protein FlgD, but when grown with exogenous FlgD it produced polyhooks and polyhook‐filaments. A suppressor mutant in the cytoplasmic domain of the export apparatus membrane protein FlhB rescued export of hook‐length control protein FliK and facilitated growth of full‐length flagella. These results suggested that the FHIPEP region is part of the gate regulating substrate entry into the export apparatus pore.     

Interaction of FliK with the bacterial flagellar hook is required for efficient export specificity switching

FliK–FlhB interaction switches export specificity of the bacterial flagellar protein export apparatus to stop hook protein export at an appropriate timing for hook length control. The hook structure is required for the productive FliK–FlhB interaction to flip the switch but it remains unknown how it works. Here, we characterize the role of FliK in the switching probability in the absence of the hook. When RflH/Flk was missing in the hook mutants, the switching occurred at a low probability. Overproduction of FliK significantly increased the switching probability although not at the wild-type level. An in-frame deletion of residues 129 through 159 of FliK weakened the interaction with the hook protein but not with the hook-capping protein, producing polyhooks with filaments attached. We suggest that temporary association of FliK with the inner surface of the hook during FliK secretion results in a pause in the secretion process to allow the C-terminal switch domain of FliK to be positioned and appropriately oriented near FlhB for catalysing the switch and that RflH/Flk interferes with premature switch by preventing access of cytoplasmic FliK to FlhB and even that of FliK during its secretion until hook length reaches 55 nm; only then FliK_C passes the RflH/Flk block.     

N-terminal signal region of FliK is dispensable for length control of the flagellar hook

The length of the flagellar hook is regulated; it is 55 +/- 6 nm long in Salmonella. Five genes involved in hook-length regulation are fliK, flhB, fliG, fliM and fliN. The last four genes encode structural components of the protein export apparatus in the flagellar base, whereas FliK is soluble and secreted during flagellar assembly. The role of FliK, however, remains ambiguous. We constructed two kinds of FliK variants: N-terminally truncated FliK protein and FliK N-terminally fused with cyan fluorescent protein (CFP-FliK). Both N-terminally truncated FliK missing the first 99 amino acids (aa) and CFP-FliK fusion variants partially complemented a fliK null (polyhook) mutant to produce cells with filaments, allowing cells to swim; the hooks, however, were not normal but were polyhooks. When the N-terminally defective FliK variants were expressed at high levels, the average polyhook length was shortened coming close to the length of the wild-type hook, independently of the sizes of the FliK variants. These FliK variants were not secreted. CFP-FliK fusion proteins were observed to homogeneously distribute in the cytoplasm. We conclude that FliK does not need to be exported to control hook length and is unlikely to be a ruler; instead, we conclude that FliK controls hook length by the timely switching of secretion modes of the flagellar type III secretion system by the FliK C-terminal domain, and that the N-terminal region is dispensable for hook length control.     

The type III flagellar export specificity switch is dependent on FliK ruler and a molecular clock

Salmonella flagellar hook length is controlled at the level of export substrate specificity of the FlhB component of the type III flagellar export apparatus. FliK is believed to be the hook length sensor and interacts with FlhB to change its export specificity upon hook completion. To find properties of FliK expected of such a molecular ruler, we assayed binding of FliK to the hook and found that the N-terminal domain of FliK (FliK(N)) bound to the hook-capping protein FlgD with high affinity and to the hook protein FlgE with low affinity. To investigate a possible role of FlgE in hook length control, flgE mutants with partially impaired motility were isolated and analyzed. Eight flgE mutants obtained all formed flagellar filaments. The mutants produced significantly shorter hooks while the hook-type substrates such as FlgE, FliK and FlgD were secreted in large amounts, suggesting defective hook assembly with the mutant FlgE proteins. Upon overexpression, mutant FlgEs produced hooks of normal length and wild-type FlgE produced longer hooks. These results suggest that hook length is dependent on the hook polymerization rate and that the start of hook polymerization initiates a "time countdown" for the specificity switch to occur or for significant slow down of rod/hook-type export after hook length reaches around 55 nm for later infrequent FliK(C)-FlhB(C) interaction. We propose that FliK(N) acts as a flexible tape measure, but that hook length is also dependent on the hook elongation rate and a switch timing mechanism.     

FliK, the protein responsible for flagellar hook length control in Salmonella, is exported during hook assembly

In wild-type Salmonella, the length of the flagellar hook, a structure consisting of subunits of the hook protein FlgE, is fairly tightly controlled at approximately 55 nm. Because fliK mutants produce abnormally elongated hook structures that lack the filament structure, FliK appears to be involved in both the termination of hook elongation and the initiation of filament formation. FliK, a soluble protein, is believed to function together with a membrane protein, FlhB, of the export apparatus to mediate the switching of export substrate specificity (from hook protein to flagellin) upon completion of hook assembly. We have examined the location of FliK during flagellar morphogenesis. FliK was found in the culture supernatants from the wild-type strain and from flgD (hook capping protein), flgE (hook protein) and flgK (hook-filament junction protein) mutants, but not in that from a flgB (rod protein) mutant. The amount of FliK in the culture supernatant from the flgE mutant was much higher than in that from the flgK mutant, indicating that FliK is most efficiently exported prior to the completion of hook assembly. Export was impaired by deletions within the N-terminal region of FliK, but not by C-terminal truncations. A decrease in the level of exported FliK resulted in elongated hook structures, sometimes with filaments attached. Our results suggest that the export of FliK during hook assembly is important for hook-length control and the switching of export substrate specificity.     

The FliK protein and flagellar hook-length control

The bacterial flagellum is a highly complex prokaryotic organelle. It is the motor that drives bacterial motility, and despite the large amount of energy required to make and operate flagella, motile organisms have a strong adaptive advantage. Flagellar biogenesis is both complex and highly coordinated and it typically involves at least three two-component systems. Part of the flagellum is a type III secretion system, and it is via this structure that flagellar components are exported. The assembly of a flagellum occurs in a number of stages, and the "checkpoint control" protein FliK functions in this process by detecting when the flagellar hook substructure has reached its optimal length. FliK then terminates hook export and assembly and transmits a signal to begin filament export, the final stage in flagellar biosynthesis. As yet the exact mechanism of how FliK achieves this is not known. Here we review what is known of the FliK protein and discuss the evidence for and against the various hypotheses that have been proposed in recent years to explain how FliK controls hook length, FliK as a molecular ruler, the measuring cup theory, the role of the FliK N terminus, the infrequent molecular ruler theory, and the molecular clock theory.     

Kinetic analysis of the growth rate of the flagellar hook in Salmonella typhimurium by the population balance method.

The growth rate of flagellar hooks in Salmonella typhimurium was analyzed by computer-aided simulation of the length distributions of mutant hooks of uncontrolled length (polyhooks). The wild-type hook has a relatively well-controlled length, with an average of 55 nm and a standard deviation of 6 nm. Mutations in the fliK gene give rise to polyhooks. A histogram of the lengths of polyhooks from a fliK mutant shows a peak at 55 nm with a long monotonic tail extending out to 1 microm. To analyze the growth rate, we employed the population balance method. Regression analysis showed that the histogram could fit a combination of two theoretical curves. In the first phase of growth, the hook starts with a very fast growth rate (40 nm/min), and then the rate exponentially slows until the length reaches 55 nm. In the second phase of growth, where the hook length is over 55 nm, the hook grows at a constant rate of 8 nm/min. Second mutations in either the fliK or flhB genes, as found in pseudorevertants from fliK mutants, give rise to polyhook filaments (phf). The ratio between the numbers of hooks with and without filament was 6:4. The calculated probability of filament attachment to polyhooks was low so that the proportion of hooks that start filament growth was only 2% per minute. The lengths of polyhooks with and without filaments were measured. A histogram of hook length in phf's was the same as that for polyhooks in single-site fliK mutants, against the expectation that the distribution would shift to a shorter average. The role of FliK in hook length control is discussed.     

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.     

Domain organization and function of Salmonella FliK, a flagellar hook-length control protein

Salmonella hook-length control protein FliK, which consists of 405 amino acid residues, switches substrate specificity of the type III flagellar protein export apparatus from rod/ hook-type to filament-type by causing a conformational change in the cytoplasmic domain of FlhB (FlhB(C)) upon completion of the hook assembly. An N-terminal region of FliK contains an export signal, and a highly conserved C-terminal region consisting of amino acid residues 265-405 (FliK((265-405))) is directly involved in the switching of FlhB(C). Here, we have investigated the structural properties of FliK. Gel filtration chromatography, multi-angle light scattering and analytical ultracentrifugation showed that FliK is monomeric in solution and has an elongated shape. Limited proteolysis showed that FliK consists of two domains, the N-terminal (FliK(N)) and C-terminal domains (FliK(C)), and that the first 203 and the last 35 amino acid residues are partially unfolded and subjected to proteolysis. Both FliK(N) and FliK(C) are more globular than full-length FliK, suggesting that these domains are connected in tandem. Overproduced His-FliK((199-405)) failed to switch export specificity of the export apparatus. Affinity blotting revealed that FlhB(C) binds to FliK and FliK((1-147)), but not to FliK((265-405)). Based on these results, we propose that FliK(N) within the central channel of the hook-basal body during the export of FliK is the sensor and transmitter of hook completion information and that the binding interaction of FliK(C) to FlhB(C) is structurally regulated by FliK(N) so as to occur only when the hook has reached a preset length. The conformational flexibility of FliK(C) may play a role in interfering with switching at an inappropriate point of flagellar assembly.     

Roles of FliK and FlhB in determination of flagellar hook length in Salmonella typhimurium.

The length of flagellar hooks isolated from wild-type and mutant cells with various hook lengths were measured on electron micrographs. The length of the wild-type hook showed a narrow distribution with a peak (+/- standard deviation) at 55.0 +/- 5.9 nm, whereas fliK mutants (so-called polyhook mutants) showed a broad distribution of hook lengths ranging from 40 to 900 nm, strongly indicating that FliK is involved in hook length determination. Among pseudorevertants isolated from such polyhook mutants, fliK intragenic suppressors gave rise to polyhook filaments. However, intergenic suppressors mapping to flhB also gave rise to hooks of abnormal length, albeit they were much shorter than polyhooks. Furthermore, double mutations of flhB and flgK (the structural gene for hook-associated protein 1; HAP1) resulted in polyhooks, suggesting another way in which hook length can be affected. The roles of FliK, FlhB, and HAP1 in hook length determination are discussed.     

Effect of Hook Subunit Concentration on Assembly and Control of Length of the Flagellar Hook of Salmonella

The flagellar hook of Salmonella is a filamentous polymer made up of subunits of the protein FlgE. Hook assembly is terminated when the length reaches about 55 nm. After our recent study of the effect of cellular levels of the hook length control protein FliK, we have now analyzed the effect of cellular levels of FlgE itself. When FlgE was overproduced in a wild-type strain, a fliC (flagellin) mutant, or a fliD (hook-associated protein 2 [HAP2], filament capping protein) mutant, the hooks remained at the wild-type length. In a fliK (hook length control protein) mutant, which produces long hooks (polyhooks), the overproduction of FlgE resulted in extraordinarily long hooks (superpolyhooks). In a flgK (HAP1, first hook-filament junction protein) mutant or a flgL (HAP3, second hook-filament junction protein) mutant, the overproduction of FlgE also resulted in longer than normal hooks. Thus, at elevated hook protein levels not only FliK but also FlgK and FlgL are necessary for the proper termination of hook elongation. When FlgE was severely underproduced, basal bodies without hooks were often observed. However, those hooks that were seen were of wild-type length, demonstrating that FlgE underproduction decreases the probability of the initiation of hook assembly but not the extent of hook elongation.     

The NMR structure of FliK, the trigger for the switch of substrate specificity in the flagellar type III secretion apparatus

The flagellar cytoplasmic protein FliK controls hook elongation by two successive events: by determining hook length and by stopping the supply of hook protein. These two distinct roles are assigned to different parts of FliK: the N-terminal half (FliK_N) determines length and the C-terminal half (FliK_C) switches secretion from the hook protein to the filament protein. The interaction of FliK_C with FlhB, the switchable secretion gate, triggers the switch. By NMR spectroscopy, we demonstrated that FliK is largely unstructured and determined the structure of a compact domain in FliK_C. The compact domain, denoted the FliK_C core domain, consists of two α-helices, a β-sheet with two parallel and two antiparallel strands, and several exposed loops. Based on the functional data obtained by a series of deletion mutants of the FliK_C core domain, we constructed a model of the complex between the FliK_C core domain and FlhB_C. The model suggested that one of the FliK_C loops has a high probability of interacting with the C-terminal domain of FlhB (FlhB_C) as the FliK molecule enters the secretion gate. We suggest that the autocleaved NPTH sequence in FlhB contacts loop 2 of FliK_C to trigger the switching event. This contact is sterically prevented when NPTH is not cleaved. Thus, the structure of FliK provides insight into the mechanism by which this bifunctional protein triggers a switch in the export of substrates.     

Mutations in fliK and flhB affecting flagellar hook and filament assembly in Salmonella typhimurium.

Mutations in the fliK gene of Salmonella typhimurium commonly cause failure to terminate hook assembly and initiate filament assembly (polyhook phenotype). Polyhook mutants give rise to pseudorevertants which are still defective in hook termination but have recovered the ability to assemble filament (polyhook-filament phenotype). The polyhook mutations have been found to be either frameshift or nonsense, resulting in truncation of the C terminus of FliK. Intragenic suppressors of frameshift mutations were found to be ones that restored the original frame (and therefore the C-terminal sequence), but in most cases with substantial loss of natural sequence and sometimes the introduction of artificial sequence; in no cases did intragenic suppression occur when significant disruption remained within the C-terminal region. By use of a novel PCR protocol, in-frame deletions affecting the N-terminal and central regions of FliK were constructed and the resulting phenotypes were examined. Small deletions resulted in almost normal hook length control and almost wild-type swarming. Larger deletions resulted in loss of control of hook length and poor swarming. The largest deletions severely affected filament assembly as well as hook length control. Extragenic suppressors map to an unlinked gene, flhB, which encodes an integral membrane protein (T. Hirano, S. Yamaguchi, K. Oosawa, and S.-I. Aizawa, J. Bacteriol. 176:5439-5449, 1994; K. Kutsukake, T. Minamino, and T. Yokoseki, J. Bacteriol. 176:7625-7629, 1994). They were either point mutations in the C-terminal cytoplasmic region of FlhB or frameshift or nonsense mutations close to the C terminus. The processes of hook and filament assembly and the roles of FliK and FlhB in these processes are discussed in light of these and other available data. We suggest that FliK measures hook length and, at the appropriate point, sends a signal to FlhB to switch the substrate specificity of export from hook protein to late proteins such as flagellin.     

Isolation and characterization of FliK-independent flagellation mutants from Salmonella typhimurium.

A flagellum of Salmonella typhimurium and Escherichia coli consists of three structural parts, a basal body, a hook, and a filament. Because the fliK mutants produce elongated hooks, called polyhooks, lacking filament portions, the fliK gene product has been believed to be involved in both the determination of hook length and the initiation of the filament assembly. In the present study, we isolated two mutants from S. typhimurium which can form flagella even in the absence of the fliK gene product. Flagellar structures were fractionated from these suppressor mutants and inspected by electron microscopy. The suppressor mutants produced polyhook-filament complexes in the fliK mutant background, while they formed flagellar structures apparently indistinguishable from those of the wild-type strain in the fliK+ background. Genetic and sequence analyses of the suppressor mutations revealed that they are located near the 3'-end of the flhB gene, which has been believed to be involved in the early process of the basal body assembly. On the basis of these results, we discuss the mechanism of suppression of the fliK defects by the flhB mutations and propose a hypothesis on the export switching machinery of the flagellar proteins.     

Three genes of a motility operon and their role in flagellar rotary speed variation in Rhizobium meliloti.

The peritrichous flagella of Rhizobium meliloti rotate only clockwise and control directional changes of swimming cells by modulating flagellar rotary speed. Using Tn5 insertions, we have identified and sequenced a motility (mot) operon containing three genes, motB, motC, and motD, that are translationally coupled. The motB gene (and an unlinked motA) has been assigned by similarity to the Escherichia coli and Bacillus subtilis homologs, whereas motC and motD are new and without known precedents in other bacteria. In-frame deletions introduced in motB, motC, or motD each result in paralysis. MotD function was fully restored by complementation with the wild-type motD gene. By contrast, deletions in motB or motC required the native combination of motB and motC in trans for restoring normal flagellar rotation, whereas complementation with motB or motC alone led to uncoordinated (jiggly) swimming. Similarly, a motB-motC gene fusion and a Tn5 insertion intervening between motB and motC resulted in jiggly swimming as a consequence of large fluctuations in flagellar rotary speed. We conclude that MotC biosynthesis requires coordinate expression of motB and motC and balanced amounts of the two gene products. The MotC polypeptide contains an N-terminal signal sequence for export, and Western blots have confirmed its location in the periplasm of the R. meliloti cell. A working model suggests that interactions between MotB and MotC at the periplasmic surface of the motor control the energy flux or the energy coupling that drives flagellar rotation.     

Interactions among components of the Salmonella flagellar export apparatus and its substrates

We have examined the cytoplasmic components (FliH, FliI and FliJ) of the type III flagellar protein export apparatus, plus the cytoplasmic domains (FlhAC and FlhBC) of two of its six membrane components. FliH, FlhAC and FliJ, when overproduced, caused inhibition of motility of wild-type cells and inhibition of the export of substrates such as the hook protein FlgE. Co-overproduction of FliH and FliI substantially relieved the inhibition caused by FliH, suggesting that it is excess free FliH that is inhibitory and that FliH and FliI form a complex. We purified His-FLAG-tagged versions of: (i) export components FliH, FliI, FliJ, FlhAC and FlhBC; (ii) rod/hook-type export substrates FlgB (rod protein), FlgE (hook protein), FlgD (hook capping protein) and FliE (basal body protein); and (iii) filament-type export substrates FlgK and FlgL (hook-filament junction proteins) and FliC (flagellin). We tested for protein-protein interactions by affinity blotting. In many cases, a given protein interacted with more than one other component, indicating that there are likely to be multiple dynamic interactions or interactions that involve more than two components. Interactions of FlhBC with rod/hook-type substrates were strong, whereas those with filament-type substrates were very weak; this may reflect the role of FlhB in substrate specificity switching. We propose a model for the flagellar export apparatus in which FlhA and FlhB and the other four integral membrane proteins of the apparatus form a complex at the base of the flagellar motor. A soluble complex of at least three proteins (FliH, FliI and FliJ) bind the protein to be exported and then interact with the complex at the motor to deliver the protein, which is then exported in an ATP-dependent process mediated by FliI.     

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.     

Domain structure of Salmonella FlhB, a flagellar export component responsible for substrate specificity switching

We have investigated the properties of the cytoplasmic domain (FlhB(C)) of the 383-amino-acid Salmonella membrane protein FlhB, a component of the type III flagellar export apparatus. FlhB, along with the hook-length control protein FliK, mediates the switching of export specificity from rod- and hook-type substrates to filament-type substrates during flagellar morphogenesis. Wild-type FlhB(C) was unstable (half-life, ca. 5 min), being specifically cleaved at Pro-270 into two polypeptides, FlhB(CN) and FlhB(CC), which retained the ability to interact with each other after cleavage. Full-length wild-type FlhB was also subject to cleavage. Coproduction of the cleavage products, FlhB(delta CC) (i.e., the N-terminal transmembrane domain FlhB(TM) plus FlhB(CN)) and FlhB(CC), resulted in restoration of both motility and flagellar protein export to an flhB mutant host, indicating that the two polypeptides were capable of productive association. Mutant FlhB proteins that can undergo switching of substrate specificity even in the absence of FliK were much more resistant to cleavage (half-lives, 20 to 60 min). The cleavage products of wild-type FlhB(C), existing as a FlhB(CN)-FlhB(CC) complex on an affinity blot membrane, bound the rod- and hook-type substrate FlgD more strongly than the filament-type substrate FliC. In contrast, the intact form of FlhB(C) (mutant or wild type) or the FlhB(CC) polypeptide alone bound FlgD and FliC to about the same extent. FlhB(CN) by itself did not bind substrates appreciably. We propose that FlhB(C) has two substrate specificity states and that a conformational change, mediated by the interaction between FlhB(CN) and FlhB(CC), is responsible for the specificity switching process. FliK itself is an export substrate; its binding properties for FlhB(C) resemble those of FlgD and do not provide any evidence for a physical interaction beyond that of the export process.     

The role of the FliK molecular ruler in hook‐length control in Salmonella enterica

A molecular ruler, FliK, controls the length of the flagellar hook. FliK measures hook length and catalyses the secretion‐substrate specificity switch from rod‐hook substrate specificity to late substrate secretion, which includes the filament subunits. Here, we show normal hook‐length control and filament assembly in the complete absence of the C‐ring thus refuting the previous ‘cup’ model for hook‐length control. Mutants of C‐ring components, which are reported to produce short hooks, show a reduced rate of hook–basal body assembly thereby allowing for a premature secretion‐substrate specificity switch. Unlike fliK null mutants, hook‐length control in an autocleavage‐defective mutant of flhB, the protein responsible for the switch to late substrate secretion, is completely abolished. FliK deletion variants that retain the ability to measure hook length are secreted thus demonstrating that FliK directly measures rod‐hook length during the secretion process. Finally, we present a unifying model accounting for all published data on hook‐length control in which FliK acts as a molecular ruler that takes measurements of rod‐hook length while being intermittently secreted during the assembly process of the hook–basal body complex.