Signaling Interactions between the Aerotaxis Transducer Aer and Heterologous Chemoreceptors in Escherichia coli

ABSTRACT Aer, a low-abundance signal transducer in Escherichia coli, mediates robust aerotactic behavior, possibly through interactions with methyl-accepting chemotaxis proteins (MCP). We obtained evidence for interactions between Aer and the high-abundance aspartate (Tar) and serine (Tsr) receptors. Aer molecules bearing a cysteine reporter diagnostic for trimer-of-dimer formation yielded cross-linking products upon treatment with a trifunctional maleimide reagent. Aer also formed mixed cross-linking products with a similarly marked Tar reporter. An Aer trimer contact mutation known to abolish trimer formation by MCPs eliminated Aer trimer and mixed trimer formation. Trimer contact alterations known to cause epistatic behavior in MCPs also produced epistatic properties in Aer. Amino acid replacements in the Tar trimer contact region suppressed an epistatic Aer signaling defect, consistent with compensatory conformational changes between directly interacting proteins. In cells lacking MCPs, Aer function required high-level expression, comparable to the aggregate number of receptors in a wild-type cell. Aer proteins with clockwise (CW)-biased signal output cannot function under these conditions but do so in the presence of MCPs, presumably through formation of mixed signaling teams. The Tar signaling domain was sufficient for functional rescue. Moreover, CW-biased lesions did not impair aerotactic signaling in a hybrid Aer-Tar transducer capable of adjusting its steady-state signal output via methylation-dependent sensory adaptation. Thus, MCPs most likely assist mutant Aer proteins to signal productively by forming collaborative signaling teams. Aer evidently evolved to operate collaboratively with high-abundance receptors but can also function without MCP assistance, provided that it can establish a suitable prestimulus swimming pattern.

Aer, an unorthodox member of the methyl-accepting chemotaxis protein (MCP) family of chemoreceptors, is the major oxygen-sensing transducer in Escherichia coli (5,19). Aer and the conventional MCPs share a highly conserved C-terminal signaling domain that forms a ternary complex with two cytoplasmic proteins, CheA, a histidine kinase, and CheW, which couples CheA activity to receptor control. CheA activity in turn modulates the phosphorylation state of the response regulator CheY, which controls the direction of rotation of the cell's flagellar motors. Orthodox MCPs have an N-terminal periplasmic ligand-binding domain that monitors chemoeffector levels and triggers changes in output activity of the signaling domain (10). Unlike MCPs, Aer has a cytoplasmic Nterminal sensing domain (PAS) that is thought to monitor environmental oxygen status through associated redox changes in a flavin adenine dinucleotide prosthetic group (25,26). Moreover, MCPs have two membrane-spanning segments that flank their sensing domain, whereas Aer is anchored to the inner side of the cytoplasmic membrane by a central hydrophobic hairpin (3). However, the most significant difference between Aer and the MCPs is their method of sensory adaptation. MCPs undergo reversible methylation at specific signaling domain sites to tune signal output to ambient chemoeffector levels. Aer, in contrast, is not methylated and does not require the MCP-specific methyltransferase (CheR) or methylesterase (CheB) to mediate aerotactic behavior (6).
E. coli has four MCPs: Tar (aspartate and maltose sensor) and Tsr (serine) comprise about 90% of the cell's receptor molecules, and Tap (dipeptides) and Trg (ribose and galactose), along with Aer, comprise the remainder (13). Receptor signaling complexes cluster at the cell pole(s) (15,22) and appear to form an interconnected array with cooperative, highgain signaling properties (17,21). Trimers of receptor homodimers, first observed in the crystal structure of the Tsr signaling domain (11), may be an important structure/function component of these signaling arrays (2,17,23). The four MCPs and Aer have identical trimer contact residues in their signaling domains, and Tar, Tsr, and Trg have been shown to form mixed trimers of dimers in vivo that are believed to comprise discrete signaling teams within the receptor array (23). The highly conserved nature of its trimer contact sites predicts that Aer molecules might form mixed trimers with conventional MCPs, which could promote functional interactions between the two transducer types.
In a companion study, we described mutations in the PAS, HAMP, and HAMP-proximal signaling domains of Aer (see Fig. 2) that produced a strong clockwise (CW) flagellar rotational bias, presumably reflecting constitutively high CheA activity (8). Although nonfunctional as the cell's sole transducer, these CW-biased mutant Aer proteins regained the ability to mediate aerotactic responses in the presence of MCPs, an effect we term functional rescue. We postulate that MCPrescuable Aer defects (designated Aer-CW) do not abrogate signal transmission through the Aer molecule but rather distort Aer's prestimulus signal output, producing an inappropriate (CW-biased) swimming pattern. According to this model, functional rescue could occur in either of two ways: (i) the presence of other transducers could simply return the cell's overall rotational bias to the normal range, allowing the mutant Aer molecules to operate more effectively, or (ii) MCPs might alter Aer signaling properties through formation of mixed, trimerbased signaling teams.
In this study we explore the mechanism of Aer-CW functional rescue by MCPs, in particular the possibility that these transducers can form mixed signaling teams. To establish the minimum MCP requirements for rescue of CW-biased Aer defects, we examined the ability of various mutant MCP molecules to rescue Aer-CW function. To investigate mixed trimer formation, we used a trifunctional cross-linking reagent [Tris-(2-maleimidoethyl-amide) (TMEA)] to detect physical interactions between Aer and MCP molecules in vivo. We also tested mutations at Aer trimer contact sites for epistatic effects on MCP signaling and to determine whether those Aer lesions were suppressible by mutations in the MCP trimer contact region. Our results indicate that Aer is able to function in the presence of high-abundance, methylation-dependent chemoreceptors by forming mixed signaling teams that may serve to amplify Aer-initiated sensory signals.
Immunoblotting Aer. Polyclonal rabbit antisera by Covance Technologies (Denver, PA) were raised against Aer residues 1 to 262 (Aer ). To prepare Aer  fragments, RP3098 cells carrying plasmid pDM17 Aer-Q263am were grown in H1 Casamino Acids at 30°C to mid-log phase and induced with 1 mM IPTG, as described previously (1). After three additional hours of growth, the cells were harvested by centrifugation and lysed by two passes through a French press at 10,000 lb/in 2 . Membranes containing Aer  were pelleted by centrifugation at 100,000 ϫ g for 1 h, and then the pellet was homogenized and solubilized in 8 M urea, 0.1 M NaH 2 PO 4 , 0.01 M Tris-HCl (pH 8) by being rocked at room temperature for 2 h. The sample was partially clarified by centrifugation at 7,800 ϫ g for 20 min and fractionated on preparative 15% acrylamide-sodium dodecyl sulfate (SDS) gels. Gel slices containing the Aer  band were used for antiserum production.
Cell extracts containing Aer proteins were prepared and analyzed as described previously (8). Aer  antiserum was treated with an acetone powder of strain UU1250 to reduce nonspecific cross-reactivity. Western blot analyses were performed with a 1/600 dilution of the primary antibody in a 5% milk solution. Aer bands were visualized with a goat anti-rabbit secondary antibody conjugated to a Cy5 fluorescent reporter (GE/Amersham Biosciences, Piscataway, NJ).
TMEA cross-linking. An Aer derivative with alanine replacements at each of the three native cysteines (C193A/C203A/C253A), which had previously been shown to support aerotaxis in the presence of MCPs (strain UU1117 carrying pSB90 [pSB90/UU1117] [6]), failed to do so in the absence of MCPs (pSB90/ UU1250 [data not shown]). We found that the C253A replacement was responsible for this defect. To construct a fully functional Aer derivative lacking all three native cysteine residues, we randomized codon 253 in pSB90 by QuikChange mutagenesis (2) and selected on tryptone soft agar for aerotactic transformants of host UU1250. A C253L derivative with full Aer function (pKG151 [Aer-C193A/C203A/C253L]) was chosen as the parental plasmid for in vivo cross-linking studies. A reporter site (S356C) and subsequent trimer contact lesion (I367P) were created in pKG151 by site-directed mutagenesis, yielding pKG158 (pKG151-S356C) and pKG193 (pKG158-I367P).
Strains carrying pKG158 or pKG193 were grown in tryptone broth plus 50 g/ml ampicillin at 30°C to early log phase (optical density at 600 nm of ϳ0.2), and Aer synthesis was induced with 15 or 60 M IPTG, respectively. After an additional 4 h of incubation at 30°C, the cells were harvested by centrifugation and resuspended in KEP buffer (2) at an optical density at 600 nm of 2. Cell samples (0.5 ml) were treated with 100 M TMEA for 5 min at 30°C, and reactions were quenched with 10 mM N-ethylmaleimide. The treated cells were pelleted, resuspended in 50 l of SDS-polyacrylamide gel electrophoresis sample buffer (12) containing 10 mM N-ethylmaleimide, and analyzed by SDS-polyacrylamide gel electrophoresis as previously described (23). Aer was visualized by immunoblotting with a 1:600 dilution of anti-Aer . Aer and Tar were visualized on the same blot with a 1:1,000 dilution of anti-Tsr[290-470] (1).

Optimal Aer stoichiometry in the presence and absence of MCPs.
Aer comprises only a few percent of the receptor population in wild-type cells (13), where the Tar and Tsr receptors predominate, and probably has little direct control over steadystate CheA activity and the cell's unstimulated swimming pattern. Yet, Aer mediates robust aerotactic responses in wild-type cells, presumably with assistance from the high-abundance receptors. With no collaborating receptors, Aer itself would need to establish an appropriate swimming pattern in order to promote aerotactic behavior.
To determine the optimal stoichiometry for Aer function in the absence of other receptors, we examined the aerotactic behavior and Aer expression level of transducerless strain UU1250 carrying pKG106, an IPTG-inducible Aer expression plasmid ( Fig. 1). With no induction, pKG106 expressed Aer at roughly sixfold the chromosomal level but produced little increase in colony size on tryptone soft agar over the vector control plasmid (pNP1). Maximal aerotactic expansion occurred with 50 M IPTG, which leads to a level of Aer expression about 350-fold higher than that supported by the chromosomal gene. Aer expression at 900-fold above the chromosomal level (500 M IPTG) caused a modest decline in colony size (Fig. 1). These findings indicate that as the cell's sole transducer, Aer functions optimally at an expression level that is roughly comparable to the aggregate number of transducer molecules in a wild-type cell.
Functional rescue of CW-biased Aer defects. Mutant Aer proteins with CW-biased (CheA-activating) output signals cannot mediate aerotactic responses as the cell's sole transducer, regardless of their expression level (8). However, even at roughly chromosomal expression levels, CW-biased Aer proteins function normally in cells containing a full complement of MCP receptors (8). To explore the mechanistic basis of this effect, we examined variants of the high-abundance aspartate receptor Tar for their ability to rescue the function of Aer-CW proteins. We chose Tar as the rescuing receptor because the other high-abundance receptor, Tsr (serine), is known to mediate an aerotactic response that could confound assessment of Aer function (19). The various receptor constructs and mutations used in these studies are listed in Fig. 2.
We first tested whether wild-type Tar alone was capable of rescuing Aer-CW mutations (M112V, K221E, M252T, and Q263L) previously shown to regain function in a strain containing all four MCPs (8). Mutant Aer plasmids were tested in strain UU1624, which expresses wild-type Tar from the chromosomal tar gene and lacks the genes for other MCPs and Aer. Because Tar mediates aspartate taxis on tryptone media, we evaluated aerotaxis on minimal succinate soft agar plates (4, 5) ( Fig. 3B). At uninduced Aer expression levels (roughly sixfold over chromosomal Aer levels), Tar alone rescued all but the Aer-Q263L mutation (Fig. 3). Several of the Tar-rescued mutants, particularly K221E and M252T, formed colonies that were consistently larger than those of cells expressing wild-type Aer (Fig. 3B). These behaviors appear to be examples of a "super-swarmer" phenomenon first noted by Ma et al. (14). In the Discussion, we offer an explanation for this interesting effect.
Functional rescue by the Tar signaling domain. We asked whether the Tar signaling domain was sufficient for rescue by testing a Tar derivative lacking the periplasmic aspartate-binding domain (Tar°[ Fig. 2]). These rescue experiments were performed in a receptorless host strain (UU1250) carrying two compatible plasmids, an IPTG-inducible Aer plasmid and a salicylate-inducible Tar°plasmid. Because Tar°cannot mediate an aspartate response, we assessed aerotactic behavior on tryptone soft agar plates. The initial Tar°construct could not induce tumbling episodes in UU1250 and failed to rescue any Aer mutants (data not shown). However, a single amino acid replacement (T303I) that restores CW-signaling ability to Tar°( Ames and Parkinson, unpublished) enabled it to rescue all but the Aer-Q263L defect (Fig. 3C). The extent of rescue was more variable and less complete with Tar°-T303I than with wild-type Tar. Aer-K221E was fully rescued by both, whereas Aer-M112V and Aer-M252T were only partly rescued by Tar°-T303I: colonies increased in size but lacked edges with the sharp ring of aerotactic cells characteristic of wild-type Aer colonies (Fig. 3C). The differential rescuability of CW-biased Aer defects may reflect their degrees of CW bias and how effectively the rescuing receptor can impose a normal swimming pattern on the cell. Wild-type Tar is capable of adjusting its signal output via methylation changes, whereas Tar°constructs could be less efficient in this regard. In any event, it is clear that a nonfunctional receptor (Tar°) with a membraneassociated signaling domain can rescue Aer-CW defects. A fully soluble Tar signaling domain might also rescue Aer-CW mutants, but we did not test this prediction in the current study.
Aer functional rescue and mixed trimer formation. The Aer signaling domain is quite similar to that of MCPs, with fully conserved trimer contact residues. Functional rescue of CWbiased Aer proteins could conceivably occur through formation of mixed trimers of dimers with the rescuing receptors. To assess Aer trimer-of-dimer formation in vivo, we used a trifunctional thiol-reactive cross-linker (TMEA) and Aer molecules with a cysteine residue near the predicted trimer interface (23). In Tar, Tsr, and Trg, a single cysteine reporter at the position corresponding to Aer-S356 allowed efficient capture of the three axial subunits in trimers of dimers upon TMEA treatment of intact cells (23). The Aer reporter protein (Aer [C193A/C203A/C253L/S356C]; hereafter, Aer-S356C) (see Materials and Methods) mediated aerotactic responses on tryptone soft agar but with some degradation in the sharpness of the aerotactic ring at the colony edge caused by the S356C alteration (data not shown). Cells expressing Aer-S356C readily yielded two-and threesubunit cross-linking products upon TMEA treatment, consistent with trimer-of-dimer formation (Fig. 4). Moreover, a null mutation at one of the putative contact residues (I367P) greatly reduced the yield of three-subunit products, confirming their trimer-dependent origin (Fig. 4). Note that Aer-S356C/ I367P still formed some two-subunit cross-linking products (Fig. 4, lane 4). In other receptors, the equivalent trimer contact lesion prevents trimer formation but also seems to enhance collisional cross-linking between subunits within a dimer, probably by destabilizing the local structure of the sig-naling domain (23). In summary, it appears that Aer can form trimers of dimers.
To look for evidence of mixed trimer formation, Aer-S356C was expressed in strain UU1604, which encodes Tar-S364C from the chromosome (17). Upon TMEA treatment of the cells, we observed both pure and mixed two-and three-subunit cross-linking products (Fig. 4, lanes 1 to 3). The I367P trimer contact lesion eliminated the mixed products, demonstrating that their formation was trimer dependent (Fig. 4). Trimer formation by Tar and other MCPs occurs efficiently in strains lacking the CheA or CheW components of receptor signaling complexes (17,23). We found that the cross-linking patterns of Aer-S356C were unchanged in strain UU1613, which carries a cheA-cheW deletion, demonstrating that Aer trimer formation is also independent of the CheA and CheW proteins (data not shown).
Aer interference with Tar and Tsr signaling. Our crosslinking results demonstrate that Aer forms trimers and mixed trimers in vivo. Accordingly, Aer lesions that allow formation of mixed, but defective, trimers might block signaling by heterologous receptors. A variety of trimer contact mutations in Tsr are known to exert epistatic effects on Tar function (2). We chose two such lesions, Tsr-F373W and Tsr-N376W, and created the comparable mutations in Aer (Aer-F363W and Aer-N366W). As expected, both alterations severely impaired Aer function, although Aer-F363W evinced some residual activity in soft agar assays (see Fig. 6A). When expressed in Tar-only (UU1624) and Tsr-only (UU1615) host strains, the mutant Aer plasmids blocked aspartate and serine chemotaxis (Fig. 5). Epistasis over Tsr, the most abundant MCP species in E. coli, was evident only upon Aer induction (Fig. 5A and B), whereas the Aer mutants impaired Tar function without explicit induction ( Fig. 5C and D). We also noted that coexpression of wild-type Aer with Tar augmented the rate of colony expansion, possibly due to synergy between the aspartate and aerotactic responses (Fig. 5C). Upon induction with 50 M IPTG, corresponding to a modest stoichiometric excess, wild-type Aer caused slight reductions in Tar and Tsr function that were much less dramatic than the epistatic Aer defects. We conclude that alterations at the Aer trimer contact sites can block signaling by heterologous receptors and propose that these epistatic effects occur in mixed trimers of receptor dimers.
Suppression of epistatic Aer defects by mutant Tar receptors. If Aer epistasis occurs in mixed trimers, it might be possible to suppress Aer signaling defects, analogous to the functional rescue phenomenon, through mutations in other receptors that create compensatory alterations in the conformation and signaling properties of the mixed trimers. For example, mutations in the trimer contact region of Tar can act as allele-specific suppressors of the epistatic Tsr-F373W defect (17). We tested several of those Tar mutations (Tar-A380V, Tar-L376W, and Tar-G393V) for ability to suppress the aerotaxis defect of Aer-F363W (Fig. 6). All three Tar mutations enhanced colony expansion and restored ring formation to the Aer mutant, in contrast to wild-type Tar, which had no effect on Aer function (Fig. 6B). Note that the mutant Tar receptors were not able to mediate aspartate taxis, either alone (Fig. 6C) or in combination with Aer-F363W (Fig. 6B), consistent with a compensatory conformational change in a Tar/Aer structural complex.
Functional rescue of CW-biased defects in an Aer/Tar chimera. Functional rescue of Aer-CW defects by Tar°molecules that lack a sensing domain implies that the mutant Aer proteins retain aerosensing and output control capability. Thus, the role of the rescuing receptor might be simply to adjust the prestimulus output activity of the mutant Aer signaling domains through mixed trimer formation. This rescue mechanism predicts that the mutant Aer molecules alone might mediate aerotactic responses if their CW-biased prestimulus output could somehow be attenuated. To test this idea, we transferred CW-biased Aer lesions into an Aer/Tar chimera (Aear-269) that has the input-output module of Aer joined to the signaling domain of Tar (6). Like Tar, Aear transducers are able to modulate their signal output through feedback control of their methylation state (6). In Aear, the effects of the CW-biased Aer input-output module should be offset by the sensory adaptation ability of the Tar signaling domain.
CW-biased Aer mutations were introduced into Aear-269, and the mutant chimeras were tested for ability to promote aerotaxis in receptorless host strains (Fig. 7). Three CW lesions (M112V, K221E, and M252T) exhibited functional rescue in Aear; the Q263L defect did not (Fig. 7). The rescue phenotypes were similar in strains with (UU1250 [Fig. 7A and B]) and without (UU1535 [ Fig. 7C and D]) the CheR/CheB functions, suggesting that the mutant chimeras functioned efficiently with two unmethylated sites and two undeamidated sites, which minic methylated sites.

DISCUSSION
Aer normally operates as a low-abundance transducer. In wild-type E. coli, Aer molecules comprise at most a few percent of the chemoreceptor population yet produce robust motility responses to aerotactic stimuli. Because Aer communi- cates with the flagellar motors by the same phosphorelay pathway as conventional MCP receptors, the high-abundance transducers presumably command the majority of CheA signaling molecules and must somehow augment Aer signal output. One possible mechanism for collaborative signaling between different MCP-type receptors is formation of mixed trimer-of-dimer signaling teams (2,23). In this study we obtained several lines of evidence that Aer forms mixed signaling teams with the aspartate receptor Tar and the serine receptor Tsr. Evidence for mixed Aer signaling teams. Aer molecules bearing a cysteine reporter diagnostic for the trimer-of-dimers geometry (23) yielded two-and three-subunit cross-linking products upon treatment with the trifunctional reagent TMEA. In the presence of corresponding Tar reporter molecules, Aer also formed mixed cross-linking products. A trimer contact site lesion (I367P) known to abolish trimer formation by MCPs (23) eliminated both Aer signaling and trimer/mixed trimer formation. Although we did not explicitly investigate crosslinking interactions between Aer and Tsr in this report, we assume that Tar is not unique in this regard. Moreover, Aer exhibited no evident preference for self-association in these cross-linking assays, which implies that at its normal relative expression level, Aer dimers seldom interact as part of the same trimer team.
Trimer contact alterations known to cause epistatic behavior in other receptors (F363W and N366W) also produced epistatic properties in Aer. These Aer lesions prevented not only aerotactic signaling but also chemotactic signaling by wild-type Tar and Tsr molecules. Amino acid replacements in the Tar trimer contact region (L376F, A380V, and G393V) suppressed the Aer-F363W signaling defect, consistent with compensatory conformational changes between directly interacting proteins.
Aer also functions as a solitary transducer. Aer can mediate aerotactic responses in cells that lack MCP receptors but must be expressed at high levels to do so. We found that the optimal Aer expression level for function in the absence of MCPs approximated the aggregate number of Aer and chemoreceptor molecules in a wild-type cell. We assume that this level of Aer expression yields satisfactory stoichiometries with the CheA/CheW components of ternary Aer signaling complexes and in turn imparts a steady-state run/tumble swimming pattern suitable for aerotactic responses. However, episodes of CW flagellar rotation are less frequent in Aer-only cells than in cells containing other transducers (8), which may reflect the lack of a methylation-dependent adaptation system in Aer or an intrinsically different efficiency of CheA activation in Aer signaling complexes.
The behavior and underlying signaling mechanisms of Aeronly cells could be distinctly different from those of wild-type cells. In the absence of other transducers, Aer molecules presumably form homogeneous trimer-of-dimer signaling teams. Such Aer complexes most likely do not exist in wild-type cells, owing to mixed trimer formation with the vast excess of MCP molecules. The MCP-dependent functional rescue of mutant Aer proteins with CW-biased signal output provides a striking example of these differences. In the absence of MCPs, CWbiased Aer proteins cannot mediate aerotactic responses, regardless of expression level (8). However, in the presence of MCPs, even very low levels of CW-biased Aer molecules produce robust aerotactic behavior (8).
We found that a Tar molecule lacking the periplasmic aspartate-binding domain (Tar°) also restored function to CWbiased Aer proteins, supporting the idea that rescue occurs in mixed teams based on trimer-of-dimer interactions between receptor signaling domains. We suggest that CW-biased Aer molecules spend more time in the counterclockwise conformation when interacting with MCPs in trimers of dimers. This shift in counterclockwise-CW equilibrium in turn enables Aer to modulate team signal output in response to aerotactic stimuli, thereby restoring aerotactic behavior. Consistent with this team-based model of functional rescue, we also found that CW-biased Aer lesions did not impair aerotactic signaling in a hybrid Aer-Tar transducer capable of adjusting its steady-state signal output via methylation-dependent sensory adaptation. The extent of rescue seemed to be correlated with the severity of the CW-biased defects, which might reflect residual stimulus sensitivity and output signaling efficiency. CW-biased lesions in PAS (M112V) and HAMP (M252T), which may interact to elicit CW rotation (8,27), were rescued less effectively than a lesion in the HAMP connector (K221E), which has been proposed to play a less direct role in the production of CW output signals in Aer (8). Similarly, a CW-biased lesion in the proximal signaling domain (Q263L), which is downstream of the proposed sensory input control point, was not effectively rescued in any test.
Functional rescue of CW-biased Aer defects and the "superswarmer" phenomenon. Ma  nies ("super swarms") on minimal succinate soft agar (14). Those plasmid-borne Aer lesions were characterized in a host that contained Tar and the low-abundance Tap and Trg transducers. More recently, several of those mutations (K221E, A223V, and V264A) were shown to be MCP-rescuable, CWbiased Aer lesions (8). We suggest that the super-swarming behavior of these mutants depends on bias adjustment by MCPs and reflects altered sensitivity to oxygen gradients in the succinate plates. This explanation predicts that some of the other super-swarmer mutations described by Ma et al. may also exhibit CW-biased signaling defects in a strain lacking MCPs. The super-swarming effect implies that band formation at the perimeter of aerotactic colonies may involve a different behavioral strategy than that for other chemoattractants. Cells travel toward conventional attractants by suppressing CW rotation whenever they head up-gradient, whereas down-gradient movements have no effect on their run/tumble bias. In contrast, aerotactic migrations in spatial oxygen gradients might involve bidirectional movement control: suppression of CW bias when cells head up-gradient and enhancement of CW bias when cells head down-gradient. Cells, such as the superswarmers, with inherently CW-biased Aer proteins should be more sensitive than wild-type cells to down-gradient movements, which might readily elicit tumbling responses, thereby reducing down-gradient travel time and speeding colony expansion.