New Insights into the Signaling Mechanism of the pH-responsive, Membrane-integrated Transcriptional Activator CadC of Escherichia coli*

The membrane-integrated transcriptional regulator CadC of Escherichia coli activates expression of the cadBA operon at low external pH with concomitantly available lysine, providing adaptation to mild acidic stress. CadC is a representative of the ToxR-like proteins that combine sensory, signal transduction, and DNA-binding activities within a single polypeptide. Although several ToxR-like regulators such as CadC, as well as the main regulator of Vibrio cholerae virulence, ToxR itself, which activate gene expression at acidic pH, have been intensively investigated, their molecular activation mechanism is still unclear. In this study, a structure-guided mutational analysis was performed to elucidate the mechanism by which CadC detects acidification of the external milieu. Thus, a cluster of negatively charged amino acids (Asp-198, Asp-200, Glu-461, Glu-468, and Asp-471) was found to be crucial for pH detection. These amino acids form a negatively charged patch on the surface of the periplasmic domain of CadC that stretches across its two subdomains. The results of different combinations of amino acid replacements within this patch indicated that the N-terminal subdomain integrates and transduces the signals coming from both subdomains to the transmembrane domain. Alterations in the phospholipid composition did not influence pH-dependent cadBA expression, and therefore, interplay of the acidic surface patch with the negatively charged headgroups is unlikely. Models are discussed according to which protonation of these acidic amino acid side chains reduces repulsive forces between the two subdomains and/or between two monomers within a CadC dimer and thereby enables receptor activation upon lowering of the environmental pH.

philic bacteria such as Escherichia coli, Salmonella typhimurium, and Vibrio cholerae possess different stress response systems to maintain the cytoplasmic pH in the physiological range. One system that is important for the response to mild acidic stress in E. coli is the Cad system (1). The Cad system of E. coli consists of the cytoplasmic protein CadA and the transmembrane proteins CadB and CadC. The lysine decarboxylase CadA converts lysine upon consumption of a cytoplasmic proton to cadaverine and carbon dioxide. Subsequently, CadB transports the basic reaction product cadaverine in exchange for lysine out of the cell (2,3). Transcription of the cadBA operon in E. coli is activated when the external pH drops below pH 6.6 if external lysine is available (4,5). The main activator of the Cad system is the inner membrane protein CadC (6).
CadC is a member of the family of ToxR-like transcriptional activators that comprise several low pH-regulated activators, including the main regulator for virulence of V. cholerae, ToxR. ToxR-like regulators are characterized by a conserved modular composition. They exhibit a cytoplasmic DNA-binding domain with a winged helix-turn-helix motif, a single transmembrane domain, and a periplasmic sensor domain. In contrast to histidine kinase/response regulator systems, in which signal transduction is accompanied by phosphorylation reactions, signal transduction in ToxR-like regulators is mediated without chemical modification (7). Thus, ToxR-like regulators are onecomponent systems that exhibit sensory, signal transduction, and effector function within one polypeptide (8). Although transcriptional activation by ToxR as well as CadC has been intensively investigated using genetic and biochemical methods, the precise molecular mechanism is hardly understood. Previously, we showed that CadC is not the direct sensor for lysine but senses lysine via interplay with the lysine-permease LysP as co-sensor (9). Using random mutagenesis, Dell et al. (10) identified several CadC variants with mutations in the periplasmic domain that were impaired in the pH-dependent regulation of the Cad system. Therefore, the pH sensory property was assigned to the periplasmic domain of CadC. Recently, the three-dimensional structure of the periplasmic domain of E. coli CadC was solved (41). In this study, we employed a structure-guided mutational analysis that led to the identification of a negatively charged patch comprising acidic amino acids on the CadC periplasmic domain surface as crucial for sensing low pH.

EXPERIMENTAL PROCEDURES
Bacterial Strains and Growth Conditions-E. coli JM109 or DH5␣ (11,12) was used as a carrier for the plasmids described. All plasmids used in this study are listed in supplemental Table  1. E. coli BL21(DE3)pLysS (13) was used for expression of cadC and its variants from the T7 promoter. E. coli EP314 (14), which carries a cadA-lacZ fusion gene and a Tn10 transposon in cadC, was complemented with plasmids (pET16b-based) encoding cadC and its variants and used for cadBA transcriptional analysis. For strain maintenance, plasmid preparation, and protein overproduction, strains were grown in LB medium (15). To monitor signal transduction in vivo, E. coli EP314 transformed with the indicated plasmids was grown in minimal medium (16). The pH was adjusted to either pH 5.8 or pH 7.6 using the corresponding phosphate-buffered medium. E. coli strains with modified phospholipid content (E. coli AD93 with or without plasmid pDD72 (17) and HDL1001 (18)) were grown in LB medium that was pH-adjusted using 100 mM MOPS (pH 7.6 or 7.0) or MES (pH 5.8). To enable growth of AD93, 50 mM MgCl 2 was added to the medium (17). Where indicated, lysine was added to a final concentration of 10 mM. Antibiotics were added for selection purpose at concentrations of 100 g/ml (ampicillin), 50 g/ml (kanamycin), and 34 g/ml (chloramphenicol).
Detection of CadC in the Membrane Fraction-Verification of production and membrane integration was carried out for all CadC variants as described previously (9).
Measurement of CadC Signal Transduction Activity in Vivo-Cultivation of cells and measurements of the signal transduction activity of different CadC variants by ␤-galactosidase assays were performed as described previously (9). To analyze the influence of changes in the phospholipid composition, cells of an overnight culture (grown in LB medium at pH 7.6) were inoculated into fresh LB medium (pH 7.6) with the A 600 adjusted to 0.05. Cells were grown under aerobic conditions at 37°C to mid-logarithmic growth phase (A 600 ϳ 0.7) and harvested by centrifugation (37°C). Pellets were resuspended and transferred to prewarmed LB medium (pH 5.8 -7.6) by adjusting the A 600 to 0.7. After growth for another 1.5 h, cells were harvested by centrifugation. To test CadA activity, a modified spectrophotometric assay for lysine decarboxylase as described by Lemonnier and Lane (20) was used. For this purpose, the cell density was adjusted to A 600 ϭ 1 with 20 mM potassium P i buffer (pH 5.8). Subsequently, 200 l of this cell suspension was mixed with 20 l of chloroform to disrupt cells. After settling of the chloroform, 10 l of the chloroform-free supernatant was added to 120 l of either a lysine-free (control) or a lysine-containing reaction mixture consisting of 16 mM potassium P i buffer (pH 5.8) and 0.1 mM pyridoxal phosphate (Sigma) with and without 5 mM lysine (Sigma) 37°C. The enzymatic reaction was performed at 37°C for 15 min and thereafter stopped by the addition of 120 l of 1 M Na 2 CO 3 . Subsequently, lysine and cadaverine were derivatized by adding 120 l of 10 mM picrylsulfonic acid (2,4,6-trinitrobenzenesulfonic acid; Sigma), followed by incubation at 40°C for 4 min. To each sample toluene (1 ml) was added, followed by vigorously mixing for 20 s. The toluene and aqueous layers were separated by centrifugation. N,NЈ-Bistrinitrophenyllysine is soluble in water but not in toluene, whereas the reverse is true for N,NЈ-bistrinitrophenyl cadaverine (21). The absorption of N,NЈ-bistrinitrophenyl cadaverine (toluene phase) was determined at 340 nm, and the specific activity of CadA (mol/min*mg) was calculated.
Three-dimensional Structure Analysis-Analysis of the three-dimensional structure of the periplasmic domain (Protein Data Bank code 3LY7) was carried out using the PyMOL molecular viewer, version 0.99rc6 (22). Calculation of electrostatic surface was carried out with the program GRASP (23).

Histidine Residues Are Not Involved in pH Detection by CadC-
Moderate acidification (pH 6.6) of the surrounding medium in the presence of lysine is sufficient to activate transcription of the cadBA operon in E. coli. Full induction of this operon is accomplished at or below pH 5.8 (4). These values are close to the pH value at which histidine side chains become protonated (pK a around 6). In addition, histidines have already been shown to mediate the pH response in several proteins such as the sensor kinase PhoQ of Salmonella typhimurium (24) and the histidine kinase ArsS of Helicobacter pylori (25). The periplasmic domain of CadC contains six histidine residues (His-240, His-332, His-345, His-349, His-387, and His-390), which were all replaced with either leucine or glutamine to substitute the imidazole ring with different side chains of similar size. Plasmids encoding the corresponding CadC variants were introduced into the reporter strain E. coli EP314, which lacks a functional chromosomal cadC gene and carries a cadA-lacZ fusion gene (9,14). With the exception of CadC-H240Q, all variants of CadC with histidine replacements induced cadBA expression at low pH but not at pH 7.6, similar to wild-type CadC (Fig. 1A). Because all CadC variants were inserted into the membrane (Fig. 1B), the lack of response of CadC-H240Q seemed to be related to defects in sensing and/or signal transduction (offstate). To test whether the off-state of CadC-H240Q was due to the loss of the positive charge of the protonated imidazole ring or other structural effects, arginine and leucine were introduced at this position, respectively. Indeed, replacement of His-240 with leucine and also with arginine resulted in pH-responsive CadC variants, albeit the signaling capacity of CadC-H240R was somewhat reduced (Fig. 1A). These results indicate that the imidazole side chain of His-240 is not important for pH sensing but that this amino acid seems to play a more intricate role in signaling.
Glu-461, Glu-468, and Asp-471 Are Involved in pH Sensing-Full induction of cadBA transcription occurs at pH 5.8, a pH value at which initial protonation of aspartate (side chain pK a of The pH Sensor CadC of Escherichia coli 3.9) or glutamate (side chain pK a of ϳ4.3 (26)) residues, depending on their electrostatic environment, could be responsible for pH sensing. The periplasmic domain contains 19 aspartates and 15 glutamates. Because almost all pH-sensitive amino acids previously identified by Dell et al. (10) were located close to the C terminus, we initially focused on 10 C-terminal aspartate and glutamate residues (Asp-434, Glu-435, Asp-445, Glu-447, Glu-461, Glu-468, Asp-471, Glu-490, Asp-506, and Glu-512). Each amino acid was substituted with the related carboxamide amino acid devoid of charge (i.e. asparagine instead of aspartate and glutamine instead of glutamate) to mimic the uncharged protonated state and also with arginine to further introduce a positive net charge. The effect of each amino acid replacement was tested as described for the histidine variants. Most of the resulting CadC variants activated cadBA expression like wild-type CadC ( Fig. 2 and Table 1). However, replacement of Glu-461, Glu-468, and Asp-471 caused either nonresponsive CadC variants (off-state) or pH-insensitive, i.e. constitutively activated, CadC variants (on-state) ( Fig. 2A). Therefore, the role of these residues was further analyzed by additional amino acid replacements. For Glu-461, shortening the side chain (CadC-E461A), removing the negative charge (CadC-E461Q), and introducing a positive charge (CadC-E461R) resulted in nonresponsive proteins. Even the introduction of aspartate at this position (CadC-E461D) abolished the response to the external low pH signal (off-state). Hence, any alteration of Glu-461 led to CadC variants that were arrested in the off-state. More or less the same results were observed when Glu-468 was replaced. In this case, only the conservative replacement with aspartate (CadC-E468D) resulted in a pH-responsive sensor, albeit with lower activity (Fig. 2A). Notably, the replacement of aspartate at position 471 evoked different effects. Small uncharged amino acids such as alanine and glycine (CadC-D471A/G) ( Fig. 2A) (10), as well as the larger uncharged asparagine (CadC-D471N) converted CadC to the on-state. On the other hand, the charged amino acids glutamate (CadC-D471E) and arginine (CadC-D471R) at this position led to nonresponsive CadC proteins, which no longer activated cadBA expression when exposed to low pH ( Fig. 2A). As the three-dimensional structure of the periplasmic domain of  that was complemented with plasmid-encoded cadC or the indicated cadC mutant. Cells were cultivated under microaerobic conditions in minimal medium with 10 mM lysine at pH 7.6 (black bars) or at pH 5.8 (white bars). The reporter enzyme ␤-galactosidase was determined as described in the legend to Fig. 1. B, verification of production and integration of CadC variants into the cytoplasmic membrane of E. coli (see Fig. 1). The pH Sensor CadC of Escherichia coli MARCH 25, 2011 • VOLUME 286 • NUMBER 12

JOURNAL OF BIOLOGICAL CHEMISTRY 10683
CadC was recently solved (41), the amino acids involved in pH sensing identified thus far could be located in the tertiary structure. The CadC periplasmic domain consists of two subdomains (Fig. 3). Only His-240 is located in the N-terminal subdomain, whereas Glu-461, Glu-468, and Asp-471 are located in the C-terminal subdomain, which forms a bundle of ␣-helices (Fig. 3). Strikingly, Glu-468 and Asp-471 are located within the same ␣-helix (helix 11), like Leu-479 and Thr-475, which were previously identified by Dell et al. (10). Glu-461 is located in helix 10, and its side chain is oriented toward helices 11 and 12. Interestingly, His-240 is found in close proximity to ␣-helices 10 and 11 and displayed on the same protein face as Glu-468 and Asp-471. Helix 11 Harbors pH-sensing Residues-Beside Glu-468 and Asp-471 within helix 11, two CadC variants with altered pH responses were already known from the random mutagenesis experiments of Dell et al. (10), namely CadC-T475A and CadC-L479S. To further clarify the role of helix 11 in pH sensing, we systematically exchanged all remaining surface-exposed residues (Arg-467, Leu-474, and Asn-478) (Fig. 4). In addition, we mutated Arg-480 and Phe-477 to analyze the influence of the charged residue (Arg-480) and the hydrophobic side chain (Phe-477) (Fig. 4). Beyond these residues, helix 11 contains four alanines. Because these alanines are part of the contact area with the neighboring helices 10 and 14, they were not replaced. Substitution of arginine at position 467 (CadC-R467A/Q/E/K) clearly abolished the pH response (off-state) of the corresponding CadC variants (Fig. 4B), although the mutations did not affect biosynthesis or membrane integration (Fig. 4C). Substitution of the other surface-exposed residues (CadC-L474A and CadC-N478A) led to CadC variants that remained in the onstate (Fig. 4B). Because changes of Arg-467, Leu-474, and Asn- The side chains of residues that were mutated but did not alter the pH response of the corresponding CadC variants are colored blue. Amino acids whose mutagenesis suggested a role in pH sensing are indicated in orange (off-state) or red (on-state). Secondary structure elements are labeled with white letters (41). A, amino acids of helix 11 that were investigated are colored blue (wild type-like phenotype), orange (off-state), or red (on-state). Side chains that are depicted in green were previously identified by random mutagenesis (Thr-475 and Leu-479) (10). The color code of the subdomains and the labeling of secondary structure elements is the same as described in the legend to Fig. 3. B, influence of amino acid replacements in helix 11 in the periplasmic domain of CadC on cadBA expression. Reporter gene assays were performed with E. coli EP314 (cadC1::Tn10, cadAЈ::lacZ fusion) that was complemented with plasmid-encoded cadC or the indicated cadC mutant as described in the legend to Fig. 1. C, verification of production and integration of CadC variants into the cytoplasmic membrane of E. coli BL21(DE3)pLysS. drastic effects on the pH-dependent cadBA expression, it is conceivable that these amino acids, together with Thr-475 and Leu-479, are responsible either for the correct positioning of the protonable residues within this helix, namely Glu-468 and Asp-471, or for their electrostatic force field. Exchange of Phe-477 with different residues resulted in opposing phenotypes: isoleucine at this position led to an almost pH-insensitive CadC variant (on-state), whereas the smaller alanine (CadC-F477A) did not alter pH sensing (Fig. 4B). Because removal of the aromatic side chain (CadC-F447A) did not affect pH-dependent activation of CadC, it is likely that the effect seen for CadC-F477I was due to steric alterations evoked through insertion of the ␤-branched isoleucine, which is less well accommodated in ␣-helices. Finally, exchange of the second inward-facing residue, Arg-480 (CadC-R480Q), did not significantly affect the pH-sensing capability of CadC.
Helix 10 Exerts a Stabilizing Effect-As Glu-461 is located in helix 10, the role of this helix in detecting low external pH was investigated in greater detail. Tyr-453, Val-454, Lys-458, and Tyr-460, together with Glu-461, decorate this helix on opposite sides (Fig. 5A). When Tyr-453 and Tyr-460 were replaced with isoleucine, the resulting CadC variants exhibited different phenotypes. CadC-Y453I regulated cadBA expression similarly to wild-type CadC, whereas CadC-Y460I blocked cadBA transcription (off-state) (Fig. 5B). Tyr-453 and Val-454, which were also inert to replacement (Fig. 5B), are located more at the N-terminal end of helix 10, whereas Tyr-460, as well as Lys-458 and Glu-461, i.e. sensitive residues, are situated at the C-terminal end. As in the case of Glu-461, each amino acid replacement of Lys-458 (CadC-K458A/Q/R) led to a pH-nonresponsive protein in the off-state (Fig. 5B), although these variants were synthesized and integrated into the membrane like wild-type CadC (Fig. 5C). The helix 10 residues analyzed are oriented toward helix 11 and seem to embrace it. For this reason and also because they are barely exposed to the surface of the protein, it is assumed that the nontitratable residues provide a kind of structural scaffold for the correct positioning of the pH-responsive residues Glu-468 and Asp-471 in helix 11.
Identification of a Negatively Charged Patch That Extends across Both Subdomains-Comparison of the location of amino acids involved in pH detection and of the electrostatic charge at the protein surface (Fig. 6A) revealed that the residues in helix 11 are part of a broader negatively charged patch. Importantly, one-half of this patch is formed by the N-terminal subdomain, whereas the second half is located on the C-terminal subdomain (encompassing residues of helix 11) of the periplasmic domain of CadC. Based on this notion, all other charged amino acids contributing to this patch were analyzed by mutagenesis: Asp-198, Asp-200, Glu-249, and also the positively charged Lys-242. The role of the aspartates and the glutamate was probed by removal of the negative charge (substitution with asparagine or glutamine, respectively) or by shortening the side chain (alanine). Furthermore, CadC variants that have a conservative exchange at these positions (mutual exchange between glutamate and aspartate, respectively) were tested. Mutations of Asp-198 and Asp-200 indicated the necessity of the aspartate side chain at these two positions. Each replacement (D198A/E/N and D200A/E/N) transformed the resulting CadC variant to a pH-nonresponsive off-state (Fig. 6B), although these proteins were properly integrated into the membrane (Fig. 6C). In contrast, substitution of Glu-249 did not significantly influence pH detection (Fig. 6B); all corresponding CadC variants (CadC-E249A/D/Q) activated cadBA expression in a wild type-like manner. In addition, we analyzed Lys-242 to explore the role of this positively charged amino acid within the  11. Amino acids that were investigated are colored blue (wild type-like phenotype) or orange (off-state). The color code of the subdomains and the labeling of secondary structure elements is the same as described in the legend to Fig. 3. B, influence of amino acid replacements in helix 10 in the periplasmic domain of CadC on cadBA expression. Reporter gene assays were performed with E. coli EP314 (cadC1::Tn10, cadAЈ::lacZ fusion) that was complemented with plasmid-encoded cadC or the indicated cadC mutant as described in the legend to Fig. 1. Black bars, pH 7.6; white bars, pH 5.8. C, verification of production and integration of CadC variants into the cytoplasmic membrane of E. coli (see Fig. 1).
cluster. Unexpectedly, only the mutation to arginine (CadC-K242R), which retained the positive charge, altered the CadCmediated pH-dependent activation, whereas CadC-K242A and CadC-K242Q showed a response like the wild-type protein (Fig. 6B). At first glance, this result would suggest that the Lys side chain naturally occurs in CadC in the unprotonated state such that its replacement with the more basic arginine would lead to an electrostatic effect. However, the salt bridge between the Lys N⑀ group and the negatively charged carboxylate side chain of Asp-200 provides a more plausible explanation, as this electrostatic interaction is probably different and possibly even stronger with the shorter arginine side chain. Notably, Asp-200 also plays a crucial role in this context, as described above.
Role of Phospholipids in Sensing-Ca 2ϩ sensing mediated by the histidine kinase PhoQ of S. typhimurium, for example, supposedly involves metal ion bridging between negatively charged side chains of the protein and the phospholipid headgroups of the cytoplasmic membrane (27). To test whether CadC might sense a higher H ϩ concentration via changes in a similar kind of interaction, cadBA expression was analyzed in different E. coli phospholipid mutant strains. These experiments were based on the hypothesis that, at neutral pH, the repulsive force between CadC and the phospholipids is stronger than after protonation of residues in the negatively charged surface patch. Hence, the cadBA expression profile was determined in two phospholipid mutants, whereby major changes in the phospholipid composition are expected to result in significant effects on CadC-mediated output. E. coli AD93 (17) has an inactivated allele of the gene encoding the phosphatidylserine synthase (pss93::kan), which catalyzes the committed step in the synthesis of phosphatidylethanolamine. Due to this defect, the mutant has a much higher content of negatively charged phospholipids (phosphatidylglycerol and cardiolipin). This property can be reverted by expressing pss from a plasmid (pDD72) (17). The second mutant, E. coli HDL1001 (18), is genetically modified such that expression of pgsA, which is crucial for the production of phosphatidylglycerol and cardiolipin, is under the control of the lac promoter. This mutant is characterized by an extremely low content of these two phospholipids (Ͻ2%). Both mutants were grown in medium at different pH values (pH 7.6, 7.0, and 5.8), and cadBA expression was recorded by measuring CadA activity (supplemental Fig. S1). In both mutants, cadBA expression was induced in a pH-dependent manner, and no shift either in the onset of expression or in the induction level was observed in comparison with the corresponding control strains (supplemental Fig. S1). Thus, alteration of the phospholipid composition was without effect on cadBA expression, and it can be concluded that the activation mechanism of CadC does not involve specific interactions with the phospholipid headgroups.
The N-terminal Subdomain Transduces Signals to the Transmembrane Domain-To gain insight into the signaling mechanism between the two subdomains within the periplasmic region of CadC, different amino acid replacements leading to the on-or off-state were combined within one polypeptide. In this way, a putative intramolecular complementation of different phenotypes was tested. For these experiments, the amino acid replacements D198E (off-phenotype) and K242R (on-phenotype) in the N-terminal subdomain and the replacements D471E (off-phenotype) and D471N (on-phenotype) in the C-terminal subdomain were assembled in all pairwise combinations. Interestingly, an intramolecular complementation was not achieved with any combination (Fig. 7). However, amino acid exchanges in the N-terminal subdomain were always dominant over exchanges in the C-terminal subdomain. Thus, the replacements D198E and K242R transformed CadC into either the off-or on-state, respectively, regardless of the second site mutation. These results suggest that the N-terminal subdomain integrates the signals coming from both subdomains and transduces them to the transmembrane and thus to the cytoplasmic domain (see Fig. 3).

DISCUSSION
The capability to adapt to changes in the external pH is vital throughout all three domains of life. Changes in the intracellular pH can have severe effects such as induction of apoptosis in human tissues (28 -30) and cell death in bacteria. To cope with an acidification of the environment, different mechanisms have evolved. Besides complete adaptation of the mode of life (i.e. for acidophilic bacteria), cells often respond by changes in gene expression. Therefore, pH sensors are crucial to monitor the pH of the environment. Different strategies to detect acidic stress are conceivable, e.g. pH-dependent protein folding and unfolding (31), but direct measurement of protons would provide the most straightforward and rapid response.
The ToxR-like regulator CadC of E. coli senses acidification of the environment through its periplasmic domain, thereby enabling the bacterium to respond to unfavorable conditions before experiencing challenges to the cellular interior. Until now, the molecular mechanism by which CadC senses an increase in the external proton concentration was not clear.
Histidine residues often mediate pH detection through protonation as shown for the pH-dependent folding switch of the Pseudomonas syringae effector protein AvrPto (32), for interaction of the diphtheria toxin T domain (33), and the pH-dependent dimer dissociation of the dynein light chain LC8 (34). Therefore and due to the fact that the activation range of cadBA expression (4) essentially matches the pK a value of the free histidine side chain, we analyzed the role of all histidines present in the periplasmic domain of CadC by site-directed mutagenesis. Our mutational analyses revealed, however, that protonation of histidines is not essentially involved in sensing low pH.
Further analyses of protonable residues in the periplasmic domain of CadC led to the identification of a negatively charged patch at the protein surface (Fig. 6). This patch is formed by Asp-198, Asp-200, Glu-461, Glu-468, and Asp-471 and extends across both subdomains. Strikingly, almost all residues are located on the same side of the protein surface, with Asp-198 and Asp-200 in the N-terminal subdomain and Glu-468 and Asp-471 in the C-terminal subdomain (Fig. 6). Glu-461 is almost buried within the protein but close to Glu-468. Substitution of the titratable residues within this patch had drastic effects (on-state, CadC-D471A/N; and off-state, CadC-D198A/ E/N, CadC-D200A/E/N, CadC-E461A/D/Q, CadC-E468A/ D/Q, and CadC-D471E/R). This might be due to a concerted effect of the entire group of negatively charged amino acids, also considering that the pK a of titratable side chains depends on the electrostatic environment and thus on the protonation state of groups in its surroundings. One could speculate that sensing the external H ϩ concentration with such an elaborate network could protect the cell from investing in an energy-consuming process (protein expression) under the wrong conditions and allows a graduated response of CadC to alterations of the external pH as it was already demonstrated (4).
Interestingly, a similar network of acidic residues was found to be involved in the pH-dependent gating of the acid-sensing ion channel 1a (35). In contrast, neither the crystal structure nor the site-directed mutagenesis studies presented here provided any evidence for the formation of specific salt bridges at neutral pH that may be broken upon proton binding within the CadC monomer, as was discussed for the pH-sensing mechanism of the bacterial potassium channel KcsA (36). Instead, it seems likely that the overall electrostatic potential at the protein surface (and associated variations in the Coulomb force field) plays a role in pH-dependent conformational changes.
Perturbation of the negatively charged patch, even via replacement of unprotonable or positively charged residues, led to CadC variants with either pH-insensitive (on-state, CadC-L479A and CadC-N478A) or nonresponsive (off-state, CadC-H240Q, CadC-L479A, CadC-N478A, CadC-T475A, CadC-L474A, CadC-R467A/E/K/Q, and CadC-K458A/Q/R) phenotypes. Because of the severe effects caused by these amino acid exchanges, one might speculate that these residues are vital for the precise structural or dynamic integrity of the protein, thus indirectly affecting pH sensing.
For the membrane-integrated kinase PhoQ, it was proposed that the positively charged calcium ions form bridges between the carboxylate side chains of the protein and the negatively charged headgroups of phospholipids (27). A similar bridging mechanism was described for the C2 membrane-binding domain of protein kinase C␣ and its interaction with phosphatidylserine (37). Alternatively, protonation of the negatively charged surface patch of CadC might reduce repulsive forces between CadC and phospholipid headgroups. Thus, protonation instead of metal ion binding might lead to alterations in the  To distinguish the monomers, they are colored in dark and pale colors, respectively. Residues that are crucial for pH sensing are indicated in orange (off-state) or red (on-state). The N-terminal subdomains of the periplasmic domain are colored gray, and the C-terminal subdomains are colored green. The N termini, which are preceded by the transmembrane helices, are indicated by white spheres, whereas the C termini are indicated by black spheres.