Modeling the transmembrane domain of bacterial chemoreceptors

Bacterial chemoreceptors signal across the membrane by conformational changes that traverse a four-helix transmembrane domain. High-resolution structures are available for the chemoreceptor periplasmic domain and part of the cytoplasmic domain but not for the transmembrane domain. Thus, we constructed molecular models of the transmembrane domains of chemoreceptors Trg and Tar, using coordinates of an unrelated four-helix coiled coil as a template and the X-ray structure of a chemoreceptor periplasmic domain to establish register and positioning. We tested the models using the extensive data for cross-linking propensities between cysteines introduced into adjacent transmembrane helices, and we found that many aspects of the models corresponded with experimental observations. The one striking disparity, the register of transmembrane helix 2 (TM2) relative to its partner transmembrane helix 1, could be corrected by sliding TM2 along its long axis toward the periplasm. The correction implied that axial sliding of TM2, the signaling movement indicated by a large body of data, was of greater magnitude than previously thought. The refined models were used to assess effects of inter-helical disulfides on the two ligand-induced conformational changes observed in alternative crystal structures of periplasmic domains: axial sliding within a subunit and subunit rotation. Analyses using a measure of disulfide potential energy provided strong support for the helical sliding model of transmembrane signaling but indicated that subunit rotation could be involved in other ligand-induced effects. Those analyses plus modeled distances between diagnostic cysteine pairs indicated a magnitude for TM2 sliding in transmembrane signaling of several angstroms.     

The ligand‐binding domain of a chemoreceptor from Comamonas testosteroni has a previously unknown homotrimeric structure

Transmembrane chemoreceptors are widely present in Bacteria and Archaea. They play a critical role in sensing various signals outside and transmitting to the cell interior. Here, we report the structure of the periplasmic ligand‐binding domain (LBD) of the transmembrane chemoreceptor MCP2201, which governs chemotaxis to citrate and other organic compounds in Comamonas testosteroni. The apo‐form LBD crystal revealed a typical four‐helix bundle homodimer, similar to previously well‐studied chemoreceptors such as Tar and Tsr of Escherichia coli. However, the citrate‐bound LBD revealed a four‐helix bundle homotrimer that had not been observed in bacterial chemoreceptor LBDs. This homotrimer was further confirmed with size‐exclusion chromatography, analytical ultracentrifugation and cross‐linking experiments. The physiological importance of the homotrimer for chemotaxis was demonstrated with site‐directed mutations of key amino acid residues in C. testosteroni mutants.     

Conformational analysis and design of cross-strand disulfides in antiparallel β-sheets

Cross‐strand disulfides bridge two cysteines in a registered pair of antiparallel β‐strands. A nonredundant data set comprising 5025 polypeptides containing 2311 disulfides was used to study cross‐strand disulfides. Seventy‐six cross‐strand disulfides were found of which 75 and 1 occurred at non‐hydrogen‐bonded (NHB) and hydrogen‐bonded (HB) registered pairs, respectively. Conformational analysis and modeling studies demonstrated that disulfide formation at HB pairs necessarily requires an extremely rare and positive χ¹ value for at least one of the cysteine residues. Disulfides at HB positions also have more unfavorable steric repulsion with the main chain. Thirteen pairs of disulfides were introduced in NHB and HB pairs in four model proteins: leucine binding protein (LBP), leucine, isoleucine, valine binding protein (LIVBP), maltose binding protein (MBP), and Top7. All mutants LIVBP T247C V331C showed disulfide formation either on purification, or on treatment with oxidants. Protein stability in both oxidized and reduced states of all mutants was measured. Relative to wild type, LBP and MBP mutants were destabilized with respect to chemical denaturation, although the sole exposed NHB LBP mutant showed an increase of 3.1°C in T _m . All Top7 mutants were characterized for stability through guanidinium thiocyanate chemical denaturation. Both exposed and two of the three buried NHB mutants were appreciably stabilized. All four HB Top7 mutants were destabilized (ΔΔG ⁰ = ?3.3 to ?6.7 kcal/mol). The data demonstrate that introduction of cross‐strand disulfides at exposed NHB pairs is a robust method of improving protein stability. All four exposed Top7 disulfide mutants showed mild redox activity. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Differential backbone dynamics of companion helices in the extended helical coiled‐coil domain of a bacterial chemoreceptor

Cytoplasmic domains of transmembrane bacterial chemoreceptors are largely extended four‐helix coiled coils. Previous observations suggested the domain was structurally dynamic. We probed directly backbone dynamics of this domain of the transmembrane chemoreceptor Tar from Escherichia coli using site‐directed spin labeling and electron paramagnetic resonance (EPR) spectroscopy. Spin labels were positioned on solvent‐exposed helical faces because EPR spectra for such positions reflect primarily polypeptide backbone movements. We acquired spectra for spin‐labeled, intact receptor homodimers solubilized in detergent or inserted into native E. coli lipid bilayers in Nanodiscs, characterizing 16 positions distributed throughout the cytoplasmic domain and on both helices of its helical hairpins, one amino terminal to the membrane‐distal tight turn (N‐helix), and the other carboxyl terminal (C‐helix). Detergent solubilization increased backbone dynamics for much of the domain, suggesting that loss of receptor activities upon solubilization reflects wide‐spread destabilization. For receptors in either condition, we observed an unanticipated difference between the N‐ and C‐helices. For bilayer‐inserted receptors, EPR spectra from sites in the membrane‐distal protein‐interaction region and throughout the C‐helix were typical of well‐structured helices. In contrast, for approximately two‐thirds of the N‐helix, from its origin as the AS‐2 helix of the membrane‐proximal HAMP domain to the beginning of the membrane‐distal protein‐interaction region, spectra had a significantly mobile component, estimated by spectral deconvolution to average approximately 15%. Differential helical dynamics suggests a four‐helix bundle organization with a pair of core scaffold helices and two more dynamic partner helices. This newly observed feature of chemoreceptor structure could be involved in receptor function.     

Structural and functional characterization of SiiA,an auxiliary protein from the SPI4‐encoded type 1 secretion system from Salmonella enterica

Salmonella invasion is mediated by a concerted action of the Salmonella pathogenicity island 4 (SPI4)‐encoded type one secretion system (T1SS) and the SPI1‐encoded type three secretion system (T3SS‐1). The SPI4‐encoded T1SS consists of five proteins (SiiABCDF) and secretes the giant adhesin SiiE. Here, we investigated structure–function relationships in SiiA, a non‐canonical T1SS subunit. We show that SiiA consists of a membrane domain, an intrinsically disordered periplasmic linker region and a folded globular periplasmic domain (SiiA‐PD). The crystal structure of SiiA‐PD displays homology to that of MotB and other peptidoglycan (PG)‐binding domains. SiiA‐PD binds PG in vitro, albeit at an acidic pH, only. Mutation of Arg162 impedes PG binding of SiiA and reduces Salmonella invasion efficacy. SiiA forms a complex with SiiB at the inner membrane (IM), and the observed SiiA‐MotB homology is paralleled by a predicted SiiB‐MotA homology. We show that, similar to MotAB, SiiAB translocates protons across the IM. Mutating Asp13 in SiiA impairs proton translocation. Overall, SiiA shares numerous properties with MotB. However, MotAB uses the proton motif force (PMF) to energize the bacterial flagellum, it remains to be shown how usage of the PMF by SiiAB assists T1SS function and Salmonella invasion.     

Adaptational modification and ligand occupancy have opposite effects on positioning of the transmembrane signalling helix of a chemoreceptor

Sensory systems adapt to persistent stimulation. In the transmembrane receptors of bacterial chemotaxis, adaptation is mediated by methylation at specific glutamyl residues in the cytoplasmic domain. Methylation counteracts effects of ligand binding on functional activities of that domain. Both ligand binding and adaptational modification are thought to act through conformational changes. As characterized for Escherichia coli chemoreceptors, a mechanistically crucial feature of the ligand-induced conformational change is piston sliding towards the cytoplasm of a signalling helix in the periplasmic/transmembrane domain. Adaptational modification could counteract this signalling movement by blocking its influence on the cytoplasmic domain or by reversing it. To investigate, we characterized effects of adaptational modification on the position of the signalling helix in chemoreceptor Trg using rates of disulphide formation between introduced cysteines. We utilized an intact cell procedure in which receptors were in their native, functional state. In vivo rates of disulphide formation between diagnostic cysteine pairs spanning a signalling helix interface changed as a function of adaptational modification. Strikingly, those changes were opposite those caused by ligand occupancy for each diagnostic pair tested. This suggests that adaptational modification resets the receptor complex to its null state by reversal of the conformational change generated by ligand binding.     

Crystal structure of the sensor domain of BaeS from Serratia marcescens FS14

The sensor histidine kinases of two‐component signal‐transduction systems (TCSs) are essential for bacteria to adapt to variable environmental conditions. The two‐component regulatory system BaeS/R increases multidrug and metal resistance in Salmonella and Escherichia coli. In this study, we report the X‐ray structure of the periplasmic sensor domain of BaeS from Serratia marcescens FS14. The BaeS sensor domain (34–160) adopts a mixed α/β‐fold containing a central four‐stranded antiparallel β‐sheet flanked by a long N‐terminal α‐helix and additional loops and a short C‐terminal α‐helix on each side. Structural comparisons revealed that it belongs to the PDC family with a remarkable difference in the orientation of the helix α2. In the BaeS sensor domain, this helix is situated perpendicular to the long helix α1 and holds helix α1 in the middle with the beta sheet, whereas in other PDC domains, helix α2 is parallel to helix α1. Because the helices α1 and α2 is involved in the dimeric interface, this difference implies that BaeS uses a different dimeric interface compared with other PDC domains. Proteins 2017; 85:1784–1790. © 2017 Wiley Periodicals, Inc.     

Dual recognition of the bacterial chemoreceptor by chemotaxis-specific domains of the CheR methyltransferase

Adaptation to persisting stimulation is required for highly sensitive detection of temporal changes of stimuli, and often involves covalent modification of receptors. Therefore, it is of vital importance to understand how a receptor and its cognate modifying enzyme(s) modulate each other through specific protein-protein interactions. In the chemotaxis of Escherichia coli, adaptation requires methylation of chemoreceptors (e.g. Tar) catalyzed by the CheR methyltransferase. CheR binds to the C-terminal NWETF sequence of a chemoreceptor that is distinct from the methylation sites. However, little is known about how CheR recognizes its methylation sites or how it is distributed in a cell. In this study, we used comparative genomics to demonstrate that the CheR chemotaxis methyltransferase contains three structurally and functionally distinct modules: (i) the catalytic domain common to a methyltransferase superfamily; (ii) the N-terminal domain; and (iii) the beta-subdomain of the catalytic domain, both of which are found exclusively in chemotaxis methyltransferases. The only evolutionary conserved motif specific to CheR is the positively charged face of helix alpha2 in the N-terminal domain. The disulfide cross-linking analysis suggested that this face interacts with the methylation helix of Tar. We also demonstrated that CheR localizes to receptor clusters at cell poles via interaction of the beta-subdomain with the NWETF sequence. Thus, the two chemotaxis-specific modules of CheR interact with distinct regions of the chemoreceptor for targeting to the receptor cluster and for recognition of the substrate sites, respectively.     

Correlation between signal input and output in PctA and PctB amino acid chemoreceptor of Pseudomonas aeruginosa

The PctA and PctB chemoreceptors of Pseudomonas aeruginosa mediate chemotaxis toward amino acids. A general feature of signal transduction processes is that a signal input is converted into an output. We have generated chimeras combining the Tar signaling domain with either the PctA or PctB ligand binding domain (LBD). Escherichia coli harboring either PctA‐Tar or PctB‐Tar mediated chemotaxis toward amino acids. The responses of both chimeras were determined using fluorescence resonance energy transfer, and the derived EC₅₀ values are a measure of output. PctA‐Tar and PctB‐Tar responded to 19 and 11 L‐amino acids respectively. The EC₅₀ values of PctA‐Tar responses differed by more than three orders of magnitude, whereas PctB‐Tar responded preferentially to L‐Gln. The comparison of amino acid binding constants and the corresponding EC₅₀ values for both receptors revealed statistically significant correlations between inputs and outputs. PctA and PctB possess a double PDC (PhoQ‐DcuS‐CitA) LBD – a family of binding domain found in various other amino acid chemoreceptors. Similarly, various chemoreceptors share the preferential response to certain amino acids (e.g. L‐Cys, L‐Ser and L‐Thr) that we observed for PctA. Defining the specific inputs and outputs of these chemoreceptors is an important step toward better understanding of their physiological role.     

Disulfide conformation and design at helix N‐termini

To understand structural and thermodynamic features of disulfides within an α‐helix, a non‐redundant dataset comprising of 5025 polypeptide chains containing 2311 disulfides was examined. Thirty‐five examples were found of intrahelical disulfides involving a CXXC motif between the N‐Cap and third helical positions. GLY and PRO were the most common amino acids at positions 1 and 2, respectively. The N‐Cap residue for disulfide bonded CXXC motifs had average (?,ψ) values of (?112 ± 25.2°, 106 ± 25.4°). To further explore conformational requirements for intrahelical disulfides, CYS pairs were introduced at positions N‐Cap‐3; 1,4; 7,10 in two helices of an Escherichia coli thioredoxin mutant lacking its active site disulfide (nSS Trx). In both helices, disulfides formed spontaneously during purification only at positions N‐Cap‐3. Mutant stabilities were characterized by chemical denaturation studies (in both oxidized and reduced states) and differential scanning calorimetry (oxidized state only). All oxidized as well as reduced mutants were destabilized relative to nSS Trx. All mutants were redox active, but showed decreased activity relative to wild‐type thioredoxin. Such engineered disulfides can be used to probe helix start sites in proteins of unknown structure and to introduce redox activity into proteins. Conversely, a protein with CYS residues at positions N‐Cap and 3 of an α‐helix is likely to have redox activity. Proteins 2010. © 2009 Wiley‐Liss, Inc.     

Two cysteines in each periplasmic domain of the membrane protein DsbB are required for its function in protein disulfide bond formation.

DsbB is a protein component of the pathway that leads to disulfide bond formation in periplasmic proteins of Escherichia coli. Previous studies have led to the hypothesis that DsbB oxidizes the periplasmic protein DsbA, which in turn oxidizes the cysteines in other periplasmic proteins to make disulfide bonds. Gene fusion approaches were used to show that (i) DsbB is a membrane protein which spans the membrane four times and (ii) both the N- and C-termini of the protein are in the cytoplasm. Mutational analysis shows that of the six cysteines in DsbB, four are necessary for proper DsbB function in vivo. Each of the periplasmic domains of the protein has two essential cysteines. The two cysteines in the first periplasmic domain are in a Cys-X-Y-Cys configuration that is characteristic of the active site of other proteins involved in disulfide bond formation, including DsbA and protein disulfide isomerase.     

Not too loose, not too tight--just right. Biphasic control of the Tsr HAMP domain

HAMP domains communicate between input and output signalling modules in a wide variety of bacterial sensor proteins. In the Tsr chemoreceptor, they convert a signal initiated by binding of serine to the periplasmic domain of the protein into regulation of receptor control of the CheA kinase, and ultimately of the direction of flagellar rotation. In this issue, Zhou et al. report an extensive mutational analysis of the Tsr HAMP domain that shows that it can assume a number of different signalling states, which presumably correspond to a variety of different conformations. The two conformational extremes of a tightly packed and a loosely packed HAMP four‐helix bundle support only low levels of CheA activity. Thus, Tsr HAMP does not function as a simple on‐off, two‐state device but rather as a dynamic structure with biphasic control. The normal physiological operating range of Tsr is proposed to be at intermediate degrees of packing of the HAMP four‐helix bundle, but HAMP domains in other proteins could occupy different portions of the conformational spectrum.     

Two-step selective formation of three disulfide bridges in the synthesis of the C-terminal epidermal growth factor-like domain in human blood coagulation factor IX.

The 45-residue C-terminal EGF-like domain in human blood coagulation factor IX has been synthesized by a 2-step method to form selectively 3 disulfide bridges. Four out of 6 cysteines are blocked with either trityl or 4-methyl-benzyl, and the remaining 2 cysteines are blocked with acetamidomethyl (Acm). In the first step, 4 free cysteinyl thiols are released concurrently with the removal of all protecting groups except Acm and are oxidized to form 1 of the 3 possible isomers containing 2 pairs of disulfides. In the second step, iodine is used to remove the Acm groups to yield the third disulfide bridge. This approach reduces the number of possible disulfide bridging patterns from 15 to 3. To determine the optimal protecting group strategy, 3 peptides are synthesized, each with Acm blocking 1 of the 3 pairs of cysteines involved in disulfide bridges: Cys5 to Cys16 (Cys 1-3), Cys12 to Cys26 (Cys 2-4), or Cys28 to Cys41 (Cys 5-6). Only the peptide having the Cys 2-4 pair blocked with Acm forms the desired disulfide isomer (Cys 1-3/5-6) in high yield after the first step folding, as identified by proteolytic digestion in conjunction with mass spectrometric peptide mapping. Thus, the choice of which pair of cysteines to block with Acm is critically important. In the case of EGF-like peptides, it is better to place the Acm blocking groups on one of the pairs of cysteines involved in the crossing of disulfide bonds.     

Role of conserved cysteine residues in hepatitis C virus glycoprotein e2 folding and function

Hepatitis C virus glycoprotein E2 contains 18 conserved cysteines predicted to form nine disulfide pairs. In this study, a comprehensive cysteine-alanine mutagenesis scan of all 18 cysteine residues was performed in E1E2-pseudotyped retroviruses (HCVpp) and recombinant E2 receptor-binding domain (E2 residues 384 to 661 [E2(661)]). All 18 cysteine residues were absolutely required for HCVpp entry competence. The phenotypes of individual cysteines and pairwise mutation of disulfides were largely the same for retrovirion-incorporated E2 and E2(661), suggesting their disulfide arrangements are similar. However, the contributions of each cysteine residue and the nine disulfides to E2 structure and function varied. Individual Cys-to-Ala mutations revealed discordant effects, where removal of one Cys within a pair had minimal effect on H53 recognition and CD81 binding (C486 and C569) while mutation of its partner abolished these functions (C494 and C564). Removal of disulfides at C581-C585 and C452-C459 significantly reduced the amount of E1 coprecipitated with E2, while all other disulfides were absolutely required for E1E2 heterodimerization. Remarkably, E2(661) tolerates the presence of four free cysteines, as simultaneous mutation of C452A, C486A, C569A, C581A, C585A, C597A, and C652A (M+C597A) retained wild-type CD81 binding. Thus, only one disulfide from each of the three predicted domains, C429-C552 (DI), C503-C508 (DII), and C607-C644 (DIII), is essential for the assembly of the E2(661) CD81-binding site. Furthermore, the yield of total monomeric E2 increased to 70% in M+C597A. These studies reveal the contribution of each cysteine residue and the nine disulfide pairs to E2 structure and function.     

Mutational Analysis of the Transmembrane Helix 2-HAMP Domain Connection in the Escherichia coli Aspartate Chemoreceptor Tar

Transmembrane helix 2 (TM2) of the Tar chemoreceptor undergoes an inward piston-like displacement of 1 to 3 Å upon binding aspartate. This signal is transmitted to the kinase-control module via the HAMP domain. Within Tar, the HAMP domain forms a parallel four-helix bundle consisting of a dimer of two amphipathic helices connected by a flexible linker. In the nuclear magnetic resonance structure of an archaeal HAMP domain, residues corresponding to the MLLT sequence between Arg-214 at the end of TM2 and Pro-219 of Tar are an N-terminal helical extension of AS1. We modified this region to test whether it behaves as a continuous helical connection between TM2 and HAMP. First, one to four Gly residues were inserted between Thr-218 and Pro-219. Second, the MLLT sequence was replaced with one to nine Gly residues. Third, the sequence was shortened or extended with residues compatible with helix formation. Cells expressing receptors in which the MLLT sequence was shortened to MLL or in which the MLLT sequence was replaced by four Gly residues performed good aspartate chemotaxis. Other mutant receptors supported diminished aspartate taxis. Most mutant receptors had biased signal outputs and/or abnormal patterns of adaptive methylation. We interpret these results to indicate that a strong, permanent helical connection between TM2 and the HAMP domain is not necessary for normal transmembrane signaling.The HAMP domain is a structural motif commonly found in histidine kinases (HKs), adenylate cyclases, methyl-accepting chemotaxis proteins (MCPs), and phosphatases (2). In Escherichia coli and Salmonella enterica MCPs, the HAMP domain is located between a transmembrane-sensing module composed of ligand-binding and transmembrane regions and a kinase-control module composed of adaptation and kinase-activating regions (Fig. ​(Fig.1A)1A) (19). Therefore, HAMP domains are responsible for bidirectional signal transduction between these modules.Open in a separate windowFIG. 1.Domain architecture of the aspartate chemoreceptor. (A) The cartoon, based on a figure from Hazelbauer et al. (2008) (19), illustrates the architecture of the aspartate chemoreceptor. Protein structural domains are labeled on the left, and functional modules are labeled on the right. (B) Schematic of TM2 and the control cable region attached to a ribbon diagram of the solution NMR structure of the Af1503 HAMP domain four-helix bundle (22). TM2 is shown in purple within the membrane. The control cable of Tar_Ec consists of 5 amino acyl residues (Gly-Ile-Arg-Arg-Met) that connect TM2 and AS1 of HAMP. AS1 is shown in blue, AS2 is shown in red, and the 14-residue AS1-AS2 connector (CTR) is shown in black. The residue equivalent to Arg-214 in Tar_Ec is also highlighted in blue, the conserved Pro residue (Pro-219 in Tar_Ec) is highlighted in yellow, and residues equivalent to the MLLT sequence between TM2 and Pro-219 in Tar_Ec are highlighted in cyan.The determination of a high-resolution three-dimensional structure of a HAMP domain from an MCP remains elusive. However, a solution nuclear magnetic resonance (NMR) structure of a HAMP domain has been determined for the Af1503 protein of unknown function from the archaeal thermophile Archeoglobus fulgidus (22). The domain forms a parallel four-helix bundle, with two amphipathic helices, AS1 and AS2, being contributed by each subunit (Fig. ​(Fig.1B).1B). In this structure, the helices pack in an unusual x-da configuration, commonly referred to as knobs-to-knobs packing, in which the large hydrophobic x residues stabilize both intrasubunit and intersubunit interactions.Evidence for the existence of a four-helix HAMP bundle within intact receptors comes from disulfide cross-linking experiments with Salmonella enterica Tar (Tar_Se) (41) and the E. coli Aer redox receptor (Aer_Ec) (44). In vivo genetic studies (1, 48) are also consistent with the existence of a four-helix bundle in the E. coli Tsr receptor (Tsr_Ec).Tar_Ec functions as the aspartate chemoreceptor in E. coli (39). Each monomer within the homodimeric (15, 29) receptor possess a periplasmic ligand-binding domain composed of four antiparallel α helices that form four-helix bundles (8). The transmembrane regions that flank this periplasmic domain (transmembrane helix 1 [TM1] and TM2) are extensions of the periplasmic helices PD1 and PD4 (27, 33, 37, 40). Aspartate binds at either of two rotationally symmetrical sites at the dimer interface. Each binding site contains residues from PD1 of one subunit and PD1′ and PD4′ of the other. Aspartate binding generates a small (∼1- to 3-Å) vertical displacement into the cytoplasm of one contiguous PD4-TM2 helix relative to the other (14).E. coli Tar (Tar_Ec) and other chemoreceptors normally activate the histidine protein kinase CheA (5), which is coupled to the receptors via the adapter protein CheW. CheA autophosphorylates, and the phosphoryl group is subsequently transferred to the response regulator CheY (21). CheY-P interacts with FliM within the flagellar motor to promote clockwise (CW) rotation of the flagella (36, 46). Counterclockwise (CCW) motor rotation allows the flagellar filaments to coalesce into a bundle that propels the cell in a run (38). CW rotation of one or more flagella disrupts the bundle and generates a tumble (43). Therefore, the relative activities of CheA and the CheY-P phosphatase, CheZ, establish the ratio of CheY to CheY-P within the cell and hence the frequency of tumbling (11, 21).The conformational changes induced by aspartate convert Tar_Ec from a stimulator of CheA activity into an inhibitor (6). The resulting drop in CheY-P activity, which is accelerated by CheZ, suppresses tumbling and lengthens the average run. Inhibition of CheA activity is reversed by covalent methylation of the cognate receptor (17). Methylation is facilitated by a transient decrease in the level of the active, phosphorylated form of the CheB methylesterase (26), which is another substrate for phosphotransfer from CheA (21). The well-studied properties of this system, and the possibility of monitoring several different in vivo parameters, make it amenable for examining signal transduction between TM2 and the adjoining HAMP domain.The apical region of AS1 in Tar_Ec is composed of the tetrapeptide Met-Leu-Leu-Thr, which connects residue Arg-214 at the end of TM2 with the conserved Pro-219 residue within AS1 of the HAMP domain (Fig. ​(Fig.1B).1B). The corresponding sequence is Thr-Ile-Thr-Arg in the Af1503 HAMP domain. In the NMR structure of the isolated Af1503 HAMP, the corresponding four residues (Thr-Ile-Thr-Arg) comprise an unpaired helical extension of the N terminus of AS1 before Pro-283 (9, 22), but it is unclear how these residues may pack in an intact membrane-spanning protein. In the Af1503 HAMP, Pro-283 packs against residues Glu-311 and Ile-312, which form the N terminus of AS2. The residues at the equivalent positions in Tar_Ec are Glu-246 and Met-247 (Fig. ​(Fig.1B1B).We modified the length and residue composition of the region between Arg-214 and Pro-219 in Tar_Ec in different ways and monitored the ability of the mutant proteins to support chemotactic migration, to generate the clockwise flagellar rotation that reflects CheA activation, and to regulate adaptive methylation. The results support a model in which the structural tension exerted by TM2 on AS1 controls its signaling state, as proposed by Zhou et al. (48). In the context of that model, the results suggest that when the receptor is in the kinase-inhibiting state, the HAMP domain is in a stable four-helix bundle.     

Site-directed spin labeling of a bacterial chemoreceptor reveals a dynamic, loosely packed transmembrane domain

We used site-directed spin labeling and electron paramagnetic resonance spectroscopy to investigate dynamics and helical packing in the four-helix transmembrane domain of the homodimeric bacterial chemoreceptor Trg. We focused on the first transmembrane helix, TM1, particularly on the nine-residue sequence nearest the periplasm, because patterns of disulfide formation between introduced cysteines had identified that segment as the region of closest approach among neighboring transmembrane helices. Along this sequence, mobility and accessibility of the introduced spin label were characteristic of loosely packed or solvent-exposed side chains. This was also the case for eight additional positions around the circumference and along the length of TM1. For the continuous nine-residue sequence near the periplasm, mobility and accessibility varied only modestly as a function of position. We conclude that side chains of TM1 that face the interior of the four-helix domain interact with neighboring helices but dynamic movement results in loose packing. Compared to transmembrane segments of other membrane proteins reconstituted into lipid bilayers and characterized by site-directed spin labeling, TM1 of chemoreceptor Trg is the most dynamic and loosely packed. A dynamic, loosely packed chemoreceptor domain can account for many experimental observations about the transmembrane domains of chemoreceptors.     

Transmembrane redox control and proteolysis of PdeC,a novel type of c‐di‐GMP phosphodiesterase

The nucleotide second messenger c‐di‐GMP nearly ubiquitously promotes bacterial biofilm formation, with enzymes that synthesize and degrade c‐di‐GMP being controlled by diverse N‐terminal sensor domains. Here, we describe a novel class of widely occurring c‐di‐GMP phosphodiesterases (PDE) that feature a periplasmic “CSS domain” with two highly conserved cysteines that is flanked by two transmembrane regions (TM1 and TM2) and followed by a cytoplasmic EAL domain with PDE activity. Using PdeC, one of the five CSS domain PDEs of Escherichia coli K‐12, we show that DsbA/DsbB‐promoted disulfide bond formation in the CSS domain reduces PDE activity. By contrast, the free thiol form is enzymatically highly active, with the TM2 region promoting dimerization. Moreover, this form is processed by periplasmic proteases DegP and DegQ, yielding a highly active TM2 + EAL fragment that is slowly removed by further proteolysis. Similar redox control and proteolysis was also observed for a second CSS domain PDE, PdeB. At the physiological level, CSS domain PDEs modulate production and supracellular architecture of extracellular matrix polymers in the deeper layers of mature E. coli biofilms.     

Evidence that the adaptation region of the aspartate receptor is a dynamic four-helix bundle: cysteine and disulfide scanning studies

The aspartate receptor is one of the ligand-specific, homodimeric chemoreceptors that detects extracellular attractants and triggers the chemotaxis pathway of Escherichia coli and Salmonella typhimurium. This receptor regulates the activity of the histidine kinase CheA, which forms a kinetically stable complex with the receptor cytoplasmic domain. An atomic four-helix bundle model has been constructed for this domain, which is functionally subdivided into the signaling and adaptation subdomains. The proposed four-helix bundle structure of the signaling subdomain, which binds CheA, is fully supported by experimental evidence. Much less evidence is available to test the four-helix bundle model of the adaptation subdomain, which possesses covalent adaptation sites and docking surfaces for adaptation enzymes. The present study focuses on a putative helix near the C terminus of the adaptation subdomain. To probe the structural and functional features of positions G467-A494 in this C-terminal region, a cysteine and disulfide scanning approach has been employed. Measurement of the chemical reactivities of scanned cysteines reveals an alpha-helical periodicity of exposed and buried residues, confirming alpha-helical secondary structure and mapping out a buried packing face. The effects of cysteine substitutions on activity in vivo and in vitro highlight the functional importance of the helix, especially its buried face. A scan for disulfide bond formation between symmetric pairs of engineered cysteines reveals promiscuous collisions between subunits, indicating the presence of significant thermal dynamics. A scan for functional disulfides reveals lock-on and signal-retaining disulfide bonds formed between symmetric pairs of cysteines at buried positions, indicating that the buried face of the helix lies near the subunit interface of the homodimer in the equilibrium structures of both the apo and aspartate-bound states where it plays a critical role in kinase regulation. These results strongly support the existing four-helix bundle model of the adaptation subdomain structure. A mechanistic model is proposed in which a signal is transmitted through the adaptation subdomain by a change in supercoiling of the four-helix bundle.     

Signalling substitutions in the periplasmic domain of chemoreceptor Trg induce or reduce helical sliding in the transmembrane domain

We used in vivo oxidative cross-linking of engineered cysteine pairs to assess conformational changes in the four-helix transmembrane domain of chemoreceptor Trg. Extending previous work, we searched for and found a fourth cross-linking pair that spanned the intrasubunit interface between transmembrane helix 1 (TM1) and its partner TM2. We determined the effects of ligand occupancy on cross-linking rate constants for all four TM1-TM2 diagnostic pairs in conditions that allowed the formation of receptor-kinase complexes for the entire cellular complement of Trg. Occupancy altered all four rates in a pattern that implicated sliding of TM2 relative to TM1 towards the cytoplasm as the transmembrane signalling movement in receptor-kinase complexes. Transmembrane signalling can be reduced or induced by single amino acid substitutions in the ligand-binding region of the periplasmic domain of Trg. We determined the effects of these substitutions on conformation in the transmembrane domain and on ligand-induced changes using the diagnostic TM1-TM2 cysteine pairs. Effects on rates of in vivo cross-linking showed that induced signalling substitutions altered the relative positions of TM1 and TM2 in the same way as ligand binding, and reduced signalling substitutions blocked or attenuated the ligand-induced shift. These results provide strong support for the helical sliding model of transmembrane signalling.     

The Intimin periplasmic domain mediates dimerisation and binding to peptidoglycan

Intimin and Invasin are prototypical inverse (Type Ve) autotransporters and important virulence factors of enteropathogenic Escherichia coli and Yersinia spp. respectively. In addition to a C‐terminal extracellular domain and a β‐barrel transmembrane domain, both proteins also contain a short N‐terminal periplasmic domain that, in Intimin, includes a lysin motif (LysM), which is thought to mediate binding to peptidoglycan. We show that the periplasmic domain of Intimin does bind to peptidoglycan both in vitro and in vivo, but only under acidic conditions. We were able to determine a dissociation constant of 0.8 μM for this interaction, whereas the Invasin periplasmic domain, which lacks a LysM, bound only weakly in vitro and failed to bind peptidoglycan in vivo. We present the solution structure of the Intimin LysM, which has an additional α‐helix conserved within inverse autotransporter LysMs but lacking in others. In contrast to previous reports, we demonstrate that the periplasmic domain of Intimin mediates dimerisation. We further show that dimerisation and peptidoglycan binding are general features of LysM‐containing inverse autotransporters. Peptidoglycan binding by the periplasmic domain in the infection process may aid in resisting mechanical and chemical stress during transit through the gastrointestinal tract.