Requirements for osmosensing and osmotic activation of transporter ProP from Escherichia coli

Transporter ProP of Escherichia coli, a solute-H+ symporter, can sense and respond to osmotic upshifts imposed on cells, on membrane vesicles, or on proteoliposomes that incorporate purified ProP-(His)6. In this study, proline uptake catalyzed by ProP was used as a measure of its osmotic activation, and the requirements for osmosensing were defined using the proteoliposome system. The initial rate of proline uptake increased with decreasing external pH and increasing DeltaPsi, lumen negative. Osmotic upshifts increased DeltaPsi by concentrating lumenal K+, but osmotic activation of ProP could be distinguished from this effect. Osmotic activation of ProP resulted from changes in Vmax, though osmotic shifts also increased the KM for proline. Osmotic activation could be described as a reversible, osmotic upshift-dependent transition linking (at least) two transporter protein conformations. No correlation was observed between ProP activation and the position of the anions of activating sodium salts within the Hofmeister series of solutes. Both the magnitude of the osmotic upshift required to activate ProP and the ProP activity attained were similar for membrane-impermeant osmolytes, including NaCl, glucose, and PEG 600. The membrane-permeant osmolytes glycerol, urea, PEG 62, and PEG 106 failed to activate ProP. Two poly(ethylene glycol)s, PEG 150 and PEG 200, were membrane-permeant and did not cause liposome shrinkage, but they did partially activate ProP-(His)6.     

Creation of a fully functional cysteine-less variant of osmosensor and proton-osmoprotectant symporter ProP from Escherichia coli and its application to assess the transporter's membrane orientation

Transporter ProP of Escherichia coli is an osmosensor and an osmoprotectant transporter. Previous results suggest that medium osmolality determines the proportions of ProP in active and inactive conformations. A cysteine-less (Cys-less) variant was created and characterized as a basis for structural and functional analyses based on site-directed Cys substitution and chemical labeling of ProP. Parameters describing the osmosensory and osmoprotectant transport activities of Cys-less ProP-(His)(6) variants were examined, including the threshold for osmotic activation and the absolute transporter activity at high osmolality (in both cells and proteoliposomes), the dependence of K(M) and V(max) for proline uptake on osmolality, and the rate constant for transporter activation in response to an osmotic upshift (in cells only). Variant ProP-(His)(6)-C112A-C133A-C264V-C367A (designated ProP) retained similar activities to ProP-(His)(6) in both cells and proteoliposomes. The bulky Val residue was favored over Ala or Ser at position 264, whereas Val strongly impaired function when placed at position 367, highlighting the importance of residues at those positions for osmosensing. In the ProP* background, variants with a single Cys residue at positions 112, 133, 241, 264, 293, or 367 retained full function. The native Cys at positions 112, 133, 264, and 367, predicted to be within transmembrane segments of ProP, were poorly reactive with membrane-impermeant thiol reagents. The reactivities of Cys at positions 241 and 293 were consistent with exposure of those residues on the cytoplasmic and periplasmic surfaces of the cytoplasmic membrane, respectively. These observations are consistent with the topology and orientation of ProP predicted by hydropathy analysis.     

Osmosensor ProP of Escherichia coli responds to the concentration,chemistry, and molecular size of osmolytes in the proteoliposome lumen

Transporter ProP of Escherichia coli mediates the cellular accumulation of organic zwitterions in response to increased extracellular osmolality. We compared and characterized the osmoregulation of ProP activity in cells and proteoliposomes to define the osmotic shift-induced cellular change(s) to which ProP responds. ProP-(His)(6) activity in cells and proteoliposomes was correlated with medium osmolality, not osmotic shift, turgor pressure, or membrane strain. Both K(M) and V(max) for proline uptake via ProP-(His)(6) increased with increasing medium osmolality, as would be expected if osmolality controls the proportions of transporter with inactive and active conformations. The osmolality yielding half-maximal ProP-(His)(6) activity was higher in proteoliposomes than in cells. The osmolality response of ProP is also attenuated in bacteria lacking soluble protein ProQ. Indeed, the catalytic constant (k(cat)) for ProP-(His)(6) in proteoliposomes approximated that of ProP in intact bacteria lacking ProQ. Thus, the proteoliposome system may replicate a primary osmosensory response that can be further amplified by ProQ. ProP-(His)(6) is designated as an osmosensor because its activity is dependent on the osmolality, but not the composition, of the assay medium to which the cell surface is exposed. In contrast, ProP-(His)(6) activity was dependent on both the osmolality and the composition of the lumen in osmolyte-loaded proteoliposomes. For proteoliposomes containing inorganic salts, glucose, or poly(ethylene glycol) 503, transporter activity correlated with total lumenal cation concentration. In contrast, for proteoliposomes loaded with larger poly(ethylene glycol)s, the osmolality, the lumenal cation concentration, and the lumenal ionic strength at half-maximal transporter activity decreased systematically with poly(ethylene glycol) radius of gyration (range 0.8-1.8 nm). These data suggest that ProP-(His)(6) responds to osmotically induced changes in both cytoplasmic K(+) levels and the concentration of cytoplasmic macromolecules.     

The role of the carboxyl terminal alpha-helical coiled-coil domain in osmosensing by transporter ProP of Escherichia coli

Concentrative uptake of osmoprotectants via transporter ProP contributes to the rehydration of Escherichia coli cells that encounter high osmolality media. A member of the major facilitator superfamily, ProP is activated by osmotic upshifts in whole bacteria, in cytoplasmic membrane vesicles and in proteoliposomes prepared with the purified protein. Soluble protein ProQ is also required for full osmotic activation of ProP in vivo. ProP is differentiated from structural and functional homologues by its osmotic activation and its C-terminal extension, which is predicted to form an alpha-helical coiled-coil. A synthetic polypeptide corresponding to the C-terminus of ProP (ProP-p) formed a dimeric alpha-helical coiled-coil. A derivative of transporter ProP lacking 26 C-terminal amino acids was expressed but inactive. A derivative harbouring amino acid changes K460I, Y467I and H495I (each at the core, coiled-coil 'a' position) required a larger osmotic upshift for activation than did the wild type transporter. The same changes extended, stabilized and altered the oligomeric state of the coiled-coil formed by ProP-p. Amino acid change R488I (also at the 'a' position) further increased the magnitude of the osmotic upshift required to activate ProP, reduced the activity attained and rendered ProP activation transient. Unexpectedly, replacement R488I destabilized the coiled-coil formed by ProP-p. The activity and osmotic activation of ProP were even more strongly attenuated by helix-destabilizing change I474P. These data demonstrate that the carboxyl terminal domain of ProP can form a homodimeric alpha-helical coiled-coil with unusual properties. They implicate the C-terminal domain in the osmotic activation of ProP.     

Formation of an antiparallel, intermolecular coiled coil is associated with in vivo dimerization of osmosensor and osmoprotectant transporter ProP in Escherichia coli

Membrane transporter ProP from Escherichia coli senses extracellular osmolality and responds by mediating the uptake of osmoprotectants such as glycine betaine when osmolality is high. Earlier EPR and NMR studies showed that a peptide replica of the cytoplasmic ProP carboxyl terminus (residues D468-R497) forms a homodimeric, antiparallel, alpha-helical coiled coil in vitro stabilized by electrostatic interactions involving R488. Amino acid replacement R488I disrupted coiled-coil formation by the ProP peptide, elevated the osmolality at which ProP became active, and rendered the osmolality response of ProP transient. In the present study, either E480 or K473 was replaced with cysteine (Cys) in ProP, a Cys-less, fully functional, histidine-tagged ProP variant, to use Cys-specific cross-linking approaches to determine if antiparallel coiled-coil formation and dimerization of the intact protein occur in vivo. The Cys at positions 480 would be closer in an antiparallel dimer than those at positions 473. These replacements did not disrupt coiled-coil formation by the ProP peptide. Partial homodimerization of variant ProP-E480C could be demonstrated in vivo and in membrane preparations via Cys-specific cross-linking with dithiobis(maleimidoethane) or by Cys oxidation to cystine by copper phenanthroline. In contrast, these reagents did not cross-link ProP with Cys at position 133 or 241. Cross-linking of ProP with Cys at position 473 was limited and occurred only if ProP was overexpressed, consistent with an antiparallel orientation of the coiled coil in the intact protein in vivo. Although replacement E480C did not alter transporter activity, replacement K473C reduced the extent and elevated the threshold for osmotic activation. K473 may play a role in ProP structure and function that is not reflected in altered coiled-coil formation by the corresponding peptide. Substitution R488I affected the activities of ProP-(His)(6), ProP-E480C, and ProP-K473C as it affected the activity of ProP. Surprisingly, it did not eliminate cross-linking of Cys at position 480, and it elevated cross-linking at position 473, even when ProP was expressed at physiological levels. This suggested that the R488I substitution may have changed the relative orientation of the C-termini within the dimeric protein from antiparallel to parallel, resulting in only transient osmotic activation. These results suggest that ProP is in monomer-dimer equilibrium in vivo. Dimerization may be mediated by C-terminal coiled-coil formation and/or by interactions between other structural domains, which in turn facilitate C-terminal coiled-coil formation. Antiparallel coiled-coil formation is required for activation of ProP at low osmolality.     

Cardiolipin controls the osmotic stress response and the subcellular location of transporter ProP in Escherichia coli

The phospholipid composition of the membrane and transporter structure control the subcellular location and function of osmosensory transporter ProP in Escherichia coli. Growth in media of increasing osmolality increases, and entry to stationary phase decreases, the proportion of phosphatidate in anionic lipids (phosphatidylglycerol (PG) plus cardiolipin (CL)). Both treatments increase the CL:PG ratio. Transporters ProP and LacY are concentrated with CL (and not PG) near cell poles and septa. The polar concentration of ProP is CL-dependent. Here we show that the polar concentration of LacY is CL-independent. The osmotic activation threshold of ProP was directly proportional to the CL content of wild type bacteria, the PG content of CL-deficient bacteria, and the anionic lipid content of cells and proteoliposomes. CL was effective at a lower concentration in cells than in proteoliposomes, and at a much lower concentration than PG in either system. Thus, in wild type bacteria, osmotic induction of CL synthesis and concentration of ProP with CL at the cell poles adjust the osmotic activation threshold of ProP to match ambient conditions. ProP proteins linked by homodimeric, C-terminal coiled-coils are known to activate at lower osmolalities than those without such structures and coiled-coil disrupting mutations raise the osmotic activation threshold. Here we show that these mutations also prevent polar concentration of ProP. Stabilization of the C-terminal coiled-coil by covalent cross-linking of introduced Cys reverses the impact of increasing CL on the osmotic activation of ProP. Association of ProP C termini with the CL-rich membrane at cell poles may raise the osmotic activation threshold by blocking coiled-coil formation. Mutations that block coiled-coil formation may also block association of the C termini with the CL-rich membrane.     

The osmotic activation of transporter ProP is tuned by both its C-terminal coiled-coil and osmotically induced changes in phospholipid composition

Transporter ProP of Escherichia coli (ProPEc) senses extracellular osmolality and mediates osmoprotectant uptake when it is rising or high. A replica of the ProPEc C terminus (Asp468-Arg497) forms an intermolecular alpha-helical coiled-coil. This structure is implicated in the osmoregulation of intact ProPEc, in vivo. Like that from Corynebacterium glutamicum (ProPCg), the ProP orthologue from Agrobacterium tumefaciens (ProPAt) sensed and responded to extracellular osmolality after expression in E. coli. The osmotic activation profiles of all three orthologues depended on the osmolality of the bacterial growth medium, the osmolality required for activation rising as the growth osmolality approached 0.7 mol/kg. Thus, each could undergo osmotic adaptation. The proportion of cardiolipin in a polar lipid extract from E. coli increased with extracellular osmolality so that the osmolality activating ProPEc was a direct function of membrane cardiolipin content. Group A ProP orthologues (ProPEc, ProPAt) share the C-terminal coiled-coil domain and were activated at low osmolalities. Like variant ProPEc-R488I, in which the C-terminal coiled-coil is disrupted, ProPEc derivatives that lack the coiled-coil and Group B orthologue ProPCg required a higher osmolality to activate. The amplitude of ProPEc activation was reduced 10-fold in its deletion derivatives. The coiled-coil structure is not essential for osmotic activation of ProP per se. However, it tunes Group A orthologues to osmoregulate over a low osmolality range. Coiled-coil lesions may impair both coiled-coil formation and interaction of ProPEc with amplifier protein ProQ. Cardiolipin may contribute to ProP adaptation by altering bulk membrane properties or by acting as a ProP ligand.     

Bacterial osmosensing: roles of membrane structure and electrostatics in lipid-protein and protein-protein interactions

Bacteria act to maintain their hydration when the osmotic pressure of their environment changes. When the external osmolality decreases (osmotic downshift), mechanosensitive channels are activated to release low molecular weight osmolytes (and hence water) from the cytoplasm. Upon osmotic upshift, osmoregulatory transporters are activated to import osmolytes (and hence water). Osmoregulatory channels and transporters sense and respond to osmotic stress via different mechanisms. Mechanosensitive channel MscL senses the increasing tension in the membrane and appears to gate when the lateral pressure in the acyl chain region of the lipids drops below a threshold value. Transporters OpuA, BetP and ProP are activated when increasing external osmolality causes threshold ionic concentrations in excess of about 0.05 M to be reached in the proteoliposome lumen. The threshold activation concentrations for the OpuA transporter are strongly dependent on the fraction of anionic lipids that surround the cytoplasmic face of the protein. The higher the fraction of anionic lipids, the higher the threshold ionic concentrations. A similar trend is observed for the BetP transporter. The lipid dependence of osmotic activation of OpuA and BetP suggests that osmotic signals are transmitted to the protein via interactions between charged osmosensor domains and the ionic headgroups of the lipids in the membrane. The charged, C-terminal domains of BetP and ProP are important for osmosensing. The C-terminal domain of ProP participates in homodimeric coiled-coil formation and it may interact with the membrane lipids and soluble protein ProQ. The activation of ProP by lumenal, macromolecular solutes at constant ionic strength indicates that its structure and activity may also respond to macromolecular crowding. This excluded volume effect may restrict the range over which the osmosensing domain can electrostatically interact. A simplified version of the dissociative double layer theory is used to explain the activation of the transporters by showing how changes in ion concentration could modulate interactions between charged osmosensor domains and charged lipid or protein surfaces. Importantly, the relatively high ionic concentrations at which osmosensors become activated at different surface charge densities compare well with the predicted dependence of 'critical' ion concentrations on surface charge density. The critical ion concentrations represent transitions in Maxwellian ionic distributions at which the surface potential reaches 25.7 mV for monovalent ions. The osmosensing mechanism is qualitatively described as an "ON/OFF switch" representing thermally relaxed and electrostatically locked protein conformations.     

Expression of eukaryotic plasma membrane transporter HUP1 from Chlorella kessleri in Escherichia coli

To study the effect of sterols on the activity of the eukaryotic plasma membrane transporter, the hexose-proton symporter HUP1 from the unicellular alga Chlorella kessleri was expressed in Escherichia coli, a prokaryotic microorganism containing virtually no sterols. Under certain conditions, the recombinant protein was partially active in this prokaryotic organism. The heterologously produced HUP1p was purified from membrane fractions of E. coli and reconstituted in an in vitro system. The presence of ergosterol during solubilization, purification and reconstitution resulted in an increased activity of the reconstituted protein. Its activity, however, was 5-6 times lower as compared to the activity of HUP1p produced in Saccharomyces cerevisiae membranes and solubilized, purified, and reconstituted under the same conditions as above.     

On the osmotic signal and osmosensing mechanism of an ABC transport system for glycine betaine.

The osmosensing mechanism of the ATP-binding cassette (ABC) transporter OpuA of Lactococcus lactis has been elucidated for the protein reconstituted in liposomes. Activation of OpuA by osmotic upshift was instantaneous and reversible and followed changes in volume and membrane structure of the proteoliposomes. Osmotic activation of OpuA was dependent on the fraction of anionic lipids present in the lipid bilayer. Also, cationic and anionic lipophilic amphiphiles shifted the activation profile in a manner indicative of an osmosensing mechanism, in which electrostatic interactions between lipid headgroups and the OpuA protein play a major role. Further support for this notion came from experiments in which ATP-driven uptake and substrate-dependent ATP hydrolysis were measured with varying concentrations of osmolytes at the cytoplasmic face of the protein. Under iso-osmotic conditions, the transporter could be activated by high concentrations of ionic osmolytes, whereas neutral ones had no effect, demonstrating that intracellular ionic strength, rather than a specific signaling molecule or water activity, signals osmotic stress to the transporter. The data indicate that OpuA is under the control of a mechanism in which the membrane and ionic strength act in concert to signal osmotic changes.     

Role of heat shock protein DnaK in osmotic adaptation of Escherichia coli.

Escherichia coli can adapt and recover growth at high osmolarity. Adaptation requires the deplasmolysis of cells previously plasmolyzed by the fast efflux of water promoted by osmotic upshift. Deplasmolysis is essentially ensured by a net osmo-dependent influx of K+. The cellular content of the heat shock protein DnaK is increased in response to osmotic upshift and does not decrease as long as osmolarity is high. The dnaK756(Ts) mutant, which fails to deplasmolyze and recover growth, does not take up K+ at high osmolarity; DnaK protein is required directly or indirectly for the maintenance of K+ transport at high osmolarity. The temperature-sensitive mutations dnaJ259 and grpE280 do not affect the osmoadaptation of E. coli at 30 degrees C.     

Overexpression and purification of the three components of the Enterobacter aerogenes AcrA-AcrB-TolC multidrug efflux pump

The tripartite AcrA-AcrB-TolC system is the major efflux pump of the nosocomial pathogen Enterobacter aerogenes. AcrA is a trimeric periplasmic lipoprotein anchored in the inner membrane, AcrB is an inner membrane transporter and TolC is a trimeric outer membrane channel. In order to reconstitute the AcrA-AcrB-TolC system of E. aerogenes in artificial membranes, we overexpressed and purified the three proteins. The E. aerogenes acrA, acrB and tolC open reading frames were individually inserted in the expression vector pET24a(+), in frame with a sequence coding a C-terminal hexahistidine tag to allow purification by INAC (Immobilized Nickel Affinity Chromatography). The mature AcrA-6His was overproduced in a soluble form in the cytoplasm of Escherichia coli BL21(DE3). AcrA-6His was purified under native conditions in two steps using INAC and gel permeation chromatography. We obtained about 25 mg of 97% pure AcrA-6His per liter of culture. AcrB-6His was solubilized from the membrane fraction of E. coli C43(DE3) in 300 mM NaCl, 5% Triton X-100 and purified in one step by INAC. The AcrB-6His enriched fraction was eluted with 100 mM imidazole. The final yield was 1-2 mg of 95% pure AcrB-6His per liter of culture. The membrane fraction of E. coli BL21(DE3)pLysS containing TolC-6His was first treated with 2% Triton X-100, 30 mM MgCl(2) to solubilize the inner membrane proteins. After ultracentrifugation, the pellet was treated with 5% Triton X-100, 5 mM EDTA to solubilize the outer membrane proteins. Approximately 5 mg of 95% pure TolC-6His trimers per liter of culture was purified by INAC.     

Structure and function of transmembrane segment XII in osmosensor and osmoprotectant transporter ProP of Escherichia coli

Escherichia coli transporter ProP acts as both an osmosensor and an osmoregulator. As medium osmolality rises, ProP is activated and mediates H+-coupled uptake of osmolytes like proline. A homology model of ProP with 12-transmembrane (TM) helices and cytoplasmic termini was created, and the protein's topology was substantiated experimentally. Residues 468-497, at the end of the C-terminal domain and linked to TM XII, form an intermolecular, homodimeric alpha-helical coiled-coil that tunes the transporter's response to osmolality. We aim to further define the structure and function of ProP residues Q415-E440, predicted to include TM XII. Each residue was replaced with cysteine (Cys) in a histidine-tagged, Cys-less ProP variant (ProP*). Cys at positions 415-418 and 438-440 were most reactive with Oregon Green Maleimide (OGM), suggesting that residues 419 through 437 are in the membrane. Except for V429-I433, reactivity of those Cys varied with helical periodicity. Cys predicted to face the interior of ProP were more reactive than Cys predicted to face the lipid. The former may be exposed to hydrated polar residues in the protein interior, particularly on the periplasmic side. Intermolecular cross-links formed when ProP* variants with Cys at positions 419, 420, 422, and 439 were treated with DTME. Thus TM XII can participate, along its entire length, in the dimer interface of ProP. Cys substitution E440C rendered ProP* inactive. All other variants retained more than 30% of the proline uptake activity of ProP* at high osmolality. Most variants with Cys substitutions in the periplasmic half of TM XII activated at lower osmolalities than ProP*. Variants with Cys substitutions on one face of the cytoplasmic half of TM XII required a higher osmolality to activate. They included elements of a GXXXG motif that are predicted to form the interface of TM XII with TM VII. These studies define the position of ProP TM XII within the membrane, further support the predicted structure of ProP, reveal the dimerization interface, and show that the structure of TM XII influences the osmolality at which ProP activates.     

Osmoprotection of Escherichia coli by ectoine: uptake and accumulation characteristics.

Ectoine (1,4,5,6-tetrahydro-2-methyl-4-pyrimidinecarboxylic acid) is a cyclic amino acid, identified as a compatible solute in moderately halophilic bacteria. Exogenously provided ectoine was found to stimulate growth of Escherichia coli in media of inhibitory osmotic strength. The stimulation was independent of any specific solute, electrolyte or nonelectrolyte. It is accumulated in E. coli cells proportionally to the osmotic strength of the medium, and it is not metabolized. Its osmoprotective ability was as potent as that of glycine betaine. The ProP and ProU systems are both involved in ectoine uptake and accumulation in E. coli. ProP being the main system for ectoine transport. The intracellular ectoine pool is regulated by both influx and efflux systems.     

The role of antioxidant enzymes in response of Escherichia coli to osmotic upshift

Aerobic growth of Escherichia coli sodAsodB and katE mutants lacking cytosolic superoxide dismutases and catalase hydroperoxidase II was inhibited by osmotic upshift to a greater extent than of their wild-type parent strains. The fur mutation leading to an intracellular overload of iron also increased sensitivity of growing E. coli cells to osmotic upshift. Using lacZ fusions, it was shown that expression of antioxidant genes soxS and katE was stimulated by an increase in osmolarity. These data suggest that in aerobically growing E. coli cells, moderate osmotic upshift causes activation of certain antioxidant systems.     

Roles of K+, H+, H2O, and DeltaPsi in solute transport mediated by major facilitator superfamily members ProP and LacY

H (+)-solute symporters ProP and LacY are members of the major facilitator superfamily. ProP mediates osmoprotectant (e.g., proline) accumulation, whereas LacY transports the nutrient lactose. The roles of K (+), H (+), H 2O, and DeltaPsi in H (+)-proline and H (+)-lactose symport were compared using right-side-out cytoplasmic membrane vesicles (MVs) from bacteria expressing both transporters and proteoliposomes (PRLs) reconstituted with pure ProP-His 6. ProP activity increased as LacY activity decreased when osmotic stress (increasing osmolality) was imposed on MVs. The activities of both transporters decreased to similar extents when Na (+) replaced K (+) in MV preparations. Thus, K (+) did not specifically control ProP activity. As with LacY, an increasing extravesicular pH stimulated ProP-mediated proline efflux much more than ProP-mediated proline exchange from de-energized MVs. In contrast to that of LacY, ProP-mediated exchange was only 2-fold faster than ProP-mediated efflux and was inhibited by respiration. In the absence of the protonmotive force (Deltamu H (+) ), efflux of lactose from MVs was much more sensitive to increasing osmolality than lactose exchange. Thus, H 2O may be directly involved in proton transport via LacY. In the absence of Deltamu H (+) , proline efflux and exchange from MVs were osmolality-independent. In PRLs with a DeltapH of 1 (lumen alkaline), ProP-His 6 was inactive when the membrane potential (DeltaPsi) was zero, was active but insensitive to osmolality when DeltaPsi was -100 mV, and became osmolality-sensitive as DeltaPsi increased further to -137 mV. ProP-His 6 had the same membrane orientation in PRLs as in cells and MVs. ProP switches among "off", "on", and "osmolality-sensitive" states as the membrane potential increases. Kinetic parameters determined in the absence of Deltamu H (+) represent a ProP population that is predominantly off.