Sidedness of native membrane vesicles of Escherichia coli and orientation of the reconstituted lactose: H+ carrier

The orientation of the lactose:H+ carrier of Escherichia coli in various preparations of native and reconstituted vesicles is determined with two impermeant, macromolecular probes: antibodies directed against the C-terminal decapeptide of the carrier and carboxypeptidase A (EC 3.4.17.1). Two methods are employed. Method I is based upon the digestion of all accessible and, therefore, presumably external, C termini of the carrier with carboxypeptidase A and detection of the remaining, internal C termini with 125I-labelled anti-(C-terminus) antibody after electrophoresis of the carrier in the presence of sodium dodecyl sulfate and transfer to nitrocellulose filters. Method II is based upon the binding of 125I-labelled anti-(C-terminus) antibody to the external C termini of the carrier in vesicles and the subsequent isolation of bound antibody by centrifugation. The labelled antibodies are calibrated using a preparation of inside-out vesicles prepared by high-pressure lysis of strain T206. The carrier content is determined by substrate binding. Because the C terminus of the carrier is known to reside on the cytoplasmic side of the membrane, these methods can also be used to determine the sidedness of various preparations of membrane vesicles. Spheroplasts are confirmed to contain carrier molecules of a single orientation, corresponding to that in right-side-out vesicles. In contrast, in purified cytoplasmic membrane vesicles and in crude membrane preparations obtained by sonication or by high-pressure lysis, 96% of the C termini are accessible to carboxypeptidase A, even after repeated sonication. This implies that nearly all carrier molecules in these preparations possess an orientation opposite to that in the cell or in right-side-out vesicles. In proteoliposomes containing carrier reconstituted or purified and reconstituted by two different methods, only 48% of the carrier molecules are oriented in the same way as in the cell. Subjecting such proteoliposomes to cycles of freezing and thawing or to sonication results in a reshuffling of carrier molecules between the inside-out and right-side-out populations while maintaining 41% in the right-side-out orientation. Digestion of the C terminus of the carrier with carboxypeptidase A does not alter either galactoside binding or countertransport. Thus carrier molecules of the inside-out orientation cannot be selectively inactivated. Additionally, an antiserum directed against the purified carrier is demonstrated to contain nearly exclusively anti-(C-terminus) antibodies, which can, in principle, be used in Method I.(ABSTRACT TRUNCATED AT 400 WORDS)     

Sealed inside-out and right-side-out plasma membrane vesicles : optimal conditions for formation and separation

Plasma membrane preparations of high purity (about 95%) are easily obtained by partitioning in aqueous polymer two-phase systems. These preparations, however, mainly contain sealed right-side-out (apoplastic side out) vesicles. Part of these vesicles have been turned inside-out by freezing and thawing, and sealed inside-out and right-side-out vesicles subsequently separated by repeating the phase partition step. Increasing the KCI concentration in the freeze/thaw medium as well as increasing the number of freeze/thaw cycles significantly increased the yield of inside-out vesicles. At optimal conditions, 15 to 25% of total plasma membrane protein was recovered as inside-out vesicles, corresponding to 5 to 10 milligrams of protein from 500 grams of sugar beet (Beta vulgaris L.) leaves. Based on enzyme latency, trypsin inhibition of NADH-cytochrome c reductase, and H⁺ pumping capacity, a cross-contamination of about 20% between the two fractions of oppositely oriented vesicles was estimated. Thus, preparations containing about 80% inside-out and 80% right-side-out vesicles, respectively, were obtained. ATPase activity and H⁺ pumping were both completely inhibited by vanadate (K_i ≈ 10 micromolar), indicating that the fractions were completely free from nonplasma membrane ATPases. Furthermore, the polypeptide patterns of the two fractions were close to identical, which shows that the vesicles differed in sidedness only. Thus, preparations of both inside-out and right-side-out plasma membrane vesicles are now available. This permits studies on transport, signal transduction mechanisms, enzyme topology, etc., using plasma membrane vesicles of either orientation.     

Formation of inside-out vesicles of Bacillus licheniformis. Dependence on buffer composition and lysis procedure.

1. The extent to which the cytoplasmic membrane of the Gram-positive bacterium Bacillus licheniformis formed inside-out vesicles was studied with the freeze-fracture technique. The membrane orientation appeared to be dependent on the buffer compositon as well as on the lysis procedure used. 2. By manipulating these conditions, membrane preparations were obtained with the percentage of inside-out vesicles varying from 15 to 80%. 3. More vesicles had the opposite orientation when the cells were lysed in potassium phosphate buffer than when they were lysed in sodium phosphate buffer. Tris-HCl buffer favoured the formation of inside-out vesicles more than phosphate buffer. 4. Lysis of protoplasts in hypotonic buffers resulted in more inside-out vesicles than did direct lysis of cells in hypotonic media. 5. In an attempt to explain the observed differences, experiments were performed in which the morphology of thin-sectioned lysing cells in sodium phosphate buffer was compared with that in potassium phosphate buffer. The results from these experiments indicate that the formation of inside-out vesicles is brought about by an effect on the membrane itself rather than on the cell wall, on the cell wall membrane association, or on the cytoplasm.     

Localization of enzymes involved in polyphosphoinositids metabolism on the cytoplasmic surface of the human erythrocyte membrane.

1. Impermeable inside-out and right-side-out vesicles were prepared from membranes of human erythrocytes. During preparation of each kind of impermeable vesicle, permeable vesicles were also obtained. 2. Incubation of vesicles with [gamma-32P]ATP at 37 degrees C for periods of up to 1 hr did not change the topography or the permeability of the vesicles. 3. Vesicles incorporated labeled phosphate from [gamma-32P]ATP into both diphosphoinositide and triphosphoinositide, but impermeable inside-out vesicles incorporated significantly more nuclide than did right-side-out vesicles. 4. Permeable vesicles derived during the preparation of inside-out vesicles were as active as impermeable inside-out vesicles in the incorporation of labeled phosphate into the polyphosphoinositides. However, permeable vesicles derived during the preparation of right-side out vesicles were not as active. 5. Impermeable right-side-out vesicles, treated with 0.01 percent saponin, incorporated labeled phosphate into the polyphosphoinositides at a level comparable to that of impermeable inside-out vesicles. 6. These data show that the enzymes involved in metabolism of diphosphoinositide and triphosphoinositide are located on the cytoplasmic surface of the erythrocyte membrane.     

Monoclonal antibody against an epitope on the cytoplasmic aspect of the plasma membrane calcium pump

Monoclonal antibody PM4A2B was prepared by immunizing mice with calmodulin affinity purified Ca2+-Mg2+-adenosine triphosphatase from rabbit erythrocytes and screening the clones with a plasma membrane-enriched fraction (F1) from rabbit stomach smooth muscle. On Western blots, PM4A2B reacted with F1 and with ghosts, right-side-out vesicles, and inside-out vesicles prepared from erythrocytes giving one major band at 130 kDa and minor lower molecular weight bands whose intensity increased on freezing and thawing the membranes. On enzyme-linked immunosorbent assay, PM4A2B reacted with inside-out vesicles, but not with the right-side-out vesicles or ghosts prepared from erythrocytes. It activated the ATP-dependent Ca2+ uptake by F1 and by the inside-out vesicles prepared from the erythrocytes. PM4A2B should be useful in determining membrane sidedness as well as in investigating the mechanism of the sarcolemmal Ca2+ pump.     

Monoclonal antibodies against the lac carrier protein from Escherichia coli. 2. Binding studies with membrane vesicles and proteoliposomes reconstituted with purified lac carrier protein

Monoclonal antibodies 4B1 and 5F7 bind to distinct, nonoverlapping epitopes in the lac carrier protein. By use of immunofluorescence microscopy and radiolabeled monoclonal antibodies and Fab fragments, it is shown that both 4B1 and 5F7 bind to spheroplasts and to right-side-out vesicles, but only to a small extent to inside-out vesicles. Clearly, therefore, the lac carrier protein has an asymmetric orientation within the cytoplasmic membrane of Escherichia coli, and both epitopes are located on the periplasmic surface. In right-side-out vesicles, radiolabeled 4B1 binds with a stoichiometry of 1 mol of antibody per 2 mol of lac carrier protein, while radiolabeled 4B1 Fab fragments bind 1:1. Importantly, the intact antibody and its Fab fragments bind to proteoliposomes reconstituted with purified lac carrier protein with a stoichiometry very similar to that observed in right-side-out membrane vesicles. Thus, it seems highly likely that the orientation of the lac carrier protein in the reconstituted system is similar to that in the bacterial cytoplasmic membrane, at least with respect to 4B1 epitope.     

Orientation of the carboxyl terminus of the transposon Tn10-encoded tetracycline resistance protein in Escherichia coli

A site-directed antibody was generated against a synthetic polypeptide corresponding to the 14 amino acid residues of the carboxyl terminus of the Tn10 TetA protein. The antibody reacted preferentially with inside-out vesicles, rather than right-side-out vesicles, prepared from Escherichia coli cells harboring transposon Tn10. When inside-out vesicles were treated with trypsin, the TetA protein was completely digested in the vicinity of the carboxyl terminus, as judged on immunoblot analysis using the antibody. In contrast, when right-side-out vesicles were treated with trypsin, the TetA protein was hardly digested. These results indicate that the carboxyl terminus of TetA is exposed to the cytoplasmic side of the membrane.     

Functional mosaicism of membrane proteins in vesicles of Escherichia coli.

Membrane vesicles of Escherichia coli prepared by osmotic lysis of lysozyme ethylenediaminetetracetate (EDTA) spheroplasts have approximately 60% of the total membrane-bound reduced nicotinamide adenine dinucleotide (NADH) dehydrogenase (ED 1.6.99.3) and Mg2+-adenosine triphosphatase (ATPase) (EC 3.6.1.3) activities exposed on the outer surface of the inner membrane. Absorption of these vesicles with antiserum prepared against the purified soluble Mg2+-ATPase resulted in agglutination of approximately 95% of the inner membrane vesicles, as determined by dehydrogenase activity, and about 50% of the total membrane protein. The unagglutinated vesicles lacked all dehydrogenase activity and may consist of outer membrane. Lysozyme-EDTA vesicles actively transported calcium ion, using either NADH or adenosine 5'-triphosphate (ATP) as energy source. However, neither D-lactate nor reduced phenazine methosulfate energized calcium uptake, suggesting that the observed calcium uptake was not due to a small population of everted vesicles. Transport of calcium driven by either NADH or ATP was inhibited by simultaneous addition of D-lactate or reduced phenazine methosulfate. Proline transport driven by D-lactate oxidation was inhibited by either NADH oxidation or ATP hydrolysis. These results suggest that the portion of the total population of vesicles capable of active transport, i.e., the inner membrane vesicles, are functionally a homogeneous population but cannot be categorized as either right-side-out or everted, since activities normally associated with only one side of the inner membrane can be found on both sides of the membrane of these vesicles. Moreover, the data indicate that oxidation of NADH or hydrolysis of ATP by externally localized NADH dehydrogenase or Mg2+-ATPase establishes a protonmotive force of the opposite polarity from that established through D-lactate oxidation.     

Orientation of vesicles isolated from baso-lataral membranes of renal cortex

Baso-lateral membranes were isolated from the canine and porcine kidney cortex by several different methods currently in use. Sidedness of the isolated membrane vesicles was determined by procedures using 1. ouabain-sensitive (Na+K+)ATPase assays in the presence and in the absence of sodium dodecylsulfate or digitoxigenin plus monensin, 2. (Na+, K+, Mg2+)ATPase assays with valinomycin, 3. sialidase accessibility, and 4. binding of hydrophilic and lipophilic cardiac glycosides. The (Na+K+)ATPase activity in the membrane preparation was increased 10-fold of that found in the crude homogenate. Isolated membrane vesicles, prepared by different techniques, were all found to be overwhelmingly of right-side-out orientation;namely, right-side-out = 51-68%, inside-out = 4-13%, and unsealed vesicles = 26-42%. Results of sidedness determinations by different methods showed a good agreement. Thus, predominantly right-side-out oriented vesicles are formed during conventional isolation procedures for membranes of the kidney cortex.     

Fractionation of membrane vesicles from coliphage M13-infected Escherichia coli.

Membrane vesicles were prepared by osmotic lysis of spheroplasts from M13-infected Escherichia coli. Reduced nicotinamide adenine dinucleotide (NADH) oxidase (reduced NAD: oxidoreductase, EC 1.6.99.3) and Mg2+-Ca2+-activated adenosine triphosphatase (ATP phosphohydrolase, EC 3.6.1.3), which are normally localized to the inner surface of the cytoplasmic membrane, were 50% acceesible to their polar substrates in these vesicles. The major coat protein of coliphage M13 is also bound to the cytoplasmic membrane (prior to phage assembly) but with its antigenic sites exposed to the exterior of the cell. Antibody to M13 coat protein was used to fractionate membrane vesicles. Neither agglutinated nor unagglutinated vesicles had altered NADH oxidase and adenosine triphosphatase specific activities. This is inconsistent with such vesicles being a mixture of correctly oriented and completely inverted membrane sacs and suggests that NADH oxidase, adenosine triphosphatase, M13 coat protein, or all three proteins rearrange during vesicle preparation.     

Generation of a membrane potential by sodium-dependent succinate efflux in Selenomonas ruminantium.

When Selenomonas ruminantium HD4 was grown in a chemostat, maximal succinate production and the highest molar growth yield values were both observed at a dilution rate of roughly 0.2 h-1. To determine the possible relationship between succinate efflux and high molar growth yields, the generation of a membrane potential by succinate efflux was studied in whole cells and vesicles (inside-out and right-side-out) prepared from S. ruminantium. Washed whole cells took up succinate in the absence of an exogenous energy supply; uptake was completely abolished by brief treatment with dinitrophenol or with nigericin and valinomycin. High levels of sodium ions (with respect to the intracellular sodium concentration in the assay buffer had a stimulatory effect on succinate uptake. When succinate was added to inside-out vesicles, a membrane potential (inside positive) was generated, as indicated by fluorescence quenching of the anionic lipophilic dye Oxonol V. Fluorescence quenching was sensitive to uncoupling by gramicidin D but only partially sensitive to the uncoupler carbonyl cyanide-p-trifluoromethoxyphenylhydrazone. In right-side-out vesicles, succinate uptake could be driven by an artificially imposed sodium gradient but not by a potassium diffusion potential; imposition of both a sodium gradient and potassium diffusion potential resulted in improved succinate uptake. The generation of a membrane potential (inside negative) upon succinate efflux was demonstrated directly in right-side-out vesicles when succinate-loaded vesicles were diluted into succinate-free buffer, and the lipophilic cationic probe tetraphenylphosphonium accumulated in the vesicles. Results indicate that an electrogenic succinate-sodium symporter is present in S. ruminantium. Transport of succinate out of the cell via the symporter might be responsible for the high molar growth yields obtained by this organism when it is grown at dilution rates where maximal succinate production occurs.     

K+ and ionic strength directly influence the autophosphorylation activity of the putative turgor sensor KdpD of Escherichia coli

The membrane-bound histidine kinase KdpD is a putative turgor sensor that regulates, together with the response regulator KdpE, the expression of the kdpFABC operon coding for the high affinity K(+)-uptake system KdpFABC of Escherichia coli. To elucidate the nature of the primary stimulus for KdpD, we developed an in vitro assay based on right-side-out membrane vesicles. Conditions were varied inside and outside of the vesicles, and KdpD autophosphorylation activity was tested. It was shown that an increase of the ionic strength inside the vesicles was accompanied by an increase of the autophosphorylation activity of KdpD with ATP. However, K(+) at concentrations higher than 1 mm inhibited KdpD autophosphorylation activity. This K(+)-specific effect was not observed with KdpD-Arg-511 --> Gln, a KdpD derivative, which causes K(+)-independent kdpFABC expression. When the osmolality outside the vesicles was increased, autophosphorylation activity of KdpD was stimulated, whereby salts were more effective than sugars. Treatment of the vesicles with amphipathic compounds did not affect KdpD autophosphorylation activity. Based on these results it is proposed that changes of intracellular parameters elicited by K(+) limitation or osmotic upshock directly influence KdpD autophosphorylation activity, whereby K(+) has an inhibitory and ionic strength a stimulatory effect.     

Ca2+ transport and permeability in inside-out red cell membrane vesicles after freezing

To evaluate the effects of freezing and thawing on Ca2+ transport and permeability, inside-out red cell membrane vesicles (IORCMV) are examined. Exposure to the cryoprotectant Me2SO as well as different cooling regimes on unprotected and cryoprotected vesicles do not affect the membrane Ca2+ transport. However, freezing and thawing increase the membrane permeability to sucrose.     

Reconstitution of Escherichia coli membrane vesicles with D-amino acid dehydrogenase

When purified D-amino acid dehydrogenase [Olsiewski, P. J., Kaczorowski, G. J., & Walsh, C. T. (1980) J. Biol. Chem. 255, 4487] is incubated with right-side-out membrane vesicles from Escherichia coli, the enzyme binds to the membrane in a time- and concentration-dependent manner. As a result, the vesicles acquire the ability to oxidize D-alanine and catalyze D-alanine-dependent active transport. Similarly, incubation of D-amino acid dehydrogenase with inside-out vesicles results in binding of enzyme and D-alanine oxidase activity. Antibody inhibition studies indicate that the enzyme is bound exclusively to the inner cytoplasmic surface of the membrane in native vesicles (i.e., membrane vesicles prepared from cells induced for D-amino acid dehydrogenase). In contrast, similar studies with reconstituted vesicles demonstrate that enzyme binds to the surface exposed to the medium regardless of the orientation of the membrane. Thus, enzyme bound to right-side-out vesicles is located on the opposite side of the membrane from where it is normally found. Remarkably, in the presence of D-alanine, reconstituted right-side-out and inside-out vesicles generate electrochemical proton gradients of similar magnitude but opposite polarity, indicating that enzyme bound to either surface of the membrane is physiologically functional. The results suggest that vectorial proton translocation via the respiratory chain occurs at a point distal to the site where electrons enter the respiratory chain from the primary dehydrogenase, a conclusion that is inconsistent with the notion that the dehydrogenase forms part of a proton-translocating loop.     

The organization of hydrogenase in the cytoplasmic membrane of Escherichia coli.

The organization of the membrane-bound hydrogenase from Escherichia coli was studied by using two membrane-impermeant probes, diazotized [125I]di-iodosulphanilic acid and lactoperoxidase-catalysed radioiodination. The labelling pattern of the enzyme obtained from labelled spheroplasts was compared with that from predominantly inside-out membrane vesicles, after recovery of hydrogenase by immunoprecipitation. The labelling pattern of F1-ATPase was used as a control for labelling at the cytoplasmic surface throughout these experiments. Hydrogenase (mol.wt. approx. 63 000) is transmembranous. Crossed immunoelectrophoresis with anti-(membrane vesicle) immunoglobulins, coupled with successive immunoadsorption of the antiserum with spheroplasts, confirmed the location of hydrogenase at the periplasmic surface. Immunoadsorption with sonicated spheroplasts suggests that the enzyme is also exposed at the cytoplasmic surface. Inside-out vesicles were prepared by agglutination of sonicated spheroplasts, and the results of immunoadsorption using these vesicles confirms the location of hydrogenase at the cytoplasmic surface.     

Sidedness of membrane structures in Rhodopseudomonas sphaeroides. Electrochemical titration of the spectrum changes of carotenoid in spheroplasts, spheroplast membrane vesicles and chromatophores.

The shift of the carotenoid absorption spectrum induced by illumination and valinomycin-K+ addition was investigated in membrane structures with different characteristics and opposite sidednesses isolated from Rhodopseudomonas sphaeroides. Right-side-out membrane structures were prepared by isotonic lysozyme-EDTA treatment of the cells (spheroplasts) and by hypotonic treatment of spheroplasts (spheroplast membrane vesicles). Inside-out membrane structures ("chromatophores") were obtained by treating spheroplast membrane vesicles by French press or sonication. The membrane structures with either sidedness showed the same light-induced change of the "red shift" type. However, the absorbance change by K+ addition in the presence of valinomycin in the right-side-out membrane structures were opposite to that in the inverted vesicles, "blue shift" in the former and "red shift" in the latter. The carotenoid absorbance change was linear to membrane potential, calculated from the concentration of KCl added, with a reference on the cytoplasmic side, through positive and negative ranges.     

The location of redox-sensitive groups in the carrier protein of proline at the outer and inner surface of the membrane in Escherichia coli

Evidence is presented in this report for the presence of two sets of dithiols associated with proline transport activity in Escherichia coli. One set is located at the outer surface, the other at the inner surface of the cytoplasmic membrane. Treatment of right-side-out membrane vesicles from E. coli ML 308-225 with the membrane-impermeable oxidant ferricyanide resulted in inhibition of L-proline uptake without having significant effect on the magnitude of the delta approximately mu H+. Subsequent addition of reducing agents restored proline transport activity. The membrane-impermeable SH-reagent glutathione hexane maleimide inhibited proline transport in right-side-out membrane vesicles irreversibly. Pretreatment of the vesicles with ferricyanide protected the carrier against inactivation by glutathione hexane maleimide. Electron transfer in the respiratory chain of right-side-out vesicles led to the generation of a delta approximately mu H+, interior negative and alkaline, and the conversion of a disulphide to a dithiol in the proline carrier as is shown by the increased inhibition of proline transport by the membrane impermeable dithiol reagent 4-(2-arsonophenyl)azo-3-hydroxy-2,7-naphthalene disulphonic acid (thorin). The inhibition exerted by thorin was completely reversed by dithiothreitol. Pretreatment of the vesicles with thorin protected against glutathione hexane maleimide inhibition, indicating that both reagents react with the same group. Treatment of inside-out membrane vesicles with ferricyanide inactivated the proline transport system reversibly. The oxidizing effect of ferricyanide in inside-out vesicles resulted in protection against inhibition by glutathione hexane maleimide. Imposition in these vesicles of a delta approximately mu H+, interior positive and acid, also protected the proline carrier against glutathione hexane maleimide inactivation, indicating that a dithiol is converted to a disulphide upon energization.     

Adenosine 5''-triphosphate synthesis energized by an artificially imposed membrane potential in membrane vesicles of Escherichia coli.

Adenosine 5'-triphosphate (ATP) synthesis driven by an artificially imposed membrane potential in right-side-out membrane vesicles of Escherichia coli was investigated. Membrane vesicles prepared in the presence of adenosine diphosphate were loaded with K+ by incubation with 0.5 M potassium phosphate. Addition of valinomycin resulted in the synthesis of 0.2 to 0.3 nmol of ATP/mg of membrane protein, whereas no synthesis was observed after addition of nigericin. Addition of K+, dicyclohexylcarbodiimide, carbonylcyanide p-trifluoromethoxyphenylhydrazone, or azide to the assay buffer inhibited ATP synthesis. Adenosine diphosphate and Mg2+ were found to be required. Ca2+, which can replace Mg2+ for the hydrolytic activity of the Mg2+-adenosine triphosphatase (ATPase) (EC 3.6.1.3), could not replace Mg2+ in the synthetic reaction and, in fact, inhibited ATP synthesis even in the presence of Mg2+. Strain NR-70, a mutant lacking the Mg2+-ATPase, was unable to synthesize ATP using an artificially imposed membrane potential. Additionally, the Mg2+-ATPase was found to contain tightly bound ATP.