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)     

Antigenic architecture of membrane vesicles from Escherichia coli.

The antigenic architecture of membrane vesicles prepared from Escherichia coli ML 308--225 has been studied using crossed immunoelectrophoresis. Progressive immunoadsorption experiments conducted with control vesicles and with physically disrupted vesicles were used to monitor and quantitate the expression of 14 different immunogens. Eleven immunogens, including NADH dehydrogenase (EC 1.6.33.3), D-lactate dehydrogenase (EC 1.1.1.27), dihydro-orotate dehydrogenase (EC 1.3.3.1), 6-phosphogluconate dehydrogenase (EC 1.1.1.43), polynucleotide phosphorylase (EC 2.3.7.8), and beta-galactosidase (EC 3.2.1.23), exhibit minimal expression (10% or less) unless the vesicles are disrupted. Three unidentified antigens are expressed to a similar extent in untreated and disrupted vesicles. Consideration of these and other results [Owen, P., & Kaback, H. R. (1978) Proc. Natl. Acad. Sci. U.S.A. 75, 3148] in terms of membrane polarity, dislocation of antigens, and possible transmembrane orientation of some immunogens reveals that over 95% of the membrane in the vesicle preparations is in the form of sealed sacculi with the same orientation as the intact cell. Furthermore, antigens are distributed across the membrane in a highly asymmetric manner, indicating that dislocation of components from the inner to the outer surface of the membrane during vesicle preparation does not occur to an extent exceeding 10%.     

Immunochemical analysis of membrane vesicles from Escherichia coli.

Membrane vesicles isolated from Escherichia coli ML 308--225 have been analyzed by crossed immunoelectrophoresis, and immunoprecipitates corresponding to the following cellular components have been identified: ATPase (EC 3.6.1,3), two or three NADH dehydrogenases (EC 1.6.99.3), D-lactate dehydrogenase (EC 1.1.1.27), glutamate dehydrogenase (EC 1.4.1.4), dihydro-orotate dehydrogenase (EC 1.3.3.1), 6-phosphogluconate dehydrogenase (EC 1.1.1.43), polynucleotide phosphorylase (EC 2.3.7.8), beta-galactosidase (EC 3.2.1.23), lipopolysaccharide, and Braun's lipoprotein. The cellular origin of many of the vesicle immunogens is determined, and Braun's lipoprotein is used as a marker to quantitate the extent of outer membrane contamination (less than 3%). Membrane antigens are also characterized with regard to their amphiphilic or hydrophilic properties by charge-shift crossed immunoelectrophoresis. Furthermore, the following immunogens cross-react with components in membrane vesicles prepared from Salmonella typhimurium: one of the three NADH dehydrogenases, ATPase, polynucleotide phosphorylase, 6-phosphogluconate dehydrogenase, Braun's lipoprotein, and three unidentified antigens. In the accompanying paper [Owen, P., & Kaback, H. R. (1979) Biochemistry 18 (following paper in this issue)] quantitative immunoadsorption is utilized to establish the topology of the vesicles with respect to the distribution of antigens on the inner and outer faces of the membrane.     

Mechanism of the melibiose porter in membrane vesicles of Escherichia coli

The melibiose transport system of Escherichia coli catalyzes sodium--methyl 1-thio-beta-D-galactopyranoside (TMG) symport, and the cation is required not only for respiration-driven active transport but also for binding of substrate to the carrier in the absence of energy and for carrier-mediated TMG efflux. As opposed to the proton--beta-galactoside symport system [Kaczorowski, G. J., & Kaback, H. R. (1979) Biochemistry 18, 3691], efflux and exchange of TMG occur at the same rate, implying that the rates of the two processes are limited by a common step, most likely the translocation of substrate across the membrane. Furthermore, the rate of exchange, as well as efflux, is influenced by imposition of a membrane potential (delta psi; interior negative), suggesting that the ternary complex between sodium, TMG, and the porter may bear a net positive charge. Consistently, energization of the vesicles leads to a large increase in the Vmax for TMG influx, with little or no change in the apparent Km of the process. It is proposed that the sodium gradient (Na+out < Na+in) and the delta psi (interior negative) may affect different steps in the overall mechanism of active TMG accumulation in the following manner: the sodium gradient causes an increased affinity for TMG on the outer surface of the membrane relative to the inside and the delta psi facilitates a reaction involved with the translocation of the positively charged ternary complex to the inner surface of the membrane.     

The membrane potential in everted vesicles of Escherichia coli.

Ion-selective electrodes were used to measure the equilibration of thiocyanate across the membrane of everted (“inside-out”) vesicles of Escherichia coli W1485. Membrane potentials, vesicle interior positive, generated by the oxidation of NADH, succinate, and d-lactate, or by the hydrolysis of ATP, fell in the range of 100–150 mV depending on the carbon source for cell growth and the substrate used to energize the membranes. There was no relationship between the rate of oxidation of different substrates and the membrane potential they generated. The membrane potential generated by oxidation of NADH was relatively constant between pH 7.0 and 8.5. Somewhat lower values obtained at pH 5.5 to 6.5 were attributed to the effect of pH on substrate oxidation.     

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.     

Oxidative phosphorylation in right-side-out membrane vesicles from Escherichia coli.

Oxidative phosphorylation in Escherichia coli membrane vesicles with a right-side-out orientation and loaded with ADP was investigated. Substrates of the electron transport chain could energize the phosphorylation of ADP, with the order of effectiveness being D-lactate greater than reduced phenazinemethosulfate greater than succinate greater than reduced nicotinamide adenine dinucleotide. Inhibitors of D-lactate oxidation, proton conductors, and inhibitor of the Mg2+ATPase (EC 3.6.1.3) all inhibited oxidative phosphorylation when coupled to D-lactate oxidation. ATP synthesis was absent in membrane vesicles prepared from a mutant strain lacking the Mg2+ATPase. Valinomycin or nigericin partially inhibited oxidative phosphorylation in the presence of potassium. Valinomycin plus nigericin completely inhibited ATP synthesis. The effect of various agents on the respiration-dependent establishment of a transmembrane pH gradient was also examined. NaCN and carbonyl cyanide p-trifluoromethoxyphenylhydrazone inhibited the establishment of a pH gradient while dicyclohexylcarbodiimide had no effect. These results are in good agreement with a chemiosmotic model for oxidative phosphorylation.     

NADH oxidation in phospholipid-enriched cytoplasmic membrane vesicles from Escherichia coli

NADH oxidation in Escherichia coli cytoplasmic membrane vesicles enriched in anionic phospholipids by de novo synthesis of lipid in the vesicles from acyl-CoA esters and sn-glycerol 3-phosphate has been studied. NADH-oxidase but not NADH-dehydrogenase activity was found to decrease during synthesis and accumulation of phospholipid in the vesicles. Density gradient fractionation showed that NADH-oxidase activity was reduced to approximately 30% in vesicles with a 3-6 fold increase in anionic phospholipid, whereas vesicles with a greater than 10-fold increase in phospholipid had virtually no NADH oxidase activity.     

Interaction of the maltose-binding protein with membrane vesicles of Escherichia coli.

The interaction of the radioactively labeled purified maltose-binding protein of Escherichia coli with membrane vesicles was studied. The maltose-binding protein bound specifically to the vesicles, in the presence of maltose, on few sites. Under conditions in which a potential was imposed across the membrane, the specific binding was (i) increased, (ii) dependent on maltose, and (iii) abolished in a mutant defective in the tar gene product, one of the methyl-accepting chemotaxis proteins. At least 1,300 binding sites were present in the membrane fraction of logarithmically growing cells.     

The electrochemical proton gradient in Escherichia coli membrane vesicles.

Membrane vesicles isolated from Escherichia coli grown under various conditions generate a transmembrane pH gradient (delta pH) of about 2 pH units (interior alkaline) under appropriate conditions when assayed by flow dialysis. Using the distribution of weak acids to measure delta pH and the distribution of the lipophilic cation triphenylmethylphosphonium to measure the electrical potential (delta psi) across the membrane, the vesicles are demonstrated to develop an electrochemical proton gradient (delta-muH+) of almost - 200 mV (interior negative and alkaline) at pH 5.5 in the presence of reduced phenazine methosulfate or D-lactate, the major component of which is a deltapH of about - 120 mV. As external pH is increased, deltapH decreases, reaching 0 at about pH 7.5 and above, while delta psi remains at about - 75 mV and internal pH remains at pH 7.5-7.8. The variations in deltapH correlate with changes in the oxidation of reduced phenazine methosulfate or D-lactate, both of which vary with external pH in a manner similar to that described for deltapH. Finally, deltapH and delta psi can be varied reciprocally in the presence of valinomycin and nigericin with little change in delta-muH+ and no change in respiratory activity. These data and those presented in the following paper (Ramos and Kaback 1976) provide strong support for the role of chemiosmotic phenomena in active transport and extend certain aspects of the chemiosmotic hypothesis.     

Effect of membrane potential on the kinetic parameters of the Na+ or H+ melibiose symport in Escherichia coli membrane vesicles

Comparison of the transport properties of the melibiose permease of E. coli acting as a H+-symport or a Na+-symport has been performed by measuring initial rates of [3H]-melibiose transport or its accumulation in isolated membrane vesicles. The results show strikingly that although the membrane potential primarily drives melibiose accumulation by both types of symport, it selectively affects the apparent affinity constant Kt of the H+-melibiose symport while it specifically changes the maximal rate of transport (Vmax) of the Na+-melibiose symport. It is suggested that modification(s) of some partial reaction constants of a given transport cycle might lead to important changes in the kinetic properties of this transport system.     

Studies on the orientation of brush-border membrane vesicles.

Orientation of rat renal and intestinal brush-border membrane vesicles was studied with two independent methods: electron-microscopic freeze-fracture technique and immunological methods. With the freeze-fracture technique a distinct asymmetric distribution of particles on the two membrane fracture faces was demonstrated; this was used as a criterion for orientation of the isolated membrane vesicles. For the immunological approach the accessibility or inaccessibility of aminopeptidase M localized on the outer surface of the cell membrane to antibodies was used. With both methods we showed that the brush-border membrane vesicles isolated from rat kidney cortex and from rat small intestine for transport studies are predominantly orientated right-side out.     

Uncoupling action of amytal in membrane vesicles from Escherichia coli.

The barbiturate amytal (5-ethyl-5-isopentylbarbituric acid) has been shown to inhibit amino acid transport in membrane vesicles from anaerobically grown Escherichia coli. Amytal has no effect on the activity of the enzymes of the nitrate respiration system, nor on electron transfer in this system. However, addition of amytal to the membrane vesicles results in a decrease of the membrane potential from -90 mV to -72 mV, and to a decrease of the pH-gradient of -61 mV to undetectable values. Furthermore, amytal causes an increase in the rate of ferricyanide reduction in liposomes, indicating that amytal increases the proton permeability of phospholipid membranes. These results demonstrate that amytal acts as an uncoupler in membrane vesicles from anaerobically grown E. coli.     

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.     

Energetic studies of lactose active transport in Escherichia coli membrane vesicles

The energetics of D-lactate-driven active transport of lactose in right-side-out Escherichia coli membrane vesicles has been investigated with a microcalorimetric method. Changes of enthalpy (delta Hox), free energy (delta Gox), and entropy (delta Sox) during the D-lactate oxidation reaction in the presence of membrane vesicles are -39.9 kcal, -46.4 kcal, and 22 cal/deg per mole of D-lactate, respectively. The free energy released by this reaction is utilized to form a proton electrochemical potential (delta-microH+) across the membrane. The higher observed heat in the D-lactate oxidation reaction in the presence of carbonylcyanide m-chlorophenylhydrazone (a proton ionophore) supports the postulate that delta-microH+ is formed across the membrane vesicles. Thermodynamic quantities for the formation of delta-microH+ are delta Hm = 14.1 kcal, delta Gm = 0.6 kcal, and delta Sm = 45 cal/deg per mole of D-lactate. The efficiency in the free energy transfer from the oxidation reaction to the formation of delta-microH+ (defined by delta Gm/delta Gox) was 2%, as compared to that in the heat transfer (defined by delta Hm/delta Hox) of 35%. The energetics of the movement of lactose in symport with proton across the membrane as a consequence of the formation of delta-microH+ are delta H1 = -19 kcal, delta G1 = -0.5 kcal, and delta S1 = -62 cal/deg per mole of lactose. No heat of reaction is contributed by lactose movement across the membrane without symport with H+.