Colicins and bacterial membranes: structures and functions. II. Studies on reconstituted homologous and hybrid membranes prepared from cytoplasmic membranes of untreated and colicin K-treated bacteria.

Cytoplasmic membranes of Escherichia coli K12 C600 treated and not treated with colicin K were dissociated into unsolubilized and solubilized fractions. Neither fraction catalyzed ATP-linked transhydrogenase activity. Mixtures of unsolubilized fractions of the untreated bacteria with solubilized fractions of either the treated or untreated bacteria yielded reconstituted membranes with restored ATP-linked transhydrogenase activity. The level of the activity was similar to that of the undissociated membranes of untreated bacteria. The membranes which were reconstituted from unsolubilized fractions of the treated bacteria and the solubilized fraction of the treated or the untreated bacteria showed impairment of activity. The impairment is not due to an inability to bind ATPase of the soluble fraction or to an incorrect binding of the ATPase. The impaired, reconstituted membranes showed striking decreases in the relative amounts of three proteins with apparent molecular weights of 122,000, 73,000, and 62,000. The affected proteins were found to be components of the unsolubilized membrane fraction. It is, thus, concluded that the impaired activity is due to the defective nature of the unsolubilized membrane fraction of colicin-treated cells.     

Colicins and bacterial membranes: structures and functions. I. Effects of colicins on the protein composition of the membranes of sensitive and tolerant Escherichia coli.

Treatment of Escherichia coli K12 C600 with colicin K or E1, but not E3, caused changes in the protein composition of the bacterial cytoplasmic membrane and an impairment of the membrane-associated ATP-linked transhydrogenase activity. The major compositional changes were loss and/or reduction in the levels of protein bands 4, 8, 9, 10, 13, and 18 with approximate molecular weights of 122,000, 81,000, 75,000, 73,000, 62,000, and 44,000, respectively. Colicin K or E1 treatment had no significant effect on the protein composition or the ATP-linked transhydrogenase activity of the cytoplasmic membranes of the isogenic tolerant strain E. coli K12 C600 TolII (A592). The cytoplasmic membranes of the untreated tolerant mutant were characteristically devoid of protein bands 4 and 13. It is proposed that protein bands 4 and/or 13 participate in colicin action by acting as receptors for colicins at the cytoplasmic membrane level. Some observations on the structural and functional heterogeneity of the cytoplasmic membrane preparations were made.     

Effect of colicin K on a membrane-associated, energy-linked function.

The purpose of this work was in investigate the capability of cell extracts of Escherichia coli and E. coli treated with colicin K to catalyze the following energy-dependent reverse transhydrogenase reaction: NADP + NADH + ATP in equilibrium NADPH + NAD +ADP + Pi. Under anaerobic conditions this reaction requires the presence of a specific portion of the electron transport chain, a functional energy coupling system, including an adenosine triphosphatase, enzyme, and ATP as energy source. The ATP-linked reaction was partially inhibited in French press extracts of E. coli K-12 C600 cells that had been pretreated with colicin K but not in extracts from similarly treated cells of a colicin-tolerant mutant. Ultracentrifugation of extracts yielded particulate fractions competent in catalyzing the reaction; this reaction is substantially inhibited in fractions from colicin-treated cells. The extent of inhibition increased with increasing concentration of colicin. Supernatants also supported ATP-linked formation of NADPH, but this reaction was insensitive to the colicin effect. A comparison between the requirement of the reaction in supernatant and particulate fractions suggests that the reaction in the supernatant is different from the one inhibited by colicin. The ATP-hydrolyzing ability of particulate fractions from the control or treated bacteria was identical. Likewise, the electron transport chain was not affected by colicin treatment, as evidenced from lack of effect on NADH oxidase, succinic dehydrogenase, and NADPH-NAD transhydrogenase. It is concluded that colicin K interferes with the coupling of ATP the utilization of the intermediate for the ATP-linked transdehydrogenase reaction.     

Energy-linked transhydrogenase. Effects of valinomycin and nigericin on the ATP-driven transhydrogenase reaction catalyzed by reconstituted transhydrogenase-ATPase vesicles

Reconstituted transhydrogenase-ATPase vesicles obtained with purified beef heart transhydrogenase and oligomycin-sensitive ATPase were investigated with respect to the mode of interaction between the two proton pumps, with special reference to the relative contributions of the membrane potential and proton gradient using valinomycin and nigericin in the presence of potassium. In the absence of ionophores and at low ATP concentrations, below 20 microM, the ATPase generated a proton motive force which was predominantly due to a membrane potential, whereas at saturating concentrations of ATP the proton gradient was the predominant component. The ATP-dependence of the rate of the ATP-driven transhydrogenase reaction showed apparent Km values in the low and high ATP concentration range of about 3 and 56 microM, respectively, with a corresponding difference in Vmax of about 3-fold. It is concluded that the reconstituted transhydrogenase can utilize both a membrane potential and a proton gradient, separately or combined, where the relative contributions of these components depend on the activity of the ATPase. In the reconstituted vesicles, the maximally active transhydrogenase is apparently driven by an electrochemical proton gradient where the membrane potential and the proton gradient contribute one-third and two-thirds, respectively. The rate-dependent relative generation of a membrane potential and pH gradient presumably reflects the proton pump characteristics of the ATPase and/or buffering/permeability characteristics of the vesicles rather than the properties of the transhydrogenase per se. These results are discussed in relation to current models for transhydrogenase-linked proton translocation.     

Localization and distribution of Microccus lysodeikticus membrane ATPase determined by ferritin labeling

Antiserum to Ca²⁺-activated ATP phosphohydrolase (EC 3.6.1.3) isolated and purified from membranes of Micrococcus lysodeikicus was prepared in rabbits and guinea pigs. The γ-globulin fractions of these antisera reacted with and inhibited ATPase activity in isolated membranes but failed to absorb to intact protoplasts or purified mesosome fractions. ATPase activity was not detectable in the purified mesosomal preparations and trypsin treatment and sonication failed to release any activity. Ferritin conjugated to the γ-globulin fractions of the antiserum reacted with the ATPase particles on the membrane as visualized in negatively stained preparations examined in the electron microscope. Labeled membranes showed a distribution of ferritin very similar to the patterns observed for ATPase particles on untreated membranes. No significant labeling occurred when the ferritin conjugate was reacted with intact protoplasts or mesosome fractions. Thin sections of ferritin-labeled membranes established the asymmetric disposition of the ATPase, with the conjugate visible on only one side of the membrane. The results indicate that the ATPase protein occurs on the inner face of the membrane. All labeling experiments were verified immunologically. When ferritin-labeled membranes were subjected to the selective release procedure used in releasing the ATPase-like particles from the membranes, a complex of ferritin-conjugate associated with the ATPase particles was released. The selective release of ferritin-antibody-enzyme complexes from the membrane opens up a new way of studying the molecular architecture of cell membranes.     

Studies on the nature of adenosine diphosphatase activity from rat liver mitochondria

Adenosine diphosphatase (ADPase) activity was studied in rat liver with [beta-32P]ADP as a substrate. Mitochondria and outer mitochondrial membrane fractions were isolated and assayed for ADPase and various marker enzymes. ADPase activity was strikingly reduced when the outer membranes were removed from the mitochondria whether by digitonin treatment or osmotic shock. Addition of the inter-membrane space subfraction to the purified outer membranes resulted in enhanced ADPase activity. Addition of the inter-mitochondrial membrane enzyme adenylate kinase to outer membranes also produced a large stimulation of activity. The ADPase activity could also be reconstituted in vitro with adenylate kinase and either mitoplast ATPase or ouabain-sensitive (Na+ + K+ + Mg2+)-ATPase. Chloroform-released ATPase, however, was not capable of producing an ADPase activity when combined with adenylate kinase. Gel permeation chromatography of Triton-solubilised outer mitochondrial membranes was unable to resolve ADPase activity from contaminating ATPase. These results suggest that the majority of ADPase activity in rat liver mitochondria consists of the coupled activity of adenylate kinase and ATPase.     

Reconstitution of oxidative phosphorylation and the adenosine triphosphate-dependent transhydrogenase activity by a combination of membrane fractions from uncA? and uncB? mutant strains of Escherichia coli K12

1. Membrane preparations from both uncA(-) and uncB(-) mutant strains of Escherichia coli K12, in which electron transport is uncoupled from phosphorylation, were fractionated by washing with a low-ionic-strength buffer. The fractionation gave a ;5mm-Tris wash' and a ;membrane residue' from each strain. This technique, applied to membranes from normal cells, separates the Mg(2+),Ca(2+)-stimulated adenosine triphosphatase activity from the membrane-bound electron-transport chain and the non-energy-linked transhydrogenase activity. 2. Reconstitution of both oxidative phosphorylation and the ATP-dependent transhydrogenase activity was obtained by a combination of the ;membrane residue' from strain AN249 (uncA(-)) with the ;5mm-Tris wash' from strain AN283 (uncB(-)). 3. Valinomycin plus NH(4) (+) inhibited oxidative phosphorylation both in membranes from a normal strain of E. coli and in the reconstituted membrane system derived from the mutant strains. 4. The electron-transport-dependent transhydrogenase activity was located in the membrane residue and was de-repressed in both the mutant strains. 5. The spatial and functional relationships between the proteins specified by the uncA and uncB genes and the transhydrogenase protein are discussed.     

Purification and properties of reconstitutively active nicotinamide nucleotide transhydrogenase of Escherichia coli

The nicotinamide nucleotide transhydrogenase of Escherichia coli has been purified from cytoplasmic membranes by pre-extraction of the membranes with sodium cholate and Triton X-100, solubilization of the enzyme with sodium deoxycholate in the presence of 1 M potassium chloride, and centrifugation through a 1.1 M sucrose solution. The purified enzyme consists of two subunits, alpha and beta, of apparent Mr 50000 and 47000. During transhydrogenation between NADPH and 3-acetylpyridine adenine dinucleotide by both the purified enzyme reconstituted into liposomes and the membrane-bound enzyme, a pH gradient is established across the membrane as indicated by the quenching of the fluorescence of 9-aminoacridine. Treatment of transhydrogenase with N,N'-dicyclohexylcarbodiimide results in an inhibition of proton pump activity and transhydrogenation, suggesting that proton translocation and catalytic activities are obligatory linked. NADH protected the enzyme against inhibition by N,N'-dicyclohexylcarbodiimide, while NADP, and to a lesser extent NADPH, appeared to increase the rate of inhibition. [14C]Dicyclohexylcarbodiimide preferentially labelled the 50000-Mr subunit of the transhydrogenase enzyme. The presence of an allosteric binding site which reacts with NADH, but not with reduced 3-acetylpyridine adenine dinucleotide, has been demonstrated.     

Resolution and reconstitution of mitochondrial nicotinamide nucleotide transhydrogenase.

Nicotinamide nucleotide transhydrogenase from bovine heart mitochondria was solubilized with cholate and partially purified by ammoniumsulphate fractionation and density gradient centrifugation. Compared to submitochondrial particles this preparation contained less than 10% of oligomycin-sensitive ATPase and cytochromes. When reconstituted with purified mitochondrial phosphatidylcholine, the enzyme catalyzed a reduction of NAD⁺ by NADPH that was stimulated by uncouplers and which showed a concomitent uncoupler-sensitive uptake of the lipophilic anion tetraphenylboron, indicating the generation of a membrane potential. It is concluded that transhydrogenase can energize the vesicles directly without the intervention of ATPase or cytochromes.     

Partial purification of active delta and epsilon subunits of the membrane ATPase from escherichia coli

We have partially purified active delta and epsilon subunits of the E. coli membranebound Mg²⁺ -ATPase (ECF₁). Treating purified ECF₁ with 50% pyridine precipitates the major subunits (α, β, and γ) of the enzyme, but the two minor subunits (δ and ϵ), which are present in relatively small amounts, remain in solution. The delta and epsilon subunits were then resolved from one another by anion exchange chromatography. The partially purified epsilon strongly inhibits the hydrolytic activity of ECF₁. The epsilon fraction inhibits both the highly purified five-subunit ATPase and the enzyme deficient in the δ subunit. The latter result indicates that the delta subunit is not required for inhibition by epsilon. By contrast, two-subunit enzyme, consisting chiefly of the α and β subunits, was insensitive to the ATPase inhibitor, suggesting that the γ subunit may be required for inhibition by epsilon. The partially purified delta subunit restored the capacity of ATPase deficient in delta to recombine with ATPase-depleted membranes and to reconstitute ATP-dependent transhydrogenase. Previously we reported (Biochem. Biophys. Res. Commun. 62:764 [1975]) that a fraction containing both the delta and epsilon subunits of ECF₁ restored the capacity of ATPase missing delta to recombine with depleted membranes and to function as a coupling factor in oxidative phosphorylation and for the energized transhydrogenase. These reconstitution experiments using isolated subunits provide rather substantial evidence that the delta subunit is essential for attaching the ATPase to the membrane and that the epsilon subunit has a regulatory function as an inhibitor of the ATPase activity of ECF₁.     

Resolution and reconstitution of Rhodospirillum rubrum pyridine dinucleotide transhydrogenase

The Rhodospirillum rubrum pyridine dinucleotide transhydrogenase system is comprised of a membrane-bound component and an easily dissociable soluble factor. Active transhydrogenase complex was solubilized by extraction of chromatophores with lysolecithin. The membrane component was also extracted from membranes depleted of soluble factor. The solubilized membrane component reconstituted transhydrogenase activity upon addition of soluble factor. Various other ionic and non-ionic detergents, including Triton X-100, Lubrol WX, deoxycholate, and digitonin, were ineffectual for solubilization and/or inhibited the enzyme at higher concentrations. The solubilized membrane component was significantly less thermal stable than the membrane-bound component. None of the pyridine dinucleotide substrate affected the thermostability of the solubilized membrane-bound component, whereas NADP⁺ and NADPH afforded protection to membrane-bound component. NADPH stimulated trypsin inactivation of membrane-bound component to a greater extent than NADP⁺, but inactivation of solubilized membrane component was stimulated to the same extent by both pyridine dinucleotides. The solubilized membrane component appears to have a slightly higher affinity for soluble factor than does the membrane-bound component.Abbreviations AcPyAD⁺ oxidized 3-acetylpyridine adenine dinucleotide - BChl bacteriochlorophyll - C_T-particles chromatophores depleted of soluble transhydrogenase factor and devoid of transhydrogenase activity This work was supported by Grant GM 22070 from the National Institutes of Health, United States Public Health Service. Paper I of this series is R. R. Fisher et al. (1975)     

Characterization of the ATPase activities of myosins isolated from the membrane and the cytoplasmic fractions of human platelets

Myosin was purified from the membrane fraction and the cytoplasm of human platelets, and the K+(EDTA)- and Ca2+-dependent ATPase activities were studied under various experimental conditions. The ATPase activity of the myosin from the membrane fraction was slightly lower than that of its cytoplasmic counterpart, regardless of the different assay conditions (pH, ionic strength, and temperature). Both myosins showed the same pH optima and a similar ionic strength dependence for the two ATPase activities measured. In addition, they exhibited the same substrate specificity using ATP, CTP, and GTP as substrates. The activation energy of the Ca2+-dependent ATPase activity was essentially the same for the two myosins, while the activation energy of the K+(EDTA)-dependent ATPase activity of the membrane myosin was higher than that of the cytoplasmic myosin. The ATPase activity of the membrane myosin was found to be more sensitive to freezing and thawing than the cytoplasmic myosin. The alkylation of the thiol groups by N-ethylmaleimide or N-iodoacetyl-N-(5-sulfo-1-naphtyl)ethylenediamine, and the trinitrophenylation of the lysyl residues by 2,4,6-trinitrobenzenesulfonate caused a significant decrease in the K+(EDTA)-dependent ATPase activity of the two myosins. However, the membrane myosin was much less affected than the cytoplasmic myosin. Actin induced inhibition of the K+ (EDTA) ATPase of both myosins, and much smaller quantities of actin were needed to inhibit the cytoplasmic myosin ATPase compared to quantities needed to inhibit the myosin ATPase from the membrane fraction. This indicates that the membrane myosin has a lower affinity toward actin. The observed variations in the ATPase activity of the myosins isolated from the membrane and the cytoplasm fractions of human platelets may reflect differences in their respective physiological functions.     

SecA protein, a peripheral protein of the Escherichia coli plasma membrane, is essential for the functional binding and translocation of proOmpA.

We have reconstituted protein translocation across plasma membrane vesicles of Escherichia coli using purified proOmpA and trigger factor, a 63 kd soluble protein. Treatment of membrane vesicles with urea inactivates them for translocation unless a factor present in cytoplasmic extracts is added during the translocation reaction. Sedimentation analysis showed that the stimulatory activity is of distinctly higher mol. wt than trigger factor. Cytoplasmic extracts from a strain that greatly overproduces the SecA protein are highly enriched in the stimulatory activity for untreated membranes and restore translocation to urea-treated membranes, suggesting that this protein is the stimulatory factor. This assay was used to monitor the isolation of SecA protein from the overproducing strain. The purified protein is soluble, yet binds peripherally to membranes with high affinity and supports translocation. Using pure proOmpA, SecA protein, trigger factor and urea-treated membranes, the protein export process was resolved into binding and translocation steps. We find that proOmpA binds to membrane vesicles with or without SecA protein, but that translocation only occurs when SecA was bound prior to proOmpA.     

Chemical modification of sarcoplasmic reticulum. Stimulation of Ca2+ release.

Pretreatment of sarcoplasmic membranes with acetic or maleic anhydrides, which interact principally with amino groups, resulted in an inhibition of Ca2+ accumulation and ATPase activity. The presence of ATP, ADP or adenosine 5'-[beta, gamma-imido]triphosphate in the modification medium selectively protected against the inactivation of ATPase activity by the anhydride but did not protect against the inhibition of Ca2+ accumulation. Acetic anhydride modification in the presence of ATP appeared to increase specifically the permeability of the sarcoplasmic reticulum membrane to Ca2+ but not to sucrose, Tris, Na+ or Pi. The chemical modification stimulated a rapid release of Ca2+ from sarcoplasmic reticulum vesicles passively or actively loaded with calcium, from liposomes reconstituted with the partially purified ATPase fraction but not from those reconstituted with the purified ATPase. The inactivation of Ca2+ accumulation by acetic anhydride (in the presence of ATP) was rapid and strongly pH-dependent with an estimated pK value above 8.3 for the reactive group(s). The negatively charged reagents pyridoxal 5-phosphate and trinitrobenzene-sulphonate, which also interact with amino groups, did not stimulate Ca2+ release. Since these reagents do not penetrate the sarcoplasmic reticulum membranes, it is proposed that Ca2+ release is promoted by modification of internally located, positively charged amino group(s).     

Energy-linked nicotinamide nucleotide transhydrogenase. Properties of proton-translocating mitochondrial transhydrogenase from beef heart purified by fast protein liquid chromatography

Mitochondrial nicotinamide nucleotide transhydrogenase from beef heart was purified by a novel procedure involving fast protein liquid chromatography and characterized with respect to molecular and catalytic properties. The method is reproducible, gives highly pure transhydrogenase as judged by silver staining, and can be modified to produce large amounts of pure transhydrogenase protein suitable for e.g. sequencing and other protein chemical studies. Transhydrogenase purified by fast protein liquid chromatography is reconstitutively active and pumps protons as indicated by an extensive quenching of 9-aminoacridine fluorescence. Under conditions which generate a proton gradient in the absence of a membrane potential the activity of reconstituted transhydrogenase is close to zero indicating a complete and proper incorporation in the membrane and a preferential regulation of the enzyme by a proton gradient rather than a membrane potential. Treatment of reconstituted transhydrogenase with N,N-dicyclohexylcarbodiimide results in an inhibition of proton pump activity without an effect on uncoupled catalytic activity, suggesting that proton translocation and catalytic activities are not obligatory linked or that this agent separates proton pumping from the catalytic activity.     

ATP-dependent reactions catalyzed by inner membrane vesicles of rat liver mitochondria. Kinetics, substrate specificity, and bicarbonate sensitivity.

Three ATP-dependent reactions catalyzed by the inner membrane of rat liver mitochondria and the ATPase reaction catalyzed by purified mitochondrial ATPase (F1), were studied with respect to kinetic properties, substrates specificity, and sensitivity to bicarbonate. The ATP-dependent transhydrogenase reaction (reduction of NADP+ by NADH) catalyzed by inner membrane vesicles displays typical Michaelis-Menten kinetics in both Tris-Cl and Tris-bicarbonate buffers, with Km (ATP) values of 0.035 mM and 0.054 mM respectively. The Vmax of transhydrogenase activity (25 nmol min-1 mg-1) is the same in Tris-bicarbonate or Tris-Cl buffer. ITP and GTP readily substitute for ATP in the transhydrogenase reaction. The ATP-P1 exchange reaction catalyzed by inner membrane vesicles displays typical Michaelis-Menten kinetics in both Tris-Cl and Tris-bicarbonate buffers with Km (ATP) values of 1.0 mM and 1.4 mM respectively. The Vmax of exchange (200 nmol min-1 mg-1) is the same in either buffer. ITP and GTP do not effectively replace ATP in the exchange reaction.     

Mutants of Escherichia coli K12 unable to grow on non-fermentable carbon substrates.

Among a number of mutants unable to utilize non-fermentable carbon substrates, scoring for membrane ATPase and for ATP-driven transhydrogenase activity permitted to distinguish two phenotypes: (A) mutants lacking ATPase and ATP-driven transhydrogenase; (B) one mutant with an ATPase which behaved according to several criteria as released into solution instead of being membrane bound, a.o it exhibited no ATP-driven transhydrogenase activity. All A and B mutants exhibited a common nutritional pattern. The ATPase-deficient group, when scored for ATPase-binding sites on its membrane particles revealed three different subgroups: (1) mutants having free ATPase-binding sites, (2) mutants with ATPase-binding sites made available by the procedure which releases ATPase from wild-type membrane, and (3) mutants with no detectable ATPase-binding sites. Membranes of the mutant B with unbound ATPase also exhibited a deficiency in ATPase-binding sites, but its soluble ATPase was also found unable to bind to ATPase-binding sites of wild type membranes. The double alteration, namely abnormal or inactive ATPase and absence of ATPase-binding sites on the membrane is compatible with a single mutational defect.     

Purification and reconstitution of the 32Pi-ATP exchange activity of bovine chromaffin granule membrane

Ghosts derived from bovine chromaffin granules have a ³²P_i-ATP exchange activity which is associated with the H⁺ pump of that membrane. This activity was low when compared to bacteria, chloroplasts or submitochondrial particles, but had similar properties (K_m for ATP and P_i, ATP/Mg²⁺ ratio, pH profile, inhibition by dicyclohexylcarbodiimide and tributyltin) to the ATPase from above membranes. The ³²P_i-ATP exchange activity was solubilized by cholate/octylglucoside mixtures. The soluble extract was lipid depleted by ammonium sulfate fractionation and partially purified by sucrose gradient centrifugation. The purified preparation was reconstituted with phospholipids by freeze-thawing. The reconstituted vesicles had a ³²P_i-ATP exchange sensitive to dicyclohexylcarbodiimide and trybutyltin and an ATPase with a sensitivity to the inhibitors which varied with the reconstitution conditions. The α- and β-subunits of F₁-ATPase were major components of the preparation.     

Purification of a putative K+-ATPase from Streptococcus faecalis

We have purified a novel membrane ATPase from Streptococcus faecalis by the following procedure: extraction of membranes with Triton X-100 followed by fractionation of the extract by successive DEAE-cellulose chromatography, hydroxylapatite chromatography and Cm-Sepharose chromatography. The overall yield was 5%. The purified ATPase appears to consist of a single polypeptide component of Mr = 78,000. The Triton-solubilized purified enzyme has a specific activity of approximately 50 mumol of ATP hydrolyzed per min per mg, is dependent on phospholipids for activity, and is strongly inhibited by vanadate (I50 = 3 microM). Maximal ATPase activity is displayed at pH 7.3. Mg2+-ATP, for which the enzyme has a Km of 60 microM, is the best substrate. The ATPase forms an acylphosphate intermediate that can also be detected in native membranes as the major acylphosphate component. The purified ATPase, when reconstituted into soybean phospholipid vesicles, exhibits coupling, e.g. the ATPase activity can be stimulated at least 8-fold by valinomycin in the presence of potassium. Based on these observations we conclude that the enzyme we have purified is an ion-motive ATPase, most likely a K+-ATPase.     

Energy-Transducing Adenosine Triphosphatase from Escherichia coli: Purification, Properties, and Inhibition by Antibody

The membrane adenosine triphosphatase (E.C. 3.6.1.3) from Escherichia coli has been solubilized with Triton X-100 and purified to near homogeneity. The purified enzyme has a sedimentation coefficient of 12.9S in a sucrose gradient, corresponding to a molecular weight of about 360,000. On electrophoresis in gels containing sodium dodecyl sulfate, it dissociates into subunits with apparent molecular weights of 60,000, 56,000, 35,000, and 13,000. The purified enzyme loses activity and breaks down into subunits when stored in the cold. Guanosine 5'-triphosphate and inosine 5'-triphosphate are alternative substrates. Ca(2+) and, to a small extent, Co(2+) or Ni(2+) will substitute for Mg(2+) in the reaction. The K(m) for Mg-adenosine triphosphate of the membrane-bound enzyme is 0.23 mM, and for the pure enzyme it is 0.29 mM. Azide is a noncompetitive inhibitor of both the membrane-bound enzyme and the pure enzyme. P(i) is a noncompetitive inhibitor of the solubilized enzyme. An antibody to the purified enzyme was obtained from rabbits. The antibody inhibits the solubilized enzyme and virtually all of the adenosine triphosphate hydrolysis by membranes from cells grown aerobically or anaerobically. The antibody also inhibits the adenosine triphosphate-stimulated pyridine nucleotide transhydrogenase (E.C. 1.6.1.1) of the E. coli membrane.