Activation and inhibition of the Escherichia coli F1-ATPase by monoclonal antibodies which recognize the epsilon subunit

The properties of two monoclonal antibodies which recognize the epsilon subunit of Escherichia coli F1-ATPase were studied in detail. The epsilon subunit is a tightly bound but dissociable inhibitor of the ATPase activity of soluble F1-ATPase. Antibody epsilon-1 binds free epsilon with a dissociation constant of 2.4 nM but cannot bind epsilon when it is associated with F1-ATPase. Likewise epsilon cannot associate with F1-ATPase in the presence of high concentrations of epsilon-1. Thus epsilon-1 activates F1-ATPase which contains the epsilon subunit, and prevents added epsilon from inhibiting the enzyme. Epsilon-1 cannot bind to membrane-bound F1-ATPase. The epsilon-4 antibody binds free epsilon with a dissociation constant of 26 nM. Epsilon-4 can bind to the F1-ATPase complex, but, like epsilon-1, it reverses the inhibition of F1-ATPase by the epsilon subunit. The epsilon subunit remains crosslinkable to both the beta and gamma subunits in the presence of epsilon-4, indicating that it is not grossly displaced from its normal position by the antibody. Presumably the activation arises from more subtle conformational effects. Antibodies epsilon-4 and delta-2, which recognizes the delta subunit, both bind to F1F0 in E. coli membrane vesicles, indicating that these subunits are substantially exposed in the membrane-bound complex. Epsilon-4 inhibits the ATPase activity of the membrane-bound enzyme by about 50%, and Fab prepared from epsilon-4 inhibits by about 40%. This inhibition is not associated with any substantial change in the major apparent Km for ATP. These results suggest that inhibition of membrane-bound F1-ATPase arises from steric effects of the antibody.     

Availability to monoclonal antibodies of antigenic sites of the alpha and beta subunits in active, denatured or membrane-bound mitochondrial F1-ATPase

The binding of five monoclonal antibodies to mitochondrial F1-ATPase has been studied. Competition experiments between monoclonal antibodies demonstrate that these antibodies recognize four different antigenic sites and provide information on the proximity of these sites. The accessibility of the epitopes has been compared for F1 integrated in the mitochondrial membrane, for purified beta-subunit and for purified F1 maintained in its active form by the presence of nucleotides or inactivated either by dilution in the absence of ATP or by urea treatment. The three anti-beta monoclonal antibodies bound more easily to the beta-subunit than to active F1, and recognized equally active F1 and F1 integrated in the membrane, indicating that their antigenic sites are partly buried similarly in purified or membrane-bound F1 and better exposed in the isolated beta-subunit. In addition, unfolding F1 by urea strongly increased the binding of one anti-beta monoclonal antibody (14 D5) indicating that this domain is at least partly shielded inside the beta-subunit. One anti-alpha monoclonal antibody (20 D6) bound poorly to F1 integrated in the membrane, while the other (7 B3) had a higher affinity for F1 integrated in the membrane than for soluble F1. Therefore, 20 D6 recognizes an epitope of the alpha-subunit buried inside F1 integrated in the membrane, while 7 B3 binds to a domain of the alpha-subunit well exposed at the surface of the inner face of the mitochondrial membrane.     

Phosphorylation of the alpha-subunits of the Na+/K+-ATPase from mammalian kidneys and Xenopus oocytes by cGMP-dependent protein kinase results in stimulation of ATPase activity.

Phosphorylation of Na+/K+-ATPase by cGMP-dependent protein kinase (PKG) has been studied in enzymes purified from pig, dog, sheep and rat kidneys, and in Xenopus oocytes. PKG phosphorylates the alpha-subunits of all animal species investigated. Phosphorylation of the beta-subunit was not observed. The stoichiometry of phosphorylation estimated for pig, sheep and dog renal Na+/K+-ATPase is 3.5, 2.2 and 2.1 mol Pi per mol alpha-subunit, respectively. Proteolytic fingerprinting of the pig alpha1-subunits phosphorylated by PKG using specific antibodies raised against N-terminus or C-terminus reveals that phosphorylation sites are located within the intracellular loop of the alpha-subunit between the 35 kDa N-terminal and 27 kDa C-terminal fragments. Phosphorylation sites within the alpha1-subunit of the purified Na+/K+-ATPase do not appear to be easily accessible for PKG since incorporation of Pi requires 0.2% of Triton X-100. Administration of cGMP and PKG in the presence of 5 mm ATP, which prevents inactivation of the Na+/K+-ATPase by detergent, leads to stimulation of hydrolytic activity by 61%. Administration of 50 microm of cGMP or dbcGMP in yolk-free homogenates of Xenopus oocytes leads to stimulation of ouabain-dependent ATPase activity by 130-198% and to incorporation of 33P into the alpha-subunit without the detergent. Hence, PKG plays regulatory role in active transmembraneous transport of Na+ and K+ via phosphorylation of the catalytic subunit of the Na+/K+-ATPase.     

Primary antibody-Fab fragment complexes: a flexible alternative to traditional direct and indirect immunolabeling techniques.

Immunolabeling with immune complexes of primary and secondary antibodies offers an attractive method for detecting and quantifying specific antigen. Primary antibodies maintain their affinity for specific antigen after labeling with Fab fragments in vitro. Incubation of these immune complexes with excess normal serum from the same species as the primary antibody prevents free Fab fragments from recognizing immunoglobulin. Effectively a hybrid between traditional direct and indirect immunolabeling techniques, this simple technique allows primary antibodies to be non-covalently labeled with a variety of reporter molecules as and when required. Using complexes containing Fab fragments that recognize both the Fc and F(ab')2 regions of IgG, we show that this approach prevents nonspecific labeling of endogenous immunoglobulin, can be used to simultaneously detect multiple antigens with primary antibodies derived from the same species, and allows the same polyclonal antibody to be used for both antigen capture and detection in ELISA.     

Monoclonal Antibodies to the [alpha]- and [beta]-Subunits of the Plant Mitochondrial F1-ATPase

We have generated nine monoclonal antibodies against subunits of the maize (Zea mays L.) mitochondrial F1-ATPase. These monoclonal antibodies were generated by immunizing mice against maize mitochondrial fractions and randomly collecting useful hybridomas. To prove that these monoclonal antibodies were directed against ATPase subunits, we tested their cross-reactivity with purified F1-ATPase from pea cotyledon mitochondria. One of the antibodies ([alpha]-ATPaseD) cross-reacted with the pea F1-ATPase [alpha]-subunit and two ([beta]-ATPaseD and [beta]-ATPaseE) cross-reacted with the pea F1-ATPase [beta]-subunit. This established that, of the nine antibodies, four react with the maize [alpha]-ATPase subunit and the other five react with the maize [beta]-ATPase subunit. Most of the monoclonal antibodies cross-react with the F1-ATPase from a wide range of plant species. Each of the four monoclonal antibodies raised against the [alpha]-subunit recognizes a different epitope. Of the five [beta]-subunit antibodies, at least three different epitopes are recognized. Direct incubation of the monoclonal antibodies with the F1-ATPase failed to inhibit the ATPase activity. The monoclonal antibodies [alpha]-ATPaseD and [beta]-ATPaseD were bound to epoxide-glass QuantAffinity beads and incubated with a purified preparation of pea F1-ATPase. The ATPase activity was not inhibited when the antibodies bound the ATPase. The antibodies were used to help map the pea F1-ATPase subunits on a two-dimensional map of whole pea cotyledon mitochondrial protein. In addition, the antibodies have revealed antigenic similarities between various isoforms observed for the [alpha]- and [beta]-subunits of the purified F1-ATPase. The specificity of these monoclonal antibodies, along with their cross-species recognition and their ability to bind the F1-ATPase without inhibiting enzymic function, makes these antibodies useful and invaluable tools for the further purification and characterization of plant mitochondrial F1-ATPases.     

Amount and turnover rate of the F0F1-ATPase and the stoichiometry of its inhibition by oligomycin in Rhodospirillum rubrum chromatophores

The amount of F1-ATPase in chromatophores from Rhodospirillum rubrum was determined by Western blotting using anti-RrF1 rabbit antibodies. 9.1 mmol F1 (mol bacteriochlorophyll)-1 was obtained or 14% of the total protein content of the chromatophores. The turnover rate of the F0F1-ATPase was 17 molecules ATP s-1 during synthesis, 2 molecules ATP s-1 during hydrolysis under coupled conditions with Mg2+ as the divalent cation, and 7 molecules ATP s-1 during hydrolysis in the presence of carbonyl cyanide p-trifluoromethoxyphenylhydrazone. Binding of 1 mol oligomycin/mol F0F1-ATPase was found to inhibit the activities of the enzyme completely. A single binding site was found with a Kd of approximately 2 microM.     

Monoclonal antibodies to Escherichia coli F1-ATPase. Correlation of binding site location with interspecies cross-reactivity and effects on enzyme activity

Twenty-one hybridoma cell lines which secret antibodies to the subunits of the Escherichia coli F1-ATPase were produced. Included within the set are four antibodies which are specific for alpha, six for beta, three for gamma, four for delta and four for epsilon. The antibodies were divided into binding competition subgroups. Two such competition subgroups are represented for the alpha, beta, and epsilon subunits, one for delta and three for gamma. The ability to bind intact F1-ATPase was demonstrated for some of the antibodies to alpha and beta, and for all of those to delta, while the antibodies to gamma and epsilon gave unclear results. All of the antibodies to alpha and beta which bound ATPase were found to have effects on the ATPase activity of purified E. coli F1-ATPase. One of those to alpha inhibited activity by about 30%. Another anti-alpha was mildly stimulatory. The four antibodies to beta which bound ATPase inhibited activity by 90%. In contrast, membrane-bound ATPase was hardly affected by the antibodies to alpha, but was inhibited by 40-60% by the antibodies to beta. The other antibodies to alpha and beta bound only free subunits, or partially dissociated ATPase, suggesting that their epitopes are buried between subunits in ATPase. These antibodies had no effects on activity. The ability of the antibodies to recognize ATPase subunits present in crude extracts from mitochondria, chloroplasts, and a variety of bacteria was tested using nitrocellulose blots of sodium dodecyl sulfate-polyacrylamide gels. One anti-beta specifically recognized proteins in the range of 50,000-60,000 daltons in each of the extracts, although the reaction with mitochondrial beta was weak. Some of the other antibodies had limited cross-reaction, but most were specific for the E. coli protein. In some species, those proteins which were recognized by the anti-beta ran with a higher apparent molecular weight than proteins which were recognized by an anti-alpha. All antibodies which exhibited cross-reactivity were found to recognize sites which were not exposed in intact ATPase, implying that the surfaces which lie between subunits are most highly conserved.     

Mitochondrial ATP synthase complex. Membrane topography and stoichiometry of the F0 subunits.

The topography of the subunits of the membrane sector F0 of the ATP synthase complex in the bovine mitochondrial inner membrane was studied with the help of subunit-specific antibodies raised to the F0 subunits b, d, 6, F6, A6L, OSCP (oligomycin-sensitivity-conferring protein), and N,N' -dicyclohexylcarbodiimide (DCCD)-binding proteolipid and to the ATPase inhibitor protein (IF1) as an internal control. Exposure of F0 subunits in inverted and right-side-out inner membranes was investigated by direct antibody binding as well as by susceptibility of these subunits to degradation by various proteases as monitored by gel electrophoresis of the membrane digests and immunoblotting with the subunit-specific antibodies. Results show that subunits b, d, F6, A6L (including its C-terminal end) and OSCP were exposed on the matrix side. Sufficient masses of these subunits to recognize antibodies or undergo proteolysis were not exposed on the cytosolic side. This was also the case for subunit 6 and the DCCD-binding proteolipid on either side of the inner membrane. Quantitative immunoblotting in which bound radio-activity from [125I]protein A was employed to estimate the concentration of an antigen in a sample allowed the determination of the stoichiometry of several F0 subunits and IF1 relative to F1-ATPase. Results showed that per mol of F1 there are in bovine heart mitochondria 1 mol each of d, OSCP, and IF1, and 2 mol each of b and F6. Subunit 6 and the DCCD-binding proteolipid could not be quantitated, because the former transferred poorly to nitrocellulose and the latter's antibody did not bind [125I]protein A.     

Inhibition of yeast mitochondrial F1-ATPase, F0F1-ATPase and submitochondrial particles by rhodamines and ethidium bromide

ATP hydrolysis by F1-ATPase is strongly inhibited by cationic rhodamines; neutral rhodamines are very poor inhibitors. Rhodamine 6G is a noncompetitive inhibitor of purified F0F1-ATPase and submitochondrial particles, however, an uncompetitive inhibitor of F1-ATPase (KI approximately equal to 2.4 microM for all three enzyme forms). Ethidium bromide is a noncompetitive inhibitor of F0F1-ATPase, submitochondrial particles and also F1-ATPase (KI approximately equal to 270 microM). Neither of the inhibitors affects the negative cooperativity (nH approximately equal to 0.7). The non-identical binding sites for rhodamine 6G and ethidium bromide are located on the F1-moiety and are topologically distinct from the catalytic site. Binding of the inhibitors prevents the conformational changes essential for energy transduction. It is concluded that the inhibitor binding sites are involved in proton translocation. In F1-ATPase, binding of MgATP at a catalytic site causes conformational changes, which allosterically induce the correct structure of the rhodamine 6G binding site. In F0F1-ATPase, this conformation of the F1-moiety exists a priori, due to allosteric interactions with F0-subunits. The binding site for ethidium bromide on F1-ATPase does not require substrate binding at the catalytic site and is not affected by F0F1-subunit interactions.     

Kinetic properties of F1-ATPase influence the ability of yeasts to grow in anoxia or absence of mtDNA

A mechanism for hypoxia survival by eukaryotic cells is suggested from studies on the petite mutation of yeasts. Previous work has shown that mutations in the alpha, beta and gamma subunit genes of F1-ATPase can suppress lethality due to loss of the mitochondrial genome from the petite-negative yeast Kluyveromyceslactis. Here it is reported that suppressor mutations appear to increase the affinity of F1-ATPase for ATP. Extension of this study to other yeasts shows that petite-positive species have a higher affinity for ATP in the hydrolysis reaction than petite-negative species. Possession of a F1-ATPase with a low K(m) for ATP is considered to be an adaptation for hypoxic growth, enabling maintenance of the mitochondrial inner membrane potential, deltapsi, by enhanced export of protons through F1F0-ATP synthase connected to increased ATP hydrolysis at low substrate concentration.     

Distribution of the intracellular Ca(2+)-ATPase isoform 2b in pig brain subcellular fractions and cross-reaction with a monoclonal antibody raised against the enzyme isoform

The presence and distribution of sarco-endoplasmic reticulum Ca(2+)-ATPase (SERCA) isoform 2b in microsomes and other subcellular fractions isolated from pig brain has been demonstrated by the combined use of a specific antibody raised against the SERCA2b isoform and ATP phosphorylation experiments. All subcellular fractions show an approximately 110 kDa phosphorylated protein, the band intensity being stronger in microsomes. Preliminary treatment of the samples with trypsin generates two phosphorylated fragments of about 57 and 33 kDa in the presence of Ca(2+). The observed fragments are typical trypsinized products of the SERCA2b isoform. The monoclonal antibody Y/1F4 raised against the sarcoplasmic reticulum Ca(2+)-ATPase (isoform 1) binds to the 110 kDa band in membranes isolated from brain. The binding was stronger in microsomes than in other fractions. Furthermore, this antibody also recognizes a clear band at around 115 kDa. This band is always stronger in plasma membrane than in synaptosomes or microsomes and is unaffected by trypsin. Phosphorylation studies in the absence of Ca(2+) suggest that the 115 kDa protein is not a Ca(2+)-ATPase.     

Interactions between the oligomycin sensitivity conferring protein (OSCP) and beef heart mitochondrial F1-ATPase. 2. Identification of the interacting F1 subunits by cross-linking

Interactions between oligomycin sensitivity conferring protein (OSCP) and subunits of beef heart mitochondrial F1-ATPase have been explored by cross-linking at an OSCP/F1 molar ratio close to 1 to ensure specific high-affinity binding of OSCP to F1 [see Dupuis et al. [Dupuis, A., Issartel, J.-P., Lunardi, J., Satre, M., & Vignais, P.V. (1985) Biochemistry (preceding paper in this issue)]]. Cross-links between F1 subunits and OSCP were established by means of two zero length cross-linkers, 1-[3-(dimethylamino)propyl]-3-ethylcarbodiimide and N-(ethoxycarbonyl)-2-ethoxydihydroquinoline. The cross-linked products were separated by sodium dodecyl suflate-polyacrylamide gel electrophoresis. Coomassie blue staining revealed two cross-linked products of Mr 75 000 and 80 000 which could result from the binding of OSCP to the alpha and beta subunits of F1. Definite identification of the cross-linked products was achieved by chemical labeling with specific radiolabeled reagents and by blotting on nitrocellulose filters followed by immunocharacterization with anti-alpha, anti-beta, and anti-OSCP antibodies. OSCP was found to cross-link with the alpha and beta subunits of F1.     

Farnesol-induced generation of reactive oxygen species dependent on mitochondrial transmembrane potential hyperpolarization mediated by F(0)F(1)-ATPase in yeast

An isoprenoid farnesol (FOH) inhibited cellular oxygen consumption and induced mitochondrial generation of reactive oxygen species (ROS) in cells of Saccharomyces cerevisiae in correlation with hyperpolarization of the mitochondrial transmembrane potential (mtDeltaPsi). The FOH-induced events were coordinately abolished with the F(1)-ATPase inhibitor sodium azide as well as the F(0)F(1)-ATPase inhibitor oligomycin, suggesting the dependence of ROS generation on mtDeltaPsi hyperpolarization mediated by the proton pumping function of F(0)F(1)-ATPase as a result of ATP hydrolysis. The role of F(1)-ATPase activity in mtDeltaPsi hyperpolarization was supported by the intracellular depletion of ATP in FOH-treated cells and its protection with sodium azide. An indirect mechanism was suggested to exist in the regulation of F(0)F(1)-ATPase by FOH to accelerate its ATP-hydrolyzing activity.     

Nickel(II) transport in human blood serum. Studies of nickel(II) binding to human albumin and to native-sequence peptide, and ternary-complex formation with l-histidine

1. The initial rapid phase of ATP hydrolysis by bovine heart submitochondrial particles or by soluble F1-ATPase is insensitive to anion activation (sulphite) or inhibition (azide). 2. The second slow phase of ATP hydrolysis is hyperbolically inhibited by azide (Ki approximately 10(-5) M); the inosine triphosphatase activity of submitochondrial particles or F1-ATPase is insensitive to azide or sulphite. 3. The rate of interconversion between rapid azide-insensitive and slow azide-sensitive phases of ATP hydrolysis does not depend on azide concentration, but strongly depends on ATP concentration. 4. Sulphite prevents the interconversion of the rapid initial phase of the reaction into the slower second phase, and also prevents and slowly reverses the inhibition by azide. 5. The presence of sulphite in the mixture when ADP reacts with ATPase of submitochondrial particles changes the pattern of the following activation process. 6. Azide blocks the activation of ATP-inhibited ATPase of submitochondrial particles by phosphoenolpyruvate and pyruvate kinase. 7. The results obtained suggest that the inhibiting effect of azide on mitochondrial ATPase is due to stabilization of inactive E*.ADP complex formed during ATP hydrolysis; the activation of ATPase by sulphite is also realized through the equilibrium between intermediate active E.ADP complex and inactive E*.ADP complex.     

Protein kinase C-α activation promotes recovery of mitochondrial function and cell survival following oxidant injury in renal cells

We demonstrated that nonselective PKC activation promotes mitochondrial function in renal proximal tubular cells (RPTC) following toxicant injury. However, the specific PKC isozyme mediating this effect is unknown. This study investigated the role of PKC-α in the recovery of mitochondrial functions in oxidant-injured RPTC. Wild-type PKC-α (wtPKC-α) and inactive PKC-α mutants were overexpressed in RPTC to selectively increase or block PKC-α activation. Oxidant (tert-butyl hydroperoxidel; TBHP) exposure activated PKC-α in RPTC but decreased PKC-α levels in mitochondria following treatment. Uncoupled and state 3 respirations and activities of complexes I and IV in TBHP-injured cells decreased to 55, 44, 49, and 65% of controls, respectively. F(0)F(1)-ATPase activity and ATP content in injured RPTC decreased to 59 and 60% of controls, respectively. Oxidant exposure increased reactive oxygen species (ROS) production by 210% and induced mitochondrial fragmentation and 52% RPTC lysis. Overexpressing wtPKC-α did not block TBHP-induced ROS production but improved respiration and complex I activity, restored complex IV and F(0)F(1)-ATPase activities, promoted recovery of ATP content, blocked mitochondrial fragmentation, and reduced RPTC lysis to 14%. In contrast, inhibiting PKC-α 1) induced mitochondrial hyperpolarization and fragmentation; 2) blocked increases in ROS production; 3) prevented recovery of respiratory complexes and F(0)F(1)-ATPase activities, respiration, and ATP content; and 4) exacerbated TBHP-induced RPTC lysis. We conclude that 1) activation of PKC-α prevents mitochondrial hyperpolarization and fragmentation, decreases cell death, and promotes recovery of mitochondrial respiration and ATP content following oxidant injury in RPTC; and 2) respiratory complexes I and IV and F(0)F(1)-ATPase are targets of active PKC-α.     

Identification of the amino acids comprising a surface-exposed epitope within the nucleotide-binding domain of the Na+,K(+)-ATPase using a random peptide library.

Monoclonal antibodies that bind native protein can generate considerable information about structure/function relationships, but identification of their epitopes can be problematic. Previously, monoclonal antibody M8-P1-A3 has been shown to bind to the catalytic (alpha) subunit of the Na+,K(+)-ATPase holoenzyme and the synthetic peptide sequence 496-HLLVMK*GAPER-506, which includes Lys 501 (K*), the major site for fluorescein-5'-isothiocyanate labeling of the Na+,K(+)-ATPase. This sequence region of alpha is proposed to comprise a portion of the enzyme's ATP binding domain (Taylor, W. R. & Green, N. W., 1989, Eur. J. Biochem. 179, 241-248). In this study we have determined M8-P1-A3's ability to recognize the alpha-subunit or homologous E1E2-ATPase proteins from different species and tissues in order to deduce the antibody's epitope. In addition the bacteriophage random peptide or "epitope" library, recently developed by Scott and Smith (1990, Science 249, 386-390) and Devlin et al. (Devlin, J. J., Panganiban, L. C., & Devlin, P. E., 1990, Science 249, 404-406), has served as a convenient technique to confirm the species-specificity mapping data and to determine the exact amino acid requirements for antibody binding. The M8-P1-A3 epitope was found to consist of the five amino acid 494-PRHLL-498 sequence stretch of alpha, with residues PRxLx being critical for antibody recognition.     

Redox regulation of rotation of the cyanobacterial F1-ATPase containing thiol regulation switch

F(1)-ATP synthase (F(1)-ATPase) is equipped with a special mechanism that prevents the wasteful reverse reaction, ATP hydrolysis, when there is insufficient proton motive force to drive ATP synthesis. Chloroplast F(1)-ATPase is subject to redox regulation, whereby ATP hydrolysis activity is regulated by formation and reduction of the disulfide bond located on the γ subunit. To understand the molecular mechanism of this redox regulation, we constructed a chimeric F(1) complex (α(3)β(3)γ(redox)) using cyanobacterial F(1), which mimics the regulatory properties of the chloroplast F(1)-ATPase, allowing the study of its regulation at the single molecule level. The redox state of the γ subunit did not affect the ATP binding rate to the catalytic site(s) and the torque for rotation. However, the long pauses caused by ADP inhibition were frequently observed in the oxidized state. In addition, the duration of continuous rotation was relatively shorter in the oxidized α(3)β(3)γ(redox) complex. These findings lead us to conclude that redox regulation of CF(1)-ATPase is achieved by controlling the probability of ADP inhibition via the γ subunit inserted region, a sequence feature observed in both cyanobacterial and chloroplast ATPase γ subunits, which is important for ADP inhibition (Sunamura, E., Konno, H., Imashimizu-Kobayashi, M., Sugano, Y., and Hisabori, T. (2010) Plant Cell Physiol. 51, 855-865).     

Monoclonal Antibodies to Rabbit Brain Acetylcholinesterase: Selective Enzyme Inhibition, Differential Affinity for Enzyme Forms, and Cross-Reactivity with Other Mammalian Cholinesterases

Eleven unique monoclonal IgG antibodies were raised against rabbit brain acetylcholinesterase (AChE, EC 3.1.1.7), purified to electrophoretic homogeneity by a two-step procedure involving immunoaffinity chromatography. The apparent dissociation constants of these antibodies for rabbit AChE ranged from about 10 nM to more than 100 nM (assuming one binding site per catalytic subunit). Species cross-reactivity was investigated with crude brain extracts from rabbit, rat, mouse cat, guinea pig, and human. One antibody bound rabbit AChE exclusively; most bound AChE from three or four species; two bound enzyme from all species tested. Identical, moderate affinity for rat and mouse brain AChE was displayed by two antibodies; two others were able to distinguish between these similar antigens. Nine of the antibodies had lowered affinity for AChE in the presence of 1 M NaCl, but two were salt resistant. Analysis of mutual interferences in AChE binding suggested that certain of the antibodies were competing for nearby epitopes on the AChE surface. One antibody was a potent AChE inhibitor (IC50 = 10(-8) M), blocking up to 90% of the enzyme activity. Most of the antibodies were less able to bind the readily soluble AChE of detergent-free brain extracts than the AChE which required detergent for solubilization. The extreme case, an antibody that was unable to recognize nearly half of the "soluble" AChE, was suspected of lacking affinity for the hydrophilic enzyme form.     

A monoclonal antibody (PL/IM 430) to human platelet intracellular membranes which inhibits the uptake of Ca2+ without affecting the Ca2+ +Mg2+-ATPase.

To probe the structure-function relationships of proteins present in the endoplasmic reticulum-like intracellular membranes of human blood platelets a panel of monoclonal antibodies have been raised, using as immunogen highly purified platelet intracellular membrane vesicles isolated by continuous flow electrophoresis [Menashi, Weintroub & Crawford (1981) J. Biol. Chem. 256, 4095-4101]. Four of these antibodies recognize a single 100 kDa polypeptide in the platelet membrane by immunoblotting. One antibody PL/IM 430 (of IgG1 subclass) inhibited (approximately 70%) the energy-dependent uptake of Ca2+ into the vesicles without affecting the Ca2+ +Mg2+-ATPase activity or the protein phosphorylation previously shown to proceed concomitantly with Ca2+ sequestration [Hack, Croset & Crawford (1986) Biochem. J. 233, 661-668]. The inhibition is independent of ATP concentration over a range 0-2 mM-ATP but shows dose-dependency for external [Ca2+] with maximum inhibition of Ca2+ translocation at concentrations of Ca2+ greater than 500 nM. This capacity of the antibody PL/IM 430 functionally to dislocate components of the intracellular membrane Ca2+ pump complex may have value in structural studies.     

Structural and functional differences in H+-ATPases with native and reconstituted inhibitor protein

Anti F1 antibodies that react with the alpha and beta subunits of the mitochondrial F0-F1 ATPase complex do not interfere with the natural inhibitor protein-ATPase interaction as revealed by inhibitor peptide titration curves. Submitochondrial particles with endogenous or added bound inhibitor protein show differences in immunoprecipitation. Submitochondrial particles which are partially depleted of inhibitor protein gave the same immunoprecipitation curve as the Mg-ATP particle. Anti F1 antibodies induce differential effects in ATP hydrolysis and ATP-Pi exchange. ATP hydrolysis is stimulated in Mg-ATP particles to 200%, while inhibitor depleted and inhibitor reconstituted particles are inhibited by the presence of the antibodies. ATP-Pi exchange is stimulated in inhibitor reconstituted particles and inhibited in Mg-ATP and inhibitor depleted particles. These results suggest that the inhibitor protein when endogenously bound confers a different conformation to the F1-ATPase than that of the F1 ATPase with added bound inhibitor protein.