Monoclonal antibody HK4001 completely inhibits K(+)-dependent ATP hydrolysis and H+ transport of hog gastric H+,K(+)-ATPase

A monoclonal antibody (designated as HK4001) was prepared against hog gastric H+,K(+)-ATPase. It dose-dependently inhibited the H+,K(+)-ATPase activity, formation of the K(+)-sensitive phosphoenzyme, and proton uptake into gastric vesicles. The H+,K(+)-ATPase activity was completely inhibited by addition of the antibody at a molar ratio of 1:2 (antibody/catalytic subunit) at pH 7.8. The maximal inhibition decreased with decrease in pH of the medium (7.8 greater than 7.4 greater than 6.2). The Fab fragment obtained by digestion of the antibody with papain was also inhibitory. The antibody did not inhibit the K(+)-dependent p-nitrophenylphosphatase or the labeling of the enzyme with fluorescein isothiocyanate. It inhibited gastric H+,K(+)-ATPase from rabbits and rats, but did not cross-react with related cation-transport ATPases (Na+,K(+)-ATPase or Ca2(+)-ATPase) or H(+)-ATPase in the multivesicular body. From these and related findings, the antibody was suggested to recognize a highly specific site on the cytosolic surface of H+,K(+)-ATPase. The conformation of the epitope was conserved after treatment with Triton X-100, but not sodium dodecyl sulfate. In addition, judging from the stoichiometry of inactivation of H+,K(+)-ATPase by this antibody, the functional unit of H+,K(+)-ATPase was suggested to be a dimer or a tetramer (not a trimer) of the catalytic unit.     

Bi-ionic potentials of bovine lens capsules and collodion membranes

Concentration dependencies of bi-ionic potentials of well-cleaned bovine lens capsules in vitro, of collodion and of modified collodion membranes were studied. The lens capsules have positively fixed charges, and collodion membranes have negatively fixed charges. As these membranes are partially selectively permeable, both co-ions and counter-ions exist in the membrane. However, many studies on bi-ionic potentials have been limited to systems in which the membrane has extreme ionic selectivity and co-ions are completely excluded from the membrane. Experimental results agreed with theoretical values obtained by assuming the common ion concentration to be constant throughout the membrane for systems such as KCl(C)-membrane (θ>0, or θ<0)-NaCl(C), NaNO₃(C)-membrane (θ>0)-NaCl(C) and CaCl₂(C₁)-membrane (θ>0)-NaCl(C₂) (C₂/C₁ = 2), where C is the bulk concentration. The theoretical reliability of this assumption was checked. When both electrolytes in solution were uni-univalent, the ratio of ionic mobilities of two counter-ions (or two co-ions) in all of these membranes was almost the same as the ratio obtained in bulk solution, while the ratio of ionic mobilities of the counter-ion and the co-ion was almost the same as the ratio obtained in bulk solution for the lens capsule, but different in the case of the collodion and modified collodion membranes.     

The Cl- channel in hog gastric vesicles is part of the function of H,K-ATPase

Hog gastric vesicles showed Cl- conductance when treated with Cu2+-o-phenanthroline, an S-S cross-linking reagent. An IgG monoclonal antibody caused dose-dependent inhibition of Cl- conductance that had been induced by S-S cross-linking. The antibody did not cause intervesicular aggregation, as determined by measurement of vesicle size. These results show that Cl- conductance, the stimulation and inhibition of which are regulated reversibly by S-S----2SH transformation, is due to native, physiological channels. The antibody also dose dependently inhibited the activities of H,K-ATPase and p-nitrophenyl phosphatase in gastric vesicles, but did not inhibit Na,K-ATPase obtained from dog kidney. Immunoblotting with the antibody of vesicle proteins solubilized in sodium dodecyl sulfate-polyacrylamide gel showed that the antibody binds to a 95-kDa subunit of H,K-ATPase and its dimeric 180-kDa polypeptide. The antibody-binding sites of H,K-ATPase activity and the Cl- channel for the inhibition were present on the external (cytosolic) surface of the transmembraneous ATPase. A gastric antisecretory compound, 2-methyl-8-(phenylmethoxy)imidazo[1,2 alpha] pyridine-3-acetonitrile (SCH 28080), competitively bound to the high affinity site of K+ on the internal (luminal) surface of H,K-ATPase, and its half-maximal inhibitory concentration for H,K-ATPase activity in tight vesicles was 0.2 microM in the presence of valinomycin. SCH 28080 also dose dependently inhibited opening of Cl- channels by S-S cross-linking, the regulatory site being present on the cytosolic side and more internally than the antibody binding site. The half-inhibitory concentration of SCH 28080 was 0.3 microM. The present results with the antibody and SCH 28080 indicate that the Cl- channel is part of the function of H,K-ATPase.     

Properties of light and heavy vesicles simultaneously prepared from hog gastric mucosae

We obtained two kinds of vesicle preparations which were of different density from the same gastric mucosae of hogs stimulated with food before slaughter. Both kinds contained H+,K+-ATPase. The light vesicle preparation differed from the heavy vesicle preparation as follows: the KCl permeability across the membrane of heavy vesicles was larger than that of light vesicles, the actin (46-kDa peptide on SDS-polyacrylamide gel) content of heavy vesicles was much higher than that of light vesicles, and the H+,K+-ATPase activity of heavy vesicles was less sensitive to a monoclonal antibody raised against light vesicles (HK2032) than that of light vesicles. Furthermore, there was a drastic difference in reactivity to SCH 28080, which is an H+,K+-ATPase-specific inhibitor and reacts competitively with the K+-high affinity site. SCH 28080 is more potent in light vesicles than in heavy vesicles. These results suggest that the conformation of H+,K+-ATPase changed during the translocation from tubulovesicles to the apical plasma membrane. On the other hand, H+,K+-ATPase activities in both vesicles had similar pH and [K+] dependences.     

Detection of a ouabain-induced structural change in the sodium, potassium-adenosine triphosphatase.

The structural consequences of ouabain interaction with a highly purified Na+K+-ATPase preparation, isolated from the outer medulla of porcine kidneys, were examined. The apparent heat capacity vs. temperature profile of the enzyme was obtained with a newly designed differential scanning calorimeter. The profile was characterized by a major endothermic transition at 55.3 degrees C. This transition appeared to correspond to irreversible protein denaturation since it was associated with loss of enzyme activity and the transition was not present in claorimetric profiles obtained after the initial scan of a sample. Interaction of ouabain with its receptor surface on the Na+, K+-ATPase shifted the endothermic transition from 55.3 to 59.5 degrees C and decreased the width of the transition. This indicated that the ouabain-Na+, K+-ATPase complex was more stable with respect to temperature and that the apparent cooperative nature of the transition was greater for the complex than for the untreated enzyme. The effects of the ouabain-enzyme interaction were examined with the fluorescence probe, 8-anilino-1-naphthalenesulfonic acid. The fluorescence of this dye in the presence of the enzyme was monitored as a function of temperature. These measurements also suggested that ouabain induces the formation of a more stable enzyme conformation. Incubation of the enzyme for 10 min at 53 degrees C with and without ouabain and measurement of remaining enzyme activity after the dissociation of bound ouabain confirmed the conclusions from the fluorescence and scanning calorimeter experiments.     

Redesigning channel-forming peptides: amino acid substitutions that enhance rates of supramolecular self-assembly and raise ion transport activity

Three series of 22-residue peptides derived from the transmembrane M2 segment of the glycine receptor alpha1-subunit (M2GlyR) have been designed, synthesized, and tested to determine the plasticity of a channel-forming sequence and to define whether channel pores with enhanced conductive properties could be created. Sixteen sequences were examined for aqueous solubility, solution-association tendency, secondary structure, and half-maximal concentration for supramolecular assembly, channel activity, and ion transport properties across epithelial monolayers. All peptides interact strongly with membranes: associating with, inserting across, and assembling to form homooligomeric bundles when in micromolar concentrations. Single and double amino acid replacements involving arginine and/or aromatic amino acids within the final five C-terminal residues of the peptide cause dramatic effects on the concentration dependence, yielding a range of K1/2 values from 36 +/- 5 to 390 +/- 220 microM for transport activity. New water/lipid interfacial boundaries were established for the transmembrane segment using charged or aromatic amino acids, thus limiting the peptides' ability to move perpendicularly to the plane of the bilayer. Formation of discrete water/lipid interfacial boundaries appears to be necessary for efficient supramolecular assembly and high anion transport activity. A peptide sequence is identified that may show efficacy in channel replacement therapy for channelopathies such as cystic fibrosis.