Studies on (K+ + H+)-ATPase. IV. Effects of phospholipase C treatment

The K(+) affinity of gastric H(+),K(+)-ATPase is affected by both lipid composition and the beta-subunit

It is generally assumed that negatively charged residues present in the alpha-subunit of gastric H(+),K(+)-ATPase are involved in K(+) binding and transport. Despite the fact that there is no difference between various species regarding these negatively charged residues, it was observed that the apparent K(+) affinity of the pig enzyme was much lower than that of the rat H(+),K(+)-ATPase. By determining the K(+)-stimulated dephosphorylation reaction of the phosphorylated intermediate K(0.5) values for K(+) of 0.12+/-0.01 and 1.73+/-0.03 mM were obtained (ratio 14.4) for the rat and the pig enzyme, respectively. To investigate the reason for the observed difference in K(+) sensitivity, both enzymes originating from the gastric mucosa were either reconstituted in a similar lipid environment or expressed in Sf9 cells. After reconstitution in K(+)-permeable phosphatidylcholine/cholesterol liposomes K(0.5) values for K(+) of 0.16+/-0.01 and 0.35+/-0.05 mM for the rat and pig enzyme respectively were measured (ratio 2.2). After expression in Sf9 cells the pig gastric H(+),K(+)-ATPase still showed a 4.1 times lower K(+) sensitivity than that of the rat enzyme. This means that the difference in K(+) sensitivity of the rat and pig gastric H(+), K(+)-ATPase is not only due to a different lipid composition but also to the structure of either the alpha- or beta-subunit. Expression of hybrid enzymes in Sf9 cells showed that the difference in K(+) sensitivity between the rat and pig gastric H(+),K(+)-ATPase is primarily due to differences in the beta-subunit.

On the principles of functional ordering in biological membranes

Integrating the available data on lipid-protein interactions and ordering in lipid mixtures allows to emanate a refined model for the dynamic organization of biomembranes. An important difference to the fluid mosaic model is that a high degree of spatiotemporal order should prevail also in liquid crystalline, "fluid" membranes and membrane domains. The interactions responsible for ordering the membrane lipids and proteins are hydrophobicity, coulombic forces, van der Waals dispersion, hydrogen bonding, hydration forces and steric elastic strain. Specific lipid-lipid and lipid-protein interactions result in a precisely controlled yet highly dynamic architecture of the membrane components, as well as in its selective modulation by the cell and its environment. Different modes of organization of the compositionally and functionally differentiated domains would correspond to different functional states of the membrane. Major regulators of membrane architecture are proposed to be membrane potential controlled by ion channels, intracellular Ca2+, pH, changes in lipid composition due to the action of phospholipase, cell-cell coupling, as well as coupling of the membrane with the cytoskeleton and the extracellular matrix. Membrane architecture is additionally modulated due to the membrane association of ions, lipo- and amphiphilic hormones, metabolites, drugs, lipid-binding peptide hormones and amphitropic proteins. Intermolecular associations in the membrane and in the membrane-cytoskeleton interface are further selectively controlled by specific phosphorylation and dephosphorylation cascades involving both proteins and lipids, and regulated by the extracellular matrix and the binding of growth factors and hormones to their specific receptor tyrosine kinases. A class of proteins coined architectins is proposed, as a notable example the pp60src kinase. The functional role of architectins would be in causing specific changes in the cytoskeleton-membrane interface, leading to specific configurational changes both in the membrane and cytoskeleton architecture and corresponding to (a) distinct metabolic/differentiation states of the cell, and (b) the formation and maintenance of proper three dimensional membrane structures such as neurites and pseudopods.

Characterization of phospholipase A2 of mycoplasma species

As phospholipases of mycoplasma species may play a role in the pathogenesis of respiratory tract and urogenital tract diseases Mycoplasma mycoides and Acholeplasma laidlawii were examined as to the production of phospholipase A2 (PLA) and attempts were made to purify and characterize it. Both species produced PLA. The purified enzyme was found to be heat-labile, active at alkaline pH, revealing a single band in polyacrylamide gel electrophoresis. Metal ions such as calcium and barium, increased its activity whereas solvents at high concentrations decreased it. It was resistant to surfactants.

Effects of phospholipases on Cl-ATPase in the rat brain

We investigated the effects of phospholipases on the activity of microsomal Cl-ATPase in the rat brain, in reference to those on the activities of Na,K-ATPase and anion-insensitive Mg-ATPase. In the presence of phospholipase A2 or phospholipase C, which almost completely hydrolyzed microsomal phosphoglycerides, the activities of Cl-ATPase and Na,K-ATPase were decreased to 8-50% of the control, but anion-insensitive Mg-ATPase activity was not altered. On the other hand, with sphingomyelinase treatment, only anion-insensitive Mg-ATPase was slightly inactivated. On the addition of phospholipids (phosphatidylserine (PS), phosphatidylinositol (PI) and microsomal phospholipid mixture), Cl-ATPase activity slightly recovered only with PI, while Na,K-ATPase activity partially recovered with either phospholipid. These data suggest that Cl-ATPase requires intact membrane lipid conformation and especially PI for its maximal activity.

Fourier transform infrared spectroscopic studies on gastric H+/K+-ATPase

Suspensions of membrane-bound H+/K+-ATPase in both H2O and 2H2O were investigated using Fourier transform infrared (FT-IR) spectroscopy. Second-derivative techniques were used to reveal the overlapping bands in the 1800-1500 cm-1 region. Analysis of the amide I band shows that the protein component contains substantial amounts of both alpha-helical and beta-sheet structures. Addition of 10 mM KCl to a suspension in 2H2O does not significantly affect the amide I band, indicating that the E1-E2 conformational transition of the enzyme, induced by K+, does not involve a gross change in protein secondary structure. Analysis of the amide II band in the spectra of suspensions in 2H2O shows that inhibition of the enzyme with omeprazole increases the rate of 1H-2H exchange, indicating an increase in conformational flexibility. Furthermore, an additional feature at 1628 cm-1 in the spectra of the inhibited samples in 2H2O could either support a conformational change or arise from a vibrational mode of omeprazole in its enzyme-bound form. The frequency of the band due to the symmetric stretching vibrations of the methylene groups of the lipid acyl chains increases steadily with increasing temperature indicating that there is no co-operative melting process in the lipid component of the membrane over the temperature range 9-50 degrees C. For comparison, FT-IR studies on aqueous suspensions of Na+/K+-ATPase were also carried out. These show that the protein components in the Na+/K+- and H+/K+-ATPases have similar secondary structures.

Does phospholipase C inhibit fusion between hamster sperm and zona-free eggs?

Previous studies (Hirao and Yanagimachi: Gamete Res. 1:3-12, 1978) have found that phospholipase C (PLC) preparations inhibit sperm-egg fusion. We have attempted to duplicate these results with PLC, as well as with a more specific enzyme, phosphatidylinositol-specific PLC. PLC preparations were applied externally to zona-free hamster eggs prior to incubation with sperm. Phosphatidylinositol-specific PLC did not inhibit sperm penetration. The degree of sperm-egg fusion observed after egg exposure to PLC, however, was dependent upon the purity of the commercial preparation. An impure sample of PLC inhibited sperm penetration, while a more purified preparation did not. The morphology of eggs was unaffected by exposure to phosphatidylinositol-specific PLC and the more purified PLC preparation. The impure preparation, however, was disruptive primarily to the egg plasma membrane as well as to internal organelle organization. The degree of damage by the impure PLC preparation was concentration dependent. The results suggest that as purity of the PLC preparation is increased, the adverse effects of PLC on sperm-egg fusion become negligible.

Sulphatide content in a membrane fraction isolated from rabbit gastric mucosal: its possible role in the enzyme involved in H+ pumping

The sulphatide content of vesicular membrane fraction from rabbit mucosal gastric microsomes was analyzed. This vesicular membrane fraction, in addition to a high sulphatide content, was enriched in an ouabain-insensitive (H+ + K+)-ATPase, a (Mg+2 + K+)-activated phosphatase, and a H+ pumping activity. The enzyme system involved in the process of acid secretion and the translocation of K+ was studied in these membrane preparations treated with arylsulphatase A, an enzyme that specifically hydrolyzes sulphatide. The results indicate that the breakdown of sulphatides of the vesicular membrane fraction inactivated both the (H+ + K+)-ATPase activity and the H+ pumping. Both activities were partially restored by the sole addition of sulphatide. The K+-stimulated ouabain-insensitive phosphatase activity, suggested as a partial reaction of the (H+ + K+)-ATPase sequence, was unaffected by arylsulphatase. These results suggest that sulphatides may play a function in the high activity binding site for K+ of the enzyme involved in H+ pumping.

Phospholipase C from Clostridium perfringens: preparation and characterization of homogeneous enzyme

A new procedure for the purification of phospholipase C from Clostridium perfringens has been devised that results in essentially pure enzyme. The procedure consists of ammonium sulfate fractionation, ion-exchange chromatography on QAE-Sephadex, and affinity chromatography on phosphatidylcholine linked to Sepharose. The molecular weight of the enzyme, determined by sodium dodecyl sulfate-gel electrophoresis, amino acid analysis, and gel filtration, is 43,000; and the isoelectric point is pH 5.4. The enzyme was optimally active with phosphatidylcholine dispersed in sodium deoxycholate, although appreciable activity was observed with either phosphatidylcholine or sphingomyelin dispersed with ethanol. The requirement for metal ions in the assay could be met by a number of different ions. The pure enzyme was found to contain 2 mol zinc per mol enzyme, thus implicating it as a zinc metalloenzyme.

Characterization of proton-transporting membranes from resting pig gastric mucosa

Membrane vesicles were purified from resting corpus mucosa of pig stomachs by velocity-sedimentation on a sucrose-Ficoll step gradient. Two vesicular fractions containing the (H+ + K+)-ATPase were obtained. One fraction was tight towards KCl, the other was leaky. At 21 degrees C maximal (H+ + K+)-ATPase activities of 0.8 and 0.4 mumol X mg-1 X min-1, respectively, were observed in lyophilized vesicles. The vesicles contained a membrane-associated carbonic anhydrase, the activity of which was in 100-fold excess of the maximal ATPase activity. Both vesicular fractions were rich in phosphatidylcholine, phosphatidylethanolamine, sphingomyelin and cholesterol. The characteristics of ion permeability and transport in the tight vesicles were in agreement with corresponding data for vesicles of a tubulovesicular origin in the parietal cell. Measurement of the rate of K+ uptake into the vesicles was based on the ability of K+ to promote H+ transport. The uptake was slow and dependent on the type of anion present. The effectiveness in promoting uptake of K+ by anions was SCN- greater than NO3- greater than Cl- much greater than HCO3- greater than SO4(2-). Uptake of K+ was much more rapid at alkaline pH than at neutral or at acidic pH. Addition of CO2 at alkaline pH strongly stimulated the rate of H+ accumulation in the vesicles. The initial part of this stimulation was sensitive to acetazolamide, an inhibitor of carbonic anhydrase. A model how the (H+ + K+)-ATPase and the carbonic anhydrase may co-operate is presented. It is concluded that membrane vesicles of a tubulovesicular origin can produce acid.

Inhibition of gastric (H+ + K+)-ATPase by unsaturated long-chain fatty acids

Arachidonic acid and unsaturated C18 fatty acids at concentrations near 10(-5) M markedly inhibited (H+ + K+)-ATPase in hog or rat gastric membranes. Arachidonic acid was a more potent inhibitor than unsaturated C18 fatty acids, but the involvement of the metabolites of arachidonic acid cascade was ruled out. Linolenic acid inhibited the formation of phosphoenzyme and the K+ -dependent p-nitrophenylphosphatase activity of the hog ATPase. Treatment with fatty acid-free bovine serum albumin abolished only the inhibitory effect of the fatty acid on the phosphatase activity without restoring the overall ATPase action. These data suggest the existence of at least two groups of hydrophobic binding sites in the gastric ATPase for unsaturated long-chain fatty acids which affect differentially the catalytic reactions of the ATPase. (H+ + K+)-ATPase in rat gastric membranes was found more susceptible to the fatty acid inhibition and also more unstable than the ATPase in hog gastric membranes. The presence of a millimolar level of lanthanum chloride or ethylene glycol bis(beta-aminoethyl ether)-N,N'-tetraacetic acid stabilized the rat ATPase probably via the inhibition of Ca2+ -dependent phospholipases in the gastric membranes.

Studies on (K+ + H+)-ATPase V. Chemical composition and molecular weight of the catalytic subunit

(1) A (K+ + H+)-ATPase preparation from porcine gastric mucosa is solubilized in sodium dodecyl sulfate, and is subjected to gel filtration. (2) A main subunit fraction is obtained, which is a protein carbohydrate lipid complex, containing 88% protein, 7% carbohydrate and 5% phospholipid. The Detailed composition of the protein and carbohydrate moieties are reported. (3) Sedimentation analysis of the subunit preparation, after detergent removal, reveals no heterogeneity, but the subunits readily undergo aggregation. (4) Acylation of the subunit preparation with citraconic anhydride causes a clear shift of the band obtained after SDS gel electrophoresis, but the absence of broadening and splitting of the band pleads against subunit heterogeneity. (5) Treatment of the subunit preparation with dansyl chloride indicates that the NH2 terminus is blocked, which favors the assumption of homogeneity of the protein. (6) Binding studies with concanavalin A indicate that at least 86% of the subunit preparation is composed of glycoprotein. (7) These findings, taken together, strongly suggest that there is a single subunit which is a glycoprotein and which represents the catalytic subunit of the enzyme. From sedimentation equilibrium analysis a molecular mass value of 119 kDa (S.E. 3, n = 6) is calculated for protein + carbohydrate and of 110 kDa (S.E. 3, N = 6) for protein only. (8) In combination with the molecular mass of 444 kDa (S. E. 10, n = 4) obtained for the intact enzyme by radiation inactivation we conclude that the enzyme appears to be composed of a homo-tetramer of catalytic subunits.