Control of the potassium ion-stimulated adenosine triphosphatase of pig gastric microsomes: effects of lipid environment and the endogenous activator

General and specific interactions of the phospholipid bilayer with P-type ATPases

Protein structure and function are modulated via interactions with their environment, representing both the surrounding aqueous media and lipid membranes that have an active role in shaping the structural topology of membrane proteins. Compared to a decade ago, there is now an abundance of crystal structural data on membrane proteins, which together with their functional studies have enhanced our understanding of the salient features of lipid-protein interactions. It is now important to recognize that membrane proteins are regulated by both (1) general lipid-protein interactions, where the general physicochemical properties of the lipid environment affect the conformational flexibility of a membrane protein, and (2) by specific lipid-protein interactions, where lipid molecules directly interact via chemical interactions with specific lipid-binding sites located on the protein. However, due to local differences in membrane composition, thickness, and lipid packing, local membrane physical properties and hence the associated lipid-protein interactions also differ due to membrane location, even for the same protein. Such a phenomenon has been shown to be true for one family of integral membrane ion pumps, the P2-type adenosine triphosphatases (ATPases). Despite being highly homologous, individual members of this family have distinct structural and functional activity and are an excellent candidate to highlight how the local membrane physical properties and specific lipid-protein interactions play a vital role in facilitating the structural rearrangements of these proteins necessary for their activity. Hence in this review, we focus on both the general and specific lipid-protein interactions and will mostly discuss the structure-function relationships of the following P2-type ATPases, Na⁺,K⁺-ATPase (NKA), gastric H⁺,K⁺-ATPase (HKA), and sarco(endo)plasmic reticulum Ca²⁺-ATPase (SERCA), in concurrence with their lipid environment.

The parietal cell gastric H, K-ATPase also functions as the Na, K-ATPase and Ca-ATPase in altered states

This article offers an explanation for the apparent lack of Na, K-ATPase activity in parietal cells although ouabain has been known to inhibit gastric acid secretion since 1962. The gastric H, K-ATPase (proton-pump) seems to be acting in altered states, thus behaving like a Na, K-ATPase (Na-pump) and/or Ca-ATPase (Ca-pump) depending on cellular needs.  This conclusion is based on the following findings. First, parietal cell fractions do not exhibit Na, K-ATPase activity at pH 7.0 but do at pH 8.5. Second, the apical plasma membrane (APM) fraction exhibits a (Ca or Mg)-ATPase activity with negligible H, K-ATPase activity. However, when assayed with Mg alone in presence of the 80 k Da cytosolic proton-pump activator (HAF), the APM fraction reveals remarkably high H, K-ATPase activity, suggesting the observed low affinity of Ca (or Mg)-ATPase is an altered state of the latter. Third, calcium (between 1 and 4 µM) shows both stimulation and inhibition of the HAF-stimulated H, K-ATPase depending on its concentration, revealing a close interaction between the  proton-pump activator and local Ca concentration in gastric H, K-ATPase function. Such interactions suggest that Ca is acting as a terminal member of the intracellular signaling system for the HAF-regulated proton-pump. It appears that during resting state, the HAF-associated H, K-ATPase remains inhibited by Ca (>1 µM) and, prior to resumption of acid secretion the gastric H, K-ATPase acts temporarily as a Ca-pump for removing excess Ca from its immediate environment. This conclusion is consistent with the recent reports of immunochemical co-localization of the gastric H, K-ATPase and Ca-ATPase by superimposition in parietal cells, and a transitory efflux of Ca immediately preceding the onset of acid secretion. These new perspectives on proton-pump function would open new avenues for a fuller understanding of the intracellular regulation of the ubiquitous Na-pump.

The cholecystokinin-induced Ca2+ shuttle from the inositol trisphosphate-sensitive and ATP-dependent pool, and initial pepsinogen release connected with cytoskeleton of the chief cell

In guinea pig chief cells, inositol 1,4,5-trisphosphate (IP3) caused release of Ca2+, which was accumulated by ATP, from an endoplasmic reticulum-enriched fraction in both the permeable system and the cell-free system. This was mimicked with the Ca2+ ionophores A23187 and ionomycin on a large scale since an IP3-sensitive Ca2+ pool might be a subset of the Ca2+ ionophore-sensitive Ca2+ pool. The permeable chief cells, but not the cell-free system, retained the ability to react to synthetic cholecystokinin octapeptide (CCK-OP) with Ca2+ release from an IP3-sensitive pool due to of the non-additive but constant effect in exerting Ca2+ release from the store(s) induced by the combination with IP3 and CCK-OP. The increase in the cytosolic free Ca2+ concentration of intact chief cells responding to CCK-OP or the Ca2+ ionophore, ionomycin, comprised two components, namely, that by the Ca2+ entry from the extracellular space, and that by the Ca2+ release from the intracellular space(s) (as measured by fura-2). When CCK-OP or ionomycin was added, there was a biphasic response of pepsinogen secretion. An initial but transient response reaching a peak in 5 min was followed by a sustained response reaching a peak in 30 min. The initial pepsinogen release was independent of medium Ca2+, whereas the sustained one was dependent on medium Ca2+. The results suggest that the intracellular Ca2+ release from the store(s), presumably endoplasmic reticulum, may trigger the initial pepsinogen release, whereas the sustained pepsinogen secretion may be caused by acting in concert with the initial response and external Ca2+ entry. On the other hand, the disruption of the microtubular-microfilamentous system by colchicine or cytochalasin D failed to cause the Ca2+ release evoked by either IP3, CCK-OP or Ca2+ ionophores and to cause the CCK-OP- or ionomycin-induced initial pepsinogen release. These findings suggest that the IP3-sensitive pool is the same Ca2+ store which is completely or partially sensitive to CCK-OP and Ca2+ ionophores, respectively, and that the assembly of the cytoskeletal system is involved in initial intracellular Ca2+ metabolism and the following initial pepsinogen release. The assembly of the cytoskeletal system may be an early event in mediating the CCK-OP-induced initial pepsinogen release, perhaps by causing the Ca2+ release from an IP3-sensitive pool of the chief cell. The translocation or attachment of the IP3-sensitive pool brought about by cytoskeletal system might be necessary to cause Ca2+ release after the cell stimulation with CCK-OP.

Modulation of membrane protein function by bilayer lipids

In many instances, the composition of fatty acyl groups of membrane phospholipids can be modified to achieve a range of fatty acyl unsaturation without any detectable change in bulk membrane fluidity. At the same time, the function of membrane proteins may be considerably altered, raising questions concerning the property of the lipids that brings about this altered protein function. There is some evidence that the lipids may be laterally distributed in a heterogeneous manner throughout the membrane, and changes in this distribution could be responsible for the effects on proteins. There is also increasing evidence for specific interactions between individual molecular species and membrane proteins that may also modulate membrane protein function.

Purification and characterization of a cytosolic activator protein for the gastric H+,K+-ATPase system from dog fundic mucosa

An endogenous protein activator (AF) responsible for the activation of the gastric H+,K+-ATPase system, identified recently as the biochemical mechanism for the transport of H+, has been purified to homogeneity and partially characterized. The purification procedure (at 0-4 degrees C) involves simultaneous concentration and dialysis of the cytosolic fraction from dog fundic cells under negative pressure, pH 4.8 precipitation and two consecutive gel filtration steps on sephacryl S-200 columns. The highly purified and active AF is a protein of 80 Kd consisting of two identical subunits of 40 Kd each. The AF not only stimulates the gastric H+,K+-ATPase activity but also greatly enhances the rate of ATPase dependent proton pumping inside gastric microsomal vesicles. The data clearly suggest an important regulatory role of the cytosolic AF in the gastric HCl secretory process.

Regulation of the gastric microsomal (H+ + K+)-transporting ATPase system by the endogenous activator. Effect of phospholipase A2 treatment

Pig gastric microsomal (H+ + K+)-stimulated ATPase activity was nearly abolished within 10 min of digestion with phospholipase A2 at room temperature. The enzyme activity could be largely restored by a cytosolic activator protein partially purified from the gastric cells. The K+ sensitivity and turnover of 32P-labelled intermediates produced by the control and the activator-reconstituted microsomal (H+ + K+)-stimulated ATPase were closely similar but were widely different to those from treated membranes without activator reconstitution. The data suggest an essential requirement for the endogenous activator for gastric (H+ + K+)-stimulated ATPase function.

Regulation of three key enzymes in cholesterol metabolism by phosphorylation/dephosphorylation

Our laboratories have investigated the role of phosphorylation/dephosphorylation in the regulation of three key enzymes in cholesterol metabolism. 3-Hydroxy-3-methylglutarylcoenzyme A (HMG-CoA) reductase (EC 1.1.1.34), the major regulatory enzyme in cholesterol biosynthesis, is inhibited by phosphorylation. Acyl-CoA:cholesterol O-acyltransferase (ACATase; EC 2.3.1.26) and cholesterol 7 alpha-hydroxylase (EC 1.14.13.7), key regulatory enzymes in the utilization of cholesterol, are activated by phosphorylation. In view of these results, we propose that short-term regulation of the concentration of intracellular unesterified cholesterol is achieved by a coordinate phosphorylation/dephosphorylation of these three enzymes. For example, if cholesterol enters the liver cell, HMG-CoA reductase would be inhibited by phosphorylation and biosynthesis of cholesterol would be reduced; however, reactions utilizing cholesterol would be activated, due to the phosphorylation of ACATase and cholesterol 7 alpha-hydroxylase. Thus, the phosphorylation/dephosphorylation of these three enzymes provides an elegant short-term mechanism for the homeostasis of intracellular unesterified cholesterol.

Role of cholesterol in the structure and function of gastric microsomal vesicles

Digitonin was used as a tool to investigate the organization and function of cholesterol in gastric microsomes. Microsomal vesicles were treated with digitonin for different time at 0-4 degrees C under isotonic conditions. The effects of digitonin treatment of the vesicles on removal of cholesterol, ultrastructural changes, (H+ + K+)-ATPase activity, and gastric ATPase-dependent H+ uptake ability were investigated. Microsomal cholesterol was extracted in an exponential manner with a t1/2 of 32 min. There was no release of microsomal phospholipids by digitonin treatment during the same period. Digitonin treatment (30 min) produced visible "holes" in the vesicles; at the same time (H+ + K+)-ATPase-dependent H+ uptake was abolished. Under the same conditions the K+-stimulated ATPase activity, however, was moderately (about 35%) reduced, although the response of K+ stimulation to valinomycin was obliterated. Longer digitonin treatment resulted in gradual diffusion and eventual disappearance of the "holes" with the generation of distorted cup-shaped microsomes. The data strongly suggest that membrane lipids are freely mobile and that there is a certain degree of specialization in the organization of gastric microsomal cholesterol for the proper maintenance of the membrane structure and function.

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. IV. Effects of phospholipase C treatment

(1) The total phospholipid content of a gradient purified (K+ + H+)-ATPase preparation from pig gastric mucosa is 105 mumol per 100 mg protein, and consists of 29% sphingomyelin, 29% phosphatidylcholine, 28% phosphatidylethanolamine, 10% phosphatidylserine and 4% phosphatidylinositol. The cholesterol content corresponds to 50 mumol per 100 mg protein. (2) Treatment with phospholipase C (from Clostridium welchii and Bacillus cereus) results in an immediate decrease of the phosphate content. Up to 50% of the phospholipids are hydrolyzed by each phospholipase C preparation alone, without further hydrolysis by increased phospholipase concentration or prolonged incubation time. Combined treatment with the two phospholipase C preparations, sequentially or simultaneously, hydrolyzes up to 65% of the phospholipids. (3) The (K+ + H+)-ATPase and K+ stimulated p-nitrophenylphosphatase activities are decreased proportionally with the total phospholipid content, indicating that these enzyme activities are dependent on phospholipids. (4) Phospholipase C treatment does not change optimal pH, Km value for ATP and temperature dependence of the gastric (K+ + H+)-ATPase, but slightly decreases the Ka value for K+. (5) Phospholipase C treatment lowers the AdoPP[NH]P binding and phosphorylation capacities, suggesting that inactivation occurs primarily on the substrate binding level. (6) Most of the results can be understood by assuming that hydrolysis of the phospholipids by phospholipase C leads to aggregation of the membrane protein molecules and complete inactivation of the aggregated ATPase molecules.

Studies of gastric Ca2+-stimulated adenosine triphosphatase. I. characterization and general properties

Gastric microsomes do not contain any significant Ca2+-stimulated ATPase activity. Trypsinization of pig gastric microsomes in presence of ATP results in significant (2-3 fold) increase in the basal (with Mg2+ as the only cation) ATPase activity, with virtual elimination of the K+-stimulated component. Such treatment causes unmasking of latent Mg2+-dependent Ca2+-stimulation ATPase. Other divalent cations such as Sr2+, Ba2+, Zn2+, and Mn2+ were found ineffective as a substitute for Ca2+. Moreover, those divalent cations acted as inhibitors of the Ca2+-stimulated ATPase activity. The pH optimum of the enzyme is around 6.8. The enzyme has a Km of 70 microM for ATP and the Ka values for Mg2+ and Ca2+ are about 4 x 10(-4) and 10(-7) M, respectively. Studies with inhibitors suggest the involvement of sulfhydryl and primary amino groups in the operation of the enzyme. Possible roles of the enzyme in gastric H+ transport have been discussed.

Characterization of gastric-mucosal membranes. Distribution of lipid- and protein-associated amino groups across pig gastric microsomes

Two NH2-reactive probes (2,4,6-trinitrobenzesulphonic acid and 1-fluoro-2,4-dinitrobenzene) were used to study the vectorial orientation of the membrane-associated free NH2 groups across pig gastric microsomal vesicles. Unlike 1-fluoro-2,4-dinitrobenzene, 2,4,6-trinitrobenzenesulphonic acid is ordinarily an impermeant probe that becomes permeant in the presence of K+ and valinomycin. Although 2,4,6-trinitrobenzenesulphonic acid alone reacts with about 28% of the total microsomal phosphatidylethanolamine, 2,4,6-trinitrobenzenesulphonic acid in the presence of valinomycin plus K+ or 1-fluoro-2,4-dinitrobenzene alone reacted with 75% of the phosphatidyl- ethanolamine. Under similar conditions the free NH2 groups associated with the microsomal proteins also exhibited an asymmetric labeling pattern, the intra- and extravesicular orientation being 74 and 26% respectively.