Induction of a chloride conductance in gastric vesicles by limited trypsin or chymotrypsin digestion or ageing.

Transport activity of the hog gastric (H+ + K+)-ATPase system was measured either as the formation of proton gradient using the dye probe acridine orange or as the formation of a proton diffusion potential using the cyanine dye 3,3'-diethyloxdicarbocyanine iodide in the presence of the protonophore tetrachlorosalicylanilide. The development of these gradients has been compared in K+ media in the presence of either Cl- or SO4-2 as the anionic species. This comparison of proton diffusion potential formation to proton gradient formation has been used to demonstrate that a Cl- conductance in this vesicular system results from limited enzymic digestion with either trypsin or alpha-chymotrypsin from the ageing process itself. The possible significance of this finding is discussed.

Identification of H+/K(+)-ATPase alpha,beta-heterodimers.

Glutaraldehyde treatment of the C12E8 solubilized H+/K(+)-ATPase crosslinks the catalytic subunit with an apparent molecular mass of 94 kDa in SDS polyacrylamide gels into two Coomassie stained particles migrating at approx. 147 and 173 kDa. The subunit composition of these particles was determined from the comparative distribution of FITC fluorescence, wheat germ agglutinin and anti-beta antibody reactivity in control and crosslinked preparations. FITC exclusively labelled the catalytic monomer of the native preparation and its fluorescence was initially distributed into two broad bands centered at approx. 147 and 173 kDa after crosslinking. These fluorescent bands coincided with the Coomassie stained particles. A glycoprotein(s) detected by wheat germ agglutinin reactivity was present in diffuse areas between 65 and 86 kDa and 95 to 134 kDa in the control preparation. This area was also labelled by the anti-beta antibodies. With crosslinking, the distribution of the wheat germ agglutinin reactive protein and anti-beta antibodies coincided with the crosslinked particles labelled by FITC. The presence of both the catalytic monomer and the beta subunit glycoprotein in the crosslinked particles indicated that these proteins were closely associated in the C12E8 solution. This suggests that the minimal structural particle of the H+/K(+)-ATPase is an alpha,beta-heterodimer.

ATP/ADP exchange activity of gastric (H+ +K+)-ATPase.

The ATP/ADP exchange is shown to be a partial reaction of the (H+ +K+)-ATPase by the absence of measurable nucleoside diphosphokinase activity and the insensitivity of the reaction to P1, P5-di(adenosine-5') pentaphosphate, a myokinase inhibitor. The exchange demonstrates an absolute requirement for Mg2+ and is optimal at an ADP/ATP ratio of 2. The high ATP concentration (K0.5=116 microM) required for maximal exchange is interpreted as evidence for the involvement of a low affinity form of nucleotide site. The ATP/ADP exchange is regarded as evidence for an ADP-sensitive form of the phosphoenzyme. In native enzyme, pre-steady state kinetics show that the formation of the phosphoenzyme is partially sensitive to ADP while modification of the enzyme by pretreatment with 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) in the absence of Mg2+ results in a steady-state phosphoenzyme population, a component of which is ADP sensitive. The ATP/ADP exchange reaction can be either stimulated or inhibited by the presence of K+ as a function of pH and Mg2+.

Ion pathways in renal brush border membranes.

The absorbance change of the weak base dye probe, Acridine orange, was used to monitor alterations of pH gradients across renal brush border membrane vesicles. The presence of Na+/H+ or Li+/H+ exchange was demonstrated by diluting Na2SO4 or Li2SO4 loaded vesicles into Na+-or Li+-free solutions, which caused dye uptake. About 20% of the uptake was abolished by lipid permeable cations such as valinomycin-K+ or tetraphenylphosphonium, indicating perhaps the presence of a finite Na+ conductance smaller than electroneutral Na+/H+ exchange. The protonophore tetrachlorosalicylanilide raised the rate of dye uptake under these conditions, hence the presence of an Na+ conductance greater than the H+ conductance was suggested. K+ gradients also induced changes of pH, at about 10% of the Na+ or Li+ rate. Partial inhibition (21%) was seen with 0.1 mM amiloride indicating that K+ was a low affinity substrate for the Na+/H+ exchange. Acceleration both by tetrachlorosalicylanilide (2-fold) and valinomycin (4-fold) suggested the presence of 2 classes of vesicles, those with high and those with low K+ conductance. The larger magnitude of the valinomycin dependent signal suggested that 75% of the vesicles has a low K+ conductance. Inward Cl- gradients also induced acidification, partially inhibited by the presence of tetraphenylphosphonium, and accelerated by tetrachlorosalicylanilide. Thus both a Cl- conductance greater than the H+ conductance and a Cl-/OH- exchange were present. The rate of Na+/H+ exchange was amiloride sensitive with a pH optimum of 6.5 and an apparent Km for Na+ or Li+ of about 10 mM and an EA of 14.3 kcal per mol. A 61-fold Na2SO4 gradient resulted in a pH gradient of 1.64 units which increased to 1.8 with gramicidin. An equivalent NaCl gradient gave a much lower delta pH even in the presence of gramicidin showing that the H+ and Cl- pathways could alter the effect of the Na+/H+ exchange.

Glutaraldehyde crosslinking analysis of the C12E8 solubilized H,K-ATPase.

A soluble porcine H,K-ATPase preparation was obtained with the nonionic detergent, C12E8. ATP hydrolysis by the soluble H,K-ATPase was stimulated with respect to the native preparation at pH 6.1, while the K(+)-phosphatase activity was comparable to the native enzyme. The soluble enzyme demonstrated characteristic ligand-dependent effects on ATP hydrolysis, including ATP activation of K(+)-stimulated hydrolysis with a K0.5 of 28 +/- 4 microM ATP, and inhibition with an IC50 of 2.1 mM ATP. The activation and inhibition of ATP hydrolysis by K+ was also observed with a K0.5 for activation of 2.8 +/- 0.4 mM KCl at 2.0 mM ATP (pH 6.1) and inhibition with an IC50 of 135 mM KCl at 0.05 mM ATP. 2-Methyl-8-(phenylmethoxy)imidazo[1,2a]pyridine-3-acetonitrile (SCH 28080), a specific inhibitor of the native H,K-ATPase, competitively inhibited the K(+)-stimulated activity with a Ki of 0.035 microM. The soluble enzyme was stable with a t0.5 for ATPase activity of 6 h between 4 and 11 degrees C. The demonstration of these related ligand responses in the catalytic reactions of the soluble preparation indicates that it is an appropriate medium for investigation of the subunit associations of the functional H,K-ATPase. Subunit associations of the active soluble enzyme were assessed following treatment with the crosslinking reagent, glutaraldehyde. The distribution of crosslinked particles was independent of the soluble protein concentration in the crosslinking buffer within the protein range 0.3 to 2.0 mg/ml or the detergent to protein ratio varied from 1 to 15 (w/w). The crosslinked pattern was unaffected by the presence or absence of K during crosslinking or nucleotide concentration. These observations suggest that crosslinking occurs in associated subunits that do not undergo rapid associations dependent upon enzyme turnover. Phosphorylation of the soluble enzyme with 0.1 mM MgATP produced a phosphoprotein at 94 kDa. A phosphoprotein obtained after glutaraldehyde treatment exhibited identical electrophoretic mobility to the crosslinked particle identified by silver stain. Glutaraldehyde treatment of soluble protein fractions resolved on a linear 10-35% glycerol gradient revealed several smaller peptides partially resolved from the crosslinked pump particle, but no active fraction enriched in the monomeric H,K-ATPase. This data indicates that the functional porcine gastric H,K-ATPase is organized as a structural dimer.

Transport characteristics of frog gastric membranes.

ATP-induced transport by fractions of frog gastric microsomes prepared either by density gradient centrifugation of by free flow electrophoresis were K+ dependent and hence considered due to a K+-activated ATPase. Significant activity of this enzyme was, however, only found in the anodic peak of the free flow electrophoretic separation, which in addition to separating transporting from non-transporting particles, also separated membranes containing a phosphorylatable peptide (Mr=105 000) region as the major peptide on SDS-polyacrylamide gel electrophoresis from those containing a peptide (Mr=44 000) on SDS-polyacrylamide gel electrophoresis. H+ uptake, measured either by acridine orange or 3,3'-diethyloxadicarbocyanine + tetrachlorosalicylanilide absorbance changes was dependent on K+ intravesicularly. Using 86Rb+, active extrusion of the cation followed ATP addition. SCN-, an inhibitor of acid secretion did not affect the latter, but blocked signals due to H+ uptake, in contrast to mammalian preparations.

SCH28080 prevents omeprazole inhibition of the gastric H+/K+-ATPase.

The interaction between SCH28080 and omeprazole, two specific inhibitors of gastric H+/K+-ATPase, was investigated using gastric glands and isolated gastric membranes. For gastric glands, inhibition of acid formation by SCH28080 was not reversed by washing whereas inhibition by omeprazole was partially reversed after washing. These features are opposite to what is found with isolated membranes. However, if gastric glands were permeabilized with digitonin after exposure to the inhibitors and recovery measured as ATP-dependent acid formation or H+/K+-ATPase activity, inhibition by SCH28080 was completely reversed while inhibition by omeprazole was non-reversible. Using a procedure of pretreatment with inhibitors followed by permeabilization and assay of recovered activity, it was found that a combined treatment with SCH28080 plus omeprazole prevented the irreversible inhibition by omeprazole, i.e. acid forming capability and ATPase activity were fully recovered. In order to test the possibility that SCH28080 prevented activation of omeprazole by dissipating an acid environment, control experiments were performed with SCN, which gave equivalent dissipation of the acid gradient but did not prevent the irreversible inhibition by omeprazole. These results were confirmed in isolated gastric membranes where residual p-nitrophenylphosphatase activity was assayed following exposure of acid transporting vesicles to omeprazole. Compared to control conditions, omeprazole inhibited 48% of the phosphatase activity whereas simultaneous addition of SCH28080 reduced the inhibition to 14%. The results therefore suggest that SCH28080 selectively blocks irreversible inhibition by omeprazole and thus that these two agents interact at a common region of the luminal aspect of the gastric H+/K+-ATPase.

Proton transport by gastric membrane vesicles.

A highly purified membrane fraction was derived from hog gastric mucosa by a combination of differential and density gradient centrifugation and free flow electrophoresis. This final fraction was 35-fold enriched with respect to cation activated ouabain-insensitive ATPase. Antibody against this fraction was shown to be bound to the luminal surface of the gastric glands. The addition of ATP to this fraction or the density gradient fraction resulted in H+ uptake into an osmotically sensitive space. The apparent Km for ATP was 1.7-10(-4) M in the absence of a K+ gradient similar to that found for ATPase activity. The reaction is specific for ATP and requires cation in the sequence K+ greater than Rb+ greater than Cs+ greater than Na+ greater than Li+ and inhibited by ATPase inhibitors such as N,N'-dicylclohexyl-carbodiimide. Maximal H+ uptake occurs with an outward K+ gradient but the minimal apparent KA is found in the absence of a K+ gradient. The pH optimum for H+ uptake is between 5.8 and 6.2 which corresponds to the pH range for phosphroylation of the enzyme, but is considerably less than the pH maximum of the K+ dependent dephosphorylation. In the presence of an inward K+ gradient, protonophores such as tetrachlorsalicylanilide only partially abolish the H+ gradient but valinomycin dissipates 75% of the gradient, and nigericin abolishes the gradient. The vesicles therefore have a low K+ conductance but a measurable H+ conductance, hence a K+ gradient can produce an H+ gradient in the presence of valinomycin. The uptake and spontaneous leak of H+ are temperature sensitive with a similar transition temperature. Ultraviolet irradiation inactivates ATPase and proton transport at the same rate, approximately at twice the rate of p-nitrophenylphosphatase inactivation. It is concluded that H+ uptake by these vesicles is probably due to a dimeric (H+ + K+)-ATPase and is probably non-electrogenic.

Effect of carbachol or histamine stimulation on rat gastric membranes enriched in (H+-K+)-ATPase.

We have examined histamine- or carbachol-induced changes in rat gastric membranes enriched in K+-stimulated ATPase. Stimulation of secretion by both secretagogues in vivo produced a class of microsomal membranes which exhibited valinomycin-independent, KCl-dependent H+ transport. In contrast, membrane vesicles isolated from cimetidine inhibited resting mucosa exhibited largely the ionophore-dependent H+ transport. In addition, only in the carbachol-stimulated membranes a portion of the ionophore-independent H+ transport was refractory to cimetidine pretreatment. The gastric microsomal membranes were resolved into light and heavy fractions by centrifugation over isotonic 2H2O media. The ionophore-independent H+ transport was almost exclusively associated with the heavy microsomal fraction while the ionophore-dependent H+ transport was detected in the light fraction. Also, these fractions were considerably different from each other in their appearance in electron micrographs and SDS gel electrophoresis patterns. Secretagogue stimulation increased the population of the heavy microsomal membrane vesicles exhibiting the valinomycin-independent, K+-dependent H+ transport and their overall content of K+-stimulated ATPase. Cimetidine treatment, on the other hand, increased the ATPase activity associated with the light microsomes, and produced the heavy microsomal membranes showing only a marginal degree of the ionophore independent H+ accumulation, even though they were very similar to the carbachol-stimulated heavy membranes in the specific activity of K+-stimulated ATPase. SDS gel patterns and appearance in electron micrograph. These observations suggest that activation of secretion involves at least two distinctive events; transformation of the light to the heavy gastric membranes containing a K+-dependent H+ pump and an increased KCl permeability in the latter.

The interaction of K+ with gastric parietal cells and gastric ATPase.

The gastric H+ secretion in isolated cell requires K+ and is ATP dependent. There is also evidence in the cell system for Na+ inhibition of H+ secretion. The isolated gastric ATPase also shows K+ activation and inhibition by K+ or Na+ located on the ATP binding side of the enzyme, which corresponds to the cytoplasmic face of the enzyme. Gastric vesicles are activated in terms of transport activity by internal K+, and this site, inhibited by reagents that modify carboxyl groups, is required for enzyme turnover and transport.

Aspects of parietal cell biology: cells and vesicles.

Many features of these gastric vesicles satisfy the requirements for the gastric H+ pump. For example, we have: (a) K+ requirement, (b) KA for K+ of about 30 mM; (c) identical cation sequence for tissue and vesicles, (d) similar anion sequence, (e) localization at the microvillus of the secretory canaliculus, (f) TI+ inhibiting H+ transport of both systems, and (g) the K+ gradient satisfying the osmotic gradient requirement for HCl-flow out of the parietal cell. Points that require explanation are lack of SCN- effects and regulation of KCl permeability.

Thallium interaction with the gastric (K, H)-ATPase.

The gastric (K, H)-ATPase has been shown to catalyze an electroneutral H+ for K+ exchange. Tl+ is able to substitute for K+ as an activating cation in the hydrolytic reaction with an apparent dissociation constant of 90 microM as compared to about 870 microM for K+. The ability of Tl+ to participate in transport is shown by the development of pH gradients in the presence of Tl+ following addition of ATP to gastric vesicles and by the ATP-dependent efflux of Tl+ from gastric vesicles. Inhibition of hydrolysis is observed at pH 7.4 with external Tl+ concentrations above 3.0 mM. This inhibition of hydrolysis is correlated with inhibition of pH-gradient formation. The inhibition of transport activity is partially relieved by a decrease in medium pH. This inhibitory effect is attributed to Tl+ binding at an external, low affinity cation site. In contrast to rubidium chloride, at high Tl+ concentrations, following the initial Tl+ efflux, there is reuptake of the cation. This rapid uptake is attributed to lipid-dependent Tl+ entry pathways. The vesicles exhibit a high permeability to thallium nitrate demonstrating a half-time (t1/2) for uptake of about 1.0 min in contrast to 46 min for rubidium chloride. In both gastric vesicles or liposomes, external Tl+ concentrations in excess of 1 to 4 mM are able to dissipate intravesicular proton gradients. Thus, although Tl+ is able to activate the gastric ATPase by mimicking K+, the permeability of this cation in lipid bilayers tends to uncouple H+ transport at concentrations high enough to generate detectable proton gradients.

Quantitation of hydrogen ion and potential gradients in gastric plasma membrane vesicles.

The ATP-dependent uptake of H+ by hog gastric parietal cell vesicles was quantitated by using the pH indicator dyes bromcresol green and malachite green, the weak bases, aminopyrine and 9-aminoacridine, and the pH electrode. A K+-dependent H+ uptake was found, with a significant difference between the quantity of H+ disappearing from the medium (deltaHo) and the quantity appearing inside the vesicle (deltaHi). 9-Aminoacridine gave a lower value for the deltaHi than any of the other probes. Probes of potential such as diethyloxadicarbocyanine or oxonol dyes showed that only secondary diffusion potentials occurred during H+ uptake and that the cationic dyes in the presence of protonophores could also be used to quantitate H+ uptake. The potential in the presence of protonophore indicated a deltaHi greater than that found with the other probes. Binding sites for acridine orange were generated either by ATP or an artificial pH gradient and corresponded to the deltaHi indicated by aminopyrine. SCN- (30mM) only partially inhibited the H+ gradient, and this, coupled with the failure to detect the physiological deltapH of 6.6, indicated that these vesicles may be an incomplete model of gastric acid secretion.