The ontogeny of rat gastric H+/K+-ATPase

The ontogeny of rat H+/K+-ATPase was studied between foetal day 18 and neonatal day 18, using a specific monoclonal antibody (95-111 mAb). The H+/K+-ATPase content of gastric subcellular membranes was assayed and the ATPase subunits were characterized by Western blot. The epithelium density in parietal cells was measured by immunohistochemistry. H+/K+-ATPase was present in the 18-day-old foetuses and parietal cells were detected on foetal day 19. The H+/K+-ATPase concentration remained stable from foetal day 18 to neonatal day 1, while the parietal cell density increased 2.5-fold. The H+/K+-ATPase concentration increased by 2.5-fold on day 6, then remained constant up to day 18. The parietal cell density remained unchanged during this period, suggesting that the concentration increase on day 6 was due to an increase in parietal cell ATPase content. The 95-111 mAb recognized a 95 kDa single band on foetal day 18 and a doublet at all the other stages of development. Previous studies had demonstrated that acid secretion drops critically at day 12 post partum in the rat and that H+/K+-ATPase activity is lost. The present study demonstrates that the H+/K+-ATPase is, however, present on day 12.     

High-pressure freezing of isolated gastric glands provides new insight into the fine structure and subcellular localization of H+/K+-ATPase in gastric parietal cells.

High-pressure freezing (HPF) is currently the most reliable method to obtain an adequately frozen sample for high-resolution morphological evaluation. Here we applied the HPF technique to isolated rabbit gastric glands to reveal structural evidence that may be correlated with functional activity of gastric parietal cells. This approach provided well-preserved fine structure and excellent antigenicity of several parietal cell proteins. Microtubules were abundant in the cytoplasm and frequently appeared to be associating with tubulovesicles. Interestingly, many electron-dense coated vesicles were apparent around the intracellular canaliculi (IC) of resting parietal cells, consistent with active membrane retrieval from the apical membranes. Immunolabeling of H+/K+-ATPase was evident on the endocytic components (e.g., multivesicular bodies) and tubulovesicles. After histamine stimulation, the parietal cells characteristically showed expanded IC membranes with varied features of their apical microvilli. The labeling density of H+/K+-ATPase was four-fold higher on the IC membrane of stimulated parietal cells than on that of resting parietal cells. Immunolabeling of ezrin was clearly identified on the IC and basolateral membranes of parietal cells, corresponding to their F-actin-rich sites. The present findings provide a new insight into the correlation of cell structure and function in gastric parietal cells.     

Acid secretion-associated translocation of KCNJ15 in gastric parietal cells

Potassium ions are required for gastric acid secretion. Several potassium channels have been implicated in providing K(+) at the apical membrane of parietal cells. In examining the mRNA expression levels between gastric mucosa and liver tissue, KCNJ15 stood out as the most highly specific K(+) channel in the gastric mucosa. Western blot analysis confirmed that KCNJ15 is abundant in the stomach. Immunofluorescence staining of isolated gastric glands indicated that KCNJ15 was expressed in parietal cells and chief cells, but not in mucous neck cells. In resting parietal cells, KCNJ15 was mainly found in puncta throughout the cytoplasm but was distinct from H(+)-K(+)-ATPase. Upon stimulation, KCNJ15 and H(+)-K(+)-ATPase become colocalized on the apical membranes, as suggested by immunofluorescence staining. Western blot analysis of the resting and the stimulated membrane fractions confirmed this observation. From nonsecreting preparations, KCNJ15-containing vesicles sedimented after a 4-h centrifugation at 100,000 g, but not after a 30-min spin, which did sediment most of the H(+)-K(+)-ATPase-containing tubulovesicles. Most of the KCNJ15 containing small vesicle population was depleted upon stimulation of parietal cells, as indicated by the fact that the KCNJ15 signal was shifted to a large membrane fraction that sedimented at 4,000 g. Our results demonstrate that, in nonsecreting parietal cells, KCNJ15 is stored in vesicles distinct from the H(+)-K(+)-ATPase-enriched tubulovesicles. Furthermore, upon stimulation, KCNJ15 and H(+)-K(+)-ATPase both translocate to the apical membrane for active acid secretion. Thus KCNJ15 can be added to the family of apical K(+) channels in gastric parietal cells.     

Redistribution and characterization of (H+ + K+)-ATPase membranes from resting and stimulated gastric parietal cells.

When isolated from resting parietal cells, the majority of the (H+ + K+)-ATPase activity was recovered in the microsomal fraction. These microsomal vesicles demonstrated a low K+ permeability, such that the addition of valinomycin resulted in marked stimulation of (H+ + K+)-ATPase activity, and proton accumulation. When isolated from stimulated parietal cells, the (H+ + K+)-ATPase was redistributed to larger, denser vesicles: stimulation-associated (s.a.) vesicles. S.a. vesicles showed an increased K+ permeability, such that maximal (H+ + K+)-ATPase and proton accumulation activities were observed in low K+ concentrations and no enhancement of activities occurred on the addition of valinomycin. The change in subcellular distribution of (H+ + K+)-ATPase correlated with morphological changes observed with stimulation of parietal cells, the microsomes and s.a. vesicles derived from the intracellular tubulovesicles and the apical plasma membrane, respectively. Total (H+ + K+)-ATPase activity recoverable from stimulated gastric mucosa was 64% of that from resting tissue. Therefore, we tested for latent activity in s.a. vesicles. Permeabilization of s.a. vesicles with octyl glucoside increased (H+ + K+)-ATPase activity by greater than 2-fold. Latent (H+ + K+)-ATPase activity was resistant to highly tryptic conditions (which inactivated all activity in gastric microsomes). About 20% of the non-latent (H+ + K+)-ATPase activity was also resistant to trypsin digestion. We interpret these results as indicating that, of the s.a. vesicles, approx. 55% have a right-side-out orientation and are impermeable to ATP, 10% right-side-out and permeable to ATP, and 35% have an inside-out orientation.     

Potassium-stimulated ATPase activity and hydrogen transport in gastric microsomal vesicles.

The Mg2+-dependent, K+-stimulated ATPase of microsomes from pig gastric mucosa has been studied in relation to observed active H+ transport into vesicular space. Uptake of fluorescent dyes (acridine orange and 9-aminoacridine) was used to monitor the generated pH gradient. Freeze-fracture electron microscopy showed that the vesicular gastric microsomes have an asymmetric distribution of intramembraneous particles (P-face was particulate; E-face was relatively smooth. Valinomycin stimulated both dye uptake and K+-ATPase (valinomycin-stimulated K+-ATPase); stimulation by valinomycin was due to increased K+ entry to some intravesicular activating site, which in turn depends upon the accompanying anion. Using the valinomycin-stimulated K+-ATPase and H+ accumulation as an index, the sequence for anion permeation was NO-3 greater than Br- greater than Cl- greater than I- greater than acetate approximately isethionate. When permeability to both K+ and H+ was increased (e.g using valinomycin plus a protonophore or nigericin), stimulation of K+-ATPase was much less dependent on the anion and the observed dissipation of the vesicular pH gradient was consistent with an 'uncoupling' of ATP hydrolysis from H+ accumulation. Thiocyanate interacts with valinomycin inhibiting the typical action of the K+ ionophore. But stimulation of ATPase activity was seen by adding 10 mM SCN- to membranes preincubated with valinomycin. From the relative activation of the valinomycin-stimulated K+-ATPase, it appears that SCN- is a very permeant anion which can be placed before NO-3 in the sequence of permeation. Valinomycin-stimulated ATPase and H+ uptake showed similar dependent correlations, including: dependence on [ATP] and [K+], pH optima, temperature activation, and selective inhibition by SH- or NH2-group reagents. These results are consistent with a pump-leak model for the gastric microsomal K+-ATPase which was simulated using Nernst-Planck conditions for passive pathways and simple kinetics for the pump. The pump is a K+/H+ exchange pump requiring K+ at an internal site. Rate of K+ entry would depend on permeability to K+ as well as the counterion, either (1) the anion to accompany K+ or (2) the H+ efflux path as an exchange ion. The former leads to net accumulation of H+ and anion, while the latter results in non-productive stimulation of ATP hydrolysis.     

The relationship between gastric acid secretion and gastric H+,K+-ATPase activity

The H+,K+-ATPase has been postulated to be the enzyme responsible for H+ secretion by the parietal cell. Omeprazole has been shown to be an inhibitor of acid secretion in vivo, but also in in vitro test models for acid secretion, including partly purified H+,K+-ATPase, the inhibitory action of omeprazole has been demonstrated (Wallmark, B., Jaresten, B. M., Larsson, H., Ryberg, B., Br?ndstr?m, A., and Fellenius, E. (1983) Am. J. Physiol. 245, G64-G71). It was thus possible to use this compound to demonstrate a correlation between H+,K+-ATPase activity in rat oxyntic mucosa and in vivo H+ secretion. Two results were found. (a) Increasing oral doses of omeprazole progressively inhibited acid secretion, H+,K+-ATPase activity, and phosphoenzyme formation of a microsomal fraction isolated from the inhibited rat mucosa. Furthermore, a Mg2+-stimulated ATPase activity, associated with the H+,K+-ATPase membrane fraction, was not affected by the omeprazole treatment. (b) Recovery of H+,K+-ATPase activity following complete omeprazole inhibition was correlated with the appearance of acid secretion. The results indicate a strict relationship between the activity of the gastric H+,K+-ATPase in the microsomal fraction and gastric acid secretion.     

The membrane-recruitment-and-recycling hypothesis of gastric HCl secretion

In the unstimulated oxyntic (or parietal) cell, the primary pump for gastric HCl secretion, the H+/K+-ATPase, is retained within the cytoplasm in a membranous compartment of tubulovesicles. Neural or hormonal stimulation of acid secretion induces extensive membrane transformations consistent with a fusion and recruitment of tubulovesicles to the apical plasma membrane. The consequent placement of H+/K+-ATPase in parallel with K(+) and Cl(-) channels provides the necessary ionic flow and ATP-driven exchange for net HCl secretion. Current evidence is consistent with a recruitment and recycling of membrane transporters, such as H+/K+-ATPase, through docking/fusion machinery analogous to that in many other systems.     

Characterization of gastric mucosal membranes. X. Immunological studies of gastric (H+ + K+)-ATPase

Gastric mucosal homogenates from hog were fractionated by differential and density gradient centrifugation and free-flow electrophoresis. The two major membrane fractions (FI and FII) thus obtained are distinct both enzymically and in terms of transport reactivity. This heterogenicity extends to their antigenic activity. Purified antibodies which were raised against the K+-ATPase-containing H+ transport fraction FI were of two types: inhibitory and non-inhibitory. Inhibitory antibodies reduced the K+-ATPase activity by approximately 80% and the K+-p-nitro-phenylphosphatase activity by approximately 40% in a concentration-dependent manner, while the small Mg++-dependent component of the enzyme activity was unaffected. Antibodies inhibiting the K+-ATPase also inhibited H+ transport. These antibodies did not cross-react with the other major membrane fraction isolated by free- flow electrophoresis, FII, and gave a single band on rocket immunoelectrophoresis. Antibodies against this FII fraction also did not react with the K+-ATPase and were heterogeneous, giving at least four bands with rocket immunoelectrophoresis and inhibiting both the 5'- nucleotidase and Mg++-ATPase of this fraction. Immunofluorescent staining of tissue sections showed that the FI was derived from the parietal cell of gastric tissue and was localized to the supranuclear area of the cell. Staining of isolated rat gastric cell suspensions by FI antibodies confirmed the selectivity of the antibody and showed a polar, plasma membrane localization. FII antibodies also largely stained the parietal cells in tissue sections. In the 16 hog tissues tested, FI antibodies cross-reacted only with gastric fundus, thyroid and weakly with thymus. Immunoelectronmicroscopy showed that FI antibodies reacted strongly with the secretory membrane at the apical cell surface of the parietal cells and at the secretory canaliculi, weakly with the apical surface of the zymogen cell, and not with the basal-lateral surface of the cells. Thus, the protontranslocating ATPase is localized in the parietal cells and in the region postulated to be the site of acid secretion.     

Localization of ClC-2 Cl- channels in rabbit gastric mucosa

HCl secretion across the parietal cell apical secretory membrane involves the H+-K+-ATPase, the ClC-2 Cl- channel, and a K+ channel. In the present study, the cellular and subcellular distribution of ClC-2 mRNA and protein was determined in the rabbit gastric mucosa and in isolated gastric glands. ClC-2 mRNA was localized to parietal cells by in situ hybridization and by direct in situ RT-PCR. By immunoperoxidase microscopy, ClC-2 protein was concentrated in parietal cells. Immunofluorescent confocal microscopy suggested that the ClC-2 was localized to the secretory canalicular membrane of stimulated parietal cells and to intracellular structures of resting parietal cells. Immunogold electron microscopy confirmed that ClC-2 is in the secretory canalicular membrane of stimulated cells and in tubulovesicles of resting parietal cells. These findings, together with previous functional characterization of the native and recombinant channel, strongly indicate that ClC-2 is the Cl- channel, which together with the H+-K+-ATPase and a K+ channel, results in HCl secretion across the parietal cell secretory membrane.     

Changes in the membrane environment of the (K+ + H+)-ATPase following stimulation of the gastric oxyntic cell

Biochemical evidence is presented for changes in the membrane environment of the (K+ + H+)-dependent ATPase enzyme of the oxyntic cell following in vivo gastric stimulation of young New Zealand rabbits. The changes are inferred from the marked differences in the sedimentation properties of the (K+ + H+)-ATPase when obtained from homogenates of either stimulated or nonstimulated (resting) fundic gastric epithelium. Stimulation resulted in a redistribution of K+-ATPase activity that was reduced to less than half in the microsomal pellet and concomitantly increased in the membrane fractions normally associated with nuclei and mitochondria. Density gradient fractionation of the mitochondrial pellet yield a preparation rich in (K+ + H+)-ATPase. Our studies indicated that the membranes in this preparation are far larger and apparently denser than the microsomal vesicles associated with the nonstimulated state of the cell. The specific nature of the relationship between stimulation and the observed changes is suggested by the lack of change in the distribution of enzymatic activities unrelated to the apical pole of the oxyntic cell. Preliminary, tentative information aimed at identifying the processes responsible for the observed changes is presented.     

Effects of phenothiazines on acid secretion in the toad gastric mucosa

The effect of phenothiazine antipsychotic drugs on acid secretion was investigated in the isolated toad gastric mucosa. The acid secretory responses induced by maximal doses of histamine, carbachol and theophylline were all inhibited in a similar fashion by chlorpromazine. The ID50 was between 300 and 600 microM. Histamine-stimulated H+ secretion was also inhibited by trifluoperazine. Soluble cyclic AMP-dependent protein kinase activity was not significantly affected by 300 microM chlorpromazine. Microsomal (H+ + K+)-ATPase activity was significantly reduced by chlorpromazine. The results indicate that phenothiazines can inhibit acid secretion in the toad gastric mucosa and that inhibition of the gastric (H+ + K+)-ATPase may be involved in the mechanism of action.     

Location of the carbohydrates present in the HK-ATPase vesicles isolated from hog gastric mucosa

The glycosylation of H+K(+)-ATPase vesicles isolated from hog gastric mucosa was investigated by various methods. Following protein separation on sodium dodecyl sulfate reducing gels and transfer to poly(vinyl difluoride) membranes, binding of concanavalin A was confined to the 94-kDa band which corresponds to the catalytic subunit. In contrast, wheat germ agglutinin binding occurred in a region below the 94-kDa subunit, corresponding to the 60-85-kDa region, and also to protein just above the catalytic subunit. Treatment with glycopeptidase F removed most of the concanavalin A staining and also the wheat germ agglutinin staining found below the 94-kDa region, but spared the higher molecular weight wheat germ agglutinin reactive material. During the deglycosylation experiments a protein of 35-kDa was produced. Sequencing analysis of V8 protease generated peptide fragments of the 35-kDa protein show at least 30% homology with the Na+K(+)-ATPase beta-subunits. Labeling of the carbohydrates by galactosyltransferase and [3H]uridine diphosphate-galactose showed that the sites of labeling were extracellular and were confined to the wheat germ agglutinin staining regions. Two molecular weight regions, below the 94-kDa region, of 60 and 85 kDa were identified. Electron microscopy using postembedding staining techniques showed that both concanavalin A and wheat germ agglutinin staining occurred on the extracellular face of the gastric vesicles.(ABSTRACT TRUNCATED AT 250 WORDS)     

Acid secretagogue-induced stimulation of gastric parietal cell gene expression

Carbamoylcholine (carbachol), histamine, and gastrin are three principal stimulants of gastric acid secretion. To explore the mechanisms by which these agents exert their actions in parietal cells, we examined their effects on the gene expression of the enzymes responsible for H+ generation. Each secretagogue induced rapid and coordinate increases in steady-state levels of mRNAs encoding carbonic anhydrase II and H+,K+-ATPase in isolated canine gastric parietal cells. Furthermore, pronounced increases, with different kinetics, in expression of beta-actin mRNA were observed. With increasing time after cell isolation, carbonic anhydrase II and H+,K+-ATPase, but not beta-actin, mRNA levels were attenuated, suggesting that parietal cell-specific genes may be dependent upon maintenance of parietal cell contacts within intact mucosal tissue. Pretreatment of the cells with competitive inhibitors of each secretagogue blocked the increases. Our results indicate that acid secretagogue-specific receptor activation in parietal cells triggers coordinate gene expression of the two enzymes involved in H+ ion generation and that beta-actin may be an important regulator of acid secretion.     

Studies on K+ permeability of rat gastric microsomes

A population of gastric membrane vesicles of high K+ permeability and of lower density than endoplasmic tubulovesicles containing (H+-K+)-ATPase was detected in gastric mucosal microsomes from the rat fasted overnight. The K+-transport activity as measured with 86RbCl uptake had a Km for Rb+ of 0.58 +/- 0.11 mM and a Vmax of 13.7 +/- 1.9 nmol/min X mg of protein. The 86Rb uptake was reduced by 40% upon substituting Cl- with SO2-4 and inhibited noncompetitively by ATP and vanadate with a Ki of 3 and 30 microM, respectively; vanadate also inhibited rat gastric (H+-K+)-ATPase but with a Ki of 0.03 microM. Carbachol or histamine stimulation decreased the population of the K+-permeable light membrane vesicles, at the same time increased K+-transport activity in the heavy, presumably apical membranes of gastric parietal cells, and enabled the heavy microsomes to accumulate H+ ions in the presence of ATP and KCl without valinomycin. The secretagogue-induced shift of K+ permeability was blocked by cimetidine, a H2-receptor antagonist. Four characteristics of the K+ permeability as measured with 86RbCl were common in the resting light and the carbachol-stimulated heavy microsomes; (a) Km for +Rb, (b) anion sensitivity (Cl- greater than SO2-4), (c) potency of various divalent cations (Hg2+, Cu2+, Cd2+, and Zn2+) to inhibit Rb+ uptake, and (d) inhibitory effect of ATP, although the nucleotide sensitivity was latent in the stimulated heavy microsomes. The Vmax for 86RbCl uptake was about 10 times greater in the resting light than the stimulated heavy microsomes. These observations led us to propose that secretagogue stimulation induces the insertion of not only the tubulovesicles containing (H+-K+)-ATPase, but also the light membrane vesicles containing KCl transporter into the heavy apical membranes of gastric parietal cells.     

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.     

The H+/ATP stoichiometry of the (H+ +K+)-ATPase of dog gastric microsomes

Gastric microsomal vesicles isolated from dog fundic mucosa were shown to be relatively ion tight and have a low level of proton permeability. The H+ translocase, basal ATPase and K+-activated ATPase activities of these vesicles were measured and the H+/ATP stoichiometry calculated using either the total K+-ATPase or the K+-stimulatable component (total K+-ATPase--basal ATPase). The former estimations consistently gave stoichiometric of approximately one, whereas the use of only the K+-stimulatable component gave widely differing values. Measurement of the dephosphorylation of the enzyme under basal conditions revealed both a labile and a stable phosphoenzyme component. The rate of decay of the labile component completely accounted for the basal ATPase activity observed. We conclude that the basal ATPase associated with our preparations is a spontaneous dephosphorylation of the phosphoenzyme occurring in the absence of K+ and that the H+/ATP stoichiometry of the gastric ATPase is one.     

Membrane domains of intestinal epithelial cells: distribution of Na+,K+- ATPase and the membrane skeleton in adult rat intestine during fetal development and after epithelial isolation

The organization of the basolateral membrane domain of highly polarized intestinal absorptive cells was studied in adult rat intestinal mucosa, during development of polarity in fetal intestine, and in isolated epithelial sheets. Semi-thin frozen sections of these tissues were stained with a monoclonal antibody (mAb 4C4) directed against Na+,K+-ATPase, and with other reagents to visualize distributions of the membrane skeleton (fodrin), an epithelial cell adhesion molecule (uvomorulin), an apical membrane enzyme (aminopeptidase), and filamentous actin. In intact adult epithelium, Na+,K+-ATPase, membrane-associated fodrin, and uvomorulin were concentrated in the lateral, but not basal, subdomain. In the stratified epithelium of fetal intestine, both fodrin and uvomorulin were localized in areas of cell-cell contact at 16 and 17 d gestation, a stage when Na+,K+-ATPase was not yet expressed. These molecules were excluded from apical domains and from cell surfaces in contact with basal lamina. When Na+,K+-ATPase appeared at 18-19 d, it was codistributed with fodrin. Detachment of epithelial sheets from adult intestinal mucosa did not disrupt intercellular junctions or lateral cell contacts, but cytoplasmic blebs appeared at basal cell surfaces, and a diffuse pool of fodrin and actin accumulated in them. At the same time, Na+,K+-ATPase moved into the basal membrane subdomain, and extensive endocytosis of basolateral membrane, including Na+,K+-ATPase, occurred. Endocytosis of uvomorulin was not detected and no fodrin was associated with endocytic vesicles. Uvomorulin, along with some membrane-associated fodrin and some Na+,K+-ATPase, remained in the lateral membrane as long as intercellular contacts were maintained. Thus, in this polarized epithelium, interaction of lateral cell-cell adhesion molecules as well as basal cell-substrate interactions are required for maintaining the stability of the lateral membrane skeleton and the position of resident membrane proteins concentrated in the lateral membrane domain.     

Distribution of carbonic anhydrase, K+-ATPase and K+-phosphatase in subcellular fractions of gastric mucosa]

The distribution of carbonic anhydrase, K+-ATPase and K+-phosphatase in the subcellular fractions of gastric mucosa was studied. It was found that 90% of carbonic anhydrase are localized in the hyaloplasm, whereas K+-ATPase and K+-phosphatase are predominantly localized in the microsomal fraction. Subfractionation of the microsomal fraction in a sucrose density gradient showed that the membrane-bound carbonic anhydrase (5% of total content) and K+-ATPase are bound to various cell organelles. It is concluded that carbonic anhydrase functions as an intracellular pH-stat and is not directly involved in proton generation by the cell.     

Presence and distribution of Na+/K+-ATPase in the ciliary epithelium of the rabbit

Regional differences in the localization of Na+/K+-ATPase in the ciliary epithelium of albino rabbits were studied histochemically using the method of Chayen et al. and ultra-histochemically using a cerium-based method. In addition, the incubation time necessary to achieve first signs of staining was investigated as an indication of Na+/K+-ATPase activity. In the entire pars plicata: prelenticular, postlenticular, as well as tips and valleys, staining was seen in the lateral infoldings of the non pigmented epithelium (NPE) after short incubation periods. Somewhat later, the apical cell membranes also stained. The ultrastructure of these cells, together with the staining pattern, point towards a functional significance of the NPE in active fluid secretion. The pigmented epithelium (PE) did not stain. In the iridial processes and in the area of the ciliary ridges staining first appeared in the apical cell membranes of the NPE, which form the typical ciliary channels. The basolateral infoldings of the NPE also stained, whilst the PE remained unstained. The difference in morphology and staining between pars plicata and iridial processes could indicate a difference in function, e.g. reabsorption of freshly secreted aqueous humour. In the pars plana, only the basolateral infoldings of the PE stained. A functional significance of this area in connection with the blood retina barrier is discussed.