Quantitative immunoelectron microscopic localization of (Na+,K+)ATPase on rat exocrine pancreatic cells

Distribution of (Na+,K+)ATPase in rat exocrine pancreatic cells was investigated quantitatively by immunoelectron microscopy using the post-embedding protein A-gold technique. We found that in acinar and duct cells (Na+,K+)ATPase exists on both the luminal and the basolateral surfaces, with higher particle density on the luminal surface (4.4 times in the acinar cells and 5.6 times in the duct cells). According to Bolender (J Cell Biol 61:269, 1974), the luminal surface represents only 5% of the total cell surface of an average pancreatic acinar cell. It is roughly estimated, therefore, that approximately 80% of the plasma membrane (Na+,K+)ATPase in the acinar cells exists on the basolateral surface. When the acinar and duct cells were compared, more than twice as many particles were found on acinar cells than on duct cells. The enzyme existed on all the cell surfaces, preferentially on the microvilli or on the cell membrane folds, and no clustering was detected. We suggest that the (Na+,K+)ATPase on the basolateral surface is mainly responsible for the extrusion of a large number of sodium ions that are incorporated into the cytoplasm accompanying the secondary active transport of various organic substances and inorganic ions, whereas that on the luminal surface is responsible for active extrusion of sodium ions that are partially responsible for the fluid secretion of the pancreatic cells.     

Quantitative immunogold localization of dipeptidyl peptidase IV (DPP IV) in rat liver cells

We investigated ultrastructural localization of dipeptidyl peptidase IV (DPP IV) [EC3.4.14 5] in rat liver cells quantitatively by post embedding protein A-gold technique. In the hepatocyte, DPP IV was mainly localized on the bile canalicular surface and the lysosomal membranes, but were scarcely detectable on the sinusoid-lateral surface. A small number of DPP IV was also detected in the trans region of the Golgi apparatus, suggesting that this part may play important roles in intracellular transport or recycling of this enzyme. In the endothelial cell, DPP IV existed on the whole surface of the plasma membrane and the lysosomes. In the Kupffer cell DPP IV was mainly localized in lysosomes and a few were detected on the plasma membrane.     

Sodium-potassium adenosine triphosphatase activity of human lymphocyte membrane vesicles: kinetic parameters, substrate specificity, and effects of phytohemagglutinin.

We have prepared human blood lymphocyte membrane vesicles of high purity in sufficient quantity for detailed enzyme analysis. This was made possible by the use of plateletpheresis residues, which contain human lymphocytes in amounts equivalent to thousands of milliliters of blood. The substrate specificity and the kinetics of the cofactor and substrate requirements of the human lymphocyte membrane Na+, K+-ATPase activity were characterized. The Na+, K+-ATPase did not hydrolyze ADP, AMP, ITP, UTP, GTP or TTP. The mean ATPase stimulated by optimal concentrations of Na+ and K+ (Na+, K+-ATPase) was 1.5 nmol of P(i) hydrolyzed, microgram protein-1, 30 min-1 (range 0.9-2.1). This activity was completely inhibited by the cardiac glycoside, ouabain. The K(m) for K+ was approximately 1.0 mM and the K(m) for Na+ was approximately 15 mM. Active Na+ and K+ transport and ouabain-sensitive ATP production increase when lymphocytes are stimulated by PHA. Na+, K+-ATPase activity must increase also to transduce energy for the transport of Na+ and K+. Some studies have reported that PHA stimulates the lymphocyte membrane ATPase directly. We did not observe stimulation of the membrane Na+, K+-ATPase when either lymphocytes or lymphocyte membranes were treated with mitogenic concentrations of PHA. Moreover, PHA did not enhance the reaction velocity of the Na+, K+-ATPase when studied at the K(m) for ATP, Na+, K+ OR Mg++, indicating that it does not alter the affinity of the enzyme for its substrate or cofactors. Thus, our data indicate that the increase in ATPase activity does not occur as a direct result of PHA action on the cell membrane.     

Localization of the ecto-ATPase (ecto-nucleotidase) in the rat hepatocyte plasma membrane. Implications for the functions of the ecto-ATPase

The surface distribution of the plasma membrane Ca2+ (Mg2+)-ATPase (ecto-ATPase) in rat hepatocytes was determined by several methods. 1) Two polyclonal antibodies specific for the ecto-ATPase were used to examine the distribution of the enzyme in frozen sections of rat liver by immunofluorescence. Fluorescent staining was observed at the bile canalicular region of hepatocytes. 2) Plasma membranes were isolated from the canalicular and sinusoidal regions of rat liver. The specific activity of ecto-ATPase in the canalicular membranes was 22 times higher than that of sinusoidal membranes. The enrichment of the ecto-ATPase activity in the canalicular membrane is closely parallel to that of two other canalicular membrane markers, gamma-glutamyltranspeptidase and leucine aminopeptidase. 3) By immunoblots with polyclonal antibodies against the ecto-ATPase and the Na+,K+-ATPase, it was found that the ecto-ATPase protein was only detected in canalicular membranes and not in sinusoidal membranes, while the Na+,K+-ATPase protein was only detected in sinusoidal membranes and not in canalicular membranes. These results indicate that the ecto-ATPase is enriched in the canalicular membranes of rat hepatocytes.     

Increase of Na+ gradient-dependent L-glutamate and L-aspartate transport in high K+ dog erythrocytes associated with high activity of (Na+, K+)-ATPase

As reported previously, some dogs possess red cells characterized by low Na+, high K+ concentrations, and high activity of (Na+, K+)-ATPase, although normal dog red cells contain low K+, high Na+, and lack (Na+, K+)-ATPase. Furthermore, these red cells show increased activities of L-glutamate and L-aspartate transport, resulting in high accumulations of such amino acids in their cells. The present study demonstrated: (i) Na+ gradient-dependent L-glutamate and L-aspartate transport in the high K+ and low K+ red cells were dominated by a saturable component obeying Michaelis-Menten kinetics. Although no difference of the Km values was observed between the high K+ and low K+ cells, the Vmax values for both amino acids' transport in the high K+ cells were about three times those of low ones. (ii) L- and D-aspartate, but not D-glutamate, competitively inhibited L-glutamate transport in both types of the cells. (iii) Ouabain decreased the uptake of the amino acids in the high K+ dog red cells, whereas it was not effective on those in the low K+ cells. (iv) The ATP-treated high K+ cells [(K+]i not equal to [K+]o, [Na+]i greater than [Na+]o) showed a marked decrease of both amino acids' uptake rate, which was almost the same as that of the low K+ cells. (v) Valinomycin stimulated the amino acids' transport in both of the high K+ and the ATP-treated low K+ cells [( K+]i greater than [K+]o, [Na+]o), suggesting that the transport system of L-glutamate and L-aspartate in both types of the cells might be electrogenic. These results indicate that the increased transport activity in the high K+ dog red cells was a secondary consequence of the Na+ concentration gradient created by (Na+, K+)-ATPase.     

Reaccumulation of [K+]o in the toad retina during maintained illumination

Using K+-selective microelectrodes, [K+]o was measured in the subretinal space of the isolated retina of the toad, Bufo marinus. During maintained illumination, [K+]o fell to a minimum and then recovered to a steady level that was approximately 0.1 mM below its dark level. Spatial buffering of [K+]o by Müller (glial) cells could contribute to this reaccumulation of K+. However, superfusion with substances that might be expected to block glial transport of K+ had no significant effect upon the reaccumulation of K+. These substances included blockers of gK (TEA+, Cs+, Rb+, 4-AP) and a gliotoxin (alpha AAA). Progressive slowing of the rods' Na+/K+ pump (perhaps caused by a light-evoked decrease in [Na+]i) also could contribute to this reaccumulation of K+ by reducing the uptake of K+ from the subretinal space. As evidence for a major contribution by this mechanism, treatments designed to prevent such slowing of the pump reversibly blocked reaccumulation. These treatments included superfusion with 2 microM ouabain, or lowering [K+]o, PO2, or temperature. It is likely that such treatments inhibit the pump, increase [Na+]i, and attenuate any light-evoked decrease in [Na+]i. The results are consistent with the following hypothesis. At light onset, the decrease in rod gNa will reduce the Na+ influx and the resulting rod hyperpolarization will reduce the K+ efflux. In combination with these reduced passive fluxes, the continuing active fluxes will lower both [K+]o and [Na+]i, which in turn will inhibit the pump. In support of this hypothesis, the solutions to a pair of coupled differential equations that model changes in both [K+]o and [Na+]i match quantitatively the time course of the observed changes in [K+]o during and after maintained illumination for all stimuli examined.     

Axonal transport of [3H]serotonin in an identified neuron of Aplysia californica

The distribution of (Na+ + K+) ATPase over the plasma membranes of the proximal convoluted tubule from canine renal cortex has been determined. Ultrathin frozen sections of this tissue were stained with rabbit antibodies to this enzyme and ferritin-conjugated goat antirabbit gamma-globulin. It is demonstrated that high concentrations of this enzyme uniformly line the intercellular spaces of this epithelium. The consequences of this observation are discussed in terms of the low resistant tight junctions of these tubules and the isotonic fluid transport which they support. Furthermore, antibodies to (Na+ + K+) ATPase recognize an antigen on the luminal surfaces of the tubules within the brush border. It is proposed that the enzyme is present in this region of the plasma membrane as well, although at much lower concentration. To further substantiate this conclusion, a brush border fraction has been purified from rabbit kidney and been shown to contain significant (Na+ + K+) ATPase. These results contradict earlier conclusions about the location of (Na+ + K+) ATPase in this tissue.     

The lateral mobility of the (Na+,K+)-dependent ATPase in Madin-Darby canine kidney cells

Fluorescence microphotolysis (recovery after photobleaching) was used to determine the lateral mobility of the (Na+,K+)ATPase and a fluorescent lipid analogue in the plasma membrane of Madin-Darby canine kidney (MDCK) cells at different stages of development. Fluorescein-conjugated Fab' fragments prepared from rabbit anti-dog (Na+,K+)ATPase antibodies (IgG) and 5-(N-hexadecanoyl)aminofluorescein (HEDAF) were used to label the plasma membrane of confluent and subconfluent cultures of MDCK cells. Fractional fluorescence recovery was 50% and 80-90% for the protein and lipid probes, respectively, and was independent of developmental stage. The estimated diffusion constants of the mobile fraction were approximately 5 X 10(-10) cm2/s for the (Na+,K+)ATPase and approximately 2 X 10(-9) cm2/s for HEDAF. Only HEDAF diffusion showed dependency on developmental stage in that D for confluent cells was approximately twice that for subconfluent cells. These results indicate that (Na+,K+)ATPase is 50% immobilized in all developmental stages, whereas lipids in confluent MDCK cells are more mobile than in subconfluent cells. They suggest, furthermore, that the degree of immobilization of the (Na+,K+)ATPase is insufficient to explain its polar distribution, and they support restricted mobility of the ATPase through the tight junctions as the likely mechanism for preventing the diffusion of this protein into the apical domain of the plasma membrane in confluent cell cultures.     

Properties of (Na+ plus K+)-activated ATPase in rat liver plasma membranes enriched with bile canaliculi.

Liver plasma membranes enriched in bile canaliculi were isolated from rat liver by a modification of the technique of Song et al. (J. Cell Biol. (1969) 41, 124-132) in order to study the possible role of ATPase in bile secretion. Optimum conditions for assaying (Na+ plus K+)-activated ATPase in this membrane fraction were defined using male rats averaging 220 g in weight. (Na+ plus K+)-activated ATPase activity was documented by demonstrating specific cation requirements for Na+ and K+, while the divalent cation, Ca(2+), and the cardiac glycosides, ouabain and scillaren, were inhibitory. (Na+ plus K+)-activated ATPase activity averaged 10.07 plus or minus 2.80 mumol Pi/mg protein per h compared to 50.03 plus or minus 11.41 for Mg(2+)-activated ATPase and 58.66 plus or minus 10.07 for 5'-nucleotidase. Concentrations of ouabain and scillaren which previously inhibited canalicular bile secretion in the isolated perfused rat liver produced complete inhibition of (Na+ plus K+)-activated ATPase without any effect on Mg(2+)-activated ATPase. Both (Na+ plus K+)-activated ATPase and Mg(2+)-activated ATPase demonstrated temperature dependence but differed in temperature optima. Temperature induced changes in specific activity of (Na+ plus K+)-activated ATPase directly paralleled previously demonstrated temperature optima for bile secretion. These studies indicate that (Na+ plus K+)-activated ATPase is present in fractions of rat liver plasma membranes that are highly enriched in bile canaliculi and provide a model for further study of the effects of various physiological and chemical modifiers of bile secretion and cholestasis.     

Cholinergic stimulation of the Na+/K+ adenosine triphosphatase as revealed by microphysiometry.

The activation of a wide range of cellular receptors has been detected previously using a novel instrument, the microphysiometer. In this study microphysiometry was used to monitor the basal and cholinergic-stimulated activity of the Na+/K+ adenosine triphosphatase (ATPase) (the Na+/K+ pump) in the human rhabdomyosarcoma cell line TE671. Manipulations of Na+/K+ ATPase activity with ouabain or removal of extracellular K+ revealed that this ion pump was responsible for 8.8 +/- 0.7% of the total cellular energy utilization by those cells as monitored by the production of acid metabolites. Activation of the pump after a period of inhibition transiently increased the acidification rate above baseline, corresponding to increases in intracellular [Na+] ([Na+]i) occurring while the pump was off. The amplitude of this transient was a function of the total [Na+]i excursion in the absence of pump activity, which in turn depended on the duration of pump inhibition and the Na+ influx rate. Manipulations of the mode of energy metabolism in these cells by changes of the carbon substrate and use of metabolic inhibitors revealed that, unlike some other cells studied, the Na+/K+ ATPase in TE671 cells does not depend on any one mode of metabolism for its adenosine triphosphate source. Stimulation of cholinergic receptors in these cells with carbachol activated the Na+/K+ ATPase via an increase in [Na+]i rather than a direct activation of the ATPase.     

Insulin activation of (Na+,K+)-adenosinetriphosphatase exhibits a temperature-dependent lag time. Comparison to activation of the glucose transporter

The time course of insulin activation of sodium and potassium ion activated adenosinetriphosphatase [(Na+,K+)ATPase] was studied in the rat adipocyte and was compared to activation of the glucose transporter. Under conditions in which the binding of insulin to its cell surface receptor was not rate limiting, a distinct time lag was apparent between insulin addition and stimulation of transport activity. At 37 degrees C, 40-50 s elapsed before an increase in Rb+ uptake [a measure of (Na+,K+)ATPase transport activity] or 2-deoxyglucose uptake could be observed. This lag time increased in an identical manner for both transport processes as the temperature was lowered to 23 degrees C. Addition of the insulinomimetic agent hydrogen peroxide also produced a lag time similar to that for insulin before activation of Rb+ and 2-deoxyglucose uptakes was detected. These data provide the first evidence of a discrete time lag involved during stimulation of the adipocyte (Na+,K+)ATPase. A model for the molecular mechanism of insulin activation of (Na+,K+)ATPase is presented that incorporates these results into the hypothesis of insulin mediated "translocation" of glucose transporters to the plasma membrane.     

Effect of salinity on expression of branchial ion transporters in striped bass (Morone saxatilis)

The time course of osmoregulatory adjustments and expressional changes of three key ion transporters in the gill were investigated in the striped bass during salinity acclimations. In three experiments, fish were transferred from fresh water (FW) to seawater (SW), from SW to FW, and from 15-ppt brackish water (BW) to either FW or SW, respectively. Each transfer induced minor deflections in serum [Na+] and muscle water content, both being corrected rapidly (24 hr). Transfer from FW to SW increased gill Na+,K+-ATPase activity and Na+,K+,2Cl- co-transporter expression after 3 days. Abundance of Na+,K+-ATPase alpha-subunit mRNA and protein was unchanged. Changes in Na+,K+,2Cl- co-transporter protein were preceded by increased mRNA expression after 24 hr. Expression of V-type H+-ATPase mRNA decreased after 3 days. Transfer from SW to FW induced no change in expression of gill Na+,K+-ATPase. However, Na+,K+,2Cl- co-transporter mRNA and protein levels decreased after 24 hr and 7 days, respectively. Expression of H+-ATPase mRNA increased in response to FW after 7 days. In BW fish transferred to FW and SW, gill Na+,K+-ATPase activity was stimulated by both challenges, suggesting both a hyper- and a hypo-osmoregulatory response of the enzyme. Acclimation of striped bass to SW occurs on a rapid time scale. This seems partly to rely on the relative high abundance of gill Na+,K+-ATPase and Na+,K+,2Cl- co-transporter in FW fish. In a separate study, we found a smaller response to SW in expression of these ion transport proteins in striped bass when compared with the less euryhaline brown trout. In both FW and SW, NEM-sensitive gill H+-ATPase activity was negligible in striped bass and approximately 10-fold higher in brown trout. This suggests that in striped bass Na+-uptake in FW may rely more on a relatively high abundance/activity of Na+,K+-ATPase compared to trout, where H+-ATPase is critical for establishing a thermodynamically favorable gradient for Na+-uptake.     

Inhibition by lead ion of Electrophorus electroplax (Na+ + K+)-adenosine triphosphatase and K+-p-nitrophenylphosphatase.

Inorganic lead ion in micromolar concentrations inhibits Electrophorus electroplax microsomal (Na+ + K+)-adenosine triphosphatase ((Na+ + K+)-ATPase) and K+-p-nitrophenylphosphatase (NPPase). Under the same conditions, the same concentrations of PbCl2 that inhibit ATPase activity also stimulate the phosphorylation of electroplax microsomes in the absence of added Na+. Enzyme activity is protected from inhibition by increasing concentrations of microsomes, ATP, and other metal ion chelators. The kinetics follow the pattern of a reversible noncompetitive inhibitor. No kinetic evidence is elicited for interactions of Pb2+ with Na+, K+, Mg2+, ATP, or p-nitrophenylphosphate. Na+- ATPase, in the absence of K+, and (Na+ + K+)-NPPase activity at low [K+] are also inhibited. ATP inhibition of NPPase is not reversed by Pb2+. The calculated concentrations of free [Pb2+] that produce 50% inhibition are similar for ATPase and NPPase activities. Pb2+ may act at a single independent binding site to produce both stimulation of the kinase and inhibition of the phosphatase activities.     

Effects of thyroid hormone and adrenalectomy on [Na+ + K+]ATPase in the ob/ob mouse

The absence of the thyroid stimulation of hepatic [Na+ + K+]ATPase in obese (ob/ob) mice has been investigated. A wide range of tri-iodothyronine (T3) concentrations failed to enhance the hepatic [Na+ + K+]ATPase of ob/ob mice made hypothyroid by methimazole treatment but glycerophosphate dehydrogenase activity was maximally stimulated at low doses of T3. Adrenalectomy increased the basal activity of [Na+ + K+]ATPase to levels found in lean control mice and restored the response of this enzyme to T3. Body weight gain was unaffected by the induction of hypothyroidism in either lean or ob/ob mice. It is concluded that the adrenal steroids play an important role in the expression of [Na+ + K+]ATPase activity in the ob/ob mouse.     

The mechanism of insulin stimulation of (Na+,K+)-ATPase transport activity in muscle

Since the mechanism underlying the insulin stimulation of (Na+,K+)-ATPase transport activity observed in multiple tissues has remained undetermined, we have examined (Na+,K+)-ATPase transport activity (ouabain-sensitive 86Rb+ uptake) and Na+/H+ exchange transport (amiloride-sensitive 22Na+ influx) in differentiated BC3H-1 cultured myocytes as a model of insulin action in muscle. The active uptake of 86Rb+ was sensitive to physiological insulin concentrations (1 nM), yielding a maximum increase of 60% without any change in 86Rb+ permeability. In order to determine the mechanism of insulin stimulation of (Na+,K+)-ATPase activity, we demonstrated that insulin also stimulates passive 22Na+ influx by Na+/H+ exchange transport (maximal 200% increase) and an 80% increase in intracellular Na+ concentration with an identical time course and dose-response curve as insulin-stimulated (Na+,K+)-ATPase transport activity. Incubation of the cells with high [Na+] (195 mM) significantly potentiated insulin stimulation of ouabain-inhibitable 86Rb+ uptake. The ionophore monensin, which also promotes passive Na+ entry into BC3H-1 cells, mimics the insulin stimulation of ouabain-inhibitable 86Rb+ uptake. In contrast, incubation with amiloride or low [Na+] (10 mM), both of which inhibit Na+/H+ exchange transport, abolished the insulin stimulation of (Na+,K+)-ATPase transport activity. Furthermore, each of these insulin-stimulated transport activities displayed a similar sensitivity to amiloride. These results indicate that insulin stimulates a large increase in Na+/H+ exchange transport and that the resulting Na+ influx increases the intracellular Na+ concentration, thus activating the internal Na+ transport sites of the (Na+,K+)-ATPase. This Na+ influx is, therefore, the mediator of the insulin-induced stimulation of membrane (Na+,K+)-ATPase transport activity classically observed in muscle.     

Quantitative immunoelectron microscopic localization of (Na+,K+)ATPase in rat parotid gland

Distribution of (Na+,K+)ATPase on the cell membranes of acinar and duct cells of rat parotid gland was investigated quantitatively by immunoelectron microscopy using the post-embedding protein A-gold technique. In acinar cells, ATPase was localized predominantly on the basolateral plasma membranes. A small but significant amount of (Na+,K+)ATPase was, however, detected on the luminal plasma membranes, especially on the microvillar region of the acinar cells; the surface density on the luminal membrane was approximately one third of that on the basolateral membranes. In duct cells, many gold particles were found on the basolateral membrane, especially along the basal infoldings of the plasma membranes, whereas no significant gold particles were found on the luminal plasma membranes, suggesting unilateral distribution of ATPase in duct cells. We suggest that in acinar cells sodium ion is not only transported paracellularly but is also actively transported intracellularly into the luminal space by the (Na+,K+)ATPase located on the luminal plasma membranes, and that water is passively transported to the luminal space to form a plasma-like isotonic primary saliva, while in the duct cells the same ion is selectively re-absorbed intracellularly by (Na+,K+)ATPase found in abundance along the many infoldings of the basal plasma membranes, thus producing the hypotonic saliva.     

Intracellular Na+ controls cell surface expression of Na,K-ATPase via a cAMP-independent PKA pathway in mammalian kidney collecting duct cells

In the mammalian kidney the fine control of Na+ reabsorption takes place in collecting duct principal cells where basolateral Na,K-ATPase provides the driving force for vectorial Na+ transport. In the cortical collecting duct (CCD), a rise in intracellular Na+ concentration ([Na+]i) was shown to increase Na,K-ATPase activity and the number of ouabain binding sites, but the mechanism responsible for this event has not yet been elucidated. A rise in [Na+]i caused by incubation with the Na+ ionophore nystatin, increased Na,K-ATPase activity and cell surface expression to the same extent in isolated rat CCD. In cultured mouse mpkCCDcl4 collecting duct cells, increasing [Na+]i either by cell membrane permeabilization with amphotericin B or nystatin, or by incubating cells in a K(+)-free medium, also increased Na,K-ATPase cell surface expression. The [Na+]i-dependent increase in Na,K-ATPase cell-surface expression was prevented by PKA inhibitors H89 and PKI. Moreover, the effects of [Na+]i and cAMP were not additive. However, [Na+]i-dependent activation of PKA was not associated with an increase in cellular cAMP but was prevented by inhibiting the proteasome. These findings suggest that Na,K-ATPase may be recruited to the cell membrane following an increase in [Na+]i through cAMP-independent PKA activation that is itself dependent on proteasomal activity.     

Purification and characterization of the plasma membrane ATPase of Neurospora crassa

The plasma membrane of Neurospora crassa contains a proton-translocating ATPase, which functions to generate a large membrane potential and thereby to drive a variety of H+-dependent co-transport systems. We have purified this ATPase by a three-step procedure in which 1) loosely bound membrane proteins are removed by treatment with 0.1% deoxycholate; 2) the ATPase is solubilized with 0.6% deoxycholate in the presence of 45% glycerol; and 3) the solubilized enzyme is purified by centrifugation through a glycerol gradient. This procedure typically yields approximately 30% of the starting ATPase activity in a nearly homogeneous enzyme preparation of high specific activity, 61-98 mumol/min/mg of protein. The membrane-bound and purified forms of the ATPase are very similar with respect to kinetic properties (pH optimum, nucleotide and divalent cation specificity, sigmoid dependence upon Mg-ATP concentration) and sensitivity to inhibitors (including N,N'-dicyclohexylcarbodiimide and vanadate). Upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the purified ATPase displays a single major polypeptide band of Mr = 104,000, which is essentially identical in its electrophoretic mobility with the large subunit of [Na+, K+]-ATPase of animal cell membranes and [Ca2+]-ATPase of sarcoplasmic reticulum. The structural similarity of the fungal and animal cell ATPases, together with the fact that both are known to form acyl phosphate intermediates, suggests that they may share a common reaction mechanism.     

Brefeldin A influences the cell surface abundance and intracellular pools of low and high ouabain affinity Na+, K(+)-ATPase alpha subunit isoforms in articular chondrocytes

The catalytic alpha isoforms of the Na+, K(+)-ATPase and stimuli controlling the plasma membrane abundance and intracellular distribution of the enzyme were studied in isolated bovine articular chondrocytes which have previously been shown to express low and high ouabain affinity alpha isoforms (alpha 1 and alpha 3 respectively; alpha 1 > alpha 3). The Na+, K(+)-ATPase density of isolated chondrocyte preparations was quantified by specific 3H-ouabain binding. Long-term elevation of extracellular medium [Na+] resulted in a significant (31%; p < 0.05) upregulation of Na+, K(+)-ATPase density and treatment with various pharmacological inhibitors (Brefeldin A, monensin and cycloheximide) significantly (p < 0.001) blocked the upregulation. The subcellular distribution of the Na+, K(+)-ATPase alpha isoforms was examined by immunofluorescence confocal laser scanning microscopy which revealed predominantly plasma membrane immunostaining of alpha subunits in control chondrocytes. In Brefeldin A treated chondrocytes exposed to high [Na+], Na+, K(+)-ATPase alpha isoforms accumulated in juxta-nuclear pools and plasma membrane Na+, K(+)-ATPase density monitored by 3H-ouabain binding was significantly down-regulated due to Brefeldin A mediated disruption of vesicular transport. There was a marked increase in intracellular alpha 1 and alpha 3 staining suggesting that these isoforms are preferentially upregulated following long-term exposure to high extracellular [Na+]. The results demonstrate that Na+, K(+)-ATPase density in chondrocytes is elevated in response to increased extracellular [Na+] through de novo protein synthesis of new pumps containing alpha 1 and alpha 3 isoforms, delivery via the endoplasmic reticulum-Golgi complex constitutive secretory pathway and insertion into the plasma membrane.