Coupling ratio of electrogenic Na+-alanine cotransport in isolated rat hepatocytes

Na+-alanine cotransport across the cell membrane in isolated rat hepatocytes was studied. Changes in the cell membrane potential associated with the transport of alanine interfere with determination of the Na+-alanine coupling ratio of the cotransport. With valinomycin present to 'clamp' the cell membrane potential, a coupling ratio of 1:1 for the Na+-alanine influx was obtained.     

Na+, Cl− cotransport in Ehrlich ascites tumor cells activated during volume regulation (regulatory volume increase)

Ehrlich ascites cells were preincubated in hypotonic medium with subsequent restoration of tonicity. After the initial osmotic shrinkage the cells recovered their volume within 5 min with an associated KCl uptake. The volume recovery was inhibited when NO-3 was substituted for Cl-, and when Na+ was replaced by K+, or by choline (at 5 mM external K+). The volume recovery was strongly inhibited by furosemide and bumetanide, but essentially unaffected by DIDS. The net uptake of Cl- was much larger than the value predicted from the conductive Cl- permeability. The undirectional 36Cl flux, which was insensitive to bumetanide under steady-state conditions, was substantially increased during regulatory volume increase, and showed a large bumetanide-sensitive component. During volume recovery the Cl- flux ratio (influx/efflux) for the bumetanide-sensitive component was estimated at 1.85, compatible with a coupled uptake of Na+ and Cl-, or with an uptake via a K+,Na+,2Cl- cotransport system. The latter possibility is unlikely, however, because a net uptake of KCl was found even at low external K+, and because no K+ uptake was found in ouabain-poisoned cells. In the presence of ouabain a bumetanide-sensitive uptake during volume recovery of Na+ and Cl- in nearly equimolar amounts was demonstrated. It is proposed that the primary process during the regulatory volume increase is an activation of an otherwise quiescent, bumetanide-sensitive Na+,Cl- cotransport system with subsequent replacement of Na+ by K+ via the Na+/K+ pump, stimulated by the Na+ influx through the Na+,Cl- cotransport system.     

Hypertonic stress increases the Na+ conductance of rat hepatocytes in primary culture

We studied the ionic mechanisms underlying the regulatory volume increase of rat hepatocytes in primary culture by use of confocal laser scanning microscopy, conventional and ion-sensitive microelectrodes, cable analysis, microfluorometry, and measurements of 86Rb+ uptake. Increasing osmolarity from 300 to 400 mosm/liter by addition of sucrose decreased cell volumes to 88.6% within 1 min; thereafter, cell volumes increased to 94.1% of control within 10 min, equivalent to a regulatory volume increase (RVI) by 44.5%. This RVI was paralleled by a decrease in cell input resistance and in specific cell membrane resistance to 88 and 60%, respectively. Ion substitution experiments (high K+, low Na+, low Cl-) revealed that these membrane effects are due to an increase in hepatocyte Na+ conductance. During RVI, ouabain-sensitive 86Rb+ uptake was augmented to 141% of control, and cell Na+ and cell K+ increased to 148 and 180%, respectively. The RVI, the increases in Na+ conductance and cell Na+, as well as the activation of Na+/K(+)-ATPase were completely blocked by 10(-5) mol/liter amiloride. At this concentration, amiloride had no effect on osmotically induced cell alkalinization via Na+/H+ exchange. When osmolarity was increased from 220 to 300 mosm/liter (by readdition of sucrose after a preperiod of 15 min in which the cells underwent a regulatory volume decrease, RVD) cell volumes initially decreased to 81.5%; thereafter cell volumes increased to 90.8% of control. This post-RVD-RVI of 55.0% is also mediated by an increase in Na+ conductance. We conclude that rat hepatocytes in confluent primary culture are capable of RVI as well as of post-RVD-RVI. In this system, hypertonic stress leads to a considerable increase in cell membrane Na+ conductance. In concert with conductive Na+ influx, cell K+ is then increased via activation of Na+/K(+)-ATPase. An additional role of Na+/H+ exchange in the volume regulation of rat hepatocytes remains to be defined.     

Volume regulatory activity of the Ehrlich ascites tumor cell and its relationship to ion transport

The volume regulatory response of the Ehrlich ascites tumor was studied in KCl-depleted, Na+-enriched cells. Subsequent incubation in K+-containing NaCl medium results in the reaccumulation of K+, Cl-, water and the extrusion of Na+. The establishment of the physiological steady state is due primarily to the activity of 2 transport systems. One is the Na/K pump (KM for K+o = 3.5 mM; Jmax = 30.1 mEq/kg dry min), which in these experiments was coupled 1K+/1 Na+. The second is the Cl--dependent (Na+ + K+) cotransport system (KM for K+o = 6.8 mM; Jmax = 20.8 mEq/kg dry min) which mediates, in addition to net ion uptake in the ratio of 1K+:1Na+:2Cl-, the exchange of K+i for K+o. The net passive driving force on the cotransport system is initially inwardly directed but does not decrease to zero at the steady state. This raises the possibility of the involvement of an additional source of energy. Although cell volume increases concomitant with net ion uptake, this change does not appear to be a major factor regulating the activity of the cotransport system.     

3H]bumetanide binding to avian erythrocyte membranes. Correlation with activation and deactivation of Na/K/2Cl cotransport

The relationship between Na/K/2Cl cotransport activation in duck erythrocytes and binding of the diuretic [3H]bumetanide to isolated membranes from stimulated cells has been assessed. Cotransport was activated by either cAMP-dependent (norepinephrine) or -independent (fluoride, hypertonicity) pathways. Membranes isolated from unstimulated cells possessed no specific bumetanide binding. In the presence of norepinephrine, cotransport and saturable binding rose in parallel, reaching a maximum after 5-7 min. In membranes from maximally stimulated cells the K1/2 and Bmax for bumetanide binding were 100 nM and 1.7 pmol/mg protein, respectively. The diuretic binding properties of these membranes were characteristic of interactions of ligands with the Na/K/2Cl cotransporter: specific binding required the presence of all three cotransported ions (Na, K, and Cl), and the rank order of potency for diuretic competition with bumetanide for binding sites was benzmetanide greater than bumetanide greater than furosemide. The appearance of specific bumetanide binding was also seen in membranes from erythrocytes activated by non-cAMP-dependent stimuli, with an excellent temporal correlation between cotransport activation and diuretic binding. On removal of all stimuli both cotransport and bumetanide binding declined in parallel. Duck erythrocytes treated with norepinephrine in a solution containing 15 mM K+ swell to a new stable cell volume after 60 min, during which time cotransport becomes inoperative. Bumetanide binding to both whole cells and isolated membranes paralleled the decline in cotransport activity. It is concluded that bumetanide binding to isolated membranes faithfully reflects the state of activation of the Na/K/2Cl cotransporter in intact cells under a variety of conditions.     

Volume-dependent regulation of ion carriers in human and rat erythrocytes: role of cytoskeleton and protein phosphorylation

This study examines the effect of heat-induced cytoskeleton transitions and phosphoprotein phosphatase inhibitors on the activity of shrinkage-induced Na+, K+, 2Cl- cotransport and Na+/H+ exchange in rat erythrocytes and swelling-induced K+, Cl- cotransport in human and rat blood cells. Preincubation of human and rat erythrocytes at 49 degrees C drastically activated K+, Cl- cotransport and completely (rat) or partly (human) abolished its volume-dependent regulation. The same procedure did not affect basal activity of Na+, K+, 2Cl- cotransport but completely abolished its activation by shrinkage thus suggesting the involvement of a thermosensitive element of cytoskeleton network in the volume-dependent regulation of cotransporters. Both the shrinkage- and electrochemical proton gradient-induced Na+/H+ exchange was inhibited by the heat treatment to the same extent (50-70%), thus indicating the different signaling pathways involved in the activation of Na+, K+, 2Cl- cotransport and Na+/H+ exchange by cell shrinkage. This suggestion is in accordance with data on the different kinetics of volume-dependent activation and inactivation of these carriers as well as on their sensitivity to medium osmolality. Both swelling- and heat-induced increments of K+, Cl- cotransport activity were diminished by inhibitors of phosphoprotein phosphatases (okadaic acid and calyculin). In rat erythrocytes these compounds potentiate shrinkage-induced Na+/H+ exchange. On the contrary, neither basal nor shrinkage-induced Na+, K+, 2Cl- cotransport was affected by these compounds. Our results indicate a key role of cytoskeleton network in volume-dependent activation of K+, Cl- and Na+, K+, 2Cl- cotransport and the involvement of protein phosphorylation-dephosphorylation cycle in regulation of the activity of K+, Cl- cotransport and Na+/H+ exchange.     

Characterization of Na+/K+/Cl- cotransport in cultured HT29 human colonic adenocarcinoma cells

A Na+/K+/Cl- cotransport pathway has been examined in the HT29 human colonic adenocarcinoma cell line using 86Rb as the K congener. Ouabain-resistant bumetanide-sensitive (OR-BS) K+ influx in attached HT29 cells was 17.9 +/- 0.9 nmol/min per mg protein at 25 degrees C. The identity of this pathway as a Na+/K+/Cl- cotransporter has been deduced from the following findings: (a) OR-BS K+ influx ceased if the external Cl- (Cl-o) was replaced by NO3- or the external Na+ (Na+o) by choline; (b) neither OR-BS 24Na+ nor 36Cl- influx was detectable in the absence of external K+ (K+o); and (c) concomitant measurements of 86Rb+, 22Na+, and 36Cl- influx indicated that the stoichiometry of the cotransport system approached a ratio of 1N+:1K+:2Cl-. In addition, OR-BS K+ influx was exquisitely sensitive to cellular ATP levels. Depletion of the normal ATP content of 35-40 nmol/mg protein to 10-15 nmol/mg protein, a concentration at which the ouabain-sensitive K+ influx was unaffected, completely abolished K+ cotransport. OR-BS K+ influx was slightly reduced by the divalent cations Ca2+, Ba2+, Mg2+ and Mn2+. Although changes in cell volume, whether shrinking or swelling, did not influence OR-BS K+ influx, ouabain-sensitive K+ influx was activated by cell swelling. As in T84 cells, we found that the OR-BS K+ influx in HT29 cells was stimulated by exogenous cyclic AMP analogues and by augmented cyclic AMP content in response to vasoactive intestinal peptide, forskolin, norepinephrine and forskolin or prostaglandin E1.     

Time-dependent biphasic regulation of Na+/K+/Cl- cotransport in rat glomerular mesangial cells

Time-dependent regulation of loop diuretic-sensitive Na+/K+/Cl- cotransport and [3H]bumetanide binding was investigated in cultured rat glomerular mesangial cells. Angiotensin II or epidermal growth factor induced stimulation of Na+/K+/Cl- cotransport within 5 min, with a return to the control values by 30 min. Treatment of cells with phorbol 12-myristate 13-acetate (0.1 microM) (PMA), the calcium ionophore A23187 (1 microM), or the combination of 5 mM NaF and 10 microM AlCl3 produced a transient stimulation of Na+/K+/Cl- cotransport in 5-10 min to 148, 135, and 163% of control, respectively, which was followed by a progressive decrease to 34, 64, and 20% of the base-line activity, respectively, by 60 min. Exposure to cyclic 8-bromo-AMP (0.1 mM) or to forskolin (1 microM) and isobutylmethylxanthine (0.1 mM) caused a maximal inhibition of the cotransport in 5 min to 79 and 60% of control, respectively, with a subsequent gradual increase to 137 and 164% of the base-line activity, respectively, by 60 min. The effects of PMA, forskolin, and cyclic 8-bromo-AMP were concentration-dependent. In order to characterize further the alterations in the cotransport activity, binding of [3H]bumetanide was determined. Saturation binding analyses showed that the late inhibition of the cotransport by PMA and stimulation by forskolin were associated with a significant decrease and increase, respectively, in Bmax, with no significant changes in binding affinity. Correlations between changes in the cotransport activity and [3H]bumetanide binding were also observed in cells treated with cyclic 8-bromo-AMP or with NaF and AlCl3. Incubation of cells in Cl- or Na+ free solution greater than or equal to 60 min resulted in an increase in both the cotransport activity and [3H]bumetanide binding. These observations indicate that, in glomerular mesangial cells, persistent stimulation of second messengers that regulate the cotransporter induces a time-dependent, biphasic regulation of Na+/K+/Cl- cotransport and that the regulation occurring after greater than or equal to 60 min of treatment is primarily due to changes in the number of the active cotransport sites. Because long term removal of the transported ions also increases the number of active cotransport sites, these results suggest that alterations in intracellular ionic homeostasis may also mediate cotransport activity.     

Expression of the hepatocyte Na+/bile acid cotransporter in Xenopus laevis oocytes

The expression of the basolateral Na+/bile acid (taurocholate) cotransport system of rat hepatocytes has been studied in Xenopus laevis oocytes. Injection of rat liver poly(A)+ RNA into the oocytes resulted in the functional expression of Na+ gradient stimulated taurocholate uptake within 3-5 days. This Na(+)-dependent portion of taurocholate uptake exhibited saturation kinetics (apparent Km approximately 91 microM) and could be inhibited by 4,4'-diisothiocyano-2,2'-disulfonic acid stilbene. Furthermore, the expressed taurocholate transport activity demonstrated similar substrate inhibition and stimulation by low concentrations of bovine serum albumin as the basolateral Na+/bile acid cotransport system previously characterized in intact liver, isolated hepatocytes, and isolated plasma membrane vesicles. Finally, a 1.5- to 3.0-kilobase size-class of mRNA could be identified that was sufficient to express the basolateral Na+/taurocholate uptake system in oocytes. These results demonstrate that "expression cloning" represents a promising approach to ultimately clone the gene and to further characterize the molecular properties of this important hepatocellular membrane transport system.     

Photoaffinity labeling studies of the rat renal sodium bile salt cotransport system

The uptake of a photolabile taurocholate derivative, (7,7-azo-3 alpha, 12 alpha-dihydroxy-5 beta-cholan-24-oyl)-2-aminoethanesulfonate, 7,7-azo-TC, into rat renal brush-border membrane vesicles was stimulated by Na+ and inhibited by taurocholate indicating an interaction with the Na+/bile salt cotransport system. Irradiation of membrane vesicles in the presence of 7,7-azo-TC inhibited Na+-dependent taurocholate uptake irreversibly. Photoaffinity labeling with [3H]7,7-azo-TC resulted in a predominant incorporation of radioactivity into a polypeptide with apparent molecular weight of 99,000. These results suggest that the proteins involved in Na+/bile salt cotransport are similar in renal and ileal brush-border membranes, but differ from those in hepatocytes.     

Transport functions of the liver. Lack of correlation between hepatocellular ouabain uptake and binding to (Na+ + K+)-ATPase

Ouabain uptake was studied on isolated rat hepatocytes. Hepatocellular uptake of the glycoside is saturable (Km = 348 mumol/l, Vmax = 1.4 nmol/mg cell protein per min), energy dependent and accumulative. Concentrative ouabain uptake is not present on permeable hepatocytes, Ehrlich ascites tumor cells and AS-30D ascites hepatoma cells. There is no correlation between ouabain binding to rat liver (Na+ + K+)ATPase and ouabain uptake into isolated rat hepatocytes. While ouabain uptake is competitively inhibited by cevadine, binding to (Na+ + K+)-ATPase is not affected by the alkaloid. Although the affinities of digitoxin and ouabain to (Na+ + K+)-ATPase are similar, digitoxin is 10000-times more potent in inhibiting [3H]ouabain uptake as compared to ouabain. That binding to (Na+ + K+)-ATPase appears to be no precondition for ouabain uptake was also found in experiments with plasmamembranes derived from Ehrlich ascites tumor cells and AS-30D hepatoma cells. While tumor cell (Na+ + K+)-ATPase is ouabain sensitive, the intact cells are transport deficient. Hepatic ouabain uptake might be related to bile acid transport. Several inhibitors of the bile acid uptake system also inhibit ouabain uptake.     

Characterization of sulfate, proline, and glucose transport systems in anterior cruciate and medial collateral ligament cells

The present study was undertaken to define the nature of key transport processes for sodium, glucose, proline, and sulfate in primary culture of canine anterior cruciate ligament (ACL) and medial collateral ligament (MCL) cells. Uptake studies using radiolabeled isotopes were performed and Na,K-ATPase activity was determined in cell lysates. At 25 degrees C both ACL and MCL cells showed a significant uptake of 86Rb. Ouabain inhibited Rb uptake by 55% in ACL cells and by 60% in MCL cells. The transport activity of Na,K-ATPase in intact cells was calculated to be 57 and 71 nmol.(mg protein)-1.(15 min)-1, respectively. The enzymatic activity of Na,K-ATPase in cell lysates was observed to be 104 for ACL cells and 121 nmol.(mg protein)-1.(15 min)-1 for MCL cells. Cytochalasin B, a known inhibitor of sodium-independent D-glucose transport, completely inhibited D-glucose uptake in ACL and MCL cells. Removal of Na+ or addition of 10-5 mol/L phlorizin, a potent inhibitor of the sodium-D-glucose cotransporter, did not alter D-glucose uptake, suggesting that glucose entered the cells using a sodium-independent pathway. Both ACL and MCL cells exhibited high sulfate uptake that was not altered by replacement of Na+ by N-methyl-D-glucamine, whereas DIDS, an inhibitor of sulfate/anion exchange abolished sulfate uptake in both cell types. Thus, neither cell type seems to possess a sodium-sulfate cotransport system. Rather, sulfate uptake appeared to be mediated by sulfate/anion exchange. Proline was rapidly taken up by ACL and MCL cells and its uptake was reduced by 85% when Na+ was replaced by N-methyl-D-glucamine, indicating that proline entered the cells via sodium-dependent cotransport systems. The data demonstrate that both ACL and MCL cells possess a highly active sodium pump, a secondary active sodium-proline cotransport system, and sodium-independent transport systems for D-glucose and sulfate.     

The Na+/K+/Cl- cotransport in C6 glioma cells. Properties and role in volume regulation

The role of the Na+/K+/Cl- cotransporter in the regulation of the volume of C6 astrocytoma cells was analyzed using isotopic fluxes and cell cytometry measurements of the cell volume. The system was inhibited by 'loop diuretics' with the following order of potency: benzmetanide greater than bumetanide greater than piretanide greater than furosemide. Under physiological conditions of osmolarity of the incubation media, equal rates of bumetanide-sensitive inward and outward K+ fluxes were observed. Blockade of the Na+/K+/Cl- cotransporter with bumetanide did not lead to a modification in the mean cell volume. When C6 cells were incubated in an hyperosmotic solution, a cell shrinkage was observed. It was accompanied by a twofold increase in the activity of the Na+/K+/Cl- cotransport, which then catalyzed the net influx of K+. In spite of this increased activity, no cell swelling could be measured. Incubation of the cells in an iso-osmotic medium deprived of either Na+, K+ or Cl- also produced cell shrinkage. Large activations (up to tenfold) of the Na+/K+/Cl- cotransport together with a cell swelling back to the normal volume were observed upon returning ion-deprived C6 cells to a physiological solution. This cell swelling was completely prevented in the presence of bumetanide. It is concluded that the Na+/K+/Cl- cotransport system is one of the transport systems involved in volume regulation of glial cells. The system can either be physiologically quiescent or active depending on the conditions used. A distinct volume regulating mechanism is the Na+/H+ exchange system.     

Sodium-dependent taurocholate uptake by isolated rat hepatocytes occurs through an electrogenic mechanism

The uptake mechanism for the bile salt, taurocholate, by the liver cell is coupled to sodium but the stoichiometry is controversial. A one-to-one coupling ratio would result in electroneutral transport, whereas cotransport of more than one sodium ion with each taurocholate molecule cause an electrogenic response. To better define the uptake of this bile salt, we measured the effect of taurocholate on the membrane potential and resistance of isolated rat hepatocytes using conventional microelectrode electrophysiology. The addition of 20 microM taurocholate caused transient but significant depolarization accompanied by a significant decrease in membrane resistance. The electrical effect induced by taurocholate mimicked that induced by L-alanine (10 mM), the uptake of which is known to occur through an electrogenic, sodium-coupled mechanism. The sodium dependence of taurocholate-induced depolarization was further confirmed by: (1) replacing Na+ with choline +, and (2) preincubating cells with ouabain (2 mM) or with the Na+-ionophore, gramicidin (25 micrograms/ml); both suppressed the electrogenic response. Further, cholic acid, which inhibits sodium-coupled taurocholate uptake in hepatocytes, inhibited taurocholate evoked depolarization. These results support the hypothesis that sodium-coupled taurocholate uptake by isolated hepatocytes occurs through an electrogenic process which transports more than one Na+ with each taurocholate molecule.     

The hormone-sensitive hepatic Na+-pump. Evidence for regulation by diacylglycerol and tumor promoters

Ouabain-sensitive 86Rb+ uptake by isolated rat hepatocytes was studied to elucidate how Ca2+-mobilizing hormones stimulate the Na+-pump. Stimulation of this uptake was observed with concentrations of vasopressin ([8-arginine]vasopressin, AVP), angiotensin II, and norepinephrine which elicited Ca2+ mobilization and phosphorylase activation. These results suggested that changes in cytosolic Ca2+, mediated by inositol trisphosphate, might trigger sodium pump stimulation by AVP. However, in hepatocytes incubated in Ca2+-free Krebs-Henseleit buffer, Na+-pump activity was not altered over 15 min by either 1.5 mM EGTA or 1.5 mM Ca2+. Furthermore, incubation of cells in 5 mM EGTA for 15-30 min drastically impaired the ability of AVP to increase cytosolic Ca2+, but only modestly attenuated AVP-stimulated Na+-pump activity. Two tumor promoters, phorbol myristate acetate (PMA) and mezerein, stimulated Na+/K+-ATPase-mediated transport activity. Similarly, addition of synthetic diacylglycerols or of exogenous phospholipase C from Clostridium perfringens to increase endogenous diacylglycerol levels also resulted in a stimulation of the Na+-pump in the absence of changes in cytosolic or total cellular Ca2+ levels. Stimulation of the Na+-pump by the combination of maximal concentrations of PMA and AVP did not produce an additive response, and both agents displayed a transient time course, suggesting that the two agents share a common mechanism. Stimulation of the Na+-pump by AVP and PMA was not blocked by amiloride analogs which inhibit Na+/H+ exchange, but these compounds blocked the action of insulin. These data suggest that the elevated Na+/K+-ATPase-mediated transport activity observed in hepatocytes following exposure to Ca2+-mobilizing hormones is a consequence of stimulated diacylglycerol formation and may involve protein kinase C.     

Effect of ischemia-reperfusion on the renal brush-border membrane sodium-dependent phosphate cotransporter NaPi-2

To understand the mechanisms underlying ischemia-reperfusion-induced renal proximal tubule damage, we analyzed the expression of the Na+-dependent phosphate (Na+/Pi) cotransporter NaPi-2 in brush border membranes (BBM) isolated from rats which had been subjected to 30 min renal ischemia and 60 min reperfusion. Na+/Pi cotransport activities of the BBM vesicles were also determined. Ischemia caused a significant decrease (about 40%, P < 0.05) in all forms of NaPi-2 in the BBM, despite a significant increase (31+/-3%, P < 0.05) in the Na+/Pi cotransport activity. After reperfusion, both NaPi-2 expression and Na+/Pi cotransport activity returned to control levels. In contrast with Na+/Pi cotransport, ischemia significantly decreased Na+-dependent glucose cotransport but did not affect Na+-dependent proline cotransport. Reperfusion caused further decreases in both Na+/glucose (by 60%) and Na+/proline (by 33%) cotransport. Levels of NaPi-2 were more reduced in the BBM than in cortex homogenates, suggesting a relocalization of NaPi-2 as a result of ischemia. After reperfusion, NaPi-2 levels returned to control values in both BBM and homogenates. These data indicate that the NaPi-2 protein and BBM Na+/Pi cotransport activity respond uniquely to reversible renal ischemia and reperfusion, and thus may play an important role in maintaining and restoring the structure and function of the proximal tubule.     

Na+, K+ and Cl- transport in isolated small intestinal cells from guinea pig. Evidences for the existence of a second Na+ pump

Isolated small intestinal epithelial cells, after incubation at 4 degrees C for 30 min, reach ion concentrations (36 mM K+, 113 mM Na+ and 110 mM Cl-) very similar to those of the incubation medium. Upon rewarming to 37 degrees C, cells are able to extrude Na+, Cl- and water and to gain K+. Na+ extrusion is performed by two active mechanisms. The first mechanism, transporting Na+ by exchanging it for K+, is inhibited by ouabain and is insensitive to ethacrynic acid. It is the classical Na+ pump. The second mechanism transports Na+ with Cl- and water, is insensitive to ouabain but is inhibited by ethacrynic acid. Both mechanisms are inhibited by dinitrophenol and anoxia. The second Na+ extruding mechanism could be the Na+/K+/2Cl- cotransport system. However, this possibility can be ruled out because the force driving cotransport would work inwards, and because Na+ extrusion with water loss continues after substitution of Cl- by NO3-. We propose that enterocytes have a second Na+ pump, similar to that proposed in proximal tubular cells.     

Sodium-amino acid cotransport by type II alveolar epithelial cells

Type II alveolar epithelial cell monolayers have been shown to actively transport sodium (Na+). Coupling to amino acid uptake could be an important mechanism for Na+ entry into these cells. This study demonstrates the presence of such a coupled cotransport mechanism in the plasma membrane of isolated type II cells by use of the nonmetabolizable amino acid analogue alpha-methylaminoisobutyric acid (MeAIB). Transport of MeAIB in 137 mM Na+ is saturable, with the uptake constant (Vmax) equaling 13.9 pmol X mg prot-1 X s-1 and the Michaelis-Menten constant (Km) equaling 0.13 mM. In the presence of Na+, MeAIB is accumulated against a concentration gradient. MeAIB uptake in the absence of Na+ is linear with MeAIB concentration, as expected for simple diffusion. The Hill coefficient for Na+-MeAIB cotransport is 1.11, suggesting a 1:1 stoichiometry. Proline inhibits Na+-MeAIB cotransport, with Ki equaling 0.5 mM. These findings suggest that Na+-amino acid cotransport may be an important pathway for Na+ (and/or amino acid) uptake into type II alveolar epithelial cells.     

Bumetanide-sensitive potassium transport and volume regulation in turkey erythrocytes

The bumetanide-sensitive (K+ + Na+ + 2Cl-)-cotransport system in turkey erythrocytes is activated by either of two treatments: addition of epinephrine or an increase in osmolarity. At elevated (20 mM) K+ concentration, cotransport activity induced by epinephrine slowly (within 90 min) declines to background level again. This time-dependent inactivation has been linked to bumetanide-sensitive cell swelling. We have compared both the initial rate of cotransport activity and its time dependence after induction by either epinephrine, increased osmolarity or a combination of the two treatments. As a measure of cotransport activity we took the bumetanide-sensitive fraction of 86Rb+ influx. Immediately after activation, several kinetic characteristics of this flux (Vmax; Km towards K+; Ki towards bumetanide; pH profile) were identical in cells activated by either treatment. By contrast, cotransport activated by hypertonicity was significantly more resistant towards subsequent inactivation. We show this to be due to the increase in intracellular ion concentrations brought about by hypertonic cell shrinkage. This tended to reverse the driving force for cotransport, and thereby prevented the bumetanide-sensitive swelling associated with inactivation. Our data support the notion that cell volume plays a key role both in the activation and in the time-dependent inactivation of bumetanide-sensitive transport.     

Characterisation of the potassium influx in rat erythrocytes.

In the rat erythrocyte membrane five different transport pathways for K+ are present. In addition to the well characterised K+ transport via the Na+ pump, the Na,K,Cl cotransport and the Ca(2+)-activated K+ channel, there are a K,Cl cotransport and a residual (leak) K+ transport. The K,Cl cotransport is already present under physiological conditions, and can be stimulated by N-ethylmaleimide treatment but not by a cell volume increase. A low ionic strength stimulated increase of the residual K+ influx can be demonstrated in rat erythrocytes after suppressing the K,Cl cotransport pathway. Between 11 and 19 weeks of age, rats show significant differences in all transport pathways of the erythrocyte potassium influx. Using influx data from individual rats a significant correlation between the total K+ influx and the ouabain-sensitive K+ influx has been found. Maintaining the rats on a diet poor in essential fatty acids leads to a significant change of the linoleic acid content of the erythrocyte membrane phospholipids. However, no significant effect on the various K+ transport pathways has been found. An analysis of the fatty acid composition of the erythrocyte membrane phospholipids showed significant correlations between the content of oleic acid, and arachidonic acid, and the ouabain-sensitive K+ influx (as well as the total K+ influx).