Lanthanum-induced alterations of cellular electrolytes in Ehrlich ascites tumor cells: a new view

We have shown previously that Ehrlich ascites tumor cells maintained at room temperature under an oxygen atmosphere lose Na⁺, K⁺ and Cl^? isosmotically when exposed to La⁺⁺⁺ (0.1 to 1.0 mM). Concomitant with these changes there is an increase in the recorded membrane potential (increasing intracellular negativity). The present studies further characterize the effect of La⁺⁺⁺ on electrolyte distribution. Ehrlich ascites tumor cells were maintained at 0.5° C to permit Na⁺ gain and K⁺ loss. The addition of 1 mM La⁺⁺⁺ to low temperature cells induces rapid loss of Na⁺, K⁺ and Cl^?. This net loss of cellular electrolytes occurs even in cells depleted of ATP content using 2-deoxyglucose (5 mM) and rotenone (10^?6 M ). Analysis of the appearance of tracer ²²Na in the environment of cells preloaded with the radioisotope shows that La⁺⁺⁺-induced changes in membrane permeability or in active ion transport mechanisms are not responsible for the dramatic loss of electrolytes from experimental cells. The electrolyte loss occurs only when the cells are resuspended mechanically during the washing procedure used to prepare the cells for electrolyte determination. We conclude that the results of La⁺⁺⁺ interaction with Ehrlich ascites tumor cells are twofold. As we have previously reported, La⁺⁺⁺ stabilizes and causes a hyperpolarization of the membrane potential. Secondly, La⁺⁺⁺ predisposes the cell membrane to become highly permeable when subjected to mechanical stress.     

Ca2+ displacement by polymyxin B from sarcolemma isolated by ‘gas dissection’ from cultured neonatal rat myocardial cells

Amphiphilic, cationic Polymyxin B is shown to displace Ca²⁺ from ‘gas dissected’ cardiac sarcolemma in a dose-dependent, saturable fashion. The Ca²⁺ displacement is only partially reversible, 57% and 63%, in the presence of 1 mM or 10 mM Ca²⁺, respectively. Total Ca²⁺ displaced by a non-specific cationic probe, lanthanum (La³⁺), at maximal displacing concentration (1 mM) was $\text{0.172 ± 0.02}\text{nmol/μg}$ membrane protein. At 0.1 mM, Polymyxin B displaced 42% of the total La³⁺-displaceable Ca²⁺ or $\text{0.072 ± 0.01}\text{nmol/μg}$ protein. 5 mM Polymyxin displaced Ca²⁺ in amounts equal to those displaced by 1 mM La³⁺. Pretreatment of the membranes with neuraminidase (removal of sialic acid) and protease leads to a decrease in La³⁺-displaceable Ca²⁺ but to an increase in the fraction displaced by 0.1 mM Polymyxin from 42% to 54%. Phospholipase D (cabbage) treatment significantly increased the La³⁺-displaceable Ca²⁺ to $\text{0.227 ± 0.02}\text{nmol/μg}$ protein ($\text{P < 0.05}$), a gain of 0.055 nmol. All of this phospholipid specific increment in bound Ca²⁺ was displaced by 0.1 mM Polymyxin B. The results suggest that Polymyxin B will be useful as a probe for phospholipid Ca²⁺-binding sites in natural membranes.     

Membrane potential and sodium flux in neuroblastoma X glioma hybrid cells: Effects of amiloride and serum

The Na⁺ uptake into neuroblastoma x glioma hybrid cells was measured in Hepes-buffered EMEM containing 10% calf serum and 5 mM ouabain in the presence and absence of amiloride (1.0 mM). Amiloride was found to markedly inhibit net Na⁺ influx (by approximately 50%). Examination of the effect of amiloride on net Na⁺ influx in the absence of calf serum revealed that a significant amiloride-sensitive Na⁺ influx remains even under serum-deprived conditions, although the degree of amiloride inhibition (35%) is substantially lower than that found in the presence of serum. The amiloride-insensitive portion of Na⁺ influx was found to be independent of serum effects. Estimation of resting membrane potential was made by measurement of the steady state distribution of the lipophilic cation, TPP⁺, in the presence and absence of amiloride. A large, immediate increase in TPP⁺ uptake, indicative of a membrane hyperpolarization, was seen upon addition of amiloride. Determination of the effect of amiloride on resting membrane potential of serum-deprived cells showed that cells are hyperpolarized to a greater extent in the presence than in the absense of amiloride, and that serum exerts a depolarizing effect on the cells. Thus, serum-stimulation of Na⁺ influx results in a depolarization of resting membrane potential, while amiloride inhibition of Na⁺ influx causes a hyperpolarization. These data strongly suggest that NG108-15 cells possess an electrogenic Na⁺ influx pathway that is sensitive to amiloride inhibition and enhanced by serum.     

The influence of cellular amino acids and the Na+: K+ pump on the membrane potential of the Ehrlich ascites tumor cell

The membrane potential of the Ehrlich ascites tumor cell was shown to be influenced by its amino acid content and the activity of the Na⁺: K⁺ pump. The membrane potential (monitored by the fluorescent dye, 3,3′-dipropylthiodicarbocyanine iodide) varied with the size of the endogenous amino acid pool and with the concentration of accumulated 2-aminoisobutyrate. When cellular amino acid content was high, the cells were hyperpolarized; as the pool declined in size, the cells were depolarized. The hyperpolarization seen with cellular amino acid required cellular Na⁺ but not cellular ATP. Na⁺ efflux was more rapid from cells containing 2-aminoisobutyrate than from cells low in internal amino acids. These observations indicate that the hyperpolarization recorded in cells with high cellular amino acid content resulted from the electrogenic co-efflux of Na⁺ and amino acids.Cellular ATP levels were found to decline rapidly in the presence of the dye and hence the influence of the pump was seen only if glucose was added to the cells. When the cells contained normal Na⁺ (approx. 30 mM), the Na⁺: K⁺ pump was shown to have little effect on the membrane potential (the addition of ouabain had little effect on the potential). When cellular Na⁺ was raised to 60 mM, the activity of the pump changed the membrane potential from the range ?25 to ?30 mV to ?44 to ?63 mV. This hyperpolarization required external K⁺ and was inhibited by ouabain.     

Intracellular compartmentation of Na+, K+ and Cl− in the Ehrlich ascites tumor cell: Correlation with the membrane potential

Summary The intracellular distribution of Na⁺, K⁺, Cl^– and water has been studied in the Ehrlich ascites tumor cell. Comparison of the ion and water contents of whole cells with those of cells exposed to La³⁺ and mechanical stress indicated that La³⁺ treatment results in selective damage to the cell membrane and permits evaluation of cytoplasmic and nuclear ion concentrations. The results show that Na⁺ is sequestered within the nucleus, while K⁺ and Cl^– are more highly concentrated in the cell cytoplasm. Reduction of the [Na⁺] of the incubation medium by replacement with K⁺ results in reduced cytoplasmic [Na⁺], increased [Cl^–] and no change in [K⁺]. Nuclear concentrations of these ions are virtually insensitive to the cation composition of the medium. Concomitant measurements of the membrane potential were made. The potential in control cells was –13.7 mV. Reduction of [Na⁺] in the medium caused significant depolarization. The measured potential is describable by the Cl^– equilibrium potential and can be accounted for in terms of cation distributions and permeabilities. The energetic implications of the intracellular compartmentation of ions are discussed.     

Role of calcium in the thyrotropin-releasing hormone-stimulated release of prolactin from pituitary cells in culture.

Thyrotropin-releasing hormone (TRH) or 50 mM K⁺ stimulated the acute release of prolactin from the GH₄C₁ strain of rat pituitary cells in culture. The enhanced release of prolactin was inhibited in a dose-related manner by the Ca⁺² antagonist Co⁺² (2.0 to 0.5 mM) as well as by the Ca⁺² chelator EGTA (1.0 mM). Co⁺² also reduced spontaneous basal prolactin release. There was partial reversal of the inhibitory effect of Co⁺² (2.0 mM) by Ca⁺² (2.0 mM) and complete reversal of the inhibitory effect of EGTA (1.0 mM) by Ca⁺² (2.0 mM). The enhanced release of prolactin stimulated by 50 mM K⁺ was maximal by 10–20 minutes in medium containing 0.67 to 0.74 mM Ca⁺². Na⁺ (50 mM) did not mimic the effect of high K⁺. We conclude that Ca⁺² is an essential cation in mediating the actions of high external K⁺ and TRH on the release of prolactin by GH₄C₁ cells.     

Phenylalanine uptake in isolated renal brush border vesicles

The uptake of l-phenylalanine into brush border microvilli vesicles and basolateral plasma membrane vesicles isolated from rat kidney cortex by differential centrifugation and free flow electrophoresis was investigated using filtration techniques.Brush border microvilli but not basolateral plasma membrane vesicles take up l-phenylalanine by an Na⁺-dependent, saturable transport system. The apparent affinity of the transport system for l-phenylalanine is 6.1 mM at 100 mM Na⁺ and for Na⁺ 13 mM at 1 mM l-phenylalanine. Reduction of the Na⁺ concentration reduces the apparent affinity of the transport system for l-phenylalanine but does not alter the maximum velocity.In the presence of an electrochemical potential difference for Na⁺ across the membrane (η_Na0 >η_Na1) the brush border microvilli accumulate transiently l-phenylalanine over the concentration in the incubation medium (overshoot phenomenon). This overshoot and the initial rate of uptake are markedly increased when the intravesicular space is rendered electrically more negative by membrane diffusion potentials induced by the use of highly permeant anions, of valinomycin in the presence of an outwardly directed K⁺ gradient and of carbonyl cyanide p-trifluoromethoxyphenylhydrazone in the presence of an outward-directed proton gradient.These results indicate that the entry of l-phenylalanine across the brush border membrane into the proximal tubular epithelial cells involves cotransport with Na⁺ and is dependent on the concentration difference of the amino acid, on the concentration difference of Na⁺ and on the electrical potential difference. The exit of l-phenylalanine across the basolateral plasma membranes is Na⁺-independent and probably involves facilitated diffusion.     

A possible involvement of cytoplasmic Ca2+ in sodium dependency of neurite outgrowth of rat pheochromocytoma PC12 cells

The effects of extracellular Na⁺, K⁺ and Cl^? on neurite outgrowth of PC12 pheochromocytoma cells were studied. Nerve growth factor (NGF)-induced neurite formation was inhibited upon substitution of choline chloride for NaCl under normal culture conditions. It was found that neurite formation increased proportionately with the concentration of Na⁺ in medium up to 150 mM. When PC12 cells were exposed to NGF in suspension culture followed by transfer to new dishes, they showed neurite extention in response to NGF in an RNA- and protein synthesis-independent manner. Under these conditions, neurite outgrowth occurred normally in 60–150 mM Na⁺, whereas it decreased significantly at lower concentrations of Na⁺. Na⁺ dependency was also observed for cyclic AMP-mediated neurite formation of PC12 cells. In contrast, neurite outgrowth was independent of K⁺ in the range 5–106 mM, suggesting that membrane potential did not play a role in this process. No alterations were observed in neurite outgrowth with Cl^? replaced by NO^?₃, SO^2?₄, or 2-hydroxyethanesulfonate. Thus, extracellular Na⁺ plays a role in controlling neurite formation of these cells. An attempt was made to relate this effect to a decrease in cytoplasmic Ca²⁺ concentration monitored by a fluorescent dye sensitive to Ca²⁺.     

Characterization of glutamate transport system in hydrophobic protein (H protein) of Bacillus subtilis

Hydrophobic protein (H protein) was isolated from membrane fractions of Bacillus subtilis and constituted into artificial membrane vesicles with lipid of B. substilis. Glutamate was accumulated into the vesicle when a Na⁺ gradient across the membrane was imposed. The maximum effect of Na⁺ on the transport was achieved at a concentration of about 40 mM, while the apparent K_m for Na⁺ was approximately 8 mM. On the other hand, K_m for glutamate in the presence of 50 mM Na⁺ was about 8 μM. Increasing the concentration of Na⁺ resulted in a decrease in K_m for glutamate, maximum velocity was not affected. The transport was sensitive to monensin (Na⁺ ionophore).Glutamate was also accumulated when pH gradient (interior alkaline) across the membrane was imposed or a membrane potential was induced with K⁺-diffusion potential. The pH gradient-driven glutamate transport was sensitive to carbonylcyanide m-chlorophenylhydrazone and the apparent K_m for glutamate was approximately 25 μM.These results indicate that two kinds of glutamate transport system were present in H protein: one is Na⁺ dependent and the other is H⁺ dependent.     

Salt tolerance inNitellopsis obtusa

Summary The mechanism of salt tolerance was studied using isolated internodal cells of the charophyteNitellopsis obtusa grown in fresh water. When 100 mM NaCl was added to artificial pond water (0.1 mM each of NaCl, KC1, CaCl₂), no cell survived for more than one day. Within the first 30 minutes, membrane potential (E_m) depolarized and membrane resistance (R_m) decreased markedly. Simultaneously, cytoplasmic Na⁺ increased and K⁺ decreased greatly. At steady state the increase in Na⁺ content was roughly equal to the decrease in K⁺ content. The Cl^– content of the cytoplasm did not change. These results suggest that Na⁺ enters the cytoplasm by exchange with cytoplasmic K⁺. Both the entry of Na⁺ and the exit of K⁺ are assumed to be passive and the latter being caused by membrane depolarization. Vacuolar K⁺, Na⁺, and Cl^– remained virtually constant, suggesting that rapid influx of Na⁺ from the cytoplasm did not occur.In 100 mM NaCl containing 10 mM CaCl₂, membrane depolarization, membrane resistance decrease and changes in cytoplasmic [Na⁺] and [K⁺] did not occur, and cells survived for many days. When cells treated with 100 mM NaCl were transferred within 1 hour to 100 mM NaCl containing 10 mM CaCl₂, Em decreased, Rm increased, cytoplasmic Na⁺ and K⁺ returned to their initial levels, and cells survived. Two possible mechanisms for the role of Ca²⁺ in salt tolerance inNitellopsis are discussed; one a reduction in plasmalemma permeability to Na⁺ and the other a stimulation of active Na⁺-extrusion.     

Sodium ion-dependent hydrogen production in Acidaminococcus fermentans

Acidaminococcus fermentans is able to ferment glutamate to ammonia, CO₂, acetate, butyrate, and H₂. The molecular hydrogen (approximately 10 kPa; E′ = –385 mV) stems from NADH generated in the 3-hydroxybutyryl-CoA dehydrogenase reaction (E°′ = –240 mV) of the hydroxyglutarate pathway. In contrast to growing cells, which require at least 5 mM Na⁺, a Na⁺-dependence of the H₂-formation was observed with washed cells. Whereas the optimal glutamate fermentation rate was achieved already at 1 mM Na⁺, H₂ formation commenced only at > 10 mM Na⁺ and reached maximum rates at 100 mM Na⁺. The acetate/butyrate ratio thereby increased from 2.0 at 1 mM Na⁺ to 3.0 at 100 mM Na⁺. A hydrogenase and an NADH dehydrogenase, both of which were detected in membrane fractions, are components of a model in which electrons, generated by NADH oxidation inside of the cytoplasmic membrane, reduce protons outside of the cytoplasmic membrane. The entire process can be driven by decarboxylation of glutaconyl-CoA, which consumes the protons released by NADH oxidation inside the cell. Hydrogen production commences exactly at those Na⁺ concentrations at which the electrogenic H⁺/Na⁺-antiporter glutaconyl-CoA decarboxylase is converted into a Na⁺/Na⁺ exchanger. Received: 3 May 1996 / Accepted: 12 August 1996     

Sodium transport in erythrocytes of the mollusc Anadara broughtonii: Evidence for inhibition by quinine

Sodium transport through the molluscan erythrocyte membrane was examined using ²²Na as a tracer. Incubation of the red cells in standard saline resulted in a rapid ²²Na uptake reaching steady state concentration (about 21.5 mmol/l cells) in the first 60 min. A similar pattern in the time course of ²²Na uptake was seen in the erythrocytes incubated in mantle fluid. The average value of unidirectional Na⁺ influx, measured as a 5-min ²²Na uptake, was 7.76 ± 0.36 mmol/1 cells/5 min or 93 ± 4.3 mmol/1 cells/hr. The initial rate of Na⁺ influx increased in a saturable fashion as a function of external Na⁺ concentration with apparent AT., of 380±12mM and V_max of 14.3 ± 2.4 mmol/1 cells/5 min. Amiloride (1 mM), furosemide (1 mM), and DIDS (0.1 mM) had no effect on either initial Na⁺ influx (5 min ²²Na uptake) or equilibrium Na⁺ concentration (60 min and 120min ²²Na uptake) in the molluscan red cells exposed to standard saline. Quinine (1 mM) caused a significant fall in the initial Na⁺ influx (by 48%) and in 60-min ²²Na uptake (by 32%) as compared with control levels. In the presence of 0.1 mM ouabain, ²²Na uptake into the red cells was enhanced by an average 27% and 44% during 60 min and 120 min of cell incubation, respectively. The ouabain-sensitive Na⁺ accumulation in the red cells reflected a contribution of the Na, K-pump to Na⁺ transport and the mean value was 5.6 ± 1.0 mmol/1 cells/hr.     

A novel method for measuring intracellular pH and potassium concentration

The concentration of Na⁺and K⁺ and the pH in the cytoplasm of Lettré cells was measured by monitoring the net flux of H⁺, Na⁺, or K⁺ across the plasma membrane which had been rendered permeable to these ions by the action of Sendal virus. Ion flux was measured directly by analysis of cell composition, or indirectly by observing the change in membrane potential of cells treated with a specific ionophore. Cytoplasmic concentrations of cations were obtained by establishing the concentration of the cation in the medium at which addition of Sendai virus causes no change in cytoplasmic cation content. The value of Lettré-cell pH was confirmed by direct measurement employing 3tp nuclear magnetic resonance, and the values of Na⁺ and K⁺ concentration were confirmed by analysis of cell cation and water content. Lettré cells suspended at 32°C in Hepes-buffered saline at pH 7.3 maintain a cytosolic pH of 7.0 and contain 30 mM Na⁺ and 80 mM K⁺.     

Feedback inhibition of sodium uptake in K+-depolarized toad urinary bladders

Ouabain-blocked toad urinary bladders were maintained in Na⁺-free mucosal solutions, and a depolarizing solution of high K⁺ activity containing only 5 mM Na⁺ on the serosal side. Exposure to mucosal sodium (20 mM activity) evoked a transient amiloride-blockable inward current, which decayed to near zero within one hour. The apical sodium conductance increased in the initial phase of the current decay and decreased in the second phase. The conductance decrease required Ca²⁺ to be present on the serosal side and was more rapid when the mucosal Na⁺ activity was higher. At 20 mM mucosal Na⁺ and 3 mM serosal Ca²⁺ the initial (maximal) rate of inhibition amounted to 20% in 10 min. The conductance decrease could be accelerated by raising the serosal Ca²⁺ activity to 10 mM. The inhibition reversed on lowering the serosal Ca²⁺ to 3 μM and, in addition, the mucosal Na⁺ to zero. Exposure of the mucosal surface to the ionophore nystatin abolished the Ca²⁺ sensitivity of the transcellular conductance, showing that the Ca²⁺-sensitive conductance resides in the apical membrane. The data imply that in the K⁺-depolarized epithelia, cellular Ca²⁺, taken up from the serosal medium by means of a Na⁺-Ca²⁺ antiport, cause feedback inhibition by blockage of apical Na⁺ channels. However, the rate of inhibition is small, such that this regulatory mechanism will have little effect at 1 mM serosal Ca²⁺ and less than 20 mM cellular Na⁺.     

Na+ transport by human placental brush border membranes: Are there several mechanisms?

Na⁺ transport was evaluated in brush border membrane vesicles isolated from the human placental villous tissue. Na⁺ uptake was assayed by the rapid filtration technique in the presence and the absence of an uphill pH gradient. Amiloride strongly decreased Na⁺ uptake whether a pH gradient was present or not. In pH gradient conditions (pH 7.5 in and 9.0 out), 1 mM amiloride decreased the 10 mM Na⁺ uptake by 84%. In the absence of pH gradient (pH 7.5 in and out), Na⁺ uptake was lower but still sensitive to amiloride. The Lineweaver-Burk plot of Na⁺ uptake consistently showed a single kinetics. Increasing the pH gradient decreased Km values of the amiloride-sensitive Na⁺ uptake, leaving the Vmax unchanged. In the absence of a pH gradient, the amiloride sensitive Na⁺ transport was maximal at pH 7.5. Here again, a single kinetics was observed, and pH influenced exclusively the Km of Na⁺. Since ethylisopropylamiloride, the specific Na/H exchanger inhibitor mimicked the effects of amiloride, decreasing by 98% the 10 mM Na⁺ uptake, whereas benzamil, the Na⁺ channel blocker, had no effect, it was concluded that the amiloride sensitive Na⁺ uptake was predominantly or exclusively due to a Na⁺-H⁺ exchanger activity. K⁺ in trans-position significantly decreased the amiloride sensitive uptake. In contrast, the presence of the cation in cis-position had no effect. The amiloride resistant Na⁺ transport was neither influenced by pH, nor saturable. Incubation of the placental tissue with 100 μM or 1 mM dibutyryl cAMP, 0.1 or 1 μM phorbol myristate acetate, 10⁻⁷ M insulin, 10⁻¹⁰ M angiotensin II, or 10⁻⁸ M human parathyroid hormone (PTH) did not influence Na⁺ transport by subsequently prepared brush border membranes. Finally, we failed to demonstrate any Na⁺-H⁺ exchange activity in the basal plasma membrane. These results indicate that (1) in the absence of co-substrates such as phosphate and aminoacids, the Na⁺-H⁺ exchange is probably the unique mechanism of Na⁺ transport by the placental brush border membrane, (2) the placental isoform of the exchanger is not regulated by PTH, angiotensin, nor insulin and, therefore, is different from the isoform present in the renal brush border membrane, and (3) there is no exchanger activity in the basal plasma membrane. © 1996 Wiley-Liss, Inc.     

Amiloride blocks cell-free protein synthesis at levels attained inside cultured rat hepatocytes

Amiloride, a passive Na⁺ influx inhibitor, lowers initial rates and plateau levels of [³⁵S]met uptake into proteins in cell-free rabbit reticulocyte lysates (ID₅₀∽0.4 mM). Isolated hepatocytes take up amiloride through a saturable (K_m∽0.02 mM; V_max∽1.43 nmol/ 10⁶ cells/min) Na⁺-dependent process. Similar temperature dependent uptake occurs in cultured hepatocyte monolayers. In chemically defined media, under growth reinitiation conditions, amiloride lowers overall rates of cellular protein and albumin synthesis (ID₅₀∽0.4 and ∽0.028 mM, respectively). Amiloride concentrations (0.02 mM) that half-maximally inhibit reinitiation of hepatocyte DNA synthesis reach, within 30 min, cellular levels (∽0.14 mM) that block reticulocyte lysate protein synthesis by 25%. These findings complicate interpretations, from studies in many eukaryotic systems, of cause and effect between mitogen-activated membrane Na⁺ influxes and the reinitiation of DNA synthesis.     

The binding of phloridzin to the isolated luminal membrane of the renal proximal tubule

The binding of [³H]ploridzin by isolated luminal membranes of the rabbit proximal tubule and by slices of rabbit kidney cortex was studied.Kinetic analyses of the relationship between the concentration of phloridizin in the incubation medium and the binding of phloridzin to the membrane indicated two distinct classes of receptors sites. One class, comprising high affinity sites, reached saturation at 20–25 μM phloridzin, had a K(phloridzin) of 8 μM, and 8·10⁺² nmoles interacted with 1 mg of brush border protein. The other class, comprising low affinity sites, had a K(phloridzin) of 2.5 mM, and the number of binding sites was 1.25 nmoles/mg Na⁺ was required for the binding of phloridzin at the high affinity sites. Na⁺ decreased the apparent K_i for phloridzin; the apparent V of binding was not altered. Binding at the low affinity sites was independent of Na⁺. Ca²⁺ was necessary for maximal binding at the high affinity sites. Binding of phloridzin at high affinity sites was more sensitive to N-ethylmalcimide and mersalyl than was binding at low affinity sites. Binding at high affinity sites, but not at low affinity sites, was temperature dependent.d-Glucose was a competitive inhibitor of the high affinity binding of phloridzin. The apparent K₁ was 1 mM. D-Glucoe inhibited non-competitively at the low affinity sites. l-Glucose had no influence on phloridzin binding. Phloretin was a competitive inhibitor of high affinity phloridzin binding with an apparent K_i of 16 μM. Phloretin inhibited low affinity bindings of phloridizin non-competitively. Binding of phloridzin at high affinity sites was completely reversible. Binding at low affinity sites was only partially reversed. Phloridzin bound at high affinity sites on the brush border was displaced by phloridzin and phloretin but not by d-glucose.The mechanism of the high affinity binding of phloridzin was distinguished from that of the initial interaction of d-glucose with the membrane. Binding of phloridzin required Na⁺, whereas the interaction of d-glucose with the membranes had a prominent Na⁺-independent component.Intact renal cells in cortical slices accumulated phloridzin. The uptake did not saturate, was Na⁺ independent, and was not competitively inhibited by sugars. These characteristics resemble those for the low affinity binding of phloridzin by isolated membranes. It is suggested that low affinity binding may represent an initial binding followed by uptake of the glycoside into membrane vesicles.     

Involvement of cation channels and NH4+-sensitive K+ transporters in Na+ uptake by cowpea roots under salinity

Na⁺ accumulation was investigated in the roots of 11-d-old cowpea [Vigna unguiculata (L.) Walp.] plants. The relative contribution of different membrane transporters on Na⁺ uptake was estimated by applying Ca²⁺, K⁺, NH₄ ⁺, and pharmacological inhibitors. Na⁺ accumulation into the root symplast was decreased by half in the presence of 1 mM Ca²⁺ and it was almost abolished by 100 mM K⁺. The inhibitory effect of external NH⁴⁺ on Na⁺ accumulation was more pronounced in the roots of NH₄ ⁺-free growing plants. Na⁺ accumulation was reduced about 73 % by 0.1 mM flufenamate and it was almost blocked by 2 mM quinine. In addition, 20 mM tetraethylammonium and 1.0 mM Cs⁺ decreased Na⁺ accumulation by 28 and 30 %, respectively. These results evidenced that low-affinity Na⁺ uptake by cowpea roots depends on Ca²⁺-sensitive and Ca²⁺-insensitive pathways. The Ca²⁺-sensitive pathway is probably mediated by nonselective cation channels and the Ca²⁺-insensitive one may involve K⁺ channels and to a lesser extent NH₄ ⁺-sensitive K⁺ transporters.     

Mechanism and Role of Divalent Cation Binding of Bacteriorhodopsin

Several observations have already suggested that the carboxyl groups are involved in the association of divalent cations with bacteriorhodopsin (Chang et al., 1985). Here we show that at least part of the protons released from deionized purple membrane (`blue membrane') samples when salt is added are from carboxyl groups. We find that the apparent pK of magnesium binding to purple membrane in the presence of 0.5 mM buffer is 5.85. We suggest this is the pK of the carboxyl groups shifted from their usual pK because of the proton concentrating effect of the large negative surface potential of the purple membrane. Divalent cations may interact with negatively charged sites on the surface of purple membrane through the surface potential and/or through binding either by individual ligands or by conformation-dependent chelation. We find that divalent cations can be released from purple membrane by raising the temperature. Moreover, purple membrane binds only about half as many divalent cations after bleaching. Neither of these operations is expected to decrease the surface potential and thus these experiments suggest that some specific conformation in purple membrane is essential for the binding of a substantial fraction of the divalent cations. Divalent cations in purple membrane can be replaced by monovalent, (Na⁺ and K⁺), or trivalent, (La⁺⁺⁺) cations. Flash photolysis measurements show that the amplitude of the photointermediate, O, is affected by the replacement of the divalent cations by other ions, especially by La⁺⁺⁺. The kinetics of the M photointermediate and light-induced H⁺ uptake are not affected by Na⁺ and K⁺, but they are drastically lengthened by La⁺⁺⁺ substitution, especially at alkaline pHs. We suggest that the surface charge density and thus the surface potential is controlled by divalent cation binding. Removal of the cations (to make deionized blue membrane) or replacement of them (e.g. La⁺⁺⁺-purple membrane) changes the surface potential and hence the proton concentration near the membrane surface. An increase in local proton concentration could cause the protonation of critical carboxyl groups, for example the counter-ion to the protonated Schiff's base, causing the red shift associated with the formation of both deionized and acid blue membrane. Similar explanations based on regulation of the surface proton concentration can explain many other effects associated with the association of different cations with bacteriorhodopsin.     

Thallium inhibition of ouabain-sensitive sodium transport and of the (Na+K)-ATPase in human erythrocytes

The influence of Tl⁺ on Na⁺ transport and on the ATPase activity in human erythrocytes was studied. 0.1–1.0 mM Tl⁺ added to a K⁺-free medium inhibited the ouabain-sensitive self-exchange of Na⁺ and activated both the ouabain-sensitive ²²Na outward transport and the transport related ATPase. 5–10 mM external Tl⁺ caused inhibition of the ouabain-sensitive ²²Na efflux as well as the (Na⁺ + Tl⁺)-ATPase. Competition between the internal Na⁺ and rapidly penetrating thallous ions at the inner Na⁺-specific binding sites of the erythrocyte membrane could account for the inhibitory effect of Tl⁺. An increase of the internal Na⁺ concentration in erythrocytes or in ghosts protected the system against the inhibitory effect of high concentration of Tl⁺. A protective effect of Na⁺ was also demonstrated on the (Na⁺ + Tl⁺)-ATPase of fragmented erythrocyte membranes studied at various Na⁺ and Tl⁺ concentrations.