Electrical Potentials and Na, K, and Cl Concentrations in the Vacuole and Cytoplasm of Nitella translucens

The potential differences across the tonoplast and plasmalemmamembranes have been measured in the single cells of Nitellatranslucens, the cells being immersed in an artificial pondwater (composition: NaCl _1.0 mM., KC1 _0.1 mM., CaCl₂, _0.1 mM.).The potential of the cytoplasm is –138 m V with respectto the bathing medium and –18 mV with respect to the vacuole.The concentrations of Na, K, and Cl have been measured in thetwo cell fractions. The concentrations in the flowing cytoplasmare: Na 14 mM., K 119 mM., and Cl 65 mM.; the vacuolar concentrationsare: Na 65 mM., K 75 mM.,and Cl 160 mM. The observed potential differences across the two membranesare compared with the Nernst potentials for all three ions.This analysis shows that all three ions are actively transportedat the plasmalemma: Na is pumped outwards while K and Cl arepumped inwards. At the tonoplast Na is pumped into the vacuolewhile K and Cl are close to electrochemical equilibrium. The inhibitor, ouabain, has no effect on the cell resting potential.     

Measurements of Electrical Potential Differences on Single Nephrons of the Perfused Necturus Kidney

Stable electrical potential differences can be measured by means of conventional glass microelectrodes across the cell membrane of renal tubule cells and across the epithelial wall of single tubules in the doubly perfused kidney of Necturus. These measurements have been carried out with amphibian Ringer's solution, and with solutions of altered ionic composition. The proximal tubule cell has been found to be electrically asymmetrical inasmuch as a smaller potential difference is maintained across the luminal cell membrane than across the peritubular cell boundary. The tubule lumen is always electrically negative with respect to the peritubular extracellular medium. Observations on the effectiveness of potassium ions in depolarizing single tubule cells indicate that the transmembrane potential is essentially an inverse function of the logarithm of the external potassium concentration. The behavior of the peritubular transmembrane potential resembles more closely an ideal potassium electrode than that of the luminal transmembrane potential. From these results, and the effects of various ionic substitutions on the electrical profile of the renal tubular epithelium, a thesis concerning the origin of the observed potential differences is presented. A sodium extrusion mechanism is considered to be located at the peritubular cell boundary, and reasons are given for the hypothesis that the electrical asymmetry across the proximal renal tubule cell could arise as a consequence of differences in the relative sodium and potassium permeability at the luminal and peritubular cell boundaries.     

Basolateral membrane Cl/HCO3 exchange in the rat proximal convoluted tubule. Na-dependent and -independent modes

To examine whether Cl-coupled HCO3 transport mechanisms were present on the basolateral membrane of the mammalian proximal tubule, cell pH was measured in the microperfused rat proximal convoluted tubule using the pH-sensitive, intracellularly trapped fluorescent dye (2',7')- bis(carboxyethyl)-(5,6)-carboxyfluorescein. Increasing the peritubular Cl concentration from 0 to 128.6 meq/liter caused cell pH to decrease from 7.34 +/- 0.04 to 7.21 +/- 0.04 (p less than 0.001). With more acid extracellular fluid (pH 6.62), a similar increase in the peritubular Cl concentration caused cell pH to decrease by a similar amount from 6.97 +/- 0.04 to 6.84 +/- 0.05 (p less than 0.001). This effect was blocked by 1 mM SITS. To examine the Na dependence of Cl/HCO3 exchange, the above studies were repeated in the absence of luminal and peritubular Na. In alkaline Na-free solutions, peritubular Cl addition caused cell pH to decrease from 7.57 +/- 0.06 to 7.53 +/- 0.06 (p less than 0.025); in acid Na-free solutions, peritubular Cl addition caused cell pH to decrease from 7.21 +/- 0.04 to 7.19 +/- 0.04 (p less than 0.05). The effect of Cl on cell pH was smaller in the absence of luminal and peritubular Na than in its presence. To examine whether the previously described Na/(HCO3)n greater than 1 cotransporter was coupled to or dependent on Cl, the effect of lowering the peritubular Na concentration from 147 to 25 meq/liter was examined in the absence of ambient Cl. Cell pH decreased from 7.28 +/- 0.03 to 7.08 +/- 0.03, a response similar to that observed previously in the presence of Cl. The results demonstrate that Cl/HCO3 (or Cl/OH) exchange is present on the basolateral membrane. Most of Cl/HCO3 exchange is dependent on the presence of Na and may be coupled to it. The previously described Na/(HCO3)n greater than 1 cotransporter is the major basolateral membrane pathway for the coupling of Na and HCO3 and is not coupled to Cl.     

Low micromolar concentrations of cadmium and mercury ions activate peritubular membrane K+ conductance in proximal tubular cells of frog kidney

The present study was designed to investigate the acute effects of extracellular low micromolar concentrations of cadmium and mercury ions on the peritubular cell membrane potential and its potassium selectivity in proximal tubular cells of the frog kidney. Peritubular exposure to 3 micromol/L Cd(2+) or 1 micromol/L Hg(2+) led to a rapid, sustained and reversible hyperpolarization of the peritubular cell membrane, paralleled by an increase in fractional K(+) conductance. Peritubular barium abolished hyperpolarization of the peritubular cell membrane to peritubular 3 micromol/L Cd(2+) or 1 micromol/L Hg(2+). Perfusing the lumen with 10 mmol/L l-alanine plus/minus 3 micromol/L Cd(2+) or Hg(2+) did not modify rapid depolarization and rate of slow repolarization of the peritubular cell membrane potential. In conclusion, low micromolar concentrations of Cd(2+) and Hg(2+) increase K(+) conductive pathway in the peritubular cell membrane and in this way can enhance ability of proximal renal tubular cells to maintain the driving force for electrogenic Na(+) and substrate reabsorption.     

Kinetic transport model for cellular regulation of pH and solute concentration in the renal proximal tubule.

An open circuit kinetic model was developed to calculate the time course of proximal tubule cell pH, solute concentrations, and volume in response to induced perturbations in luminal or peritubular fluid composition. Solute fluxes were calculated from electrokinetic equations containing terms for known carrier saturabilities, allosteric dependences, and ion coupling ratios. Apical and basolateral membrane potentials were determined iteratively from the requirements of cell electroneutrality and equal opposing transcellular and paracellular currents. The model converged to membrane potentials accurate to 0.05% in one to four iterations. Model variables included cell concentrations of Na, K, HCO3, glucose, pH (uniform CO2), volume, and apical and basolateral membrane potentials. The basic model contained passive apical membrane transport of Na/H, Na/glucose, H and K, basolateral transport of Na/3HCO3, K, H, and glucose, and paracellular transport of Na, K, Cl, and HCO3; apical H and basolateral 3Na/2K-ATPases were present. Apical Na/H and basolateral K transport were regulated allosterically by pH. Apical Na/H transport, basolateral Na/3HCO3 transport, and the 3Na/2K-ATPase were saturable. Model parameters were chosen from data in the rat proximal tubule. Model predictions for the magnitude and time course of cell pH, Na, and membrane potential in response to rapid changes in apical and peritubular Na and HCO3 were in excellent agreement with experiment. In addition, the model requires that there exist an apical H-ATPase, basolateral Na/3HCO3 transport saturable with HCO3, and electroneutral basolateral K transport.     

Role of ouabain and diuretics on sodium, potassium and chloride retention in perfused rat kidney

A novel in situ kidney perfusion technique is described in Sprague-Dawley rats. The procedure involves retrograde perfusion from the renal veins via the kidneys, and then through the renal arteries and dorsal aorta. Ouabain (15 mM) in perfusate increased Na retention by 92%, decreased K retention by 53% and produced no effect on Cl retention. Ethacrynic acid (1 mM) in perfusate decreased Na retention by 52%, increased K retention by 105% and decreased Cl retention by 27%. Furosemide (1.5 mM) in perfusate decreased Na retention by 52%, increased K retention by 47% and decreased Cl retention by 56%. The Na-K-ATPase pump localized at the peritubular side of the proximal tubule cell is ouabain sensitive and Mg dependent. An Na-K pump responsible for Na influx and K effux exists at the luminal side of the proximal tubule cell and is ethacrynic acid and furosemide sensitive.     

Kinetics of Na(+) transport in necturus proximal tubule

The dependence of proximal tubular sodium and fluid readsorption on the Na(+) concentration of the luminal and peritubular fluid was studied in the perfused necturus kidney. Fluid droplets, separated by oil from the tubular contents and identical in composition to the vascular perfusate, were introduced into proximal tubules, reaspirated, and analyzed for Na(+) and [(14)C]mannitol. In addition, fluid transport was measured in short-circuited fluid samples by observing the rate of change in length of the split droplets in the tubular lumen. Both reabsorptive fluid and calculated Na fluxes were simple, storable functions of the perfusate Na(+) concentration (K(m) = 35-39 mM/liter, V(max) = 1.37 control value). Intracellular Na(+), determined by tissue analysis, and open-circuit transepithelial electrical potential differences were also saturable functions of extracellular Na(+). In contrast, net reabsorptive fluid and Na(+) fluxes were linearly dependent on intracellular Na(+) and showed no saturation, even at sharply elevated cellular sodium concentrations. These concentrations were achieved by addition of amphotericin B to the luminal perfusate, a maneuver which increased the rate of Na(+) entry into the tubule cells and caused a proportionate rise in net Na(+) flux. It is concluded that active peritubular sodium transport in proximal tubule cells of necturus is normally unsaturated and remains so even after amphotericin-induced enhancement of luminal Na(+) entry. Transepithelial movement of NaCl may be described by a model with a saturable luminal entry step of Na(+) or NaCl into the cell and a second, unsaturated active transport step of Na(+) across the peritubular cell boundary.     

Ion Transport in Hydrodictyon africanum

The concentrations of K, Na, and Cl in the cytoplasm and vacuole, the tracer fluxes of these ions into and out of the cenocyte, and the electrical potential difference between bathing solution and vacuole and cytoplasm, have been measured in Hydrodictyon africanum. If the ions were acted on solely by passive electrochemical forces, a net efflux of K and Cl and a net influx of Na would be expected. Tracer fluxes indicate a net influx of K and Cl and efflux of Na in the light; these net fluxes are consequently active, with an obligate link to metabolism. The effects of darkness and low temperature indicate that most of the tracer K and Cl influx and Na efflux are linked to metabolism, while the corresponding tracer fluxes in the direction of the free energy gradient are not. Ouabain specifically inhibits the metabolically linked portions of tracer K influx and Na efflux. Alterations in the external K concentration have similar effects on metabolically mediated K influx and Na efflux. It would appear that K influx and Na efflux are linked, at least in the light.     

Cat Heart Muscle In Vitro : IV. Inhibition of transport in quiescent muscles

Cellular concentrations, [K]_i, [Na]_i, and [Cl]_i, and cell water contents were measured in vitro at 27°C in cat papillary muscles. Measurements were made with and without ouabain at varying concentrations of K and ouabain, at pH 5.2 and 9.0, in absence of O₂, and in NaCl-free solution. Large losses of cell K and increases of cell Na occurred in presence of ouabain, at 2–3°C, and in K-free medium. The dependence of inhibition of cation transport by ouabain on external K concentration, studied at constant initial [K]_i, was consistent with a competition between K and ouabain localized to the external face of the membrane. In NaCl-free sucrose solution [K]_i remained at its physiological value and was not affected by exposure to ouabain or low temperature, except when Ca was also omitted. Ouabain inhibition persisted at pH 9.0 and in Ca-poor media. Cells swelled and lost K at pH 5.2, and residual ouabain effect was small. At pH 9.0, or in absence of O₂, or in Ca-poor solutions cells became permeable to mannitol. The ion movements observed after inhibition of active transport are compatible either with a passive K distribution and a primary inhibition of Na extrusion or with inhibition of a coupled active transport of both K and Na.     

Na, Cl, and Water Transport by Rat Colon

Segments of the colon of anesthetized rats have been perfused in vivo with isotonic NaCl solutions and isotonic mixtures of NaCl and mannitol. Unidirectional and net fluxes of Na and Cl and the net fluxes of water and mannitol have been measured. Net water transport was found to depend directly on the rate of net Na transport. There was no water absorption from these isotonic solutions in the absence of net solute transport, indicating that water transport in the colon is entirely a passive process. At all NaCl concentrations studied, the lumen was found to be electrically negative to the surface of the colon by 5 to 15 mv. Na fluxes both into and out of the lumen were linear functions of NaCl concentration in the lumen. Net Na absorption from lumen to plasma has been observed to take place against an electrochemical potential gradient indicating that Na is actively transported. This active Na transport has been interpreted in terms of a carrier model system. Cl transport has been found to be due almost entirely to passive diffusion.     

Ion transport and permeability in the mouse egg

Sodium, potassium, and chloride unidirectional fluxes have been studied in the mature mouse egg. Their relationship to cell membrane potential and conductance has been investigated. Unidirectional Na efflux is composed of a ouabain sensitive component, presumably representing an active Na efflux, an external Na-dependent component and a diffusional component. The data indicate that the external Na-dependent component represents a Na:Na exchange mechanism. There also exists an ouabain-sensitive component of K influx. The stoichiometry of the ouabain-sensitive fluxes is approx. 2.7:1 (Na to K). From the diffusional components of Na and K flux, the membrane permeability to these cations has been estimated. P_Na and P_K are 1.2 × 10⁻⁷ cm sec⁻¹ and 0.8 × 10⁻⁷ cm sec⁻¹ respectively. These permeabilities, in conjunction with the internal exchangeable fractions of Na and K and the external concentrations, predict an egg membrane potential of −11 mV (inside negative). Microelectrode measurements yield an egg membrane potential of −14 ± 0.4 mV, indicating that the cell membrane potential is predominantly a result of the Na and K permeabilities and distributions. Internal exchangeable Cl is 67 ± 3 mM in standard medium, as determined from ³⁶Cl distribution. The chloride equilibrium potential is therefore −15 mV, which is not significantly different from the egg membrane potential. This suggests that Cl distributes passively across the egg membrane, reflecting the egg membrane potential. Hyperpolarization of the egg membrane potential to −27 ± 1.5 mV by reduction of external Na results in an exchangeable internal Cl of 49 ± 8 mM. This yields a Cl equilibrium potential of −24 mV, indicating that the Cl distribution shifts in the predicted manner upon a change in cell membrane potential. Tracer flux data indicate that Cl conductance comprises the bulk of the total membrane conductance with Na and K sharing the remainder in approximately equal amounts.     

Theoretical effects of transmembrane electroneutral exchange on membrane potential

Transmembrane electroneutral transport mechanisms [e.g., Na/H exchange, Cl/HCO3 exchange, (K + Cl) cotransport] have recently been identified in a wide variety of cell types. If these exchanges sum to give a net electroneutral Na/K exchange, they may hyperpolarize the membrane potential beyond the value calculated from the Mullins-Noda equation, provided the cell maintains steady state intracellular ionic concentrations. In extreme circumstances, the membrane potential could hyperpolarize beyond the potassium reversal potential. This effect is mediated by the electrogenic Na/K pump. If either Na or K exchanges electroneutrally against a third ion (e.g., Na/Ca exchange), then the exchange may depolarize the membrane potential.     

Sodium Extrusion and Potassium Uptake in Guinea Pig Kidney Cortex Slices

Slices from the cortex corticis of the guinea pig kidney were immersed in a chilled solution without K and then reimmersed in warmer solutions. The Na and K concentrations and the membrane potential V_m were then studied as a function of the Na and K concentrations of the reimmersion fluid. It was found that Na is extruded from the cells against a large electrochemical potential gradient. Q₁₀ for net Na outflux was ∼2.5. At bath K concentrations larger than 8 mM the behavior of K was largely passive. At the outset of reimmersion (V_m > E_K) K influx seemed secondary to Na extrusion. Na extrusion would promote K entrance, being limited and requiring the presence of K in the bathing fluid. At bath K concentrations below 8 mM, K influx was up an electrochemical potential gradient. Thus a parallel active K uptake is apparent. Q₁₀ for net K influx was ∼2.0. Dinitrophenol inhibited net Na outflux and net K influx, Q₁₀ became <1.1 for both fluxes. The ratio between these fluxes varied. Thus at the outset of reimmersion the net Na outflux to net K influx ratio was >1. After 8 minutes it was <1.     

Effect of catecholamines on electrolyte and water transport in the nephron of lower vertebrates

Micropuncture technique and electron microprobe analysis have been used to investigate the role of noradrenalin in ion and water balance in the renal tubules of the lamprey Lampetra fluviatilis and newt Triturus vulgaris. Noradrenalin decreased Na, K, and Ca concentrations in the proximal lumen of the lamprey increasing the value of (TF/P)in from 1.1 +/- 0.1 to 1.3 +/- 0.1 (p less than 0.001). Regitin blocked these effects. Noradrenalin perfusion of the peritubular capillaries in newt kidney increased ion and water reabsorption in the proximal segment of the nephron and resulted in differential changes of ion transport in the distal tubule, increasing reabsorption of Na, Cl and K and inhibiting that of Ca and Mg. The rate of glomerular filtration in the nephron remained practically unaffected. The data obtained reveal direct effect of noradrenalin on the renal tubular function in lower vertebrates, this effect being realized presumably via alpha-adrenoreceptors.     

Modeling epithelial cell homeostasis: Steady-state analysis

Critical to epithelial cell viability is the homeostasis of cell volume and composition during changes in transcellular transport. In this study, two previously developed mathematical models (principal cell of the collecting duct and proximal tubule cell) are approximated by their linearizations about a reference condition. This yields matrices which estimate cell volume, cell composition, and transcellular fluxes in response to perturbations of bath conditions and membrane transporter activity. These approximations are themselves extended with the inclusion of linear dependence of membrane transport coefficients on cell variables (e.g., volume, solute concentrations, or electrical potential). This provides cell models with variable permeabilities, which may be homeostatic, and which can be examined systematically: sequentially testing each membrane permeability and its controlling cell variable. In the proximal tubule approximation, volume-mediated increases in peritubular K—Cl or Na—3HCO₃ cotransport, and volume-mediated decreases in Na,K-ATPase activity are homeostatic; modulation of peritubular K permeability has little impact. In the principal cell model, volume homeostasis is afforded by volume-sensitive peritubular Na/H exchange or Cl⁻ conductance. Predictions from the linear analysis are confirmed in the full models. This approach yields a systematic examination of homeostasis in an epithelial model, and identifies candidate control parameters.     

Effects of changes in sodium electrochemical potential gradient on p-aminohippurate transport in newt kidney

1. The relation between p-aminohippurate uptake and the electrochemical potential gradient of Na+ (delta muNa+) across the peritubular membrane was examined in newt (Triturus pyrrhogaster) kidney. The delta muNa+ was modified by changing cellular Na+ concentration and/or lowering the electrical potential difference across the peritubular membrane (peritubular membrane potential) 2. Elevation of external K+ concentration or addition of alanine at 40 mM to the medium decreased the delta muNa+ mainly through the depolarization of the cells. Addition of 1 mM ouabain resulted in a decrease in the peritubular membrane potential and increase in cellular Na+ concentration, thus decrease in the delta muNa+. 3. p-Aminohippurate uptake decreased in proportion to the decrease in the delta muNa+ under all experimental conditions, indicating that the maintenance of the delta muNa+ is required for p-aminohippurate transport. 4. All three different experimental conditions, high medium K+ concentration, 40 mM alanine or 1 mM ouabain, increased the apparent Michaelis constant, Kt, without affecting the maximal uptake rate, V, for p-aminohippurate. These results suggests that the delta muNa+, largely the peritubular membrane potential, may affect the association and/or dissociation of p-aminohippurate and Na+ at both interfaces of the peritubular membrane of the proximal tubular cells.     

IONIC COMPOSITION OF THE CYTOPLASM OF NITELLA FLEXILIS

The K, Na and Cl concentrations of the chloroplast layer andthe flowing cytoplasm of Nitella flexilis have been determinedby applying an internal perfusion technique, which enabled usto avoid contamination of ions from the cell sap. K, Na andCl concentrations of the chloroplast layer are 110, 26 and 136mM and those of the flowing cytoplasm are 125, 5 and 36 mM respectively.The cell sap contains 80 mM K, 28 mM Na and 136 mM Cl. Althoughthere are some variations in these values among samples, theflowing cytoplasm is rich in K and poor in Cl and especiallyin Na. The exchange of K and Na across the tonoplasl occursfairly easily (half-time, a few hours), while that of Cl occursextremely slowly (half-time, a few days). ¹This work was supported by Research Grants from the Ministryof Education of Japan     

Effects of cumene hydroperoxide on cellular cation composition in frog kidney proximal tubular cells

Effects of cumene hydroperoxide were studied on the peritubular membrane potential and cellular cation composition in frog kidney proximal tubular cells. After perfusion of isolated frog kidneys for 30 min with 1.3x10(-4) mol l(-1) cumene hydroperoxide Ringer solution, the peritubular membrane potential gradually declined. The ouabain-like effects were demonstrated on cell Na and K activities after 1 h of perfusion with cumene hydroperoxide. The peritubular apparent transference number for potassium was decreased. Intracellular pH was not altered in the presence of cumene hydroperoxide. Intracellular free Ca(2+) concentration increased slowly and moderately. The concentration of the malondialdehyde in the kidney homogenates, measured as an index of lipid peroxidation, was increased. A previously observable effect of cumene hydroperoxide on the peritubular membrane potential was prevented by oxygen radical scavengers.     

3H]bumetanide binding to membranes isolated from dog kidney outer medulla. Relationship to the Na,K,Cl co-transport system

We have synthesized the radiolabeled "loop" diuretics [3H]bumetanide and [3H]benzmetanide (3-benzylamino-4-phenoxy-5-sulfamoylbenzoic acid) and have tested their potential as reversible labels of the Na,K,Cl co-transport system. These compounds bind with high affinity (Kd less than or equal to 30 nM, under optimal conditions) to membranes isolated from dog kidney; we found approximately 2 pmol/mg of sites in crude membranes from the outer medulla, and less than or equal to 0.5 pmol/mg in a similar preparation from kidney cortex. On sucrose gradient centrifugation, a peak of [3H]bumetanide binding activity (30 pmol/mg) is obtained at 37% (w/v) sucrose, distinct from the basolateral membranes in outer medulla and from brush borders in proximal tubule; our hypothesis is that this peak contains luminal membranes from the thick ascending limb of the loop of Henle. [3H]Bumetanide is displaced from its binding sites by various unlabeled loop diuretics at concentrations that have previously been shown to inhibit co-transport. Na+, K+, and Cl- (K1/2 congruent to 2, 1, and 1 mM, respectively) are required for [3H]bumetanide binding, and Cl- inhibits at higher concentrations. We interpret these data to demonstrate that the Na,K,Cl cotransport system is the site involved in [3H]bumetanide binding in kidney membranes.     

Ionic regulation of the unicellular green algadunaliella tertiolecta

Summary Different techniques were investigated in order to determine the Na, K and Cl concentrations ofDunaliella tertiolecta cells adapted to a large range of salinity (20 to 1640 mM NaCl). The K cell concentrations were 6 to 13 times higher than the K concentration of the external medium (11 mM). The The Na and Cl cell concentrations, on the other hand, were lower than in the external medium at all salinities tested. Considerable differences in the absolute values of Na and Cl were, however, found according to the technique employed. These results are interpreted in terms of compartmentalization of the cells (at least two compartments). It is postulated that the larger compartment regulates its ion concentrations, maintaining low Na and Cl and high K concentrations, whereas the second compartment equilibrates with the external medium. The cation permeability of the membrane limiting the regulating compartment is altered by the antibiotics nystatin and monensin. Incubation of cells in K-free medium leads to a decrease of K and to an increase of the cell Na, this effect being reversed by addition of KCl to the medium. A good correlation is found between gain of K and loss of Na, suggesting a stoichiometric exchange of these two ions. The magnitude of this apparent Na/K exchange increases as the salinity increases. The external K concentration necessary to mediate half-saturation of the Na/K exchange is a function of the NaCl concentration of the adaptation medium. This Na/K exchange is partially light-dependant and inhibited by cold, cyanide and DCCD. It is suggested that this mechanism helps in the regulation of the ionic composition ofDunaliella cells.