Quantitation of corneal endothelial potentials using a carbocyanine dye

The carbocyanine dye, diS-C₃-(5) was used to quantitate the plasma membrane potential of the bullfrog corneal endothelium. It was shown that valinomycin hyperpolarized the endothelial cell and that in the presence of the ionophore the membrane potential largely reflected the K⁺ equilibrium potential. Using calibration curves constructed by changing medium K⁺ concentration in the presence of valinomycin, and nigericin and ouabain to abolish ion gradients and electrogenic pump activity, the cell membrane potential was calculated to be 28.6 ± 4.2 mV. The major source of this potential was a K⁺ diffusion potential, and the membrane Na⁺ conductance reduced the cell potential to less than the apparent K⁺ equilibrium potential of 51.5 ± 5.1 mV. About 20% of the cell potential could be ascribed to the rheogenic (Na⁺+K⁺)-ATPase.     

Resistance properties of the diluting segment ofAmphiuma kidney: Influence of potassium adaptation

Summary Chronic exposure to high potassium stimulates K⁺-secretory mechanisms in the diluting segment of the amphibian kidney (K⁺ adaptation). Since K⁺ net flux depends critically on the passive cell membrane permeabilities for K⁺ ions, cable analysis and K⁺-concentration step changes were applied in this nephron segment to assess the individual resistances of the epithelium and the K⁺ conductance of the luminal cell membrane. Experiments were performed in the isolated, doubly-perfused kidney of both control and K⁺-adaptedAmphiuma. In control animals transepithelial resistance was 290±27 cm², which decreased significantly to 199±17 cm² after K⁺ adaptation. The resistance in parallel of the luminal and peritubular cell membrane decreased from a control value of 157±14 to 108±6 cm² after chronic K⁺ treatment. This was paralleled by a decrease of the ratio of the luminal to peritubular cell membrane resistance from 2.5±0.1 to 1.9±0.1, respectively. Estimation of the individual cell membrane resistances reveals that the combined resistance of the luminal and peritubular cell membrane is in the same order of magnitude as the paracellular shunt resistance in diluting segments of both control and K⁺-adapted animals. The luminal cell membrane is K⁺ selective under both conditions, but the absolute luminal K⁺ conductance increases by some 60% with K⁺ adaptation. This leads to an increased back-leak of K⁺ from cell to lumen and may explain stimulated K⁺ net secretion found after chronic K⁺ loading.     

X-ray microanalysis of elements in frozen-hydrated sections of an electrogenic K+ transport system: The posterior midgut of tobacco hornworm (Manduca sexta) in vivo andin vitro

Summary The lepidopteran midgut is a model for the oxygendependent, electrogenic K⁺ transport found in both alimentary and sensory tissues of many economically important insects. Structural and biochemical evidence places the K⁺ pump on the portasome-studded apical plasma membrane which borders the extracellular goblet cavity. However, electrochemical evidence implies that the goblet cell K⁺ concentration is less than 50mm. We used electron probe X-ray microanalysis of frozenhydrated cryosections to measure the concentration of Na, Mg, P, S, Cl, K, Ca and H₂O in several subcellular sites in the larval midgut ofManduca sexta under several experimental regimes. Na is undetectable at any site. K is at least 100mm in the cytoplasm of all cells. Typicalin vivo values (mm) for K were: blood, 25; goblet and columnar cytoplasm, 120; goblet cavity, 190; and gut lumen, 180. The high K concentration in the apically located goblet cavity declined by 100mm under anoxia. Both cavity and gut fluid are Cl deficient, but fixed negative charges may be present in the cavity. We conclude that the K⁺ pump is sited on the goblet cell apical membrane and that K⁺ follows a nonmixing pathway via only part of the goblet cell cytoplasm. The cavity appears to be electrically isolated in alimentary tissues, as it is in sensory sensilla, thereby allowing a PD exceeding 180 mV (lumen positive) to develop across the apical plasma membrane. This PD appears to couple K⁺ pump energy to nutrient absorption and pH regulation.     

Route,mechanism, and implications of proton import during Na+/K+ exchange by native Na+/K+-ATPase pumps

A single Na⁺/K⁺-ATPase pumps three Na⁺ outwards and two K⁺ inwards by alternately exposing ion-binding sites to opposite sides of the membrane in a conformational sequence coupled to pump autophosphorylation from ATP and auto-dephosphorylation. The larger flow of Na⁺ than K⁺ generates outward current across the cell membrane. Less well understood is the ability of Na⁺/K⁺ pumps to generate an inward current of protons. Originally noted in pumps deprived of external K⁺ and Na⁺ ions, as inward current at negative membrane potentials that becomes amplified when external pH is lowered, this proton current is generally viewed as an artifact of those unnatural conditions. We demonstrate here that this inward current also flows at physiological K⁺ and Na⁺ concentrations. We show that protons exploit ready reversibility of conformational changes associated with extracellular Na⁺ release from phosphorylated Na⁺/K⁺ pumps. Reversal of a subset of these transitions allows an extracellular proton to bind an acidic side chain and to be subsequently released to the cytoplasm. This back-step of phosphorylated Na⁺/K⁺ pumps that enables proton import is not required for completion of the 3 Na⁺/2 K⁺ transport cycle. However, the back-step occurs readily during Na⁺/K⁺ transport when external K⁺ ion binding and occlusion are delayed, and it occurs more frequently when lowered extracellular pH raises the probability of protonation of the externally accessible carboxylate side chain. The proton route passes through the Na⁺-selective binding site III and is distinct from the principal pathway traversed by the majority of transported Na⁺ and K⁺ ions that passes through binding site II. The inferred occurrence of Na⁺/K⁺ exchange and H⁺ import during the same conformational cycle of a single molecule identifies the Na⁺/K⁺ pump as a hybrid transporter. Whether Na⁺/K⁺ pump–mediated proton inflow may have any physiological or pathophysiological significance remains to be clarified.     

Cell proliferation,potassium channels,polyamines and their interactions: a mini review

Polyamines, which are obligatory molecules involved in cell cycling and proliferation, are subject to a change in their free intracellular concentrations during the cell cycle. Potassium (K⁺) channels are also considered, but less well recognized, to be necessary for cell proliferation by either hyperpolarizing or depolarizing cells during the cell cycle. A block of polyamine synthesis as well as block or knockout of K⁺ channels can halt cell proliferation. K⁺ channels like BK (maxi calcium (Ca²⁺)-activated K⁺), Kir (inward rectifier), M-type K⁺-and TASK (two-pore domain K⁺) channels or the delayed rectifier K⁺ channels are modulated in their electrical properties by polyamines. Polyamines are most effective in blocking these channels when applied to the intracellular face of these channels except for TASK channels where they act only from the extracellular side. Quinidine, a general K⁺ channel blocker, was found to reduce putrescine concentrations, to block the ornithine decarboxylase and halt cell proliferation. From these results, the question arises if there is an interaction between polyamines, K⁺ channels and proliferation. It might be speculated that a decrease of intracellular polyamines allows more K⁺ channels to be active, thus inducing hyperpolarization, while an increase of the polyamine concentration may block K⁺ channel activity leading to depolarization of the membrane potential. On the other hand, a block or a deletion of K⁺ channels may cause a decrease of the polyamine concentration in cells. More research is needed to test these hypotheses.     

Potassium-activated phosphatase from human red blood cells

Summary The cell membrane K⁺-activated phosphatase activity was measured in reconstituted ghosts of human red cells having different ionic contents and incubated in solutions of varying ionic composition. When K⁺-free ghosts are suspended in K⁺-rich media, full activation of the phosphatase is obtained. Conversely, very little ouabainsensitive activity is detected in K⁺-rich ghosts suspended in K⁺-free media. These results, together with the fact that Na⁺ competitively inhibits the effects of K⁺ only when present externally, show that the K⁺ site of the membrane phosphatase is located at the outer surface of the cell membrane. The Mg⁺⁺ requirements for K⁺ activation of the membrane phosphatase are fulfilled by internal Mg⁺⁺. Addition of intracellular Na⁺ to ATP-containing ghosts raises the apparent affinity of the enzyme for K⁺, suggesting that the sites where ATP and Na⁺ produce this effect are located at the inner surface of the cell membrane. The asymmetrical features of the membrane phosphatase are those expected from the proposed role of this enzyme in the Na⁺–K⁺-ATPase system.The authors are established investigators of the Consejo Nacional de Investigaciones Científicas y Técnicas, Argentina.     

Pathophysiology of mitochondrial volume homeostasis: Potassium transport and permeability transition

Regulation of mitochondrial volume is a key issue in cellular pathophysiology. Mitochondrial volume and shape changes can occur following regulated fission-fusion events, which are modulated by a complex network of cytosolic and mitochondrial proteins; and through regulation of ion transport across the inner membrane. In this review we will cover mitochondrial volume homeostasis that depends on (i) monovalent cation transport across the inner membrane, a regulated process that couples electrophoretic K⁺ influx on K⁺ channels to K⁺ extrusion through the K⁺-H⁺ exchanger; (ii) the permeability transition, a loss of inner membrane permeability that may be instrumental in triggering cell death. Specific emphasis will be placed on molecular advances on the nature of the transport protein(s) involved, and/or on diseases that depend on mitochondrial volume dysregulation.     

The Membrane Potential of Acetabularia mediterranea

The cytoplasm of an Acetabularia cell is normally at a potential of about -170 mv relative to the external solution; the vacuole is also at this potential. Although there is strict flux equilibrium for all ions, the potential is more negative than the Nernst potentials of any of the permeating ions. Darkness, CCCP, low temperature, and reducing [Cl^-]_o by a factor of 25 all rapidly depolarize the membrane and inhibit Cl^- influx. Some of these treatments do not inhibit the effluxes of K⁺ and Na⁺. Increasing [K⁺]_o also depolarizes the membrane both under normal conditions and at low temperature; in the latter case the membrane is partially depolarized in normal seawater (low [K⁺]_o) and in high [K⁺]_o positive potentials of up to +15 mv are attained. It is concluded that the membrane potential is controlled by the electrogenic influx of Cl^-, and also, at least in some circumstances, by the diffusion of K⁺. In addition, it is suggested that electrogenic efflux of H⁺ may be important in transient nonequilibrium situations. An Appendix deals with the interpretation of simple nonsteady-state tracer kinetic data.     

Mechanism of action of cesalin, an antitumor protein.

A protein, cesalin, isolated from $\text{Caesalpinia}$$\text{gilliesii}$ is cytotoxic to KB cells in tissue culture. It has been shown to bind to the plasma membrane of this cell line and to inhibit Na⁺, K⁺-ATPase (ATP phosphohydrolase EC 3.6.1.3). Similar studies with HTC cells show no cytotoxicity or inhibition of plasma membrane Na⁺, K⁺-ATPase. The Na⁺, K⁺-ATPase of human erythrocytes and rat brain and kidney tissues are not inhibited. 5′-Nucleotidase and Mg⁺⁺-ATPase are not inhibited by cesalin in any cells tested.     

The chemiosmotic model of stomatal opening revisited

Stomata are light‐activated biological valves in the otherwise gas‐impermeable epidermis of aerial organs of higher plants. Stomata often regulate rates of photosynthesis and transpiration in ways that optimize whole‐plant carbon gain against water loss. Each stoma is flanked by a pair of opposing guard cells. Stomatal opening occurs by light‐activated increases in the turgor pressure of guard cells, which causes them to change shape so that the stomatal pore between them widens. These increases in turgor pressure oppose increases in cellular osmotic pressure that result from uptake of K⁺. K⁺ uptake occurs by a chemiosmotic mechanism in response to light‐activated extrusion of H⁺ outward across the plasma membrane of the guard cell. The initial changes in cellular membrane potential lead to the opening of inward‐rectifying K⁺ channels, after which K⁺ is taken up along its electrochemical gradient. Changes in membrane potential resulting from K⁺ uptake may be balanced by accumulation of Cl^?ions by guard cells and/or by synthesis of malic acid within each cell. Malic acid also acts to buffer increases in cytosolic pH caused by H⁺ extrusion. This review describes how the application of patch‐clamp technology to guard cell protoplasts has enabled investigators to elucidate the mechanisms by which H⁺ is extruded from guard cells, the types of ion channels present in the guard cell plasma membrane, how those ion channels are regulated, and the signal transduction processes that trigger stomatal opening and closing.     

The Influence of the Intracellular Potential on Potassium Uptake by Beetroot Tissue

Intracellular potentials were measured in beetroot tissue during the steady-state uptake of K⁺ from various solutions. In solutions containing bicarbonate, the membrane potential becomes up to 70 mv more negative than the estimated equilibrium potential for K⁺. The uptake of K⁺ from such solutions is correlated with variations in the potential, both when the bicarbonate concentration is changed and also when the metabolic activity of the tissue is changed by washing in water for various periods. However, the estimated permeability to K⁺ varies from 0.4 x 10^-7 to 1.5 x 10^-7 cm·sec^-1. It is postulated that the change of potential arises from the metabolic transport of HCO₃^- into the cell or H⁺ outwards, and that the associated uptake of K⁺ is partly or entirely by passive diffusion across the cell membrane. In contrast, K⁺ uptake from KCl solutions is not accompanied by any significant change in the membrane potential, which remains relatively close to the K⁺ equilibrium potential. In solutions containing both KHCO₃ and KCl, it appears that an amount of K⁺ equal to the influx of Cl^- is taken up independently of the potential, while the component of K⁺ uptake which is not balanced by Cl^- uptake is related to the potential in the manner described. These results suggest that K⁺ uptake is linked to Cl^- uptake in an electrically neutral active transport process.     

ATP-mediated potassium recycling in the cochlear supporting cells

Gap junction-mediated K⁺ recycling in the cochlear supporting cell has been proposed to play a critical role in hearing. However, how potassium ions enter into the supporting cells to recycle K⁺ remains undetermined. In this paper, we report that ATP can mediate K⁺ sinking to recycle K⁺ in the cochlear supporting cells. We found that micromolar or submicromolar levels of ATP could evoke a K⁺-dependent inward current in the cochlear supporting cells. At negative membrane potentials and the resting membrane potential of −80 mV, the amplitude of the ATP-evoked inward current demonstrated a linear relationship to the extracellular concentration of K⁺, increasing as the extracellular concentration of K⁺ increased. The inward current also increased as the concentration of ATP was increased. In the absence of ATP, there was no evoked inward current for extracellular K⁺ challenge in the cochlear supporting cells. The ATP-evoked inward current could be inhibited by ionotropic purinergic (P2X) receptor antagonists. Application of pyridoxalphosphate-6-azophenyl-2′,4′-disulfonic acid (PPADS, 50 μM) or pre-incubation with an irreversible P2X7 antagonist oxidized ATP (oATP, 0.1 mM) completely abolished the ATP-evoked inward current at the negative membrane potential. ATP also evoked an inward current at cell depolarization, which could be inhibited by intracellular Cs⁺ and eliminated by positive holding potentials. Our data indicate that ATP can activate P2X receptors to recycle K⁺ in the cochlear supporting cells at the resting membrane potential under normal physiological and pathological conditions. This ATP-mediated K⁺ recycling may play an important role in the maintenance of cochlear ionic homeostasis.     

Localization of Na+, K+-ATPase to the inside of the basolateral cell membranes of epithelial cells of proximal and distal tubules in rabbit kidney

Summary Cysteine-sensitive alkaline phosphatase and/or ouabain-sensitive Na⁺, K⁺-ATPase were studied by ultrastructure cytochemistry in epithelial cells of proximal and distal kidney tubules. Alkaline phosphatase reactivity was confined to the surface of the microvillous luminal cell membrane of proximal tubule cells, whereas distal tubules and collecting ducts were unreactive. The Na⁺, K⁺-ATPase reactivity was localized evenly along the cytoplasmic side of the basolateral cell membrane of cells of proximal and distal tubules and in collecting ducts. In the proximal tubules, where the activity was strongest, the Na⁺, K⁺-ATPase deposits were also found in the 10–50 nm gap between the cell membrane and the cisternae of tubulo-cisternal endoplasmic reticulum (TER) underlying a major part of the basolateral cell membrane. The restriction of Na⁺, K⁺-ATPase sites, which are involved in extrusion of Na⁺ from the cell, to a narrow cytoplasmic compartment located between the cell membrane and the cisternae of TER, is consistent with a transport role for the TER.     

Properties of (Sodium Potassium)-Stimulated ATPases in English Ryegrass Roots and Implications in Ion Transport

Maximum ATPase activities in the cell wall fraction of English ryegrass (Lolium perenne L.) roots were stimulated by foru discrete millimole ratios of (Na⁺+ K⁺); 40:0, 35:5, 5:35, and 0:40. The optimal pH for stimlation was found to be 6.5. Contrary to data in the literature, Mg²⁺ inhibited all stimulatory ratios of (Na⁺+ K⁺) when plants were cultured on an adequate nutrient solution. When grown on a dilute solution, Mg²⁺ enhanced (Na⁺+ K⁺)-stimulated ATPase activity in this membrane preparation. The single optimal combined concentration of (Na⁺+ K⁺) for all stimulatory ratios was 40 MM. The ratios of (Na⁺+ K⁺) which stimulated ATPase activity in the cell wall fraction varied with position along the root axis such that all rarely existed simultaneously nor did any exist in the terminal millimetre of the root. Both cell wall and microsomal fractions showed stimulation by (Na⁺+ K⁺) at all the above ratios indicating the possible presence of plasma membrane fragments in both fractions. Only the 35:5 ratio was stimulations were found in the supernatant. Implications of ion-stimulated ATPase involvement in ion transport were drawn from the appearance of ATPase activity at a 40:0 ratio of (Na⁺+ K⁺) and the disappearance of stimulations at 35:5, 5:35, and 0:40 ratios when plants were moved from a strong (35 mM total concentration) to a dilute (0.75 mM) nutrient solution.     

Inactivation of (Na+ + K+)-stimulated ATPase by a cytotoxic protein from cobra venom in relation to its lytic effects on cells

The mechanism of action of the cytotoxic protein P₆ isolated from cobra venom (Naja naja) which shows preferential cytotoxicity particularly to Yoshida sarcoma cells has been studied by its effects on the membrane-bound enzyme (Na⁺ + K⁺)-ATPase (ATP phosphohydrolase, EC 3.6.1.3) of a variety of cell systems. Evidence obtained with Yoshida sarcoma cells, dog and human erythrocytes and three tissue culture cell lines KB (human oral carcinoma), Hela (human cervix carcinoma) and L-132 (human lung embryonic) shows that inhibition of (Na⁺ + K⁺)-ATPase by the P₆ protein can be correlated with its lytic activity. (Na⁺ + K⁺)-ATPase of Yoshida sarcoma membrane fragments inactivated by P₆ protein could be reconstituted by the addition of phosphatidylserine and phosphatidic acid. It is conceivable that lysis of cells by the P₆ protein may be due to an imbalance of K⁺ and Na⁺ in the cell which leads to swelling and disintegration of the membrane structure. Observations indicate that the P₆ protein combines with membrane constituents of susceptible cells. The overall evidence suggests that both the specificity of its protein structure and the highly basic nature of the P₆ protein are factors which enable it to compete with the lipid moiety maintaining the (Na⁺ + K⁺)-ATPase of the susceptible cells in proper conformation for activity.     

Ion and water transport across multicellular membranes through extracellular space by chemiperistaltic waves

It is assumed that waves of configurational change of cell surface proteins can pass over the length of columnar cells in a multicellular membrane, thus passing across the membrane. It is expected that waves of change in fluidity of surface water and of Na⁺ vs K⁺ complexing preference by cell surface proteins will result from the waves of change in surface protein configuration. The entire wave process is called a chemiperistaltic wave, and is a natural extension of the concepts embodied in the association-induction hypothesis of Ling. It is shown that chemiperistaltic waves may transport Na⁺ across multicellular membranes through extracellular space between cells in a manner which is consistent with the experiments of Cereijidoet al. (1968) on frog skin. Equations for transport of Na⁺ by chemiperistaltic waves are derived for an idealized membrane. It seems possible that Na⁺−K⁺ activated ATPase may represent the isolated form of the cell surface protein in which chemiperistaltic waves are propagated or that an actomyosin-like protein may be involved.     

Effect of sodium on potassium fluxes at the cell membrane and vacuole membrane of red beet

Slices of red beet (Beta vulgaris) washed for 5 to 6 days are known to accumulate Na⁺ in preference to K⁺ from solutions containing both ions. The present work, using ion concentrations of 1.0 mm or less, with Ca²⁺ added in some cases, shows that Na⁺ strongly inhibits K⁺ influx at the cell membrane (plasmalemma) while K⁺ efflux is increased to a lesser extent. This result from compartmental analysis is confirmed by short (15-minute) influx experiments, which indicate an immediate inhibitory effect of Na⁺ on K⁺ influx at the cell membrane. It is concluded that cation selectivity, even when Na⁺ is favored for uptake, is primarily determined at the cell membrane. Nevertheless, a high level of K⁺ in the cytoplasm is maintained during Na⁺ influx, by an inhibition of K⁺ transfer to the vacuole.     

A calcium-activated potassium channel present in foetal red cells of the sheep but absent from reticulocytes and mature red cells

Red cells of adult sheep, like those of other ruminants, lack the calcium-activated potassium channel which is present in the membrane of human red cells. Since the activities of other transport systems in the sheep red cell are known to decrease during maturation of the cell or during development of the animal it was investigated whether the K⁺ channel is present in red cells from younger animals or in reticulocytes. Using the divalent cation ionophore A23187 to increase the intracellular Ca of intact cells, it was found that the K⁺-selective channel is present in foetal red cells from the foetus or newborn animal but not in reticulocytes. The presence of the channel showed no dependence on the K⁺ genotype of the sheep and was not associated with either “high K⁺”-or “low K⁺”-type Na⁺ pump. No Ca²⁺-dependent change in K⁺ permeability was found in red cells from either newborn or adult donkeys suggesting that its presence in the red cells of the foetus may not be general. The role of the K⁺ channel in the mammalian red cell and the relationship between the K⁺ channel and the Na⁺ pump are discussed.     

Ion movements induced by transcellular osmosis inNitella flexilis

Summary Movements of K⁺, Na⁺, and Cl^}- ions during transcellular osmosis were studied in internodal cells ofNitella flexilis. Much K⁺ was released from the endosmotic cell part, but only a little from the exosmotic cell part. The amount of K⁺ released depended on the osmotic gradient driving transcellular osmosis. Movement of Na⁺ was hardly detected. Cl^}- was released in nearly the same amounts as K⁺. Release of K⁺ from the endosmotic cell half was stimulated remarkably by lowering the temperature from 20 to 1 °C, and also by lowering the internal osmotic pressure but inhibited by raising it.The dependence of K⁺ release on osmotic gradient, internal osmotic pressure and temperature can be explained by their effects on membrane depolarization and membrane resistance (Hayama et al. 1978). We concluded thatP _K remained unchanged, whileP _Cl increased a great deal in the endosmotic cell part.     

Fluxes of h and k in corn roots : characterization and stoichiometries using ion-selective microelectrodes

We report here on an experimental system that utilizes ion-selective microelectrodes to measure the electrochemical potential gradients for H⁺ and K⁺ ions within the unstirred layer near the root surface of both intact 4-day-old corn seedlings and corn root segments. Analysis of the steady state H⁺ and K⁺ electrochemical potential gradients provided a simultaneous measure of the fluxes crossing a localized region of the root surface. Net K⁺ influx values obtained by this method were compared with unidirectional K⁺ (⁸⁶Rb⁺) influx kinetic data; at any particular K⁺ concentration, similar values were obtained by either technique. The ionspecific microelectrode system was then used to investigate the association between net H⁺ efflux and net K⁺ influx. Although the computed H⁺:K⁺ stoichiometry is dependent upon the choice of diffusion coefficients, the values obtained were extremely variable, and net K⁺ influx rarely appeared to be charge-balanced by H⁺ efflux. In contrast to earlier studies, we found the cortical membrane potential to be highly K⁺ sensitive within the micromolar K⁺ concentration range. Simultaneous measurements of membrane potential and K⁺ influx, as a function of K⁺ concentration, revealed similar K_m values for the depolarization of the potential (K_m 6-9 micromolar K⁺) and net K⁺ influx (K_m 4-7 micromolar K⁺). These data suggest that K⁺ may enter corn roots via a K⁺-H⁺ cotransport system rather than a K⁺/H⁺ antiporter.