The effect of imidoesters,fluorodinitrobenzene and trinitrobenzenesulfonate on ion transport in human erythrocytes

Several amino-reactive chemical probes which differ in hydrophobicity and charge and in their ability to penetrate the red cell membrane were tested for their ability to modify K⁺ leak and inorganic phosphate (Pi) leak in intact human red cells. Methyl picolinimidate (MP), ethyl acetimidate (EA), methyl acetimidate (MA) are hydrophilic penetrating probes whereas isethionylacetimidate (IA) is a hydrophilic non-penetrating probe. The order of their effectiveness in inhibiting Pi leak was found to be MP>EA>MA>IA. This order is in decreasing hydrophobicity and suggests that some penetration into the bilayer or into hydrophobic domains of the anion transport protein is required to modify an amino group required for Pi permeability through the membrane. These imidoesters have little or no effect on K⁺ leak in the red cell.Trinitrobenzenesulfonate (TNBS) a relatively non-penetrating hydrophobic anionic probe and fluorodinitrobenzene (FDNB) a penetrating hydrophobic neutral probe have markedly different effects on K⁺ and Pi leak. TNBS has little effect on K⁺ leak but markedly inhibits Pi leak. The effect of TNBS on Pi leak is not blocked by prior treatment with IA suggesting that these probes sense different populations of amino groups in the membrane. FDNB nearly completely blocks Pi leak and markedly increases K⁺ leak. The results with TNBS and FDNB indicate an asymmetric arrangement of amino groups on the red cell membrane. Certain amino groups on the outer surface of the membrane regulate Pi permeability whereas certain amino groups on the inner surface of the membrane regulate K⁺ permeabilty. The data also suggest that these amino groups are in a hydrophobic domain.     

Effect of phospholipid surface charge on the conductance and gating of a Ca2+-activated K+ channel in planar lipid bilayers

Summary A Ca-activated, K-selective channel from plasma membrane of rat skeletal muscle was studied in artificial lipid bilayers formed from either phosphatidylethanolamine (PE) or phosphatidylserine (PS). In PE, the single-channel conductance exhibited a complex dependence on symmetrical K⁺ concentration that could not be described by simple Michaelis-Menten saturation. At low K⁺ concentrations the channel conductance was higher in PS membranes, but approached the same conductance observed in PE above 0.4m KCl. At the same Ca²⁺ concentration and voltage, the probability of channel opening was significantly greater in PS than PE. The differences in the conduction and gating, observed in the two lipids, can be explained by the negative surface charge of PS compared to the neutral PE membrane. Model calculations of the expected concentrations of K⁺ and Ca²⁺ at various distances from a PS membrane surface, using Gouy-Chapman-Stern theory, suggest that the K⁺-conduction and Ca²⁺-activation sites sense a similar fraction of the surface potential, equivalent to the local electrostatic potential at a distance of 9 Å from the surface.     

Effect of lysolecithin treatment on the structure and functions of the mitochondrial inner membrane

Lysolecithin treatment of electron transport particles (ETP) generated membrane fragments capable of catalyzing ATP-³²P_i exchange, which was resistant to the uncoupling action of Valinomycin plus Nigericin or Valinomycin plus Monensin A in the presence of K⁺. Electron micrographs of ultrathin, positively stained sections of lysolecithin treated ETP were virtually devoid of circular patterns characteristic of closed vesicles. The results suggest that the closed vesicular structure of the mitochondrial inner membrane demanded by the chemiosmotic hypothesis of energy transduction (1) may not be essential for the ATP-³²P_i exchange reaction.     

Immunocytochemical localization of Na+/K+-ATPase and V-H+-ATPase in the salivary glands of the cockroach,Periplaneta americana

The acinous salivary glands of the cockroach (Periplaneta americana) consist of four morphologically different cell types with different functions: the peripheral cells are thought to produce the fluid component of the primary saliva, the central cells secrete the proteinaceous components, the inner acinar duct cells stabilize the acini and secrete a cuticular, intima, whereas the distal duct cells modify the primary saliva via the transport of water and electrolytes. Because there is no direct information available on the distribution of ion transporting enzymes in the salivary glands, we have mapped the distribution of two key transport enzymes, the Na⁺/K⁺-ATPase (sodium pump) and a vacuolar-type H⁺-ATPase, by immunocytochemical techniques. In the peripheral cells, the Na⁺/K⁺-ATPase is localized to the highly infolded apical membrane surface. The distal duct cells show large numbers of sodium pumps localized to the basolateral part of their plasma membrane, whereas their highly folded apical membranes have a vacuolar-type H⁺-ATPase. Our immunocytochemical data are supported by conventional electron microscopy, which shows electrondense 10-nm particles (portasomes) on the cytoplasmic surface of the infoldings of the apical membranes of the distal duct cells. The apically localized Na⁺/K⁺-ATPase in the peripheral cells is probably directly involved in the formation of the Na⁺-rich primary saliva. The latter is modified by the distal duct cells by transport mechanisms energized by the proton motive force of the apically localized V-H⁺-ATPase.     

Association of spectrin with its membrane attachment site restricts lateral mobility of human erythrocyte integral membrane proteins

Interactions between spectrin and the inner surface of the human erythrocyte membrane have been implicated in the control of lateral mobility of the integral membrane proteins. We report here that incubation of “leaky” erythrocytes with a water-soluble proteolytic fragment containing the membrane attachment site for spectrin achieves a selective and controlled dissociation of spectrin from the membrane, and increases the rate of lateral mobility of fluorescein isothiocyanate-labeled integral membrane proteins (> 70% of label in band 3 and PAS-1). Mobility of membrane proteins is measured as an increase in the percentage of uniformly fluorescent cells with time after fusion of fluorescent with nonfluorescent erythrocytes by Sendai virus. The cells are permeable to macromolecules since virus-fused erythrocytes lose most of their hemoglobin. The membrane attachment site for spectrin has been solubilized by limited proteolysis of inside-out erythrocyte vesicles and has been purified (V). Bennett, J Biol Chem 253:2292 (1978). This 72,000-dalton fragment binds to spectrin in solution, competitively inhibits association of ³²P-spectrin with inside-out vesicles with a K_i of 10^?7M, and causes rapid dissociation of ³²P-spectrin from vesicles. Both acid-treated 72,000-dalton fragment and the 45,000 dalton-cytoplasmic portion of band 3, which also was isolated from the proteolytic digest, have no effect on spectrin binding, release, or membrane protein mobility. The enhancement of membrane protein lateral mobility by the same polypeptide that inhibits binding of spectrin to inverted vesicles and displaces spectrin from these vesicles provides direct evidence that the interaction of spectrin with protein components in the membrane restricts the lateral mobility of integral membrane proteins in the erythrocyte.     

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.     

Membrane Cholesterol Depletion and K+ Transport in High and Low Potassium Sheep Red Cells

The effect of cholesterol depletion on potassium tracer fluxes was studied in sheep red cells. Removal by the plasma incubation method (5, 12, 30) of approximately 31 and 34% membrane cholesterol from high-potassium (HK) and low-potassium (LK) sheep red cells, respectively, did not induce significant changes in the steady-state cation composition of these cells nor in their passive (leak) and active (pump) K⁺ influxes. In cholesterol-depleted LK sheep red cells, there was no impairment nor augmentation of the L_p an tibody stimulated K⁺ pump flux and L₁-antibody-mediated reduction of K⁺ leak flux indicating that the removed cholesterol does not contribute to the activity of the L_p and L₁ antigens.     

The Proton Permeability of Liposomes Made from Mitochondrial Inner Membrane Phospholipids: Comparison with Isolated Mitochondria

Unilamellar liposomes with native phospholipid fatty acid composition were prepared from rat liver mitochondrial inner membrane phospholipids by extrusion in medium containing 50 mm potassium. They were diluted into low potassium medium to establish a transmembrane potassium gradient. A known membrane potential was imposed by addition of valinomycin, and proton flux into liposomes was measured. Valinomycin in the range 10 pm–1nm was sufficient to fully establish membrane potential. Valinomycin concentrations above 3 nm catalyzed additional proton flux and were avoided. At 300 pm valinomycin, proton flux depended nonlinearly on membrane potential. At 160 mV membrane potential the flux was 30 nmol H⁺/min/mg phospholipid—approximately 5% of the proton leak flux under comparable conditions in isolated mitochondria, indicating that leak pathways through bulk phospholipid bilayer account for only a small proportion of total mitochondrial proton leak. Received: 5 August 1996/Revised: 1 October 1996     

An estimation of the proton conductance of the inner membrane of turnip (Brassica napus L.) mitochondria

The permeability of the inner membrane of turnip mitochondria to H⁺ and OH^- ions has been investigated using an acid pulse technique. The rate of decay of a H⁺ pulse across the inner membrane is exponential having first-order kinetics and gives t 1/2 values of approx 54 s at neutral pH and at 25° C. Valinomycin or 1799 alone have little effect on t 1/2 values, whereas in combination, values of <15 s are observed. Nigericin produces a similar effect. The effective proton conductance of the inner membrane near pH 7 at 25° C is 0.27 nmol H⁺ min^-1 mg protein^-1 mV^-1. The results suggest that at neutral pH, the inner membrane of plant mitochondria is relatively impermeable to H⁺ and OH^- ions.     

Effect of phospholipase A2 on purified gastric vesicles

The phospholipid and fatty acid composition and role of phospholipids in enzyme and transport function of gastric (H⁺+K⁺)-ATPase vesicles was studied using phospholipase A₂ (bee venom). The composition (%) was phosphatidylcholine (PC) 33%; sphingomyelin (sph) 25%; phosphatidylethanolamine (PE) 22%; phosphatidylserine (PS) 11%; and phosphatidylinositol (PI) 8%. The fatty acid composition showed a high degree of unsaturation. In both fresh and lyophilized preparations, even with prolonged incubation, only 50% of phospholipids were hydrolyzed, but the amount of PE and PS disappearing was increased following lyophilization. There was a marked decrease in K⁺-ATPase activity (75%) but essentially no loss of the associated K₊ p-nitrophenyl phosphatase was found. ATPase activity could be largely restored by various phospholipids (PE > PC > PS). There was also an increase in Mg²⁺-ATPase activity, partially reversed in fresh preparations by the addition of phospholipids (PE > PS > PC). Proton transport activity of the preparation was rapidly inhibited, initially due to a large increase in the HC1 permeability of the preparation. Associated with these enzymatic and functional changes, the ATP-induced conformational changes, as indicated by circular dichroism spectra were inhibited.     

p-CMBS Modifies Extrafacial Sulfhydryl Groups at the Chara Plasma Membrane: Activation of Ca2+ Influx and Inhibition of Two Different K+ Currents

The effect of the membrane impermeant sulfhydryl group (SH) reagent, p-chloromercuribenzenesulfonic acid (p-CMBS), on electrical membrane transport properties of the giant alga, Chara corallina, was determined. In an external medium with a high K⁺ concentration (5 mM) cells typically exhibited stable membrane potentials close to the K⁺equilibrium potential. The steady-state current-voltage (I-V) relation could be dissected into two distinct components: an almost linear ohmic leak current and a voltage-dependent K⁺ current. Adding 0.5 mM p-CMBS to the external medium resulted in an immediate, short depolarization transient (resembling the time course of an action potential) and was associated with a slow down of the cytoplasmic streaming velocity. The depolarization, as well as the streaming inhibition, could be abolished by pretreating cells with the Ca²⁺ channel inhibitor, LaCl₃. This suggests that the depolarization transient reflected a p-CMBS induced Ca²⁺ influx, a scenario known to trigger membrane excitation and slow down of cytoplasmic streaming. From the I-V analysis it appeared that p-CMBS also caused a reversible inhibition of two additional transmembrane currents: (1) a reduction of a leak current and (2) a modification of the deactivation kinetics of the voltage-dependent K⁺ channels. From the I-V difference analysis, the inhibited leak current was identified as a K⁺ current, because the reversal potential was close to the estimated K⁺ equilibrium potential. Control experiments have furthermore shown that the mercapto reagent, dithiothreitol, partly reversed the effect of p-CMBS. This strengthens the view that the action of the mercurial is related to a specific and direct modification of SH groups. The p-CMBS-evoked inhibition of K⁺ currents was not abolished by the LaCl₃ pretreatment, which suggests that the effect of the SH reagent is not induced indirectly by p-CMBS-triggered Ca²⁺ influx. Therefore, it is suggested that the mercurial interacts direcly with the K⁺ transport protein.     

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.     

Flux ratio of valinomycin-mediated K+ fluxes across the human red cell membrane in the presence of the protonophore CCCP

Summary The ratio of valinomycin-mediated unidirectional K⁺ fluxes across the human red cell membrane, has been determined in the presence of the protonophore carbonylcyanidem-chlorophenylhydrazone, CCCP, using the K⁺ net efflux and⁴²K influx. The driving force for the net efflux (V _m –E _K ⁺) has been calculated from the membrane potential, estimated by the CCCP-mediated proton distribution and the Nernst potential for potassium ions across the membrane. An apparent driving potential for the K⁺ net efflux has been calculated from the K⁺ flux ratio, determined in experiments where the valinomycin and CCCP concentrations were varied systematically. This apparent driving force, in conjunction with the actual driving force calculated on basis of the CCCP estimated membrane potential, is used to calculate a flux ratio exponent, which represents an estimate of the deviation of valinomycin-mediated K⁺ transport from unrestricted electrodiffusion, when protonophore is present.In the present work, the flux ratio exponent is found to be 0.90 when the CCCP concentration is 5.0 m and above, while the exponent decreases to about 0.50 when no CCCP is present. The influence of CCCP upon the rate constants in the valinomycin transport cycle is discussed. The significance of this result is that red cell membrane potentials are overestimated, when calculated from valinomycin-mediated potassium isotope fluxes, using a constant field equation.     

Electrophoretic polyamine transport in rat liver mitochondria

Summary Naturally occurring polyamines (spermidine, putrescine, cadaverine), as the well studied spermine, are transported into rat liver mitochondrial matrix provided that mitochondria are energized and the electrical membrane potential has a value of about 180 mV. This condition is achieved by the presence of inorganic phosphate, or acetate, or nigericin in the incubation medium. Valinomycin plus K⁺ almost completely blocks polyamine transport.The obtained results clearly show that all naturally occurring polyamines are transported by an electrophoretic mechanism in responce to a high negative inner electrical potential.The distribution ratio of polyamines across the mitochondrial membrane is far from the thermodynamic equilibrium by many orders of magnitude. This result might suggest the existence of a different pathway for polyamine efflux.     

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.     

Membrane phospholipid composition affects function of potassium channels from rabbit colon epithelium

We tested the effects of membrane phospholipids on the functionof high-conductance,Ca²⁺-activatedK⁺ channels from the basolateralcell membrane of rabbit distal colon epithelium by reconstituting thesechannels into planar bilayers consisting of different 1:1 mixtures ofphosphatidylethanolamine (PE), phosphatidylcholine (PC),phosphatidylserine (PS), and phosphatidylinositol (PI). At low ambientK⁺ concentrations single-channelconductance is higher in PE/PS and PE/PI bilayers than in PE/PCbilayers. At high K⁺concentrations this difference in channel conductance is abolished. Introducing the negatively charged SDS into PE/PC bilayersincreases channel conductance, whereas the positively chargeddodecyltrimethylammonium has the opposite effect. All these findingsare consistent with modulation of channel current by the charge of thelipid membrane surrounding the channel. But theK⁺ that permeates the channelsenses only a small fraction of the full membrane surface potential ofthe charged phospholipid bilayers, equivalent to separation of theconduction pathway from the charged phospholipid head groups by 20 Å. This distance appears to insulate the channel entrancefrom the bilayer surface potential, suggesting large dimensions of thechannel-forming protein. In addition, in PE/PC and PE/PI bilayers, butnot in PE/PS bilayers, the open-state probability of the channeldecreases with time ("channel rundown"), indicating thatphospholipid properties other than surface charge are required tomaintain channel fluctuations.

     

Organelle-localized potassium transport systems in plants

Some intracellular organelles found in eukaryotes such as plants have arisen through the endocytotic engulfment of prokaryotic cells. This accounts for the presence of plant membrane intrinsic proteins that have homologs in prokaryotic cells. Other organelles, such as those of the endomembrane system, are thought to have evolved through infolding of the plasma membrane. Acquisition of intracellular components (organelles) in the cells supplied additional functions for survival in various natural environments. The organelles are surrounded by biological membranes, which contain membrane-embedded K⁺ transport systems allowing K⁺ to move across the membrane. K⁺ transport systems in plant organelles act coordinately with the plasma membrane intrinsic K⁺ transport systems to maintain cytosolic K⁺ concentrations. Since it is sometimes difficult to perform direct studies of organellar membrane proteins in plant cells, heterologous expression in yeast and Escherichia coli has been used to elucidate the function of plant vacuole K⁺ channels and other membrane transporters. The vacuole is the largest organelle in plant cells; it has an important task in the K⁺ homeostasis of the cytoplasm. The initial electrophysiological measurements of K⁺ transport have categorized three classes of plant vacuolar cation channels, and since then molecular cloning approaches have led to the isolation of genes for a number of K⁺ transport systems. Plants contain chloroplasts, derived from photoautotrophic cyanobacteria. A novel K⁺ transport system has been isolated from cyanobacteria, which may add to our understanding of K⁺ flux across the thylakoid membrane and the inner membrane of the chloroplast. This chapter will provide an overview of recent findings regarding plant organellar K⁺ transport proteins.     

Induction of the Na+/Pi cotransport system in the plasma membrane of Chara corallina requires external Na+ and low levels of Pi

It was shown in previous studies that the giant freshwater alga Chara corallina does not control its Na⁺‐dependent Pi uptake by monitoring the internal Pi concentration and it was hypothesized that Chara may instead detect changes in Pi supply from the environment. The present work investigated the conditions that control the induction and inactivation of high affinity Na⁺/Pi influx in Chara. Withdrawal of Pi from the external medium resulted in a gradual increase in the rate of uptake measured immediately after Pi was resupplied. The increase continued for at least 7 d of starvation. In the initial stages, 0·5 or 1 µm Pi were more effective at inducing transport activity than no Pi, suggesting that low levels of Pi are actually required for induction. The high Na⁺‐dependent Pi uptake observed in Pi‐starved cells was inactivated by treatment with as little as 1 µm Pi over 6 d. External Na⁺ plays a major role in controlling the capacity for Na⁺/Pi cotransport activity, and in the absence of Na⁺, both induction and inactivation were either delayed or abolished. Na⁺ starvation stimulated Na⁺ uptake even though there were no measurable changes in the concentrations of Na⁺, or of K⁺ or Pi in either the vacuole or cytoplasm. It was concluded that both substrate (Pi) and driver ion (Na⁺) are required at adequate concentrations for the induction of the cotransporter. In the case of Pi, it was suggested that passive leakage of Pi from the cell into the apoplast is sufficient for this purpose but that supplementation by up to 1 µm Pi is more effective at the earlier stage. A mechanism for sensing the external supply of Pi is proposed.     

Glutamate,aspartate, and γ-aminobutyrate transport by membrane vesicles prepared from rat brain

To prepare membrane vesicles, nerve terminal preparations (synaptosomes) isolated from rat cerebral cortex were first subjected to hypotonic lysis. After collecting the membranes contained in this fraction by centrifugation, membrane vesicles were then reconstituted during incubation in a potassium salt solution at 37 °C. The transport of glutamate, aspartate, or γ-aminobutyric acid (GABA) was measured by transferring vesicles to 10 vol of 0.1 m NaCl solution containing the radioactive substrate. Transport was temperature dependent and exhibited saturation kinetics with an apparent K_m of 2.5 μm. The rates and extent of l-glutamate and l-aspartate uptake were equivalent and were greater than those for GABA. Valinomycin increased the rate of uptake of each of these substances suggesting a role for an electrogenic component in transport. Consonant with this notion, external K⁺ and Rb⁺ decreased uptake of all three compounds. External thiocyanate also increases the rate of glutamate, aspartate, and GABA transport. Uptake of these neuroactive amino acids was absolutely dependent on external Na⁺; no other monovalent cation tested substitutes for it. Gramicidin D and nigericin inhibit glutamate transport by abolishing both the Na⁺ and K⁺ gradients. Monensin inhibits uptake by selectively dissipating the Na⁺ gradient. For both glutamate and GABA transport, the Na⁺ and K⁺ gradients are synergistic and not additive.     

Sulfatide role in the sodium pump

Summary Sodium efflux was studied in²²Na-loaded red blood cells in the presence of arylsulfatase, an enzyme that specifically hydrolyzes sulfatide. Sodium efflux was inhibited in proportion to the amount of arylsulfatase present. Maximum inhibition was almost as high as the efflux obtained in medium with K⁺ absent. At maximum inhibition 83.2% of the sulfatide content of the fragmented red blood cell membranes was hydrolyzed and ouabain-sensitive (Na⁺+K⁺)-ATPase activity was inhibited by 100%. Sodium efflux, sulfatide content, and (Na⁺+K⁺)-ATPase activity were unaffected with arylsulfatase in the presence of a high concentration of sulfatide. These results indicate that sulfatide plays a specific role in sodium and potassium ion transport. They also suggest that most sulfatide is localized externally in the red blood cell membrane.