Intracellular Monovalent Ions as Second Messengers

It is generally accepted that electrochemical gradients of monovalent ions across the plasma membrane, created by the coupled function of pumps, carriers and channels, are involved in the maintenance of resting and action membrane potential, cell volume adjustment, intracellular Ca²⁺ handling and accumulation of glucose, amino acids, nucleotides and other precursors of macromolecular synthesis. In the present review, we summarize data showing that side-by-side with these classic functions, modulation of the intracellular concentration of monovalent ions in a physiologically reasonable range is sufficient to trigger numerous cellular responses, including changes in enzyme activity, gene expression, protein synthesis, cell proliferation and death. Importantly, the engagement of monovalent ions in regulation of the above-listed cellular responses occurs at steps upstream of Ca²⁺ _i and other key intermediates of intracellular signaling, which allows them to be considered as second messengers. With the exception of HCO ₃ ⁻ -sensitive soluble adenylyl cyclase, the molecular origin of sensors involved in the function of monovalent ions as second messengers remains unknown.     

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.     

Inhibition of prostaglandin synthesis in human endothelial cells treated with metabolic inhibitors

Endothelial cell injury is often associated with increased synthesis of prostaglandin (PG)I₂. We observed, however, that endothelial cells treated with metabolic inhibitors which reduce cellular ATP content develop an injury pattern characterized by reduced PGI₂ synthesis. This study examined the relationship between cell injury, arachidonic acid metabolism and ATP content in human umbilical vein endothelial cells treated with 2-deoxyglucose (2DG), a glycolytic inhibitor, and oligomycin (OG), a respiratory chain inhibitor. Either inhibitor alone significantly reduced cellular ATP concentrations, but only OG reduced basal PG synthesis. The combination of 2DG and OG, however, was more effective than either agent alone in reducing cellular ATP content (≥ 50% of control) and inhibiting basal and agonist-stimulated PGI₂ synthesis. This reduced PGI₂ synthesis preceded ⁵¹ chromium release, lactic dehydrogenase release and was not associated with a net release of arachidonic acid from cell membranes. Histamine, A23187 and bradykinin stimulated PGI₂ synthesis in untreated but not in 2DG and OG treated cells. Exogenous arachidonic acid increased PGI₂ synthesis to a similar extent in both 2DG and OG treated and untreated cells. Therefore, reduced PG synthesis in 2DG and OG treated endothelial cells is not due to inhibition of cyclooxygenase. Furthermore, reduced PG synthesis in these cells occurs prior to cell injury and is not strictly associated with cellular ATP depletion.     

Induction of intracellular ATP synthesis by extracellular ferricyanide in human red blood cells

Summary Human red blood cells rapidly convert extracellular ferricyanide into extracellular ferrocyanide. The reaction is enhanced by the addition of a substrate, adenosine. This increase of the rate of reaction is abolished by iodoacetate. The results indicate there is a flow of electrons across the membrane of metabolizing red blood cells. The reduction of extracellular ferricyanide is accompanied by the formation of intracellular ATP. The effect of an uncoupler and of inhibitors of oxidative phosphorylation on this reaction was studied under conditions where the natural rate of ATP synthesis was slightly reduced by 10^–4 moles/liter iodoacetate. ATP formation was found to be inhibited by DNP, cyanide, and, to a lesser extent, by azide. Amytal is ineffective. Ferrocyanide enhances ATP breakdown. The action of DNP requires the presence of the cell membrane. It can probably not be related to a stimulation of the membrane ATPase of Laris and Letchworth, nor can it be explained on the basis of Mitchell's chemiosmotic hypothesis by effects on the passive permeability of the erythrocyte membrane to H⁺ or alkali ions. In contrast to methylene blue and other oxidants, ferricyanide does not stimulate oxygen consumption in adult red blood cells.     

The role of calcium ions in the permeability changes produced by external ATP in transformed 3T3 cells

External ATP causes a rapid increase in passive permeability to nucleotides and phosphate esters in transformed cell lines, such as 3T6 mouse fibroblasts. However, untransformed lines, such as 3T3, do not show a similar sensitivity to external ATP. Ca²⁺ inhibits permeabilization, but only at concentrations approaching those of external ATP. In contrast, La³⁺ and Tb³⁺ inhibit ATP-dependent permeabilization at one-fifth the concentration of external ATP. Considering reports that lanthanides can substitute for calcium ion in many enzymatic reactions, often with a higher affinity, it would appear that Ca²⁺ plays a specific role in the maintenance of a passive membrane permeability barrier and in opposing the effects of external ATP.Other data suggest a regulatory role for the Ca²⁺-calmodulin complex in the permeabilization process. Trifluoperazine, chlorpromazine and W-7, compounds which inhibit cellular functions dependent on the Ca²⁺-calmodulin complex, are able to enhance the effect of external ATP. Thus, a dramatic stimulation of nucleotide permeability occurs with concentrations of external ATP and inhibitor that are ineffective when added alone. Calmodulin antagonists and low concentrations of external ATP increased membrane permeability to Na⁺ and K⁺ as was previously shown for permeabilization with ATP alone. Earlier studies have shown that energy inhibitors which reduce intracellular ATP levels greatly increase the sensitivity of transformed cells to external ATP. However, the Ca²⁺-calmodulin antagonists used in the present study exert their effects at concentrations which do not alter intracellular ATP levels.     

Role of membrane-bound Ca in ghost permeability to Na and K

Summary The permeability of red cell ghosts to K is determined by the amount of membrane-bound Mg which, in turn, depends on internal Mg. Contrasting with such effect, an increase in cellular Ca raises K permeability. To test whether this, action is due to a competitive displacement of membrane Mg, the free Ca content of human red cell ghosts was altered by means of Ca-EGTA buffers. Net Na and K movements as well as Ca and Mg bindings, were assessed after incubation in a Na-medium at 37°C. Raising Ca from 3×10^–7 to 1×10^–2M caused a large K efflux with very little Na gain. Under similar conditions, Ca binding was increased without affecting membranebound Mg. Both Ca binding and K loss were markedly diminished by either adding ATP to the hemolytic medium or increasing internal Mg at a fixed Ca concentration. A Scatchard analysis showed three Ca binding sites, two of them having high affinity. It is concluded that Ca action does not arise from a displacement of membrane-bound Mg but from binding to different sites in the membrane. Presumably, high affinity sites are involved in the control of K permeability.     

Inhibition of membrane functions in intact HeLa cells byClostridium difficile cytotoxic culture filtrates

The basis for cytotoxicity to intact HeLa cells by culture filtrates ofClostridium difficile has been investigated. Decrease in intracellular K⁺ levels and inhibition of -aminoisobutyric acid uptake were detected first after exposure to filtrates, followed by inhibition of macromolecular synthesis. Twenty-five percent of the K⁺ remained associated with the cell monolayer, and amino acid uptake and macromolecular synthesis were not totally abolished. These results indicate thatC. difficile culture filtrates preferentially inhibited membrane functions, either by exhausting ATP supplies or by disrupting the permeability barrier of the cell.     

Dissecting the Molecular Mechanism of Nucleotide-Dependent Activation of the KtrAB K+ Transporter

KtrAB belongs to the Trk/Ktr/HKT superfamily of monovalent cation (K⁺ and Na⁺) transport proteins that closely resemble K⁺ channels. These proteins underlie a plethora of cellular functions that are crucial for environmental adaptation in plants, fungi, archaea, and bacteria. The activation mechanism of the Trk/Ktr/HKT proteins remains unknown. It has been shown that ATP stimulates the activity of KtrAB while ADP does not. Here, we present X-ray structural information on the KtrAB complex with bound ADP. A comparison with the KtrAB-ATP structure reveals conformational changes in the ring and in the membrane protein. In combination with a biochemical and functional analysis, we uncover how ligand-dependent changes in the KtrA ring are propagated to the KtrB membrane protein and conclude that, despite their structural similarity, the activation mechanism of KtrAB is markedly different from the activation mechanism of K⁺ channels.     

Effects of trypsin on protein synthesis in macrophages

Treatment of rabbit alveolar macrophages with crystalline trypsin (0.04–2 mg/10⁸ cells) inhibits protein synthesis and results in increased leakage of cell proteins. Trypsinization does not significantly decrease cellular DNA content or viability, and it does not increase protein breakdown.Trypsin treatment results in decreased oxidation of [1-¹⁴C]glucose and [6-¹⁴C]glucose, and also a decrease in ATP content. Trypsinization also causes a depression of net leucine transport and a reduction in the translational activity of polyribosomes.When normal and trypsinized macrophages are preincubated at 37 °C for several hours and then pulse-labelled with radioactive leucine, protein synthesis is stimulated to approximately the same extent in both the control and the enzyme-treated cells. Since the trypsinized cells still exhibit depressed protein synthesis, this suggests that the inhibition cannot be readily reversed.Indirect evidence indicates that the inhibition of protein synthesis is not due to entry of trypsin into the cells and suggests that the inhibition is due to changes in metabolism resulting from the action of the enzyme at the cell surface.     

Yeast killer factor: ATP leakage and coordinate inhibition of macromolecular synthesis in sensitive cells

The action of the yeast killer factor proteins on sensitive yeast cells has been examined. The killer factor caused a coordinate inhibition of protein synthesis, nucleic acid synthesis and d-[⁴C]glucose incorporation into macromolecules in growing sensitive cells. During the inhibition period ATP became detectable in the growth medium and the cellular ATP pool level fell to exhaustion. ATP synthesis continued over this period as extracellular ATP accumulated to levels 4–20-fold those found in the cellular pools of control cultures. Leakage studies on other cellular components over the ATP leakage period indicated little loss of macromolecules, but an increased efflux of pools of leucine and glucose. The results are consistent with a killer-induced alteration in the yeast cell membrane.     

Structural changes ofNoetia ponderosa red blood cell membranes during cell volume regulation in reduced salinities: A freeze fracture study

Summary Changes in molluscan blood cell membrane structure coincided with changes in membrane amino acid permeability during cell volume regulation. Blood cells were freeze fractured after the free amino acid permeability of their membranes had been altered by modifying the extracellular Ca²⁺ and intracellular ATP levels and the membrane particles examined for changes in size, number/area and distribution. Test substances that altered the divalent cation or ATP levels also altered membrane particle densities, but not size or distribution, of freeze fractured blood cells. Those test substances (Ca²⁺-free seawater, DNP, low temperature) that inhibited volume regulation and the FAA efflux caused decreased membrane particle density, while those test substances (Co²⁺, Mn²⁺) that potentiated volume regulation and the FAA efflux increased the number of membrane particles/unit area. These changes in membrane particle density appear to result from the changes in surface area due to the treatment effects on cell volume, so that the number of membrane particles per cell remained constant. Therefore, altered membrane FAA permeability is associated with altered membrane particle density, but the effect of this structural alteration on membrane permeability is not clear.Abbreviations FAA free amino acid - DMSO dimethylsulfoxide - DNP dinitrophenol - ASW artificial seawater     

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.     

Effect of ionophore A23187 on the membrane permeability in mouse fibroblasts.

Addition of the divalent cation ionophore A23187 to transformed mouse fibroblasts (3T6) resulted in an increase in the cell membrane permeability to normally impermeant solutes (e.g., nucleotides). The membrane permeability was assessed by following the efflux of prelabeled adenine nucleotides, the influx of p-nitrophenyl phosphate in cells attached to plastic dishes and reconstitution of intracellular protein synthesis in the presence of exogenously added normally impermeant factors required for macromolecular synthesis. The permeability change of 3T6 cells was found to be dependent on the specific presence of external calcium ion. The permeabilization was found to occur preferably in alkaline pH and specific to certain transformed cells. It is preceded by rapid efflux of K+, influx of Na+ and partial hydrolysis of cellular nucleotides in 3T6 cells. Similar ion fluxes were previously found to precede cell permeabilization by electrogenic ionophores for monovalent ions and by exogenous ATP. Our data suggest that a calcium dependent process caused the K+ release and excess Na+ entry, causing dissipation of the membrane potential and subsequent formation of aqueous channels.     

Biochemical and physiological changes induced by anthrax lethal toxin in J774 macrophage-like cells.

Experiments were performed to probe the mechanism by which Bacillus anthracis Lethal Toxin (LeTx) causes lysis of J774 macrophage-like cells. After incubation of cells with saturating concentrations of the toxin, two categories of effects were found, which were distinguishable on the basis of chronology, Ca(2+)-dependence, and sensitivity to osmolarity. The earliest events (category I), beginning 45 min postchallenge, were an increase in permeability to 22Na and 86Rb and a rapid conversion of ATP to ADP and AMP. Later events (category II) included alterations in membrane permeability to 45Ca, 51Cr, 36Cl, 35SO4, 3H-amino acids, and 3H-uridine, beginning at 60 min; inhibition of macromolecular synthesis, leakage of cellular lactate dehydrogenase and onset of gross morphological changes, at approximately 75 min; and cell lysis, beginning at 90 min. Category II events exhibited an absolute requirement for extracellular Ca2+ and were blocked by addition of 0.3 M sucrose to the medium, whereas category I events were attenuated, but not blocked, by either of these conditions. On the other hand, both ATP depletion and the category II events were blocked in osmotically stabilized medium that was also isoionic for Na+ and K+. This suggests that permeabilization of the plasma membrane to monovalent cations and water may be the earliest of the physiological changes described here. The resulting influx of Na+ and efflux of K+ would be expected to cause depletion of ATP, via increased activity of the Na+/K+ pump. Subsequently the influx of Ca2+, induced by depletion of ATP, imbalances in monovalent cautions, and/or more dramatic changes in permeability due to influx of water, would be expected to trigger widespread changes leading ultimately to cytolysis.     

Mitochondrial Dysfunction in the Pathogenesis of Necrotic and Apoptotic Cell Death

Mitochondria are frequently the target of injury after stresses leading to necrotic and apoptoticcell death. Inhibition of oxidative phosphorylation progresses to uncoupling when opening ofa high conductance permeability transition (PT) pore in the mitochondrial inner membraneabruptly increases the permeability of the mitochondrial inner membrane to solutes of molecularmass up to 1500 Da. Cyclosporin A (CsA) blocks this mitochondrial permeability transition(MPT) and prevents necrotic cell death from oxidative stress, Ca²⁺ ionophore toxicity,Reye-related drug toxicity, pH-dependent ischemia/reperfusion injury, and other models of cell injury.Confocal fluorescence microscopy directly visualizes onset of the MPT from the movementof green-fluorescing calcein into mitochondria and the simultaneous release from mitochondriaof red-fluorescing tetramethylrhodamine methylester, a membrane potential-indicatingfluorophore. In oxidative stress to hepatocytes induced by tert-butylhydroperoxide, NAD(P)Hoxidation, increased mitochondrial Ca²⁺, and mitochondrial generation of reactive oxygen speciesprecede and contribute to onset of the MPT. Confocal microscopy also shows directly thatthe MPT is a critical event in apoptosis of hepatocytes induced by tumor necrosis factor-.Progression to necrotic and apoptotic cell killing depends, at least in part, on the effect theMPT has on cellular ATP levels. If ATP levels fall profoundly, necrotic killing ensues. If ATPlevels are at least partially maintained, apoptosis follows the MPT. Cellular features of bothapoptosis and necrosis frequently occur together after death signals and toxic stresses. A newterm, necrapoptosis, describes such death processes that begin with a common stress or deathsignal, progress by shared pathways, but culminate in either cell lysis (necrosis) or programmedcellular resorption (apoptosis) depending on modifying factors such as ATP.     

Extracellular ATP perturbs transmembrane ion fluxes, elevates cytosolic [Ca2+], and inhibits phagocytosis in mouse macrophages

In addition to its important role in intracellular metabolic pathways, ATP appears to function as a neurotransmitter in mammalian neurones. The extracellular effects of ATP are not restricted to neurones. We describe the effects of ATP on transmembrane fluxes of monovalent and divalent cations and on phagocytosis in the J774 mouse macrophage cell line and in mouse macrophages elicited by intraperitoneal injection of thioglycollate broth. Of all nucleotides tested, only ATP is capable of depolarizing the macrophage plasma membrane potential, promoting Na+ influx and K+ efflux, effecting an increase in intracellular free Ca2+, and inhibiting phagocytosis. Nonhydrolyzable ATP analogs had no effect on membrane permeability or phagocytosis. The effect mediated by ATP is not accompanied by an increase in membrane permeability to nucleotides, indicating that the action of ATP is restricted to the external surface of macrophages.     

Autolysis of Bacillus subtilis induced by low temperature

By exposure to a temperature below the membrane phase transition point, Bacillus subtilis 168 lost their permeability control followed by the leakage of intracellular K⁺ and incapability of glucose uptake, resulting in cellular lysis in the following incubation at 37°C in the presence of a high concentration (∼ 100 mM) of monovalent cations. The result confirmed that the concomitance of energy deprivation and the presence of monovalent cations were the factors that caused the lysis observed after low temperature exposure.     

Cation selectivity of the resting membrane of squid axon

Summary Permeability constant ratios among monovalent cations were studied in the resting membrane of a giant axon of a Pacific squid,Loligo opalescens, by observing the relationship between the membrane potential and the ion concentration.The average permeability ratios are: Tl, 1.8; K, 1.0; Rb, 0.72; Cs, 0.16; Na, <0.08; Li, <0.08. These permeability ratios suggest that neither valinomycin nor nonactin are adequate models for the sites producing the resting permeability in the axonal membrane.Cyclic polyetherbis(t-butyl cyclohexyl) 18-crown-6 does not increase the permeability ratioP _Cs/P _K except when applied at concentrations (5×10^–5 m) at which the surfactant properties of this molecule may become significant.     

Permeability of membranes to amino acids and modified amino acids: Mechanisms involved in translocation

Summary The amino acid permeability of membranes is of interest because they are one of the key solutes involved in cell function. Membrane permeability coefficients (P) for amino acid classes, including neutral, polar, hydrophobic, and charged species, have been measured and compared using a variety of techniques. Decreasing lipid chain length increased permeability slightly (5-fold), while variations in pH had only minor effects on the permeability coefficients of the amino acids tested in liposomes. Increasing the membrane surface charge increased the permeability of amino acids of the opposite charge, while increasing the cholesterol content decreased membrane permeability. The permeability coefficients for most amino acids tested were surprisingly similar to those previously measured for monovalent cations such as sodium and potassium (approximately 10^–12–10^–13 cm · s^–1). This observation suggests that the permeation rates for the neutral, polar and charged amino acids are controlled by bilayer fluctuations and transient defects, rather than partition coefficients and Born energy barriers. Hydrophobic amino acids were 10² more permeable than the hydrophilic forms, reflecting their increased partition coefficient values.External pH had dramatic effects on the permeation rates for the modified amino acid lysine methyl ester in response to transmembrane pH gradients. It was established that lysine methyl ester and other modified short peptides permeate rapidly (P = 10^–2 cm · s^–1) as neutral (deprotonated) molecules. It was also shown that charge distributions dramatically alter permeation rates for modified di-peptides. These results may relate to the movement of peptides through membranes during protein translocation and to the origin of cellular membrane transport on the early Earth.Abbreviations DCP dicetylphosphate - DMPC dimyristoyl phosphatidylcholine - EPC egg phosphatidylcholine - LUV large unilamellar vesicle - MLV multilamellar vesicle - PLM planar lipid membrane - SUV small unilamellar vesicle - pH transmembrane pH gradient     

The influence of Methylprednisolone on the energy metabolism of Ehrlich ascites tumour cells

Using Ehrlich ascites tumour cells, the short-term effects of the therapeutic glucocorticoid Methylprednisolone (MP) on the cellular energy metabolism were studied. ATP-consuming processes involved in the rapid MP effects were identified indirectly from the effects of MP on cellular oxygen consumption related to the inhibition of respiration by selective inhibitors of Ca²⁺-ATPase and protein synthesis. The effects of MP on plasma membrane permeability for Ca²⁺ ions and phospholipid turnover were studied directly by using confocal laser scanning microscopy and tracerkinetic measurements, respectively. MP inhibited cellular oxygen consumption, suppressed the inhibitory effect of lanthanum but not that of cycloheximide on oxygen consumption, blocked the [Ca²⁺]_i rise in response to calcium ionophore A 23187, and decreased phospholipid turnover. MP acted instantly in a dose-dependent manner.The observed effects of MP are discussed in relation to the hypothesis that the drug has direct membrane effect affecting plasma membrane permeability and function.