Ionophoretic activity in pancreatic islets.

Extracts of pancreatic islets stimulate the translocation of calcium from an aqueous into an organic immiscible phase. This ionophoretic activity, which is derived mainly from membrane-rich subcellular fractions, displays several features in common with that of A23187 in the same model. The phenomenon of calcium translocation caused by either the islet extract or the antibiotic ionophore represents a power function of the concentration of ionophoretic material; it is saturable at high calcium concentrations, affected by the concentration of Na⁺ and pH of the aqueous phase, increased at low temperature, and inhibited by suloctidil, the latter inhibitory effect being antagonized by calcium itself. These findings underline the potential significance of native ionophores in the regulation of calcium movements across membrane systems in the islet cells.     

Calcium transport by a beta-diketone in model membranes

The beta-diketone 1,1,1,2,2,3,3-heptafluoro-7,7-dimethyloctane-4,6-dione (FOD) translocates calcium from an aqueous medium into an organic phase. FOD is less efficient than but acts synergistically with A23187 in causing calcium translocation. The FOD-mediated process of calcium translocation is inhibited by NaCl, although the translocation of sodium by FOD is two to three orders of magnitude lower than that of calcium, when expressed relative to the concentration of these cations in the aqueous medium. At pH 7.4, FOD mediates calcium exchange-diffusion in fluid liposomes as efficiently as A23187. The extent of exchange-diffusion depends on the rigidity and cholesterol content of the liposomes. Conformational analysis of the complex formed by two molecules of FOD and one calcium atom at a simulated membrane interface reveals the existence of several interconvertible, asymmetrical and more-or-less planar configurations. The efficiency of FOD-mediated calcium ionophoresis thus appears to be regulated in a multifactorial manner by such factors as the concentration of calcium and monovalent cations, chemical composition and fluidity of the membrane, availability of other ionophoretic molecules and spatial configuration of the calcium complex.     

Phospholipids as ionophores.

The ionophoretic capabilities of phospholipids have been examined by direct measurement in a Pressman cell of the phospholipid-mediated translocation of cations across an organic phase separating two aqueous phases. Cardiolipin and phosphatidic acid were the most active inonophores among the phospholipids tested, with activities comparable to that of X537A in respect to the translocation of divalent cations. Cardiolipin translocates both divalent and monovalent cations at approximately equal rates. The ionophoretic activity of cardiolipin could be modulated by other phospholipids (inhibition), by butacaine (stimulation), by complexation with cytochrome c (inhibition), and by ruthenium red and lanthanum (inhibition). The rate of translocation of cations mediated by cardiolipin was independent of pH over a wide pH range (5.4 to 8.3). The same general pattern of properties observed for cardiolipin applied to phosphatidic acid except for stimulation by butacaine. Complexation of phospholipid mixtures, such as asolectin or mitochondrial lipid, with reduced cytochrome c, enhanced the ionophoretic capability of these phospholipids by 1 order of magnitude. The complex thus formed has the properties of a polyionophore. The possible physiological significance of this enormous ionophoretic potential of phospholipids is examined.     

Lipid associated calcium ionophores in islet cell plasma membrane following glucose stimulation

The effect of glucose exposure on lipid associated calcium ionophoretic activity was measured in cultured neonatal rat pancreatic islet cells using two model systems. The first measured the ability of a lipid extract of islet cells to facilitate calcium transfer from an aqueous to organic phase and thus detected lipids which transfer calcium in the manner of authentic ionophores or which chelate the ion. In this system glucose stimulation was followed by an increase in total cell ionophoretic activity and a decrease in the activity associated with the plasma membrane. The second system measured the transfer of calcium across an artificial phospholipid membrane and detected authentic ionophoretic activity. In this model an increase in total ionophoretic activity was again seen following glucose but there was no change in the ionophoretic activity of a plasma membrane extract. The results indicate that the lipid modifications which accompany glucose-induced insulin release may alter cellular calcium stores by decreasing lipid bound calcium at the plasma membrane and increasing the capacity for calcium ionophoresis at intracellular sites.     

A mechanism for phosphoglyceride and Ca2+ transbilayer movement

The ionophoretic capabilities of phosphoglycerides (PL) have been examined by measuring their translocation via cations from aqueous dispersions into linear and cyclic hydrocarbons. The PL surveyed were phosphatidic acid (PA), phosphatidylglycerol (PG), phosphatidylethanolamine (PE), phosphatidylcholine (PC) and phosphatidylinositol (PI). Only PA displayed ionophoretic activity in single lipid dispersions with a cation selectivity order of Mn greater than Ca. PG, PE and PC, but not PI, had a synergistic affect of PA induced translocation. These PL, inactive individually or in any combination, became strong Ca2+ ionophores of variable activity in association with PA. A dimeric structure proposed for the ionophoretic species forms the basis of a mechanism for transbilayer movement of PA, PG, PE and PC which would establish an asymmetric distribution of these lipids in the two faces of the bilayer by equilibrium processes.     

An ionophoretic model for the study of calcium-calcium exchange

A Pressman cell was used to study the Br-X537A-mediated translocation of ⁴⁵Ca from one aqueous phase into another across an immiscible organic phase. In this system, an increase in the concentration of ⁴⁰Ca in one chamber (mimicking the extracellular compartment) resulted in an increased efflux of ⁴⁵Ca added in trace amount to the other chamber (simulating the cytosolic compartment). Such a Ca-Ca exchange process was also observed when the concentration of ionophore was increased, and could be blocked by the organic Ca-antagonist suloctidil. However, no Ca-Ca exchange occurred when the downhill rate of ⁴⁰Ca translocation was increased by use of a pH gradient. This ionophoretic model also suggests that a low intracellular concentration of Ca tends to maintain Ca influx at a low rate, and that the asymetrical distribution of Ca facilitates rather than impeeds the ionophoretic extrusion of intracellular Ca against its chemical gradient.     

Phosphatidate and oxidized fatty acids are calcium ionophores. Studies employing arsenazo III in liposomes

Liposomes which have entrapped the metallochromic dye, arsenazo III, constitute a sensitive assay system for ionophoresis of divalent cations. By this means we have compared known calcium ionophores (A23187, ionomycin) with membrane phospholipids, fatty acids, prostanoids, and retinoids. Added at micromolar concentrations to preformed multilamellar liposomes (phosphatidylcholine 7:dicetyl phosphate 2: cholesterol 1) both A23187 and ionomycin, as well as phosphatidic acid and products derived from linoleic acid, linolenic acid, and two eicosatrienoic acids provoked Ca influx (e.g. phosphatidic acid: 0.13 mol of Ca2+/mol of membrane lipid/5 min). A variety of other phospholipids (e.g. phosphatidylinositol), fatty acids (e.g. arachidonic acid), prostanoids (e.g. PGE1) retinoids (e.g. retinoic acid), and glyceryl ether phosphorylcholines ("platelet-activating factors") were without effect. Phosphatidic acid and oxidized fatty acids translocated divalent cations selectively, demonstrating the same rank order as A23187 or ionomycin: Mn greater than Ca greater than Sr much greater than Mg. Membrane lysis did not contribute to the perceived translocation; the liposomes remained impermeable to EDTA, EGTA, arsenazo III, or Mg. Liposomes with phosphatidic acid or oxidized trienoic acids preincorporated at 1-5 mole % of total lipids also permitted translocation of Ca but not Mg. Reduction of ionophoretic fatty acids or ionomycin with stannous chloride abolished their ionophoretic activity. Release of Ca from liposomes which had entrapped arsenazo III-Ca complexes into a medium rich in EGTA permitted calculation of efflux induced by ionophores, whether these were added to the outside of liposomes or preincorporated. Data suggest that phosphatidic acid and oxidized di- and trienoic fatty acids, which act as calcium ionophores in model bilayers, could serve as "endogenous ionophores" in cells.     

Partitioning behavior and enrichment of proteins with reversed micellar extraction: I. forward extraction of proteins from aqueous to reversed micellar phase

Protein extractions using aerosol OT (AOT)-isooctane reverse micelle solutions have been studied to explore the potential for separating and enriching proteins with the reversed micellar extraction. The effects of pH, ionic strength, and different cations of chlorides in a bulk aqueous phase and of AOT concentration in an organic phase on the partitioning of lysozyme and myoglobin and the solubilization of water are presented in detail. The extraction of lysozyme was affected by the concentration of potassium or barium but was almost independent of that of sodium or calcium, whose ionic diameter is smaller than that of potassium and barium. For the extraction of myoglobin, however, the effect of barium concentration was not appreciable. Lysozyme could be enriched into the reversed micellar phase up to 30 times the aqueous feed concentration. (c) 1993 John Wiley & Sons, Inc.     

Studies of the cation binding properties of an oligomeric derivative of prostaglandin B1

The ionophoretic activity of PGBx, an oligomeric mixture synthesized from 15-dehydro PGB1, with different cations was measured using arsenazo III-entrapped liposomes. The order of ionophoretic activity was Zn2+ greater than Co2+ greater than Mn2+ greater than Cu2+ greater than Ca2+ greater than Ba2+ greater than Sr2+ greater than Mg2+. The intrinsic fluorescence of PGBx was quenched by the binding of divalent cations as well as by La3+ and H+. Quenching by K+ and Na+ was minimal. The order of quenching strength of divalent cations was Zn2+ greater than Co2+ greater than Cu2+ = Mn2+ greater than Ca2+ greater than Ba2+ greater than Sr2+ greater than Mg2+. Binding affinities of these cations determined by a murexide indicator method were in good agreement with that determined by the fluorescence quenching reaction. The cation binding affinity of PGBx in aqueous solutions correlates with the ionophoretic activity in liposomes. The binding affinity for K+ was estimated from the inhibition by K+ of Ca2+ binding by PGBx. Although PGBx has a lower selectivity for divalent cation binding than the ionophore A23187, the characteristics of the binding affinity of these two compounds for various ions were similar. The pK of PGBx as determined by fluorescence quenching was 6.7. The molecular weight of the divalent cation binding unit was estimated to be about 680, with each PGBx molecule having three such binding sites. The binding of Ca2+ to such a site is one-to-one.     

The effects of cations on the activity of the gypsy moth (Lepidoptera: Lymantriidae) nuclear polyhedrosis virus

Fourteen cations were tested at a 1% concentration (wt:wt), as chlorides, for their effects on the biological activity of the gypsy moth, Lymantria dispar (L.), nuclear polyhedrosis virus (LdMNPV). Cupric chloride was toxic to gypsy moth larvae. Ferrous and ferric chloride were inhibitory to larval growth and development as well as to virus activity. Strontium chloride was inhibitory to virus activity but had no apparent effects on gypsy moth larvae. Six cations had little or no effect on virus activity (i.e., calcium, lanthanum, magnesium, nickel, potassium, sodium), whereas four cations (i.e., cobalt, manganese, ruthenium, zinc) acted as viral enhancers, as indicated by reductions in LC50s.     

Inhibitory analysis of the monovalent metals' cations interaction with the system of Na+-dependent Ca2+ efflux from the liver mitochondria

Kinetic analysis reveals the mainly competitive inhibition of Na+-dependent Ca2+ efflux from mitochondria by cations of monovalent metals. Potency of the inhibitory effect of metals' cations on Na+-dependent Ca2+ efflux from mitochondria matrix increases in such an order (I50, mM): Cs+ (137.11) < Rb+ (122.63) < Li+ (24.59) < Tl+ (0.541). The results of correlation analysis show that sodium ions translocation by mitochondrial exchanger and its inhibition by the cations of monovalent metals is determined by their affinity for the oxygen-containing ligands and are accompanied with the ions dehydration. Inhibition of the mitochondrial Na+/Ca2+ exchanger by monovalent metal cations is also accompanied with the inhibition of cooperative interactions of metal ions with the ionbinding centers during transport cycle, which can be one of the mechanisms of the inhibition of ions translocation by this ion-transporting system.     

Ionophore-mediated cation translocation in artificial systems. I. A23187-mediated calcium translocation.

The inophore A23187 stimulates the translocation of calcium from an aqueous Hepes buffer into an organic immiscible phase. At saturating calcium concentrations, 2 molecules of ionophore seem to complex each atom of calcium. Consistent with such a stoichiometric behaviour, the apparent ratio of calcium-ionophore association to dissociation rate constants increases as the concentration of ionophore is raised. As a result, at low calcium concentrations, the amount of translocated calcium increases as a power function of A23187 concentration. When allowance is made for such a phenomenon, the relation between calcium translocation and concentration is characterized by usual substrate-receptor binding kinetics.     

Effect of aqueous extract of Ipomoea carnea leaf on isolated frog and mouse heart

Ipomoea carnea fam. Convolvulaceae is a poisonous plant and its toxicity is supposed to be due to the cardiac and respiratory failure. The present paper describes the cardiac effect of aqueous extract of the fresh leaves of I. carnea using mouse and frog heart. The aqueous extract produced an initial blockade of isolated frog heart for 5-10 sec followed by dose dependent increase in both amplitude and rate that lasts up to 2 min. Atropine (1 microgram/ml) blocked the initial depressant phase and potentiated the stimulant effect of the aqueous extract. The dose dependent increase in cardiac contractility of aqueous extract was not altered by propranolol or calcium channel blockers like nifedipine or diltiazem. The decrease in sodium chloride concentration or increase in potassium chloride concentration or calcium chloride concentration in physiological salt solution inhibited the responses to aqueous extract while an increase in sodium chloride concentration or decrease in potassium chloride or calcium chloride concentration in physiological salt solution potentiated the responses to the aqueous extract of I. carnea. It may be suggested from the data that aqueous extract of I. carnea produces positive inotropic effect on isolate frog heart possibly by sodium extrusion or release of the intracellular calcium.     

Phosphatidic acid as a calcium ionophore in large unilamellar vesicle systems

The ionophoretic capabilities of dioleoylphosphatidic acid (DOPA) for transporting calcium across phospholipid bilayers have been investigated. Calcium uptake by large unilamellar vesicles is shown to depend on the presence of DOPA. This uptake is sensitive to the nature and concentration of calcium chelators in the vesicle interior, indicating that accumulation results from DOPA-mediated translocation of calcium across the membrane. Further, it is shown that characteristics of DOPA-mediated Ca2+ uptake are similar to those observed for the fungal calcium ionophore, A23187.     

Ionic changes induced by excitatory amino acids in the rat cerebral cortex

The ionic mechanisms underlying the action of excitatory amino acids were investigated in the rat motor cortex. Ion-selective microelectrodes were attached to micropipettes such that their tips were very close and local changes in extracellular concentration of sodium, calcium, and potassium ions elicited through ionophoretic applications of glutamate (Glu) and of its agonists N-methyl-D-aspartate (NMDA), quisqualate (Quis), and kainate (Ka) were measured. These agents produced moderate increases in [K+]o (up to 13 mM) but, in contrast, substantial tetrodotoxin-insensitive decreases in [Na+]o (maximally of 60 mM). NMDA-induced sodium responses could be blocked by manganese, while the Quis- and Ka-induced responses were not. Quis and Ka produced increases in [Ca2+]o or biphasic responses while NMDA, even with small doses, induced each time drastic decreases in [Ca2+]o (maximally of 1.15 mM), which could be attenuated or blocked by manganese but not by organic calcium channel blockers. NMDA responses could be abolished by reduced doses of 2-amino-phosphonovalerate. The largest Glu- and NMDA-induced calcium responses were observed in the superficial cortical layers, but such maxima disappeared after selective degeneration of pyramidal tract neurons. All amino acids produced sizeable reductions in the extracellular space volume. The following can be concluded. (i) All the excitatory amino acids tested induce an increased permeability to sodium and potassium ions. (ii) In addition, the NMDA-operated channels have specifically a large permeability for calcium, although calcium ions contribute only by less than 10% to the NMDA-induced inward currents.(ABSTRACT TRUNCATED AT 250 WORDS)     

Erratum

The ionophoretic capabilities of dioleoylphosphatidic acid (DOPA) for transporting calcium across phospholipid bilayers have been investigated. Calcium uptake by large unilamellar vesicles is shown to depend on the presence of DOPA. This uptake is sensitive to the nature and concentration of calcium chelators in the vesicle interior, indicating that accumulation results from DOPA-mediated translocation of calcium across the membrane. Further, it is shown that characteristics of DOPA-mediated Ca²⁺ uptake are similar to those observed for the fungal calcium ionophore, A23187.     

Effects of Internal Divalent Cations on Voltage-Clamped Squid Axons

We have studied the effects of internally applied divalent cations on the ionic currents of voltage-clamped squid giant axons. Internal concentrations of calcium up to 10 mM have little, if any, effect on the time-course, voltage dependence, or magnitude of the ionic currents. This is inconsistent with the notion that an increase in the internal calcium concentration produced by an inward calcium movement with the action potential triggers sodium inactivation or potassium activation. Low internal zinc concentrations (~1 mM) selectively and reversibly slow the kinetics of the potassium current and reduce peak sodium current by about 40% with little effect on the voltage dependence of the ionic currents. Higher concentrations (~10 mM) produce a considerable (ca. 90%) nonspecific reversible reduction of the ionic currents. Large hyperpolarizing conditioning pulses reduce the zinc effect. Internal zinc also reversibly depolarizes the axon by 20–30 mV. The effects of internal cobalt, cadmium, and nickel are qualitatively similar to those of zinc: only calcium among the cations tested is without effect.     

The stimulus-secretion coupling of glucose-induced insulin release. Metabolic effects of menadione in isolated islets.

Pancreatic islets contain an enzyme system which catalyzes the donation of hydrogen from NAD(P)H to menadione (2-methyl-1,4-naphthoquinone). In high concentrations (20 to 50 micrometer), menadione, in addition to lowering the concentration of reduced pyridine nucleotides in the islets, also impairs glycolysis and glucose oxidation, decreases ATP concentration, and inhibits proinsulin biosynthesis. However, at a 10 micrometer concentration, menadione fails to affect the concentration of adenine nucleotides, the utilization of glucose, the production of lactate and pyruvate, the oxidation of [6-14C]glucose and the synthesis of proinsulin; whereas the metabolism of glucose through the pentose shunt is markedly increased. The sole inhibitory effect of menadione 10 micrometer upon metabolic parameters is to reduce the concentration of both NADH and NADPH, such an effect being noticed in islets exposed to glucose 11.1 mM but not in those incubated at a higher glucose level (27.8 mM). Since, in the presence of glucose 11.1 mM, menadione 10 micrometer also severely decreases glucose-stimulated45 calcium net uptake and subsequent insulin release, it is concluded that the availability of reduced pyridine nucleotides may play an essential role in the secretory sequence by coupling metabolic to cationic events. Thus, when insulinotropic nutrients are oxidized in the B-cell, the increased availability of reduced pyridine nucleotides could modify the affinity for cations of native ionophoretic systems, eventually leading to the accumulation of calcium up to a level sufficient to trigger insulin release.     

Coordinated cations in dipicolinato complexes of divalent metal ions

Several salts of alkali, alkaline earth metal and organic ammonium cations of a complex anion [ML₂]²⁻ {Where L = dipicolinato dianion, M = copper(II), nickel(II) and zinc(II)} are prepared. The coordination effect of [ML₂]²⁻ with the cations such as sodium, potassium, calcium, magnesium, and organic cations namely diammonium cation of 1,5-pentanediamine, diammonium cation of 1,8-octyldiamine, mono ammonium cation of 4-aminobenzylamine are studied by determining their X-ray crystal structures. Depending on the nature of cations, four different types of structures are obtained. When calcium is the cation a polymeric structure with calcium ions bridging the [ML₂]²⁻ is observed. The salts having sodium and potassium cations form polymeric chain like structures by oxo and aqua bridges. In the case of magnesium, the hydrated form of magnesium cations coordinates to [ML₂]²⁻. The organic ammonium salts of [ML₂]²⁻ have the structural features of conventional ionic complexes. These salts easily exchange cations. The organic ammonium salts of [ML₂]²⁻ decomposes to give the corresponding metal oxides at relatively low temperature range 300-450 °C.     

The calcium channel: electrophysiological findings in cardiac cells

General properties of the calcium channel are analyzed in the myocardium under voltage clamp conditions both in multicellular properties and in single isolated cells. More recently the patch-clamp has allowed us to study single channels. In normal conditions, the selectivity of the calcium channel to Ca2+ ions is very high; however, in the absence of calcium many divalent cations and even Na ions can go through this channel. Kinetic analysis shows: calcium channel inactivation depends on Ca2+ entry rather than on membrane potential, opening of this channel requires at least two transitions of closed states before the open state. Many works refer to pharmacology of the calcium channel in heart tissue. beta-adrenergic stimulation induces a large increase in current amplitude related to the increase in maximal conductance without variation in the unitary conductance. Two interpretations are available: an increase in the opening probability and/or an increase in the number of available channels, both are consecutives to phosphorylations of the channel. Cholinergic stimulation seems to have little effect. Studies of calcium antagonists have revealed that all these substances have, at various levels, use-dependent and voltage-dependent inhibitory effect. Moreover, some dihydropyridine derivatives can even, activate the channel. Antiarrhythmic as well as general anaesthetic agents have an inhibitory action on the calcium channel besides their effects on the sodium channel or the Na-Ca exchange. Very recently, the existence of another calcium conductance was demonstrated. It is characterized by a low threshold, a pure voltage-dependent inactivation, a relatively weak sensitivity to anticalcic agents and neurotransmettors.