Simulation analysis of intracellular Na+ and Cl- homeostasis during beta 1-adrenergic stimulation of cardiac myocyte

To quantitatively understand intracellular Na⁺ and Cl⁻ homeostasis as well as roles of Na⁺/K⁺ pump and cystic fibrosis transmembrane conductance regulator Cl⁻ channel (I_CFTR) during the β1-adrenergic stimulation in cardiac myocyte, we constructed a computer model of β1-adrenergic signaling and implemented it into an excitation-contraction coupling model of the guinea-pig ventricular cell, which can reproduce membrane excitation, intracellular ion changes (Na⁺, K⁺, Ca²⁺ and Cl⁻), contraction, cell volume, and oxidative phosphorylation. An application of isoproterenol to the model cell resulted in the shortening of action potential duration (APD) after a transient prolongation, the increases in both Ca²⁺ transient and cell shortening, and the decreases in both Cl⁻ concentration and cell volume. These results are consistent with experimental data. Increasing the density of I_CFTR shortened APD and augmented the peak amplitudes of the L-type Ca²⁺ current (I_CaL) and the Ca²⁺ transient during the β1-adrenergic stimulation. This indirect inotropic effect was elucidated by the increase in the driving force of I_CaL via a decrease in plateau potential. Our model reproduced the experimental data demonstrating the decrease in intracellular Na⁺ during the β-adrenergic stimulation at 0 or 0.5 Hz electrical stimulation. The decrease is attributable to the increase in Na⁺ affinity of Na⁺/K⁺ pump by protein kinase A. However it was predicted that Na⁺ increases at higher beating rate because of larger Na⁺ influx through forward Na⁺/Ca²⁺ exchange. It was demonstrated that dynamic changes in Na⁺ and Cl⁻ fluxes remarkably affect the inotropic action of isoproterenol in the ventricular myocytes.     

Role of stretch-activated channels on the stretch-induced changes of rat atrial myocytes

The role of stretch-activated channels (SACs) on the stretch-induced changes of rat atrial myocytes was studied using a computer model that incorporated various ion channels and transporters including SACs. A relationship between the extent of the stretch and the activation of SACs was formulated in the model based on experimental findings to reproduce changes in electrical activity and Ca²⁺ transients by stretch. Action potentials (APs) were significantly changed by the activation of SACs in the model simulation. The duration of the APs decreased at the initial fast phase and increased at the late slow phase of repolarisation. The resting membrane potential was depolarised from −82 to −70 mV. The Ca²⁺ transients were also affected. A prolonged activation of SACs in the model gradually increased the amplitude of the Ca²⁺ transients. The removal of Ca²⁺ permeability through SACs, however, had little effect on the stretch-induced changes in electrical activity and Ca²⁺ transients in the control condition. In contrast, the removal of the Na⁺ permeability nearly abolished these stretch-induced changes. Plotting the peaks of the Ca²⁺ transients during the activation of the SACs along a time axis revealed that they follow the time course of the Na_i⁺ concentration. The Ca²⁺ transients were not changed when the Na_i⁺ concentration was fixed to a control value (5.4 mM). These results predicted by the model suggest that the influx of Na⁺ rather than Ca²⁺ through SACs is more crucial to the generation of stretch-induced changes in the electrical activity and associated Ca²⁺ transients of rat atrial myocytes.     

A model of the guinea-pig ventricular cardiac myocyte incorporating a transverse-axial tubular system

A model of the guinea-pig cardiac ventricular myocyte has been developed that includes a representation of the transverse–axial tubular system (TATS), including heterogeneous distribution of ion flux pathways between the surface and tubular membranes. The model reproduces frequency-dependent changes of action potential shape and intracellular ion concentrations and can replicate experimental data showing ion diffusion between the tubular lumen and external solution in guinea-pig myocytes. The model is stable at rest and during activity and returns to rested state after perturbation. Theoretical analysis and model simulations show that, due to tight electrical coupling, tubular and surface membranes behave as a homogeneous whole during voltage and current clamp (maximum difference 0.9 mV at peak tubular I_Na of −38 nA). However, during action potentials, restricted diffusion and ionic currents in TATS cause depletion of tubular Ca²⁺ and accumulation of tubular K⁺ (up to −19.8% and +3.4%, respectively, of bulk extracellular values, at 6 Hz). These changes, in turn, decrease ion fluxes across the TATS membrane and decrease sarcoplasmic reticulum (SR) Ca²⁺ load. Thus, the TATS plays a potentially important role in modulating the function of guinea-pig ventricular myocyte in physiological conditions.     

Differential effects of stretch and compression on membrane currents and [Na+]c in ventricular myocytes

Mechano-electrical feedback was studied in the single ventricular myocytes. A small fraction (approximately 10%) of the cell surface could be stretched or compressed by a glass stylus. Stretch depolarised, shortened the action potential and induced extra systoles. Stretch activated non-selective cation currents (I_ns) showed a linear voltage dependence, a reversal potential of 0 mV, a pure cation selectivity, and were blocked by 8 μM Gd³⁺ or 30 μM streptomycin. Stretch reduced Ca²⁺ and K⁺ (I_K) currents. Local compression of broadwise attached cells activated I_K but not I_ns. Cytochalasin D or colchicin, thought to disrupt the cytoskeleton, suppressed the mechanosensitivity of I_ns and I_K. During stretch, the cytosolic sodium concentration increased with spatial heterogeneities, local hotspots with [Na⁺]_c>24 mM appeared close to surface membrane and t-tubules (pseudoratiometric imaging using Sodium Green fluorescence). Electronprobe microanalysis confirmed this result and indicated that stretch increased total sodium [Na] in cell compartments such as mitochondria, nuclear envelope and nucleus. Our results obtained by local stretch differ from those obtained by end-to-end stretch (literature). We speculate that channels may be activated not only by axial but also by shear stress, and, that stretch can activate channels outside the deformed sarcomeres via second messenger.     

The blocking effect of BmP02, one novel short-chain scorpion peptide on transient outward K(+) channel of adult rat ventricular myocyte

Two components F-2-7-4 and F-2-7-5, each composed of 28 amino acid residues, were purified from the venom of Buthus martensi Karsch by an opportune procedure with cation-exchange column chromatography and repeated HPLC. Both components were totally accounted to about 0.88% dry weight of the crude venom.The molecular weights of both components were determined to be 2950 and 2935 by mass spectrometry, which were fully coincidence with that of the known novel short-chain peptides BmP02 and BmP03, respectively [Romi-Lebrun R, Martin-Eauclaire M-F, Escoubas P, Wu FQ, Lebrun B, Hisada M, Nakajima T. Characterization of four toxins from Buthus martensi scorpion venom, which act on apamin-sensitive Ca²⁺-activated K⁺ channels. Eur J Biochem 1997;145:457–464]. In addition, the sequence of component F-2-7-4 was analyzed to be the same as that of BmP02. The components F-2-7-4 and F-2-7-5 purified in this study were, thus, finally distinguished to be BmP02 and BmP03 from the same venom. Using whole cell patch-clamp recording, it was found that BmP02 diminished the current of transient outward K⁺ channel in adult rat ventricular myocyte in a concentration-dependent manner. The inhibitory effect was reversible. Dynamic studies showed that the activation, inactivation and recovery processes of the transient outward K⁺ channel were not changed significantly after applying of BmP02. In addition, when BmP02 was applied to guinea pig ventricular myocyte, both delayed and inward rectified K⁺ currents showed no change compared with the control. The results suggest strongly that BmP02 or -like peptides from scorpion venom may provide a useful probe for the studying of transient outward K⁺ channel in rat ventricular myocyte.     

Mechanisms underlying adaptation of action potential duration by pacing rate in rat myocytes

Heart rate is an essential determinant of cardiac performance. In rat ventricular myocytes, a sudden increase in rate yields to a prolongation of the action potential duration (APD). The mechanism underlying this prolongation is controversial: it has been proposed that the longer APD is due to either: (1) a decrease in K⁺ currents only or (2) an increase in Ca²⁺ current only. The aim of this study was to quantitatively investigate the contribution of Ca²⁺ and K⁺ currents in the adaptation of APD to pacing rate. Simulation using a mathematical model of ventricular rat cardiac cell model [Pandit, S.V., Clark, R.B., Giles, W.R., Demir, S.S., 2001. A mathematical model of action potential heterogeneity in adult rat left ventricular myocytes. Biophys. J. 81, 3029–3051] predicted a role in the prolongation of APD for K⁺ currents only. In patch clamp experiments, increasing the pacing rate leads to a significant increase in APD in both control and detubulated myocytes, although it was more marked in control than detubulated myocytes. Supporting the model prediction, we observed that increasing stimulation frequency leads to a decrease in K⁺ currents in voltage clamped rat ventricular myocytes (square and action potential waveforms), and to a similar extent in both cell types. We have also observed that frequency-dependent facilitation of Ca²⁺ current occurred in control cells but not in detubulated cells (square and action potential waveforms). From these experiments, we calculated that the relative contribution of Ca²⁺ and K⁺ currents to the longer APD following an increase in pacing rate is 65% and 35%, respectively. Therefore, in contrast to the model prediction, Ca²⁺ current has a significant role in the adaptation of APD to pacing rate. Finally, we have introduced a simplistic modification to the Pandit's model to account for the frequency-dependent facilitation of Ca²⁺ current.     

Docosahexaenoic acid (omega-3) blocks voltage-gated sodium channel activity and migration of MDA-MB-231 human breast cancer cells

Omega − 3 polyunsaturated fatty acids have been suggested to play an important role in cancer prevention/progression, on the one hand, and in modulation of membrane ion channels on the other. We investigated whether docosahexaenoic acid would influence the in vitro migration of MDA-MB-231 human breast cancer cells. An important follow-up question was whether any effect would involve voltage-gated Na⁺ channels, shown previously to occur in human breast cancer in vitro and in vivo and to correlate with metastatic potential. Short-term (acute) and long-term (24–72 h) application of docosahexaenoic acid suppressed the activity of the channel activity in a dose-dependent manner. At the working concentrations of docosahexaenoic acid used (0.05–0.5 μM), there was no effect on proliferation. Long-term treatment with docosahexaenoic acid down-regulated mRNA and protein (total and plasma membrane) levels of neonatal Nav1.5 voltage-gated Na⁺ channel, known to be predominant in these cells. Docosahexaenoic acid suppressed migration of the MDA-MB-231 cells to the same extent as tetrodotoxin, a highly specific blocker of voltage-gated Na⁺ channels, but the two effects were not additive. It was concluded that the docosahexaenoic acid-induced suppression of cellular migration occurred primarily via down-regulation of voltage-gated Na⁺ channel (neonatal Nav1.5) mRNA and functional protein expression.     

A significant fraction of calcium transients in intact Guinea Pig ventricular myocytes is mediated by Na-Ca exchange

Ca²⁺ mobilization elicited by simulation with brief pulses of high K + were monitored with confocal laser scanned microscopy in intact, guinea pig cardiac myocytes loaded with the calcium indicator fluo-3. Single wavelength ratioing of fluorescence images obtained after prolonged integration times revealed non-uniformities of intracellular Ca²⁺ changes across the cell, suggesting the presence of significant spatial Ca²⁺ gradients. Treatment with 20 μM ryanodine, an inhibitor of Ca²⁺ release from the SR, and 10 μM verapamil, a calcium channel blocker, reduced by 42% and 76% respectively the changes in [Ca²⁺]_i elicited by membrane depolarization. The overall spatial distribution of [Ca²⁺]_i changes appeared unchanged. Ca²⁺ transients recorded in the presence of verapamil and ryanodine (about 20% of the size of control responses), diminished in the presence of 50 μM 2-4 Dichlorbenzamil (DCB) or 5 mM nickel, two relatively specific inhibitors of the exchange mechanism. Conversely, when the reversal potential of the exchange was shifted to negative potentials by lowering [Na⁺]₀ or by increasing [Na⁺]_i by treatment with 20 μM monensin, the amplitude of these Ca²⁺ transients increased. Ca²⁺ transients elicited by membrane depolarization and largely mediated by reverse operation of Na⁺-Ca²⁺ exchange could be recorded in the presence of ryanodine, verapamil and monensin. These findings suggest that in intact guinea pig cardiac cells, Ca²⁺ influx through the exchange mechanism activated by a membrane depolarization in the physiological range can be sufficient to play a significant role in excitation-contraction coupling.     

Effect of U-50,488H on the contractile response of cardiomyopathic hamster ventricular myocytes

We examined the effects of a selective κ opioid receptor agonist (U-50,488H) on the contractile properties of single ventricular myocytes from 127 day old control (F1B) and cardiomyopathic (BIO 14.6) hamsters. Myocytes in bicarbonate buffered solution with 1.5 mM [Ca²⁺] were electrically stimulated with field electrodes in the bath. Length changes were monitored via myocyte edge tracking. Twitch amplitude and the velocity of cell shortening were less in the cardiomyopathic hamster myocytes than in age-matched hamsters (P≤0.05). There was a concentration-dependent effect of U-50,488H (0.1–20 μM) to decrease twitch amplitude and shortening velocity in both control and cardiomyopathic myocytes (P≤0.001). In cells loaded with the Ca²⁺ indicator indo-1 the negative inotropic action of U-50,488H was associated with a decreased indo-1 fluorescence transient amplitude. There was no difference in the negative inotropic effect of U-50,488H on control and cardiomyopathic cells. Thus, the CM hamster does not demonstrate a different contractile response to U-50,488H.     

Glutamate transporter GLAST/EAAT1 directs cell surface expression of FXYD2/gamma subunit of Na, K-ATPase in human fetal astrocytes

Na⁺-dependent uptake of excitatory neurotransmitter glutamate in astrocytes increases cell energy demands primarily due to the elevated ATP consumption by glutamine synthetase and Na⁺, K⁺-ATPase. The major pool of GLAST/EAAT1, the only glutamate transporter subtype expressed by human fetal astrocytes in undifferentiated cultures, was restricted to the cytoplasmic compartment. Elevated glutamate concentrations (up to 50 μM) stimulated both glutamate uptake and Na⁺, K⁺-ATPase activity and concomitantly increased cell surface expression of GLAST and FXYD2/γ subunit of Na⁺, K⁺-ATPase. Intracellular accumulation of glutamate or its metabolites per se was not responsible for these changes since metabolically inert transport substrate, d-aspartate, exerted the same effect. Nanomolar concentrations of TFB-TBOA, a novel nontransportable inhibitor of glutamate carriers, almost completely reversed the action of glutamate or d-aspartate. In the same conditions (i.e. block of glutamate transport) monensin, a potent Na⁺ ionophore, had no significant effect neither on the activation of Na⁺, K⁺-ATPase nor on the cell surface expression of γ subunit or GLAST. In order to elucidate the roles of γ subunit in the glutamate uptake-dependent trafficking events or the activation of the astroglial sodium pump, in some cultures γ subunit/FXYD2 was effectively knocked down using siRNA silencing. Unlike the blocking effect of TFB-TBOA, the down-regulation of γ subunit had no effect neither on the trafficking nor activity of GLAST. However, the loss of γ subunit effectively abolished the glutamate uptake-dependent activation of Na⁺, K⁺-ATPase. Following withdrawal of siRNA from cultures, the expression levels of γ subunit and the sensitivity of Na⁺, K⁺-ATPase to glutamate/aspartate uptake have been concurrently restored. Thus, the activity of GLAST directs FXYD2 protein/γ subunit to the cell surface, that, in turn, leads to the activation of the astroglial sodium pump, presumably due to the modulatory effect of γ subunit on the kinetic parameters of catalytic subunit(s) of Na⁺, K⁺-ATPase.     

Late sodium current in failing heart: Friend or foe?

Most cardiac Na⁺ channels open transiently upon membrane depolarization and then are quickly inactivated. However, some channels remain active, carrying the so-called persistent or late Na⁺ current (I_NaL) throughout the action potential (AP) plateau. Experimental data and the results of numerical modeling accumulated over the past decade show the emerging importance of this late current component for the function of both normal and failing myocardium. I_NaL is produced by special gating modes of the cardiac-specific Na⁺ channel isoform. Heart failure (HF) slows channel gating and increases I_NaL, but HF-specific Na⁺ channel isoform underlying these changes has not been found. Na⁺ channels represent a multi-protein complex and its activity is determined not only by the pore-forming subunit but also by its auxiliary β subunits, cytoskeleton, calmodulin, regulatory kinases and phosphatases, and trafficking proteins. Disruption of the integrity of this protein complex may lead to alterations of I_NaL in pathological conditions. Increased I_NaL and the corresponding Na⁺ flux in failing myocardium contribute to abnormal repolarization and an increased cell Ca²⁺ load. Interventions designed to correct I_NaL rescue normal repolarization and improve Ca²⁺ handling and contractility of the failing cardiomyocytes. This review considers (1) quantitative integration of I_NaL into the established electrophysiological and Ca²⁺ regulatory mechanisms in normal and failing cardiomyocytes and (2) a new therapeutic strategy utilizing a selective inhibition of I_NaL to target both arrhythmias and impaired contractility in HF.     

The sodium cycle. II. Na-coupled oxidative phosphorylation in Vibrio alginolyticus cells

The role of Na⁺ in Vibrio alginolyticus oxidative phosphorylation has been studied. It has been found that the addition of a respiratory substrate, lactate, to bacterial cells exhausted in endogenous pools of substrates and ATP has a strong stimulating effect on oxygen consumption and ATP synthesis. Phosphorylation is found to be sensitive to anaerobiosis as well as to HQNO, an agent inhibiting the Na⁺-motive respiratory chain of V. alginolyticus. Na⁺ loaded cells incubated in a K⁺ or Li⁺ medium fail to synthesize ATP in response to lactate addition. The addition of Na⁺ at a concentration comparable to that inside the cell is shown to abolish the inhibiting effect of the high intracellular Na⁺ level. Neither lactate oxidation nor Δω generation coupled with this oxidation is increased by external Na⁺ in the Na⁺-loaded cells. It is concluded that oxidative ATP synthesis in V. alginolyticus cells is inhibited by the artificially imposed reverse ΔPNa, i.e., [Na⁺]_in > [Na⁺]_out. Oxidative phosphorylation is resistant to a protonophorous uncoupler (0.1 mM CCCP) in the K⁺-loaded cells incubated in a high Na⁺ medium, i.e., when ΔpNa of the proper direction ([Na⁺]_in < [Na⁺]_out) is present. The addition of monensin in the presence of CCCP completely arrests the ATP synthesis. Monensin without CCCP is ineffective. Oxidative phosphorylation in the same cells incubated in a high K⁺ medium (ΔpNa is low) is decreased by CCCP even without monensin. Artificial formation of ΔpNa by adding 0.25 M NaCl to the K⁺-loaded cells (Na⁺ pulse) results in a temporary increase in the ATP level which spontaneously decreases again within a few minutes. Na⁺ pulse-induced ATP synthesis is completely abolished by monensin and is resistant to CCCP, valinomycin and HQNO. 0.05 M NaCl increases the ATP level only slightly. Thus, V. alginolyticus cells at alkaline pH represent the first example of an oxidative phosphorylation system which uses Na⁺ instead of H⁺ as the coupling ion.     

Physiological modulation of voltage-dependent inactivation in the cardiac muscle L-type calcium channel: a modelling study

The inactivation of the L-type Ca²⁺ current is composed of voltage-dependent and calcium-dependent mechanisms. The relative contribution of these processes is still under dispute and the idea that the voltage-dependent inactivation could be subject to further modulation by other physiological processes had been ignored. This study sought to model physiological modulation of inactivation of the current in cardiac ventricular myocytes, based upon the recent detailed experimental data that separated total and voltage-dependent inactivation (VDI) by replacing extracellular Ca²⁺ with Mg²⁺ and monitoring L-type Ca²⁺ channel behaviour by outward K⁺ current flowing through the channel in the absence of inward current flow. Calcium-dependent inactivation (CDI) was based upon Ca²⁺ influx and formulated from data that was recorded during β-adrenergic stimulation of the myocytes. Ca²⁺ influx and its competition with non-selective monovalent cation permeation were also incorporated into channel permeation in the model. The constructed model could closely reproduce the experimental Ba²⁺ and Ca²⁺ current results under basal condition where no β-stimulation was added after a slight reduction of the development of fast voltage-dependent inactivation with depolarization. The model also predicted that under β-adrenergic stimulation voltage-dependent inactivation is lost and calcium-dependent inactivation largely compensates it. The developed model thus will be useful to estimate the respective roles of VDI and CDI of L-type Ca²⁺ channels in various physiological and pathological conditions of the heart which would otherwise be difficult to show experimentally.     

Hypoosmotic shock activates Ca channels in isolated nerve terminals

Influence of hypotonic swelling on Ca²⁺ (⁴⁵Ca²⁺) uptake in rat brain synaptosomes was studied. A decrease in medium osmolality from 310 to 260-180 mOsm led to a progressive stimulation of ⁴⁵Ca²⁺ accumulation. The effect was blocked by verapamil (IC₅₀ = 5 μM), CoCl₅₀ = 58 μM) and retained at a fixed concentration of external sodium indicating the involvement of Ca²⁺ channels rather than Na⁺/Ca²⁺ exchange in swelling-induced Ca²⁺ influx. The populations of calcium channels observed in hypoosmotic and depolarizing conditions are different in three aspects: (i) kinetics of ⁴⁵Ca²⁺ entry; (ii) insensitivity to dihydropyridines and ω-conotoxin GVIA; (iii) insensitivity to preliminary depolarization by high potassium. The effects of swelling and depolarization on Ca²⁺ uptake were additive. No change in membrane potential monitored with diS-C₃-(5) was recorded during synaptosome hypotonic swelling. The results suggest the existence in synaptosomal plasma membrane of volume-dependent calcium-permeable channels with properties distinct from those of the voltage-dependent calcium channels. Activation of these channels may constitute an early event in volume regulation of nerve terminals in anisoosmotic conditions.     

The role of the Na+/Ca2+ exchangers in Ca2+ dynamics in ventricular myocytes

The role of the Na⁺/Ca²⁺ exchanger (NCX) as the main pathway for Ca²⁺ extrusion from ventricular myocytes is well established. However, both the role of the Ca²⁺ entry mode of NCX in regulating local Ca²⁺ dynamics and the role of the Ca²⁺ exit mode during the majority of the physiological action potential (AP) are subjects of controversy. The functional significance of NCXs location in T-tubules and potential co-localization with ryanodine receptors was examined using a local Ca²⁺ control model of low computational cost. Our simulations demonstrate that under physiological conditions local Ca²⁺ and Na⁺ gradients are critical in calculating the driving force for NCX and hence in predicting the effect of NCX on AP. Under physiological conditions when 60% of NCXs are located on T-tubules, NCX may be transiently inward within the first 100 ms of an AP and then transiently outward during the AP plateau phase. Thus, during an AP NCX current (I_NCX) has three reversal points rather than just one. This provides a resolution to experimental observations where Ca²⁺ entry via NCX during an AP is inconsistent with the time at which I_NCX is thought to become inward. A more complex than previously believed dynamic regulation of I_NCX during AP under physiological conditions allows us to interpret apparently contradictory experimental data in a consistent conceptual framework. Our modelling results support the claim that NCX regulates the local control of Ca²⁺ and provide a powerful tool for future investigations of the control of sarcoplasmic reticulum (SR) Ca²⁺ release under pathological conditions.     

Inhibition of K+ efflux prevents mitochondrial dysfunction, and suppresses caspase-3-, apoptosis-inducing factor-, and endonuclease G-mediated constitutive apoptosis in human neutrophils

Neutrophils die rapidly via apoptosis and their survival is contingent upon rescue from constitutive programmed cell death by signals from the microenvironment. In these experiments, we investigated whether prevention of K⁺ efflux could affect the apoptotic machinery in human neutrophils. Disruption of the natural K⁺ electrochemical gradient suppressed neutrophil apoptosis (assessed by annexin V binding, nuclear DNA content and nucleosomal DNA fragmentation) and prolonged cell survival within 24–48 h of culture. High extracellular K⁺ (10–100 mM) did not activate extracellular signal-regulated kinase (ERK) and Akt, nor affected phosphorylation of p38 MAPK associated with constitutive apoptosis. Consistently, pharmacological blockade of ERK kinase or phosphatidylinositol 3-kinase (PI 3-kinase) did not affect the anti-apoptotic action of KCl. Inhibition of K⁺ efflux effectively reduced, though never completely inhibited, decreases in mitochondrial transmembrane potential (ΔΨ_m) that preceded development of apoptotic morphology. Changes in ΔΨ_m resulted in attenuation of cytochrome c release from mitochondria into the cytosol and decreases in caspase-3 activity. Culture of neutrophils in medium containing 80 mM KCl with the pan-caspase inhibitor Z-VAD-FMK resulted in slightly greater suppression of apoptosis than KCl alone. High extracellular KCl also attenuated translocation of apoptosis-inducing factor (AIF) and endonuclease G (EndoG) from mitochondria to nuclei. The DNase inhibitor, aurintricarboxylic acid (ATA) partially inhibited nucleosomal DNA fragmentation, and the effects of ATA and 80 mM KCl were not additive. These results show that prevention of K⁺ efflux promotes neutrophil survival by suppressing apoptosis through preventing mitochondrial dysfunction and release of the pro-apoptotic proteins cytochrome c, AIF and EndoG independent of ERK, PI 3-kinase and p38 MAPK. Thus, K⁺ released locally from damaged cells may function as a survival signal for neutrophils.     

Mg2+ ion effect on conformational equilibrium of poly A . 2 poly U and poly A poly U in aqueous solutions

Differential UV spectroscopy and thermal denaturation were used to study the Mg²⁺ ion effect on the conformational equilibrium in poly A · 2 poly U (A2U) and poly A · poly U (AU) solutions at low (0.01 M Na⁺) and high (0.1 M Na⁺) ionic strengths. Four complete phase diagrams were obtained for Mg²⁺–polynucleotide complexes in ranges of temperatures 20–96 °C and concentrations (10⁻⁵–10⁻²) M Mg²⁺. Three of them have a ‘critical’ point at which the type of the conformational transition changes. The value of the ‘critical’ concentration ([Mg_t²⁺]_cr=(4.5±1.0)×10⁻⁵ M) is nearly independent of the initial conformation of polynucleotides (AU, A2U) and of Na⁺ contents in the solution. Such a value is observed for Ni²⁺ ions too. The phase diagram of the (A2U+Mg²⁺) complex with 0.01 M Na⁺ has no ‘critical’ point: temperatures of (3→2) and (2→1) transitions increase in the whole Mg²⁺ range. In (AU+Mg²⁺) phase diagram at 0.01 M Na⁺ the temperature interval in which triple helices are formed and destroyed is several times larger than at 0.1 M Na⁺. Using the ligand theory, a qualitative thermodynamic analysis of the phase diagrams was performed.     

Possible interaction of [H]glutamate binding sites with anion channels in rat neural tissues

The effect of various ions on [³H] -glutamic acid (Glu) binding was examined using crude synaptic membrane preparations from the rat brain. In vitro addition of sodium acetate (1–100 mM) exhibited a significant enhancement of the binding in a concentration dependent manner. Ammonium chloride (20 mM) prevented the potentiation by sodium acetate at 2°C, whereas sodium acetate exerted an inhibitory action on the ammonium chloride-induced augmentation of the binding at 30°C. Ammonium chloride (1–100 mM) itself elicited a temperature dependent stimulation of the binding, which was invariably attenuated by an antagonist for the anion channels such as picrotoxinin (10⁻³ M) as well as by inhibitors of anion transport including ethacrynic acid (10⁻³ M) and 4,4′-diisothiocyanatostilbene-2,2′-disulfonic acid (10⁻⁴−10⁻³ M), respectively. The later two inhibitors also caused a significant additional raise of the sodium acetate-induced enhancement of the binding. A significant augmentation of the binding resulted from the addition (20 mM) of various anions known to penetrate the anion channels such as bromide, iodide, nitrate, bicarbonate and thiocyanate in a permeability related manner, while that of non-permeable anions including fluoride, sulfate, acetate, formate, phosphate, oxalate, lactate, succinate and tartarate had no such a profound effect on the binding. Addition of -aspartic acid resulted in the complete abolition of the Na⁺-dependent binding while sparing the Cl⁻-dependent binding. Scatchard analysis revealed that Cl⁻ ions induced a two-fold increase in the number of the binding sites without affecting their affinity, whereas Na⁺ ions reduced the affinity with a concomitant increase of the number of the binding sites. Addition of quisqualic acid (10⁻⁵−10⁻³ M) inhibited the Cl⁻-dependent binding of [³H]Glu to a significantly greater extent than the inhibition on Na⁺-dependent binding. acid and kainic acid exerted no preventive action on the basal, Cl⁻-dependent and Na⁺-dependent binding. respectively. The highest basal binding activity was found in the retina among various central structures examined. A significant basal binding activity of [³H]Glu was also detected in the pituitary and adrenal but not in the kidney. Chloride ions exhibited a significant facilitation of [³H]Glu binding to central regions without altering that to peripheral tissues such as pituitary and adrenal. In contrast, Na⁺ ions induced significant attenuation of the binding to the pituitary, adrenal and retina despite the occurrence of augmentation of the binding to other central structures.

These results suggest the Glu binding sites may be linked to the anion channels in the rat central nervous system and that this linkage may be absent from the pituitary, adrenal and retina.     

Effects of Tetraethylammoniumchloride (TEA), Vanadate, and Alkali Ions on the Lateral Leaflet Movement Rhythm of Desmodium motorium (Houtt.) Merr

The period (∼3-5 min) of the ultradian rhythm of the lateral leaflet movement of Desmodium motorium is strongly lengthened (≤30-40%) by the K⁺ channel blocker tetraethylammoniumchloride (20, 30, and 40 mM) and vanadate (0.5 and 1 mM), which is an effective inhibitor of the plasma membrane-bound H⁺ pump. The alkali ions K⁺, Na⁺, Rb⁺, and Cs⁺ (10-40 mM) shorten the period only slightly (≤ 10-15%). Li⁺ (5-30 mM), however, increases the period of the leaflet rhythm drastically (≤80%). We concluded that the plasmalemma-H⁺-ATP-ase-driven K⁺ transport through K⁺ channels is an essential component of the ultradian oscillator of Desmodium, as has been proposed for the circadian oscillator.     

Modulation of ouabain-insensitive Na(+)-ATPase activity in the renal proximal tubule by Mg(2+), MgATP and furosemide

In addition to the (Na⁺+K⁺)ATPase another P-ATPase, the ouabain-insensitive Na⁺-ATPase has been observed in several tissues. In the present paper, the effects of ligands, such as Mg²⁺, MgATP and furosemide on the Na⁺-ATPase and its modulation by pH were studied in the proximal renal tubule of pig. The principal kinetics parameters of the Na⁺-ATPase at pH 7.0 are: (a) K_0.5 for Na⁺=8.9±2.2 mM; (b) K_0.5 for MgATP=1.8±0.4 mM; (c) two sites for free Mg²⁺: one stimulatory (K_0.5=0.20±0.06 mM) and other inhibitory (I_0.5=1.1±0.4 mM); and (d) I_0.5 for furosemide=1.1±0.2 mM. Acidification of the reaction medium to pH 6.2 decreases the apparent affinity for Na⁺ (K_0.5=19.5±0.4) and MgATP (K_0.5=3.4±0.3 mM) but increases the apparent affinity for furosemide (0.18±0.02 mM) and Mg²⁺ (0.05±0.02 mM). Alkalization of the reaction medium to pH 7.8 decreases the apparent affinity for Na⁺ (K_0.5=18.7±1.5 mM) and furosemide (I_0.5=3.04±0.57 mM) but does not change the apparent affinity to MgATP and Mg²⁺. The data presented in this paper indicate that the modulation of the Na⁺-ATPase by pH is the result of different modifications in several steps of its catalytical cycle. Furthermore, they suggest that changes in the concentration of natural ligands such as Mg²⁺ and MgATP complex may play an important role in the Na⁺-ATPase physiological regulatory mechanisms.