Characterization of the plasma and mitochondrial membrane potentials of alveolar type II cells by the use of ionic probes

Synthesis and ex vivo biological evaluation of gallium-68 labelled NODAGA chelates assessing cardiac uptake and retention

Radiolabelled lipophilic cations can be used to non-invasively report on mitochondrial dysfunction in diseases such as cardiovascular disease, cardiotoxicity and cancer. Several such lipophilic cations are currently used clinically to map myocardial perfusion using SPECT imaging. Since PET offers significant advantages over SPECT in terms of sensitivity, resolution and the capacity for dynamic imaging to allow pharmacokinetic modelling, we have synthesised and radiolabelled a series of NODAGA-based radiotracers, with triarylphosphonium-functionalisation, with gallium-68 to develop PET-compatible cationic complexes. To evaluate their capacity to report upon mitochondrial membrane potential, we assessed their pharmacokinetic profiles in isolated perfused rat hearts before and after mitochondrial depolarisation with the ionophore CCCP. All three tracers radiolabel with over 96% RCY, with log D7.4 values above -0.4 observed for the most lipophilic example of this family of radiotracers. The candidate tracer [68Ga]Ga4c exhibited non-preferential uptake in healthy cardiac tissue over CCCP-infused cardiac tissue. While this approach does show promise, the lipophilicity of this family of probes needs improving in order for them to be effective cardiac imaging agents.

K2P2.1 (TREK-1) potassium channel activation protects against hyperoxia-induced lung injury

No targeted therapies exist to counteract Hyperoxia (HO)-induced Acute Lung Injury (HALI). We previously found that HO downregulates alveolar K_2P2.1 (TREK-1) K⁺ channels, which results in worsening lung injury. This decrease in TREK-1 levels leaves a subset of channels amendable to pharmacological intervention. Therefore, we hypothesized that TREK-1 activation protects against HALI. We treated HO-exposed mice and primary alveolar epithelial cells (AECs) with the novel TREK-1 activators ML335 and BL1249, and quantified physiological, histological, and biochemical lung injury markers. We determined the effects of these drugs on epithelial TREK-1 currents, plasma membrane potential (Em), and intracellular Ca²⁺ (iCa) concentrations using fluorometric assays, and blocked voltage-gated Ca²⁺ channels (Ca_V) as a downstream mechanism of cytokine secretion. Once-daily, intra-tracheal injections of HO-exposed mice with ML335 or BL1249 improved lung compliance, histological lung injury scores, broncho-alveolar lavage protein levels and cell counts, and IL-6 and IP-10 concentrations. TREK-1 activation also decreased IL-6, IP-10, and CCL-2 secretion from primary AECs. Mechanistically, ML335 and BL1249 induced TREK-1 currents in AECs, counteracted HO-induced cell depolarization, and lowered iCa²⁺ concentrations. In addition, CCL-2 secretion was decreased after L-type Ca_V inhibition. Therefore, Em stabilization with TREK-1 activators may represent a novel approach to counteract HALI.

The mitochondrial phosphate carrier TbMCP11 is essential for mitochondrial function in the procyclic form of Trypanosoma brucei

Conserved amongst all eukaryotes is a family of mitochondrial carrier proteins (SLC25A) responsible for the import of various solutes across the inner mitochondrial membrane. We previously reported that the human parasite Trypanosoma brucei possesses 26 SLC25A proteins (TbMCPs) amongst which two, TbMCP11 and TbMCP8, were predicted to function as phosphate importers. The transport of inorganic phosphate into the mitochondrion is a prerequisite to drive ATP synthesis by substrate level and oxidative phosphorylation and thus crucial for cell viability. In this paper we describe the functional characterization of TbMCP11. In procyclic form T. brucei, the RNAi of TbMCP11 blocked ATP synthesis on mitochondrial substrates, caused a drop of the mitochondrial oxygen consumption and drastically reduced cell viability. The functional complementation in yeast and mitochondrial swelling experiments suggested a role for TbMCP11 as inorganic phosphate carrier. Interestingly, procyclic form T. brucei cells in which TbMCP11 was depleted displayed an inability to either replicate or divide the kinetoplast DNA, which resulted in a severe cytokinesis defect.

DO2A-based ligands for gallium-68 chelation: synthesis, radiochemistry and ex vivo cardiac uptake

New DO2A-based lipophilic and cationic chelators for gallium-68 have been synthesised for cardiac PET imaging. These radiotracers show preferential uptake in healthy cardiac tissue over cardiac tissue depolarised by CCCP.

Synthesis, gallium-68 radiolabelling and biological evaluation of a series of triarylphosphonium-functionalized DO3A chelators

Radiolabelled lipophilic cations that accumulate in mitochondria according to the magnitude of the mitochondrial membrane potential can be used to report non-invasively on mitochondrial dysfunction in cardiovascular disease, cardiotoxicity, and cancer. While several such cations are already commercially available for SPECT imaging, PET offers greater promise in terms of sensitivity, resolution, and capacity for dynamic imaging and pharmacokinetic modelling. We have therefore synthesised a series of three triarylphosphonium-functionalised DO3A chelators for positron emitter gallium-68, with differing alkyl-functionalisation motifs to provide opportunities for tunable lipophilicity as a means of optimising their pharmacokinetics. To assess their capacity to report on mitochondrial membrane potential, we assessed their pharmacokinetic profiles in isolated tumour cells and isolated perfused rat hearts before and after mitochondrial depolarisation with the ionophore CCCP. All three compounds radiolabelled with over 97% RCY and exhibited log D values of between -3.12 and -1.81. In vitro assessment of the uptake of the radiotracers in cultured tumour cells showed a three-fold increase in uptake compared to unchelated [⁶⁸Ga]Ga(iii). However, each complex exhibited less than 1% retention in healthy hearts, which was not significantly diminished by mitochondrial depolarisation with CCCP. This preliminary work suggests that while this approach is promising, the lipophilicity of this class of tracers must be increased in order for them to be useful as cardiac or cancer imaging agents.

Regulation of ion transport by oxidants

Ion channels perform a variety of cellular functions in lung epithelia. Oxidant- and antioxidant-mediated mechanisms (that is, redox regulation) of ion channels are areas of intense research. Significant progress has been made in our understanding of redox regulation of ion channels since the last Experimental Biology report in 2003. Advancements include: 1) identification of nonphagocytic NADPH oxidases as sources of regulated reactive species (RS) production in epithelia, 2) an understanding that excessive treatment with antioxidants can result in greater oxidative stress, and 3) characterization of novel RS signaling pathways that converge upon ion channel regulation. These advancements, as discussed at the 2013 Experimental Biology Meeting in Boston, MA, impact our understanding of oxidative stress in the lung, and, in particular, illustrate that the redox state has profound effects on ion channel and cellular function.

Function of Proton Channels in Lung Epithelia

The properties of the voltage-dependent H(+) channel have been studied in lung epithelial cells for many years, and recently HVCN1 mRNA expression has been linked directly to H(+) channel function in lung epithelium. The H(+) channel is activated by strong membrane depolarization, intracellular acidity, or extracellular alkalinity. Early on it was noted that these are surprising physiological channel characteristics when considering that lung epithelial cells have rather stable membrane potentials and a well pH-buffered intracellular milieu. This raised the question under which conditions the H(+) channel is active in lung epithelium and what is its physiological function there. Current understanding of the HVCN1 H(+) channel in lung epithelial acid secretion, its activation by an alkaline mucosal extracellular pH, and its role in the regulation of the mucosal pH of the lung has resulted in a model of mucosal pH regulation based on the parallel function of the HVCN1 H(+) channel and the CFTR HCO(3) (-) channel, which suggests that HVCN1 is a critical factor that maintains a neutral surface pH in the lung.

Trypanosoma brucei: differential requirement of membrane potential for import of proteins into mitochondria in two developmental stages

Trypanosome alternative oxidase (TAO) and the cytochrome oxidase (COX) are two developmentally regulated terminal oxidases of the mitochondrial electron transport chain in Trypanosoma brucei. Here, we have compared the import of TAO and cytochrome oxidase subunit IV (COIV), two stage-specific nuclear encoded mitochondrial proteins, into the bloodstream and procyclic form mitochondria of T. brucei to understand the import processes in two different developmental stages. Under in vitro conditions TAO and COIV were imported and processed into isolated mitochondria from both the bloodstream and procyclic forms. With mitochondria isolated from the procyclic form, the import of TAO and COIV was dependent on the mitochondrial inner membrane potential (delta psi) and required protein(s) on the outer membrane. Import of these proteins also depended on the presence of both internal and external ATP. However, import of TAO and COIV into isolated mitochondria from the bloodstream form was not inhibited after the mitochondrial delta psi was dissipated by valinomycin, CCCP, or valinomycin and oligomycin in combination. In contrast, import of these proteins into bloodstream mitochondria was abolished after the hydrolysis of ATP by apyrase or removal of the ATP and ATP-generating system, suggesting that import is dependent on the presence of external ATP. Together, these data suggest that nuclear encoded proteins such as TAO and COIV are imported in the mitochondria of the bloodstream and the procyclic forms via different mechanism. Differential import conditions of nuclear encoded mitochondrial proteins of T. brucei possibly help it to adapt to different life forms.

Physiology of fetal lung fluid clearance and the effect of labor

Respiratory morbidity in near term (> or =34 and <37 weeks) infants delivered spontaneously or by elective cesarean section (ECS) has been well documented in the literature, and accounts for a significant number of admissions to intensive care units among these neonates. Given the high rates of near-term deliveries in the USA and worldwide, the public health and economic impact of morbidity in this subgroup is considerable. Causes of respiratory distress include transient tachypnea of the newborn (TTNB), surfactant deficiency, pneumonia, and pulmonary hypertension. There is considerable evidence that physiologic events in the last few weeks of pregnancy coupled with the onset of spontaneous labor are accompanied by changes in the hormonal milieu of the fetus and its mother, resulting in rapid maturation and preparation of the fetus for delivery and neonatal transition. A surge in endogenous steroids and catecholamines accompanies term gestation and spontaneous vaginal delivery, and is responsible for some of the maturational effects. Rapid clearance of fetal lung fluid clearance plays a key role in the transition to air breathing. The bulk of this fluid clearance is mediated by transepithelial sodium reabsorption through amiloride-sensitive sodium channels in the alveolar epithelial cells with only a limited contribution from mechanical factors and Starling forces. Disruption of this process can lead to retention of fluid in air spaces, setting the stage for alveolar hypoventilation. When infants are delivered near-term, especially by cesarean section (repeat or primary) before the onset of spontaneous labor, the fetus is often deprived of these hormonal changes, making the neonatal transition more difficult. This chapter discusses the physiologic mechanisms underlying fetal lung fluid absorption and explores potential strategies for facilitating neonatal transition.

Voltage-gated proton channels help regulate pHiin rat alveolar epithelium

Voltage-gated proton channels are expressed highly in rat alveolar epithelial cells. Here we investigated whether these channels contribute to pH regulation. The intracellular pH (pHi) was monitored using BCECF in cultured alveolar epithelial cell monolayers and found to be 7.13 in nominally HCO3−-free solutions [at external pH (pHo) 7.4]. Cells were acid-loaded by the NH4+prepulse technique, and the recovery was observed. Under conditions designed to eliminate the contribution of other transporters that alter pH, addition of 10 μM ZnCl2, a proton channel inhibitor, slowed recovery about twofold. In addition, the pHiminimum was lower, and the time to nadir was increased. Slowing of recovery by ZnCl2was observed at pHo7.4 and pHo8.0 and in normal and high-K+Ringer solutions. The observed rate of Zn2+-sensitive pHirecovery required activation of a small fraction of the available proton conductance. We conclude that proton channels contribute to pHirecovery after an acid load in rat alveolar epithelial cells. Addition of ZnCl2had no effect on pHiin unchallenged cells, consistent with the expectation that proton channels are not open in resting cells. After inhibition of all known pH regulators, slow pHirecovery persisted, suggesting the existence of a yet-undefined acid extrusion mechanism in these cells.

Hypothesis: do voltage-gated H(+) channels in alveolar epithelial cells contribute to CO(2) elimination by the lung?

Although alveolar epithelial cells were the first mammalian cells in which voltage-gated H(+) currents were recorded, no specific function has yet been proposed. Here we consider whether H(+) channels contribute to one of the main functions of the lung: CO(2) elimination. This idea builds on several observations: 1) some cell membranes have low CO(2) permeability, 2) carbonic anhydrase is present in alveolar epithelium and contributes to CO(2) extrusion by facilitating diffusion, 3) the transepithelial potential difference favors selective activation of H(+) channels in apical membranes, and 4) the properties of H(+) channels are ideally suited to the proposed role. H(+) channels open only when the electrochemical gradient for H(+) is outward, imparting directionality to the diffusion process. Unlike previous facilitated diffusion models, HCO(-)(3) and H(+) recombine to form CO(2) in the alveolar subphase. Rough quantitative considerations indicate that the proposed mechanism is plausible and indicate a significant capacity for CO(2) elimination by the lung by this route. Fully activated alveolar H(+) channels extrude acid equivalents at three times the resting rate of CO(2) production.

Mechanisms and regulation of ion transport in adult mammalian alveolar type II pneumocytes

The adult alveolar epithelium consists of type I and type II (ATII) pneumocytes that form a tight barrier, which severely restricts the entry of lipid-insoluble molecules from the interstitial to the alveolar space. Current in vivo and in vitro evidence indicates that the alveolar epithelium is also an absorptive epithelium, capable of transporting Na+ from the alveolar lumen, which is bathed by a small amount of epithelial lining fluid, to the interstitial space. The in situ localization of Na(+)-K(+)-ATPase activity in ATII cells and the fact that these cells are involved in a number of crucial functions, such as surfactant secretion and alveolar remodeling after injury, led investigators to examine their transport characteristics. Radioactive flux studies, in both freshly isolated and cultured cells, and bioelectric measurements in ATII cells grown on porous supports indicate that they transport Na+ according to the Koefoed-Johnsen and Ussing model of epithelial transport. Na+ enters the apical membrane, because of the favorable electrochemical gradient, through Na+ cotransporters, a Na(+)-H+ antiport, and cation channels and is pumped across the basolateral membrane by a ouabain-sensitive Na(+)-K+ pump. Na+ transport is enhanced by substances that increase intracellular adenosine 3',5'-cyclic monophosphate. In addition to Na+ transporters, ATII cells contain several transporters that regulate their intracellular pH, including a H(+)-ATPase, which may explain the low pH of the epithelial lining fluid. The absorptive properties of ATII cells may play an important role in regulating the degree of alveolar fluid in health and disease.

Physiologic and toxicologic responses of alveolar type II cells

This report summarizes recent data regarding the direct responses of the type II alveolar epithelial cell to agents that are known to produce lung injury. These responses are not limited to cytotoxicity or cell death, but include alterations in the known differentiated functions of this cell type. Among the functions assessed and shown to be altered by toxic agents are: (1) synthesis and secretion of pulmonary surfactant; and (2) proliferation and renewal of the alveolar type I cell population. Agents such as ionizing radiation, CdCl2 and hyperoxia are shown to directly alter pulmonary surfactant phospholipid synthesis and secretion by type II cells in a manner consistent with their known effect at the whole animal level. Changes in protein synthesis are also observed. In addition, information is presented which suggests that pulmonary epithelial proliferation and repair is a complex process mediated, in part, by complex cell-cell interaction in the pulmonary parenchyma. In particular, the alveolar macrophage may play a significant role through its ability to synthesize and secrete potent growth factors that influence type II cell growth.

Simultaneous imaging of cell and mitochondrial membrane potentials

The distribution of charged membrane-permeable molecular probes between intracellular organelles, the cytoplasm, and the outside medium is governed by the relative membrane electrical potentials of these regions through coupled equilibria described by the Nernst equation. A series of highly fluorescent cationic dyes of low membrane binding and toxicity (Ehrenberg, B., V. Montana, M.-D. Wei, J. P. Wuskell, and L. M. Loew, 1988. Biophys. J. 53:785-794) allows the monitoring of these equilibria through digital imaging video microscopy. We employ this combination of technologies to assess, simultaneously, the membrane potentials of cells and of their organelles in situ. We describe the methodology and optimal conditions for such measurements, and apply the technique to concomitantly follow, with good time resolution, the mitochondrial and plasma membrane potentials in several cultured cell lines. The time course of variations induced by chemical agents (ionophores, uncouplers, electron transport, and energy transfer inhibitors) in either or both these potentials is easily quantitated, and in accordance with mechanistic expectations. The methodology should therefore be applicable to the study of more subtle and specific, biologically induced potential changes in cells.

Thallium-201 uptake relates to membrane potential and potassium permeability in human glioma cells

The mechanism for 201Tl+ uptake was studied in cultured human glioma cell lines. Ouabain (1 mM) decreased the uptake at steady-state to 60%, but the rate of uptake was faster in the presence of ouabain. Addition of non-radioactive Tl+ (to a K+-free medium) decreased the uptake, but much less than expected for a system limited by the number of transport sites. Changes in K+ concentration of incubation medium affected the 201Tl+ uptake as predicted by the electrochemical equilibrium (Nernst equation). Using the uptake in isotonic KCl as a reference for membrane potential (0 mV), the calculated membrane potential was -75 mV in a medium with 3.0 mM K+. The Tl+-flux constants and the membrane permeabilities for Tl+ and K+ were calculated from the rate of uptake and from wash-out experiments. This is a new method for membrane potential and permeability studies in cell populations. The mechanism for 201Tl+ uptake is relevant for the clinical interpretation of 201Tl+ scintigraphy.

Ultraviolet radiation induces a change in cell membrane potential in vitro: a possible signal for ultraviolet radiation induced alteration in cell activity

The regulation of a transmembrane ionic gradient, reflected by the cellular membrane potential, has been shown in several cell systems to be involved in the regulation of cell function. This investigation presents evidence that biologically relevant doses of ultraviolet radiation (UVR) will alter the membrane potential of keratinocytes in vitro. Estimation of the relative change in the steady-state membrane potential of the murine keratinocyte cell line PAM 212, the murine myelomonocytic cell line P388D1, and normal human keratinocytes in culture, were made through the use of the lipophilic cationic membrane potential sensitive probe; triphenylmethylphosphonium. Our observations indicate that UVR composed primarily of UVB (280-320 nm) radiation at doses as low as 100 J/m2 can induce a depolarization in the murine cell lines and a hyperpolarization in human keratinocytes. Evidence suggests that this difference in the direction of the membrane potential response reflects a difference in Na+/K+ ATPase activity following UVR. These results suggest a possible mechanism for modulation of keratinocyte activity induced by UVR.

The activity of powdery-mildew haustoria after feeding the host cells with different sugars, as measured with a potentiometric cyanine dye

The biotrophic parasite Erysiphe graminis f. sp. hordei produces haustoria within the cells of its host Hordeum vulgare. To determine the physiological activity of these haustoria, the electric potential across the membranes in the mitochondria of the haustorium was studied. The membrane potential was estimated with the fluorescent potentiometric cyanine dye 3,3'-dibutyloxacarbocyanine iodide. The addition of depolarizing agents (carbonylcyanide m-chlorophenylhydrazone, 2,4-dinitrophenol or KCN) to infected cells resulted in an increase of fluorescence after the addition of low concentrations or a decrease of fluorescence after the addition of higher concentrations. When the infected host cell was fed with increasing concentrations of D-glucose (25, 50, 75 mM), corresponding decreases of fluorescence were measured immediately in the mitochondria of the fungal haustoria. Sucrose induced a similar reduction of fluorescence about 20 min late. D-Galactose and D-fructose induced a somewhat smaller reduction of fluorescence, L-glucose and D-glucitol had no effect. The results indicate that haustoria take up glucose from the host cells immediately. Sucrose, D-galactose and D-fructose seem to require time to be metabolized before their products reach the fungal haustorium or mitochondria.

Potassium currents in rat type II alveolar epithelial cells

1. Type II alveolar epithelial cells isolated from adult rats and grown in primary culture were studied using the whole-cell configuration of the gigohm-seal voltage clamp technique. 2. The average specific capacitance of type II cells was 2.5 microF/cm2, suggesting that type II cell membranes in vitro are irregular, with an actual area more than twice the apparent area. 3. Most type II cells have time- and voltage-dependent outward currents carried by potassium ions. Potassium currents activate with a sigmoid time course upon membrane depolarization, and inactivate during maintained depolarization. The average maximum whole-cell K+ conductance was 1.6 nS. 4. Two distinct types of K+-selective channels underlie outward currents in type II cells. Most cells have currents resembling delayed rectifier K+ currents in skeletal muscle, nerve and immune cells. A few cells had a different type of K+ conductance which is more sensitive to block by tetraethylammonium ions, has faster 'tail currents', and activates at more positive potentials. 5. In some experiments, individual type II cells were identified by staining with phosphine, a fluorescent dye which is concentrated in lamellar bodies. Both types of K+ channels were seen in type II cells identified with this dye. 6. Phosphine added to the bathing solution reversibly reduced K+ currents and shifted K+ channel activation to more positive potentials. Excitation of phosphine to fluoresce reduced irreversibly K+ currents in type II cells. The usefulness of phosphine as a means of identifying cells for study is discussed.

Monitoring of the mitochondrial and plasma membrane potentials in human fibroblasts by tetraphenylphosphonium ion distribution

The lipophilic cation tetraphenylphosphonium (TPP+) is accumulated by human skin fibroblasts across both the plasma and mitochondrial membranes. We show here that TPP+ uptake is indeed greatly decreased under conditions leading to de-energization of mitochondria. The TPP+ accumulation in the presence of the proton ionophore FCCP has been used for determination of the plasma membrane potential across the plasma membrane, after correction for potential-independent binding of TPP+ to cellular components. Following this procedure, a value of 75 mV has been obtained. Through the amount of TPP+ released by FCCP treatment, an estimate of the in situ mitochondrial membrane potential has been made. Furthermore, we report that the mitochondrial component of TPP+ accumulation decreases with aging of fibroblast cultures.

Tetradecanoylphorbol acetate and terbutaline stimulate surfactant secretion in alveolar type II cells without changing the membrane potential

Alveolar type II cells were isolated from adult rat lungs after tissue dissociation with elastase. The effect of known secretagogues on transmembrane potential was examined in freshly isolated cells (day 0 cells) and in cells after one day of primary culture (day 1 cells). Freshly isolated type II cells were incubated with 3,3'-dipentyloxacarbocyanine (di-O-C5(3)) or 3,3'-dipropylthiadicarbocyanine (di-S-C3(5)), dyes whose intracellular fluorescence intensity is a direct function of the cellular transmembrane potential. Fluorescence was continuously recorded by fluorescence spectrophotometry. Type II cells rapidly incorporated the dyes, and the addition of gramicidin (1 microgram/ml) depolarized the cells as indicated by a change in fluorescence. Neither 12-O-tetradecanoylphorbol 13-acetate (TPA) nor terbutaline plus 3-isobutyl-1-methylxanthine (IBMX), which stimulate surfactant secretion from isolated alveolar type II cells, changed the transmembrane potential. The lipophilic cation triphenylmethylphosphonium (TPMP+) was used to quantitate the transmembrane potential of type II cells cultured for one day. Addition of TPA or terbutaline plus IBMX induced surfactant secretion but did not alter the transmembrane potential. To study further the relationship of secretion to the transmembrane potential, secretion was also determined in the presence of high extracellular potassium which depolarizes the cells and in the presence of choline in place of sodium. High potassium enhanced the basal secretion of phosphatidylcholine from 1.8% to 3.4% (P less than 0.01, n = 7). Substitution of sodium chloride by choline chloride had no effect on basal secretion but enhanced TPA-induced secretion (P less than 0.01). We conclude that high extracellular potassium induces membrane depolarization and stimulates surfactant secretion, but TPA or terbutaline plus IBMX stimulates secretion without detectable membrane depolarization and stimulation of secretion by TPA does not require extracellular sodium.

Characterization of Na+-H+ antiport in type II alveolar epithelial cells

The presence of a Na+-H+ exchange pathway in the plasma membrane of type II alveolar epithelial cells was explored using the pH-sensitive fluorescent probe 2,7-biscarboxyethyl-5,6-carboxyfluorescein (BCECF) to monitor changes in cytosolic pH. Freshly prepared pneumocytes suspended in medium at pH 7.4 had an intracellular pH of 7.07 +/- 0.07. Acid-loaded cells equilibrated in sodium-free buffer showed rapid cytoplasmic alkalinization when exposed to sodium. This response to sodium was inhibited greater than 90% by 10(-4) M amiloride. The presence of the K+ ionophore, valinomycin, had no effect on the rate of Na+-dependent alkalinization, indicating the electroneutrality of the system. Li+ partially supported the alkalinization process, but other monovalent cations, notably K+, Rb+, and Cs+, were without effect. Kinetic analysis for Na+ at the external binding site yielded KNat (dissociation constant) = 62 +/- 3 mM. Hill equation analysis of the data derived a Hill coefficient (n) = 1.2 +/- 0.1 for Na+, consistent with a 1:1 stoichiometry for Na+ and H+ for the transporter. The Ki for amiloride inhibition of proton efflux at the external locus was 0.45 microM. These findings define the transport pathway as Na+-H+ antiport, with kinetic parameters somewhat similar to those described for other cell types. Antiport activity was detected at intracellular pH (pHi) values of 6.8 or below, with no activity observed at pHi 7.0-7.2. It is suggested that Na+-H+ exchange is a major mechanism whereby pneumocytes recover from an acid load and that this transport pathway may play an important role in vectorial reabsorption of Na+ from the alveolar air spaces.

Flow cytometric estimation of transmembrane potential of macrophages--a comparison with microelectrode measurements

Potential-dependent accumulation of the lipophilic cationic dye 3,3' dihexyloxacarbocyanine (DiOC6(3)) in macrophages has been investigated. Resulting fluorescence of cells was measured by flow cytometry. Alterations of membrane potential of macrophages were induced by ionophore treatment (valinomycin and gramicidin) in a dose-dependent (10(-5) M-10(-7) M) and time-dependent (0 min-45 min) manner. Resulting changes in relative fluorescence intensity were compared with changes of transmembrane potential measured by intracellular recordings obtained by applying glass microelectrodes. The comparative studies offer the possibility to calibrate the flow cytometric estimate of membrane potential of suspended cells. Equilibration of dye partition between cells and surrounding medium is strictly potential-dependent at dye concentrations between 5 X 10(-8) M and 10(-7) M and within an incubation interval from 10 min up to 30 min after addition of dye. Conclusions are drawn concerning the field of application of the optical method. Dynamics of electrical processes following ionophore treatment are discussed in terms of molecular mechanisms of altered ionic transport.

Calcium release by noradrenaline from central sarcoplasmic reticulum in rabbit main pulmonary artery smooth muscle

The subcellular composition of relaxed and noradrenaline-contracted rabbit main pulmonary artery smooth muscle cells was measured by electron probe X-ray microanalysis of cryosections of rapidly frozen tissue. Some of the preparations were made permeable with saponin and exposed to a known free Ca ion concentration, rapidly frozen, freeze-substituted, and also analysed by electron probe X-ray microanalysis. 98% of intracellular K could be replaced by Rb. This was done to remove the K peak that partially overlaps the Ca peak in the X-ray spectra. The final [Rb]i plus residual [K]i was not significantly different from the [K]i of normal tissue. The [Ca]i in Rb-containing tissue was not significantly different from the [Ca]i in normal, K-containing tissue. Non-mitochondrial micro-regions containing high [Ca] (up to 33 mmol/kg dry wt.) were found at sites 200 nm or more away from the plasma membrane. These micro-regions also contained high [P]. We consider the identification of these regions containing high [Ca] as sarcoplasmic reticulum (s.r.), validated by: (a) conventional electron micrographs that show no other structures in main pulmonary artery smooth muscle in sufficient quantity and location to account for the frequency of these regions, (b) the previous localization of strontium, a functional calcium analogue, in the central s.r. in these smooth muscles (Somlyo & Somlyo, 1971 a), (c) the present demonstration that the central s.r. in this tissue can accumulate large amounts of calcium oxalate. The proportion of regions containing high [Ca] (greater than 12.0 mmol/kg dry wt.) was significantly higher in relaxed (35 of 330 measurements) than in the contracted (14 of 337) tissues (P less than 0.005), or 26 of 34 vs. 6 of 31 high [Ca] measurements in regions identified as s.r. through their high phosphorus content (P less than 0.006). This difference is thought to represent Ca release from the central s.r. There was no significant difference (P greater than 0.05) between the distributions of P in relaxed and contracted smooth muscle. The total cell [Ca]i in relaxed Rb-containing tissue, measured with randomly positioned small probes (3.6 mmol/kg dry wt.), was the same as that measured with large defocused probes, indicating the validity of random sampling. A mathematical model was used to estimate the frequency of including s.r. (35 nm diameter and 5% of cell volume) by a randomly positioned electron probe (50 nm), because we could not visualize s.r. in the cryosections.(ABSTRACT TRUNCATED AT 400 WORDS)

Lysophosphatidylcholine cell depolarization: increased membrane permeability for use in the determination of cell membrane potentials

Current techniques for the determination of cellular membrane potentials based on the uptake of a radiolabeled lipophilic cation, [3H]triphenylmethylphosphonium, and the cyanine dye, DiOC5(3), were analyzed in terms of the proportions of these probes which are accumulated due to potential-dependent and potential-independent forces. Measurements were made of probe uptake in two model systems: rabbit type II pneumocytes and human promyelocytic HL60 cells. For both cell types, the membrane potential-independent component of triphenylmethylphosphonium uptake was found to be a function of several variables, including the length of exposure of the cells to the transport facilitator tetraphenylboron, the concentration of tetraphenylboron, and the integrity of the cell membrane. To accurately determine the magnitude of the potential-independent component of probe uptake by type II and HL60 cells, the cell-permeabilizing agent lysophosphatidylcholine was used. The ability of lysophosphatidylcholine to depolarize cell membranes and accurately predict membrane potential-independent accumulation was found to be equal to or superior to several other techniques commonly used to achieve membrane depolarization (e.g. gramicidin, valinomycin plus high external potassium). Lysophosphatidylcholine cell treatment was found to be a simple, rapid, and accurate technique to increase cell membrane permeability and allow equilibration of intra- and extracellular ions. The method is shown to be useful for determining membrane potential-independent accumulation of both radiolabeled and fluorescent probes of membrane potential.