Sensitivity of erythrocyte acetycholinesterase to inhibition by linolenoyl sorbitol. Dependence on a transmembrane potential

Acetylcholinesterase activity of human erythrocytes is known to be inhibited by linolenoyl sorbitol, the inhibition being critically dependent on cell membrane intactness. The extent of enzyme inhibition by the added lipid is correlated with the magnitude of Cl^? gradient across the erythrocyte membrane, indicating that enzyme sensitivity is associated with a transmembrane potential. If linolenoyl sorbitol is allowed to interact with the erythrocytes while a Cl^? gradient exists, enzyme sensitivity can subsequently be demonstrated not only in the absence of a gradient but even when the cells are lyzed. It is concluded that the transmembrane potential determines the accessibility of a membrane component to the added lipid.     

Acetylcholine esterase as a probe for erythrocyte-membrane intactness

Erythrocyte acetylcholine esterase can be assayed in intact cells and was tested as a probe for membrane changes. Acetylcholine esterase activity correlated with the erythrocyte relative volume. Antihemolytic acyl sorbitols, fatty acids and phenothiazines inhibit to varying extents the activity of acetylcholine esterase. The inhibition of acetylcholine esterase by linolenoyl sorbitol was further characterized and found to be non-competitive and critically dependent on cell intactness over a wide temperature range. Neither solubilized nor ghost acetylcholine esterase was affected by the acyl sorbitol while under conditions optimal for ghost resealing, the enzyme resumed the sensitivity to the acyl sorbitol. Acetylcholine esterase sensitivity thus appears to be a promising tool to follow the dynamics of membrane integrity.     

Characterisation of the effects of anthranilic and (indanyloxy) acetic acid derivatives on chloride transport in membrane vesicles.

The effects of the Cl- channel blockers, NPPB, IAA94/95 and a number of related compounds on 36Cl- transport in membrane vesicles from bovine kidney cortex and rabbit ileum mucosa brush borders have been studied. These vesicles have been previously shown to be enriched in Cl- channel and Cl-/anion cotransport activity, respectively. Chloride transport was assayed in both types of vesicles by measuring the uptake of 36Cl- in response to an outwardly-directed Cl- concentration gradient. In kidney microsomes, a large proportion of the observed 36Cl- uptake was mediated by an electrogenic uniport and could be substantially reduced by clamping the membrane potential at zero mV using K+ and valinomycin. Chloride uptake was inhibited by both NPPB and IAA94/95 with apparent IC50 values of around 10 microM under optimal conditions (i.e., 4 min uptake at 4 degrees C). Under other conditions (e.g., 10 min uptake at 25 degrees C), where uptake had reached a steady-state level, much higher concentrations of inhibitor were required to cause inhibition. Therefore, previous differences in the reported potency of these compounds may, in part, have been due to the conditions under which Cl- uptake was measured. In addition, both NPPB and, to a lesser extent, IAA94/95 were found to have other effects on the vesicles, in that, when added at a concentration of 100 microM, they induced a leakage of pre-accumulated 36Cl-. This was probably caused by either dissipation of membrane potential or damage to the vesicle membranes. The sulphonic acid derivatives of NPPB and IAA94/95 (NPPB-S and ISA94/95, respectively) blocked 36Cl- uptake with around the same potency as NPPB and IAA94/95, but did not cause any non-specific Cl- leakage, when added at concentrations up to 100 microM. Inhibition of 36Cl- uptake by all four compounds was almost completely reversible. However, when vesicles were incubated with the inhibitors in the presence of an outward Cl- concentration gradient, or if vesicles were freeze/thawed in the presence of the compounds, inhibition could be only partially reversed. In rabbit brush border membrane vesicles, 36Cl- uptake was not reduced when the vesicles were voltage clamped using valinomycin and K+, and was therefore probably mediated by Cl-/Cl- exchange. However, despite the lack of effect of valinomycin, 36Cl- uptake was inhibited by both NPPB (approx. 80% inhibition at 100 microM) and, to a lesser extent, by IAA94/95 (approx. 30% inhibition at 100 microM).(ABSTRACT TRUNCATED AT 400 WORDS)     

ATP-dependent uptake of 5-hydroxytryptamine by secretory granules isolated from thyroid parafollicular cells.

The current study was done to test the hypotheses that parafollicular granules contain a vacuolar ATPase (V-ATPase) similar to that found in chromaffin granules, that the transport of H+ into granules mediated by this enzyme drives the granular uptake of 5-hydroxytryptamine (5-HT, serotonin), and that secretagogues stimulate both the acidification of parafollicular granules and their ability to take up 5-HT by opening an anion channel in the granular membrane. Our studies indicate that parafollicular granules contain a V-ATPase that is antigenically similar to that of the V-ATPase of adrenal chromaffin granules; however, the parafollicular granular membrane differs from that of chromaffin granules in permeability to Cl- and K+. The membranes of granules derived from resting parafollicular cells appear to be relatively impermeable to Cl- but permeable to K+. Parafollicular granules (and ghosts derived from them) manifest ATP-dependent transmembrane transport of 5-HT. This transport is more dependent on the pH difference (delta pH) than on the membrane potential component of the proton electrochemical gradient across the granular membrane. Transport of 5-HT is thus inhibited more by exposure of parafollicular granules to agents, such as nigericin, that collapse delta pH than by those, such as valinomycin, that decrease transmembrane difference in potential. ATP-dependent uptake of 5-HT by granules isolated from secretagogue-stimulated parafollicular cells is greater than that into granules isolated from unstimulated cells. Since secretagogues open a Cl- channel in parafollicular granule membranes, which enhances acidification of the granules, the facilitation of 5-HT uptake by secretagogues is probably due to an increase in delta pH.     

Electroneutral, HCO3(-)-independent, pH gradient-dependent uphill transport of Cl- by ileal brush-border membrane vesicles. Possible role in the pathogenesis of chloridorrhea.

By applying a rapid filtration technique to isolated brush border membrane vesicles from guinea pig ileum, 36Cl uptake was quantified in the presence and absence of electrical, pH and alkali-metal ion gradients. A mixture of 20 mM-Hepes and 40 mM-citric acid, adjusted to the desired pH with Tris base, was found to be the most suitable buffer. Malate and Mes could be used to replace the citrate, but succinate, acetate and maleate proved to be unsuitable. In the absence of a pH gradient (pHout:pHin = 7.5:7.5), Cl- uptake increased slightly when an inside-positive membrane potential was applied, but uphill transport was never observed. A pH gradient (pHout:pHin = 5.0:7.5) induced both a 400% increase in the initial Cl- influx rate and a long-lasting (20 to 300 s) overshoot, indicating that a proton gradient can furnish the driving force for uphill Cl- transport. Under pH gradient conditions, initial Cl- entry rates had the following characteristics. (1) They were unaffected by cis-Na+ and/or -K+, indicating the absence of Cl-/K+, Cl-/Na+ or Cl-/K+/Na+ symport activity. (2) Inhibition by 20-100 mM-trans-Na+ and/or -K+ occurred, independent of the existence of an ion gradient. (3) Cl- entry was practically unaffected by short-circuiting the membrane potential with equilibrated potassium and valinomycin. (4) Carbonyl cyanide m-chlorophenylhydrazone was strongly inhibitory and so, to a lesser extent, was 4-acetamido-4'-isothiocyanostilbene-2,2'-disulphonic acid [(SITS)], independent of the sign and size of the membrane potential. (5) Cl- entry was negligibly increased (less than 30%) by either trans-Cl- or -HCO3-, indicating the absence of an obligatory Cl-/anion antiport activity. In contrast, the height of the overshoot at 60 s was increased by trans-Cl-, indicating time-dependent inhibition of 36Cl efflux. That competitive inhibition of 36Cl fluxes by anions is involved here is supported by initial influx rate experiments demonstrating: (1) the saturability of Cl- influx, which was found to exhibit Michaelis-Menten kinetics; and (2) competitive inhibition of influx by cis-Cl- and -Br-. Quantitatively, the conclusion is warranted that over 85% of the total initial Cl- uptake energized by a pH gradient involves an electroneutral Cl-/H+ symporter or its physicochemical equivalent, a Cl-/OH- antiporter, exhibiting little Cl- uniport and either Cl-/Cl- or Cl-/HCO3- antiport activities.(ABSTRACT TRUNCATED AT 400 WORDS)     

Chloride transport across rat ileal basolateral membrane vesicles.

The present study was designed to investigate Cl- transport across rat ileal basolateral membranes. Basolateral membrane vesicles were prepared by a well-validated technique. The purity of the basolateral membrane vesicles was verified by marker enzyme studies and by studies of d-glucose and calcium uptake. Cl- uptake was studied by a rapid filtration technique. Neither an outwardly directed pH gradient, nor a HCO3- gradient, or their combination could elicit any stimulation of Cl- transport when compared with no gradient. 4,4-Diisothiocyanostilbene-2,2-disulfonic acid at 5 mM concentration did not inhibit Cl- uptake under gradient condition. Similarly, the presence of the combination of outwardly directed Na+ and HCO3- gradients did not stimulate Cl- uptake compared with the combination of K+ and HCO3- gradients or no HCO3- gradient. This is in contrast to our results in the brush border membranes, where an outwardly directed pH gradient caused an increase in Cl- uptake. Cl- uptake was stimulated in the presence of combined Na+ and K+ gradient. Bumetanide at 0.1 mM concentration inhibited the initial rate of Cl- uptake in the presence of combined Na+ and K+ gradients. Kinetic studies of bumetanide-sensitive Cl- uptake showed a Vmax of 5.6 +/- 0.7 nmol/mg protein/5 sec and a Km of 30 +/- 8.7 mM. Cl- uptake was stimulated by an inside positive membrane potential induced by the ionophore valinomycin in the setting of inwardly directed K+ gradient compared with voltage clamp condition. These studies demonstrate two processes for Cl- transport across the rat ileal basolateral membrane: one is driven by an electrogenic diffusive process and the second is a bumetanide-sensitive Na+/K+/2 Cl- process. Cl- uptake is not enhanced by pH gradient, HCO3- gradient, their combination, or outwardly directed HCO3- and Na+ gradients.     

A sensitive technique for the determination of anion exchange activities in brush-border membrane vesicles. Evidence for two exchangers with different affinities for HCO3- and SITS in rat intestinal epithelium

A large percentage (up to 70%) of 36Cl- influx in brush-border membrane vesicles from rat small intestine under equilibrium exchange conditions was found to be mediated by SITS-inhibitable anion exchange. This Cl-/anion exchange could be measured 10-15-times more sensitive by determining the uptake of trace amounts of 125I- driven by a large Cl- gradient (in greater than out) generated by passing the vesicles through an anion-exchange column. Voltage clamping of the vesicle membrane with K+ and valinomycin did not effect the chloride driven 125I- uptake, showing that the 'overshooting' I- uptake was not mediated by an electrical diffusion potential, as might be generated by the Cl- gradient in the presence of a chloride channel. The Cl-/anion exchange was further characterized in brush-border membrane vesicles from both rat ileum and jejunum by studying the inhibitory action of various anions on the Cl- driven I- uptake. NO3-, Cl-, SCN- and formate at 2 mM could inhibit Cl-/I- exchange for more than 80%. The ileal brush-border membrane vesicles displayed a clear heterogeneity with respect to the inhibitory action of SO2-(4), SITS and HCO-3 on Cl-/I- exchange. Approximately 30% of the Cl-/I- exchange was insensitive to SO2-(4) and showed a relatively low sensitivity to SITS (IC50 = 1 mM) but could be inhibited for 80% by 2 mM HCO-3. Presumably this component represents Cl-/OH- or Cl-/HCO-3 exchange. The residual 70% showed a high sensitivity to SO2-(4) (IC50 = 0.5 mM) and SITS (IC50 = 2.5 microM) but was less sensitive to HCO-3. This part of the exchange activity showed inhibition characteristics very similar to the Cl-/I- exchange in the jejunal vesicles. The latter process was also inhibited for 80% by 2 mM oxalate. As discussed in this paper both exchangers may be involved in the electroneutral transport of NaCl across the apical membrane of the small intestinal villus cell.     

Inhibition of anion and glucose permeabilities by anesthetics in erythrocytes. The mechanisms of action of positively and negatively charged drugs

(1) The mode of action of anesthetics as inhibitors of Cl- and glucose transports in human red cells was studied. The term anesthetic is taken in its broad meaning as defined by Seeman (Seeman, P. (1972) Pharmacol. Rev. 24, 583-655) and covers anionic and cationic liposoluble compounds which reversibly block the rising phase of the action potential, without effect on the resting membrane potential. (2) Phenothiazine derivatives were chosen as prototypes of anesthetics because they represent a set of compounds having the same basic chemical structure, the phenothiazine ring, but with either a positive or a negative charge. (3) The Cl- self-exchange is inhibited by both cationic and anionic derivatives. However, to obtain the same level of inhibition, it is necessary to use a concentration 10-100 times higher with cationic than with anionic drugs. (4) At a concentration which inhibits Cl- permeability, cationic derivatives induce a very strong morphological change (cup-shaped cells: stomatocytes or spherostomatocytes) and protect erythrocytes against osmotic hemolysis, signifying that the membrane is fully expanded. Conversely, with anionic derivatives, inhibition occurs at a concentration which does not induce any apparent shape change or protect against osmotic hemolysis: there is no significant membrane expansion. (5) Glucose permeability, measured by glucose exit, is inhibited by cationic and anionic phenothiazine, but always at a concentration which fully expands the membrane as indicated by morphological changes and anti-hemolytic effects. It is interesting to point out that whilst glucose exit shows inhibition by cationic derivatives, glucose exchange flux is scarcely altered. (6) It is concluded that cationic and anionic anesthetics are general inhibitors of transmembrane solute movements involving a facilitated-diffusion process. However, the mechanism of inhibition is not identical for all: inhibition of glucose permeability by anionic and cationic anesthetics, as well as inhibition of Cl- permeability by cationic anesthetics may be of a non-specific nature and result from their interaction with the bilayer (this indirect effect is discussed); on the other hand, inhibition of Cl- permeability by anionic anesthetics may result from a specific perturbation of the transport mechanism according to recent evidence in some cases (Cousin, J.L. and Motais, R. (1979) J. Membrane Biol. 46, 125-153; Zaki, L., Ruffing, W. G?rtner, E.M., Fasold, H., Motais, R. and Passow, H. (1977) 11th FEBS Meeting, Copenhagen, A4 17-671.     

Effects of membrane potential on electrically silent transport. Potential-independent translocation and asymmetric potential-dependent substrate binding to the red blood cell anion exchange protein

Tracer anion exchange flux measurements have been carried out in human red blood cells with the membrane potential clamped at various values with gramicidin. The goal of the study was to determine the effect of membrane potential on the anion translocation and binding events in the catalytic cycle for exchange. The conditions were arranged such that most of the transporters were recruited into the same configuration (inward-facing or outward-facing, depending on the direction of the Cl- gradient). We found that the membrane potential has no detectable effect on the anion translocation event, measured as 36Cl(-)-Cl- or 36Cl(-)-HCO3- exchange. The lack of effect of potential is in agreement with previous studies on red cells and is different from the behavior of the mouse erythroid band 3 gene expressed in frog oocytes (Grygorczyk, R., W. Schwarz, and H. Passow. 1987. J. Membr. Biol. 99:127-136). A negative potential decreases the potency of extracellular SO4= as an inhibitor of either Cl- or HCO3- influx. Because of the potential-dependent inhibition by SO4=, conditions could be found in which a negative intracellular potential actually accelerates 36Cl- influx. This effect is observed only in media containing multivalent anions. The simplest interpretation of the effect is that the negative potential lowers the inhibitory potency of the multivalent anion by lowering its local concentration near the transport site. The magnitude of the effect is consistent with the idea that the anions move through 10-15% of the transmembrane potential between the extracellular medium and the outward-facing transport site. In contrast to its effect on extracellular substrate binding, there is no detectable effect of membrane potential on the competition between intracellular Cl- and SO4= for transport sites. The lack of effect of potential on intracellular substrate binding suggests that the access pathway leading to the inward-facing transport site is of lower electrical resistance than that leading to the extracellular substrate site.     

Lipid peroxidation in Plasmodium falciparum-parasitized human erythrocytes.

cis-Parinaric acid (PnA) was used as a fluorescent probe to study lipid peroxidation in nonparasitized and Plasmodium falciparum-parasitized erythrocytes, upon challenge by cumene hydroperoxide and tert-butyl hydroperoxide. Parasitized erythrocytes were less susceptible toward lipid peroxidation than nonparasitized erythrocytes with which they had been cultured. Furthermore, nonparasitized erythrocytes cultured together with parasitized cells, and thereafter isolated on a Percoll gradient, were less susceptible toward lipid peroxidation than erythrocytes kept under the same experimental conditions but in the absence of parasitized cells. We concluded, therefore, that the intracellular development of the parasite leads to an increase in the resistance against oxidative stress, not only of the host cell membrane of the parasitized erythrocyte, but also in the plasma membrane of the neighboring cells. The erythrocyte cytosol of parasitized cells and/or the intraerythrocytic parasite was required for the increased protection of the host cell membrane, since ghosts prepared from parasitized erythrocytes were more susceptible to lipid peroxidation than those prepared from nonparasitized ones. Vitamin E content of parasitized erythrocytes was lower than that of nonparasitized cells. However, parasitized erythrocytes promoted extracellular reduction of ferricyanide at higher rates, which might be indicative of a larger cytosolic reductive capacity. It is suggested that the improved response of intact erythrocytes is due to an increased reduction potential of the host-erythrocyte cytosol. The role of vitamin C as a mediator of this process is discussed.     

Protonmotive force and catecholamine transport in isolated chromaffin granules.

The effect of the transmembrane potential (delta psi) and the proton concentration gradient (delta pH) across the chromaffin granule membrane upon the rate and extent of catecholamine accumulation was studied in isolated bovine chromaffin granules. Freshly isolated chromaffin granules had an intragranular pH of 5.5 as measured by [14C]methylamine distribution. The addition of ATP to a suspension of granules resulted in the generation of a membrane potential, positive inside, as measured by [14C]thiocyanate (SCN-) distribution. The addition of carboxyl cyanide p-trifluoromethoxyphenylhydrazone (FCCP), a proton translocator, resulted in a reversal of the potential to negative values (measured by [3H]tetramethylphenylphosphonium (TPMP+)) approaching -90 mV. Changing the external pH of a granular suspension incubated with FCCP produced a linear perturbation in the measured potential from positive to negative values, which can be explained by the distribution of protons according to their electrochemical gradient. When ammonia (1 to 50 mM) was added to highly buffered suspensions of chromaffin granules there was a dose-dependent decrease in the transmembrane proton gradient (delta pH) and an increase in the membrane potential (delta psi). On the other hand, thiocyanate or FCCP, at varying concentration, produced a dose-related collapse of the membrane potential and had no effect upon the transmembrane proton gradient. The addition of larger concentrations of catecholamines caused a decrease in the transmembrane proton gradient and an increase in the membrane potential. Time-resolved influx of catecholamines into the granules was studied radiochemically using low external catecholamine concentrations. The accumulation of epinephrine or norepinephrine was over one order of magnitude greater in the presence of ATP than in its absence. The rate and extent of amine accumulation was found to be related to the magnitude of the membrane potential at fixed transmembrane proton concentration (delta pH) values. Likewise, the accumulation was related to the magnitude of the delta pH at fixed membrane potential values. These results suggest that the existence of both a transmembrane proton gradient and a membrane potential are required for optimal catecholamine accumulation to occur.     

ATP synthesis by F-type ATP synthase is obligatorily dependent on the transmembrane voltage.

ATP synthase is the universal enzyme that manufactures cellular ATP using the energy stored in a transmembrane ion gradient. This energy gradient has two components: the concentration difference (DeltapH or DeltapNa(+)) and the electrical potential difference DeltaPsi, which are thermodynamically equivalent. However, they are not kinetically equivalent, as the mitochondrial and bacterial ATP synthases require a transmembrane potential, DeltaPsi, but the chloroplast enzyme has appeared to operate on DeltapH alone. Here we show that, contrary to the accepted wisdom, the 'acid bath' procedure used to study the chloroplast enzyme develops not only a DeltapH but also a membrane potential, and that this potential is essential for ATP synthesis. Thus, for the chloroplast and other ATP synthases, the membrane potential is the fundamental driving force for their normal operation. We discuss the biochemical reasons for this phenomenon and a model that is consistent with these new experimental facts.     

Acetylcholinesterase: A probe for the study of antiarrhythmic drug-membrane interactions

Structural consequences of antiarrhythmic drug interaction with erythrocyte membranes were analyzed in terms of resulting changes in the activity of membrane-associated acetylcholinesterase. When enzyme inhibitory effects of drugs were compared at concentrations producing an equivalent degree of erythrocyte antihemolysis, a number of distinct groupings emerged, indicating that the molecular consequences of drug-membrane interaction are not identical for all agents examined. Differences in drug-induced acetylcholinesterase inhibition in intact erythrocytes, erythrocyte membranes and a brain synaptic membrane preparation emphasized the role of membrane structural organization in determining the functional consequences of antiarrhythmic interaction in any given system. While the inhibitory actions of lidocaine, D-600 and bretylium in intact red cells were not altered by an increased transmembrane chloride gradient, enhanced enzyme inhibition by quinidine and propranolol was observed under these conditions. The diverse perturbational actions of these membrane-stabilizing antiarrhythmics observed here may be indicative of a corresponding degree of complexity in the mechanisms whereby substances modify the potential-dependent properties of excitable tissues.     

Purification and characterization of two human erythrocyte arylamidases preferentially hydrolysing N-terminal arginine or lysine residues.

Two arylamidases (I and II) were purified from human erythrocytes by a procedure that comprised removal of haemoglobin from disrupted cells with CM-Sephadex D-50, followed by treatment of the haemoglobin-free preparation subsequently with DEAE-cellulose, gel-permeation chromatography on Sephadex G-200, gradient solubilization on Celite, isoelectric focusing in a pH gradient from 4 to 6, gel-permeation chromatography on Sephadex G-100 (superfine), and finally affinity chromatography on Sepharose 4B covalently coupled to L-arginine. In preparative-scale purifications, enzymes I and II were separated at the second gel-permeation chromatography. Enzyme II was obtained as a homogeneous protein, as shown by several criteria. Enzyme I hydrolysed, with decreasing rates, the L-amino acid 2-naphtylamides of lysine, arginine, alanine, methionine, phenylalanine and leucine, and the reactions were slightly inhibited by 0.2 M-NaCl. Enzyme II hydrolysed most rapidly the corresponding derivatives of arginine, leucine, valine, methionine, proline and alanine, in that order, and the hydrolyses were strongly dependent on Cl-. The hydrolysis of these substrates proceeded rapidly at physiological Cl- concentration (0.15 M). The molecular weights (by gel filtration) of enzymes I and II were 85 000 and 52 500 respectively. The pH optimum was approx. 7.2 for both enzymes. The isoelectric point of enzyme II was approx. 4.8. Enzyme I was activated by Co2+, which did not affect enzyme II to any noticeable extent. The kinetics of reactions catalysed by enzyme I were characterized by strong substrate inhibition, but enzyme II was not inhibited by high substrate concentrations. The Cl- activated enzyme II also showed endopeptidase activity in hydrolysing bradykinin.     

Cation gradient dependence of the steps in thrombin stimulation of human platelets

Thrombin causes a dose-dependent depolarization of the transmembrane potential of normal human platelets which can be continuously measured by the fluorescent probe, 3,3'-dipropylthiodicarbocyanine, whose distribution across the plasma membrane has been shown to be dependent upon the membrane potential. The dose-dependent depolarization of the platelet's negative membrane potential by thrombin is in large part due to a rapid uptake of sodium. Both the membrane potential change and the rapid sodium influx can be inhibited by a fast acting analog of amiloride, a sodium channel blocker, while valinomycin, a potassium ionophore, has no effect on the potential change nor on the sodium uptake, suggesting that the transmembrane potassium gradient is not important in the thrombin-induced depolarization. Neither the secretion of serotonin nor that of lysosomal enzymes nor the secondary release of the fluorescent probe which correlates with the lysosomal enzyme secretion occur if treatment with valinomycin precedes activation by thrombin. It is thus apparent that: 1) the change in the membrane potential induced by thrombin is directly dependent upon the transmembrane sodium gradient and is primarily due to a dose-dependent sodium uptake by the platelets; and 2) the thrombin-induced secretory processes are dependent upon maintenance of the transmembrane potassium gradients.     

Uptake of malate dehydrogenase into mitochondria in vitro. Some characteristics of the process

1. It was previously shown [Passarella, Marra, Doonan & Quagliariello (1980) Biochem. J. 192, 649-658] that, when mitochondrial malate dehydrogenase from rat liver is incubated with sulphite-loaded mitochondria from the same source, uptake of the enzyme occurs, as judged by a fluorimetric assay of intramitochondrial enzyme activity. Confirmation of sequestration of the enzyme inside the organelles is provided by its proteinase-resistance after uptake. 2. Enzyme uptake into mitochondria is inhibited by enzyme treatment with mersalyl at concentrations that do not affect its catalytic activity. 3. Enzyme uptake is energy-dependent, as shown by inhibition of the process by carbonyl cyanide p-trifluoromethoxyphenylhydrazone and by antimycin. ATP and oligomycin, on the other hand, both stimulate the process, but stimulation by ATP is inhibited by oligomycin. These results suggest that uptake depends on maintenance of transmembrane ion gradient rather than direct ATP involvement. 4. Measurements of delta psi by means of the 'redistribution signal' probe safranine suggest no dependence of malate dehydrogenase uptake on membrane potential. 5. Comparison of the effects of the ionophores valinomycin, nonactin, gramicidin and nigericin shows that uptake depends on maintenance of a transmembrane pH gradient.     

Mechanism of the increase in cation permeability of human erythrocytes in low-chloride media. Involvement of the anion transport protein capnophorin

When human erythrocytes are suspended in low-Cl- media (with sucrose replacing Cl-), there is a large increase in both the net efflux and permeability of K+. A substantial portion (greater than 70% with Cl- less than 12.5 mM) of this K+ efflux is inhibited by the anion exchange inhibitor DIDS (4,4'-diisothiocyanostilbene-2,2'-disulfonic acid). This inhibition cannot be explained as an effect of DIDS on net Cl- permeability (Pcl) and membrane potential, but rather represents a direct effect on the K+ permeability. When cells are reacted with DIDS for different times, the inhibition of K+ efflux parallels that of Cl- exchange, which strongly indicates that the band 3 anion exchange protein (capnophorin) mediates the net K+ flux. Since a noncompetitive inhibitor of anion exchange, niflumic acid, has no effect on net K+ efflux, the net K+ flow does not seem to involve the band 3 conformational change that mediates anion exchange. The data suggest that in low-Cl- media, the anion selectivity of capnophorin decreases so that it can act as a very low-conductivity channel for cations. Na+ and Rb+, as well as K+, can utilize this pathway.     

Chloride transport pathways and their bioenergetic implications in the obligate acidophile Bacillus coagulans.

The protonophore-mediated collapse of the large delta pH that acidophiles maintain across their cytoplasmic membranes was augmented by the presence of Cl-, and Cl- influx into the cells occurred evidently in response to the protonophore-induced increase in the inside-positive membrane potential (+ delta psi). In respiring cells, the addition of Cl- but not SO4(2-) salts caused a rapid and precipitous decrease in the + delta psi. A Nernstian relationship between the imposed transmembrane K+ gradient and the valinomycin-induced K+ diffusion potentials was observed when everted membrane vesicles were loaded with K2SO4 or KH2PO4 but not when loaded with KCl or KNO3. Thus, electrogenic Cl- transport occurred in Bacillus coagulans. In addition, a nonelectrogenic temperature-sensitive Cl- transport mechanism, with the net Cl- efflux coefficient (PCl-) ranging from 1.5 x 10(-4) to 6.1 x 10(-6) cm/s, accounted for the massive Cl- efflux from Cl(-)-loaded cells. Thus, B. coagulans, despite its dependence on the + delta psi and therefore the need to exclude anions, apparently possesses specific mechanisms for Cl- permeation. Active cells of B. coagulans prevented Cl- accumulation from attaining an electrochemical equilibrium, maintaining a delta micro Cl- of ca. -63 mV. B. coagulans therefore also possesses an energy-dependent mechanism for Cl- exclusion from the cells.     

Biological amine transport in chromaffin ghosts. Coupling to the transmembrane proton and potential gradients.

The effect of the transmembrane proton gradient (delta pH) and potential gradient (delta psi) upon the rate and extent of amine accumulation was investigated in chromaffin ghosts. The chromaffin ghosts were formed by hypo-osmotic lysis of isolated bovine chromaffin granules and extensive dialysis in order to remove intragranular binding components and dissipate the endogenous electrochemical gradients. Upon ATP addition to suspensions of chromaffin ghosts, a transmembrane proton gradient alone, a transmembrane gradient alone, or both, could be established, depending upon the compositions of the media in which the ghosts were formed and resuspended. When chloride was present in the medium, addition of ATP resulted in the generation of a transmembrane proton gradient, acidic inside of 1 pH unit (measured by [14C]methylamine distribution), and no transmembrane potential (measured by [14C]-thiocyanate distribution). When ATP was added to chromaffin ghosts suspended in a medium in which chloride was substituted by isethionate, a transmembrane potential, inside positive, of 45 mV and no transmembrane proton gradient, was measured. In each medium, the addition of agents known to affect proton or potential gradients, respectively, exerted a predictable mechanism of action. Accumulation of [14C]epinephrine or [14C]5-hydroxytryptamine was over 1 order of magnitude greater in the presence of the transmembrane proton gradient or the transmembrane potential than in the absence of any gradient and, moreover, was related to the magnitude of the proton or potential gradient in a dose-dependent manner. When ghosts were added to a medium containing chloride and isethionate, both a delta pH and delta psi could be generated upon addition of ATP. In this preparation, the maximal rate of amine accumulation was observed. The results indicate that amine accumulation into chromaffin ghosts can occur in the presence of either a transmembrane proton gradient, or a transmembrane potential gradient, and that the maximal rate of accumulation may exist when both components of the protonmotive force are present.     

Concanavalin A-induced increase in the membrane fluidity of chicken erythrocytes.

To determine the fluidity of the membrane lipid phase, chicken erythrocytes were labeled with a stearic acid derivative spin label. When chicken erythrocytes were treated with concanavalin A (Con A), ESR spectra showed a change in the peaks of the labels in membrane lipids, indicating an increase of membrane fluidity. The degree of the increase in fluidity of the membrane lipid phase depended on the valency of the lectin used. Tetravalent Con A induced an increase of membrane fluidity at a concentration as low as 30 micrograms/ml, while a monovalent derivative of Con A did not affect membrane fluidity. This increase in membrane fluidity was observed within 10 min after the addition of Con A. If bound Con A was removed with methyl alpha-D-mannoside later than 60 min after its addition, a complete return of the fluidity to the normal level could not be observed. However, no change was found in the composition of phospholipids or in the fatty acid compositions of phosphatidylcholine and phosphatidylethanolamine of chicken erythrocytes after the addition of Con A, indicating that this increase in membrane fluidity is not caused by a change of lipid composition. The clustering of membrane receptors of chicken erythrocytes for Con A was demonstrated when the two-dimensional distribution of ferritin-conjugated Con A on the membranes was assayed by transmission electron microscopy. Furthermore, it was shown that major receptors for Con A of chicken erythrocytes were transmembrane glycoproteins having apparent molecular weights of 100K, 45, and 33K.