Chloride transport and the membrane potential in the marine alga,Halicystis parvula

Summary The relationship between the rate of Cl^– transport and the electrical properties ofHalicystis parvula was investigated. Three metabolic inhibitors-darkness, cyanide (2mm), and low temperature (4°C)-all rapidly and reversibly reduce both the short circuit current (SCC), which is a measure of net Cl^– transport, and the vacuole electrical potential (PD). Plotting thePD vs. SCC for inhibited cells yields a linear regression with ay-intercept of zero. ThePD is also greatly reduced when the [Cl^–] of the external medium is lowered. Raising the external [K⁺] produces an appreciable, but less than Nernstian, depolarization, while increasing the external [H⁺] tenfold has no net effect on thePD. Decreasing the external [Na⁺] by tenfold produces only a slight depolarization. Thus, the outer plasma membrane appears to be moderately selective for K⁺ over Na⁺ or H⁺. The effects of ion substitutions in the vacuolar perfusing solutions on thePD reveal that the vacuolar membrane does not discriminate electrically between Cl^– and the much larger anions, isethionate and benzenesulfonate, or between Na⁺ and K⁺. The data suggest that in internally perfused cells ofH. parvula generation of thePD of –50 to –60 mV by a transport system involving only electroneutral pumps is unlikely and that most of thisPD is generated by an electrogenic Cl^– pump.     

Mechanism of Cl− transport at the plasma membrane ofChara corallina: II. Transinhibition and the determination of H+/Cl− binding order from a reaction kinetic model

Summary Internal Cl^– and low internal pH are strong inhibitors of Cl^– influx at the plasma membrane ofChara. The present investigation seeks to understand the mechanism by which this is achieved. Since both Cl^– and H⁺ are transported by the same system, one possible mechanism is simply through a change in the electrochemical gradients of these ions. However, it is found that transport is more sensitive to theinternal concentrations of the two ions than to their respective gradients. It is demonstrated that Cl^– influx, which shows Michaelis-Menten kinetics with respect to external concentration, is affected only in itsV _max by internal Cl^– and pH; the apparentK _m of the transport system for external Cl^– is unchanged. In addition, it is found that there is an apparent interaction between internal Cl^– and pH in their effects on Cl^– influx, both in intact cells and those that have been perfused internally. A kinetic model is proposed which can account quantitatively for all these observations simply through the effects of substrate concentration on the apparent rate constants of a recycling carrier. The model predicts (i) strictly ordered binding of Cl^– and H⁺ to the carrier at both internal and external surfaces, with Cl^– first on and first off (ii) movement of charge through the membrane on the loaded, rather than the unloaded, carrier. The present model is expected to account for similar kinetic observations from a variety of other cotransport systems.     

Tonoplast action potential inNitella in relation to vacuolar chloride concentration

Summary The action potential ofNitella internode was studied in relation to K⁺ and Cl^– concentrations in the vacuole. When the vacuole ofNitella pulchella was filled with an artificial solution with extremely low Cl^– concentration, a diphasic action potential (DAP) was observed. The first phase consists of a rapid depolarization followed by a relatively rapid repolarization, and the second one consists of a strong hyperpolarization followed by a gradual return to the resting potential.When the cell was stimulated immediately after the generation ofDAP, a monophasic action potential which resembles an action potential of the natural cell was observed, indicating that theDAP consists of two components with different refractory periods. The refractory period of the component responsible for the depolarizing phase is shorter than that of a component responsible for the hyperpolarizing phase. Measuring the plasmalemma potential and vacuolar potential separately, it was demonstrated that the hyperpolarizing component ofDAP originates from the tonoplast.The action potential of the tonoplast, in contrast with that of the plasmalemma, could be generated independently of concentration of K⁺ in the vacuole. Since the maximum amplitude of hyperpolarization decreased significantly by increasing Cl^– concentration of the vacuole, it is concluded that the tonoplast is very sensitive to Cl^– during excitation.     

Ion fluxes inAcetabularia: Vesicular shuttle

Summary Ion flux relations in the unicellular marine algaAcetabularia have been investigated by uptake and washout kinetics of radioactive tracers (²²Na⁺,⁴²K⁺,³⁶Cl^– and⁸⁶Rb⁺) in normal cells and in cell segments with altered compartmentation (depleted of vacuole or of cytoplasm). Some flux experiments were supplemented by simultaneous electrophysiological recordings. The main results and conclusions about the steady-state relations are: the plasmalemma is the dominating barrier for translocation of K⁺ with influx and efflux of about 100 nmol·m^–2·sec^–1×K⁺ passes three- to sevenfold more easily than Rb⁺ does. Under normal conditions, Cl^– (the substrate of the electrogenic pump, which dominates the electrical properties of the plasmalemma in the resting state) shows two efflux components of about 17 and 2 mol·m^–2·sec^–1, and a cytoplasmic as well as vacuolar [Cl^–] of about 420mm ([Cl^–] _o =529mm). At 4°C, when the pump is inhibited, both influx and efflux, as well as the cellular [Cl^–], are significantly reduced. Na⁺ ([Na⁺] _i : about 70mm, [Na⁺] _o : 461mm), which is of minor electrophysiological relevance compared to K⁺, exhibits rapid and virtually temperature-insensitive (electroneutral) exchange (two components with about 2 and 0.2 mol·m^–2·sec^–1 for influx and efflux). Some results with Na⁺ and Cl^– are inconsistent with conventional (noncyclic) compartmentation models: (i) equilibration of the vacuole (with the external medium) can be faster than equilibration of the cytoplasm, (ii) absurd concentration values result when calculated by conventional compartmental analysis, and (iii) large amounts of ions can be released from the cell without changes in the electrical potential of the cytoplasm. These observations can be explained by the particular compartmentation of normalAcetabularia cells (as known by electron micrographs) with about 1 part cytoplasm, 5 parts central vacuole, and 5 parts vacuolar vesicles. These vesicles communicate directly with the central vacuole, with the cytoplasm and with the external medium.     

Open-vacuole method for measuring membrane potential and membrane resistance of Characeae cells

A simple method called the open-vacuole (o.v.) method was developedto measure the vacuolar potential (E_vo) and membrane resistance(R_m) of Characeae cells without inserting a microelectrode intothe vacuole. Values of E_vo and R_m measured by this method arehigher than those measured by the microelectrode method. Usingthe o.v. method we can measure E_vo and R_m exactly in cells withinternal media of extremely low ionic concentrations. In respect to E_vo and R_m, the tonoplast is less sensitive thanthe plasmalemma to a change in ionic concentration. The existenceof a significant amount of E_vo (–40 mV), even when boththe internal and external media are isotonic artificial pondwater with a high Ca^2$content, may be accounted for by the differencein sensitivity to ionic species between these two membranes. Irrespective of the presence or absence of Ca^2$in the vacuole,practically the same values of E_vo and R_m were measured withthe open-vacuole method, when measurements were carried outwithin 20 min after the end of perfusion. The discrepanciesbetween the present and previous results (16) may be accountedfor by the difference in methods. ¹Present address: Sanki Engineering Ltd., Nagaokakyo, Kyoto. (Received January 31, 1975; )     

Changes in membrane potential, membrane resistance, and intracellular H, K, Na, and Cl activities during the progesterone-induced maturation of urodele amphibian oocytes

Changes in intracellular activities of H⁺, K⁺, Na⁺, and Cl⁻ ions were recorded with ion-selective microelectrodes during progesterone-induced maturation of full-grown oocytes of the urodele amphibians Ambystoma mexicanum and Pleurodeles waltlii. The membrane potential (E_m) and electrical resistance (R_m) were also determined. During the first hours after initiation of maturation, the oocytes slowly depolarized and R_m gradually increased. By the end of maturation of Pleurodeles oocytes E_m had stabilized at about −10 mV and R_m had increased from 410 to 1760 kΩ. The same initial pattern was observed for Ambystoma, but in most oocytes a rapid transition occurred at about the time of germinal vesicle breakdown (GVBD): E_m spontaneously shifted from about −15 to about +30 mV; simultaneously R_m dropped from 1230 down to 100 kΩ (i.e., less than the initial 270 kΩ resistance). The internal K⁺ activity did not show any important variation during maturation of Ambystoma and Pleurodeles oocytes. Na⁺ activity increased slightly at the onset of GVBD in Ambystoma; a further marked increase of Na⁺, accompanied by an increase in Cl⁻ activity, was observed as soon as E_m shifted to a positive value. In Pleurodeles sodium activity was also more elevated in matured than in immature oocytes. The average pH of Ambystoma immature oocytes was 7.48 ± 0.05 (external pH 7.5). A transient alkalinization to 7.64 ± 0.04 took place during the first 4–6 hr postprogesterone. Cytoplasmic pH was restored to 7.50 ± 0.07 between 10 and 12 hr postprogesterone, before the onset of GVBD and the shift of E_m. The difference between the measured oocyte pH and the calculated equilibrium pH decreases during the course of maturation, due partly to the depolarization of E_m.     

Current-voltage relationships and voltage sensitivity of the Cl− pump inHalicystis parvula

Summary The current-voltage (I–V) relationships for internally perfused and nonperfused cells ofHalicystis parvula were determined. In both types of cells theI–V curve shows a conspicuous region of negative slope, beginning at vacuole potentials around –30 mV and continuing to values of +20 to +40mV. The negative slope in perfused cells is abolished by the metabolic inhibitors, darkness and low temperature. In order to determine the origin of this negative slope, we measured the voltage sensitivity of the unidirectional fluxes of Cl^–, Na⁺ and K⁺ in perfused cells. The results show that the Cl^– influx, which is mediated primarily by a Cl^– pump, increases as the vacuole potential is clamped at increasingly morenegative values up to –50 mV, while the other fluxes measured changed in the directions predicted by the change in electrical driving force. The voltage sensitivity of the Cl^– pump quantitatively accounts for the negative slope of theI–V curve. Also, we observed a large transient outward current of 10–20-sec duration following an abrupt depolarization by voltage clamping. This transient current was reduced or abolished by low temperature, which suggests that it may be due to the voltage-sensitive Cl^– pump. Finally, we found an inverse relationship between the transprotoplasm resistance (R _m ) and thePD under standard conditions, which suggests that the activity of the electrogenic Cl^– pump lowerR _m , i.e., it is a conductive pump.     

Physiological Control of Chloride Transport in Chara corallina: II. THE ROLE OF CHLORIDE AS A VACUOLAR OSMOTICUM

The extent to which Cl⁻ is replaceable as the major anionic constituent of the vacuole of Chara corallina was investigated. It was found that external Cl⁻ is not essential in order for nongrowing cells to increase internal osmotic pressure. After growth of cells in low (9 micromolar) Cl⁻, the vacuolar Cl⁻ concentration is one-half that of cells grown at normal external Cl⁻ concentration (850 micromolar). In contrast, both internal osmotic pressure and total concentration of the major cations, K⁺ and Na⁺, in the same cells were found to be only slightly sensitive to the external Cl⁻ concentration. Thus, it is proposed that, at limiting external Cl⁻ concentration, the cell is able to transport or synthesize another anion for vacuolar use rather than utilize a neutral solute.     

Effects of anions on cellular volume and transepithelial Na+ transport across toad urinary bladder

Summary The effects of complete substitution of gluconate for mucosal and/or serosal medium Cl^– on transepithelial Na⁺ transport have been studied using toad urinary bladder. With mucosal gluconate, transepithelial potential difference (V _T) decreased rapidly, transepithelial resistance (R _T) increased, and calculated short-circuit current (I _sc) decreased. CalculatedE _Na was unaffected, indicating that the inhibition of Na⁺ transport was a consequence of a decreased apical membrane Na⁺ conductance. This conclusion was supported by the finding that a higher amiloride concentration was required to inhibit the residual transport. With serosal gluconateV _T decreased,R _T increased andI _sc fell to a new steady-state value following an initial and variable transient increase in transport. Epithelial cells were shrunken markedly as judged histologically. CalculatedE _Na fell substantially (from 130 to 68 mV on average). Ba²⁺ (3mm) reduced calculatedE _Na in Cl^– Ringer's but not in gluconate Ringer's. With replacement of serosal Cl^– by acetate, transepithelial transport was stimulated, the decrease in cellular volume was prevented andE _Na did not fall. Replacement of serosal isosmotic Cl^– medium by a hypo-osmotic gluconate medium (one-half normal) also prevented cell shrinkage and did not result in inhibition of Na⁺ transport. Thus the inhibition of Na⁺ transport can be correlated with changes in cell volume rather than with the change in Cl^– per se. Nystatin virtually abolished the resistance of the apical plasma membrane as judged by measurement of tissue capacitance. With K⁺ gluconate mucosa, Na⁺ gluconate serosa, calculated basolateral membrane resistance was much greater, estimated basolateral emf was much lower, and the Na⁺/K⁺ basolateral permeability ratio was much higher than with acetate media. It is concluded the decrease in cellular volume associated with substitution of serosal gluconate for Cl^– results in a loss of highly specific Ba²⁺-sensitive K⁺ conductance channels from the basolateral plasma membrane. It is possible that the number of Na⁺ pump sites in this membrane is also decreased.     

The mechanism of Cl− transport at the plasma membrane ofChara corallina I. Cotransport with H+

Summary Cl^– transport into cells ofChara corallina was studied in relation to that of other ions which have been proposed as cosubstrates for the Cl^– transport system. Although there appears to be a partial mutual dependence between K⁺ and Cl^– for transport in intact cells, this is not apparent in cells which have been perfused internally. Moreover, in intact cells, the fluxes of K⁺ and Cl^– show a large degree of independence in their responses to Cl^– starvation. Cl^– transport is electrogenic in a direction indicating the transport of excess positive charge into the cell. In the absence of any other likely counter ion, it is suggested that Cl^– is cotransported with H⁺. Response of Cl^– influx to internal and external pH in perfused cells is consistent with this suggestion. There appears, in addition, to be a role for ATP in transport as judged by fourfold stimulation of Cl^– influx in perfused cells when 1mm ATP is incorporated in the perfusion medium.     

Cellular and whole-plant chloride dynamics in barley: insights into chloride–nitrogen interactions and salinity responses

The first analysis of chloride fluxes and compartmentation in a non-excised plant system is presented, examining ten ecologically pertinent conditions. The short-lived radiotracer couple ³⁸Cl/³⁹Cl was used as a Cl^– tracer in intact barley (Hordeum vulgare L. cv. Klondike) seedlings, which were cultured and investigated under four external [Cl^–], from abundant (0.1 mM) to potentially toxic (100 mM). Chloride–nitrogen interactions were investigated by varying N source (NO₃ ^– or NH₄ ⁺) and strength (0.1 or 10 mM), in order to examine, at the subcellular compartmentation level, the antagonism, previously documented at the influx level, between Cl^– and NO₃ ^–, and the potential role of Cl^– as a counterion for NH₄ ⁺ under conditions in which cytosolic [NH₄ ⁺] is excessive. Cytosolic [Cl^–] increased with external [Cl^–] from 6 mM to 360 mM. Cl^– influx, fluxes to vacuole and shoot, and, in particular, efflux to the external medium, also increased along this gradient. Efflux reached 90% of influx at the highest external [Cl^–]. Half-times of cytosolic Cl^– exchange decreased between high-affinity and low-affinity influx conditions. The relationship between cytosolic [Cl^–] and shoot flux indicated the presence of a saturable low-affinity transport system (SLATS) responsible for xylem loading of Cl^–. N source strongly influenced Cl^– flux to the vacuole, and moderately influenced Cl^– influx and shoot flux, whereas efflux and half-time were insensitive to N source. Cytosolic pool sizes were not strongly or consistently influenced by N source, indicating the low potential for Cl^– to act as a counterion to hyperaccumulating NH₄ ⁺. We discuss our results in relation to salinity responses in cereals.Abbreviations [Cl^–]_cyt cytosolic chloride concentration - [Cl^–]_o external chloride concentration     

Microelectrode Measurements on Red Beet Vacuole : Biological Effect of Na OR NO(3) Ions, Diffusing from the Microelectrode

Glass microelectrodes filled with 3 molar KCl are widely used to measure intracellular potentials and it is usual to try to minimize their electrolyte loss. In these experiments we have used the ionic leak of our microelectrodes, filled with various salt solutions, to introduce a given ion into the red beet vacuole. This allowed us to show that NO₃⁻ ions reduce the magnitude of the current spectral density while they do not change the resistance of the tonoplast. This is true when NO₃⁻ is either added to the external medium or used as the microelectrode filling solution. This can be interpreted by a NO₃⁻ effect on the vacuolar side of the tonoplast, resulting in an inhibition of the ion transporting ATPase. Replacing K⁺ by Na⁺ ions in the medium has no effect on tonoplast resistance (R_s). On the contrary, when ions leaking from the microelectrode are H⁺, Li⁺ or K⁺, R_s is close to 4 kilohm square centimeter, whereas R_s is of the order of 30KΩ square centimeter when Na⁺ are the leaking ions. We also found a possible correlation between the presence of a Lorentzian in the current spectral density (cut-off frequency = 2 hertz) and a Cl⁻ efflux from the vacuole. This could be explained by the existence of Cl⁻ channels on the tonoplast.     

Intracellular chloride and potassium ions in relation to excitability ofChara membrane

Summary Internodal cells ofChara australis were made tonoplast-free by replacing the cell sap with EGTA-containing media; then the involvement of internal Cl^– and K⁺ in the excitation of the plasmalemma was studied.[Cl^–] _i was drastically decreased by perfusing the cell interior twice with a medium lacking Cl^–. The lowered [Cl^–] _i was about 0.01mm. Cells with this low [Cl^–] _i generated action potential and showed anN-shapedV–I curve under voltage clamped depolarization like Cl^–-rich cells containing 13 or 29mm Cl^–.E _m at the peak of the action potential was constant at [Cl^–] _i between 0.01 and 29mm. The possibility that the plasmalemma becomes as permeable to other anions as to Cl^– during excitation is discussed.At [Cl^–] _i higher than 48mm, cells were inexcitable. When anions were added to the perfusion medium to bring the K⁺ concentration to 100mm, NO ₃ ^– , F^–, SO ₄ ^2– , acetate, and propionate inhibited the generation of action potentials like Cl^–, while methane sulfonate, PIPES, and phosphate did not inhibit excitability.The duration of the action potential depended strongly on the intracellular K⁺ concentration. It decreased as [K⁺] _i (K-methane sulfonate) increased. Increase in [Na⁺] _i (Na-methane sulfonate) also caused its decrease, although this effect was weaker than that of K⁺. The action of these monovalent cations on the duration of the action potential is the opposite of their action on the membrane from the outside (cf. Shimmen, Kikuyama & Tazawa, 1976,J. Membrane Biol. 30:249).     

Cyclic AMP-induced changes in membrane conductance ofNecturus gallbladder epithelial cells

Summary Enhanced cellular cAMP levels have been shown to increase apical membrane Cl^– and HCO ₃ ^– conductances in epithelia. We found that the phosphodiesterase inhibitor 3-isobutyl-1-methyl-xanthine (IBMX) increases cAMP levels inNecturus gallbladder. We used conventional open-tip and double-barreled Cl^–-selective microelectrodes to study the effects of IBMX on membrane conductances and intracellular Cl^– activities in gallbladders mounted in a divided chamber and bathed with Ringer's solutions at 23°C and pH 7.4. In HCO ₃ ^– -free media, 0.1mM IBMX added to the mucosal medium depolarized the apical membrane potentialV _a , decreased the fractional resistanceF _R , and significantly reduced intracellular Cl^– activity (a _Cl ⁱ ). Under control conditions,a _Cl ⁱ was above the value corresponding to passive distribution across the apical cell membrane. In media containing 25mM HCO ₃ ^– , IBMX caused a small transient hyperpolarization ofV _a followed by a depolarization not significantly different from that observed in HCO ₃ ^– -free Ringer's. Removal of mucosal Cl^–, Na⁺ or Ca²⁺ did not affect the IBMX-induced depolarization inV _a . The basolateral membrane ofNecturus gallbladder is highly K⁺ permeable. Increasing serosal K⁺ from 2.5 to 80mM, depolarizedV _a . Mucosal IBMX significantly reduced this depolarization. Addition of 10mM Ba²⁺, a K⁺ channel blocker, to the serosal medium depolarizedV _a and, essentially, blocked the depolarization induced by IBMX. These results indicate that mucosal IBMX increases apical HCO ₃ ^– conductance and decreases basolateral K⁺ conductance in gallbladder epithelial cells via a cAMP-dependent mechanism. The latter effect, not previously reported in epithelial tissues, appears to be the major determinant of the IBMX-induced depolarization ofV _a .     

Active, Irreversible Accumulation of Extreme Levels of H(2)SO(4) in the Brown Alga, Desmarestia

The brown algae Desmarestia ligulata var. ligulata (Lightf.) Lamour., and D. viridis (Mull.) Lamour., accumulate H₂SO₄ until their average internal pH is 0.5 to 0.8. A related species, D. aculeata (L.) Lamour., does not accumulate acid. The H₂SO₄ accumulation is accompanied by a reduction in the K⁺ and Cl⁻ content, presumedly to maintain osmotic balance. Measurements of the membrane potential and H⁺ and SO₄²⁻ concentrations indicate that both ions are accumulated in the vacuole against their electrochemical potential gradients.

The internal pH remains constant in all three species over the growing season, despite striking changes in the algal morphology. The pH is not affected by periods of darkness of up to 34 hours. Sulfate accumulated in the vacuoles appears to be trapped there since incubation of D. ligulata for up to 10 days in sulfate-free medium resulted in little loss of either vacuolar sulfate or H⁺. Although the uptake of H₂SO₄ into the vacuole must require energy, the maintenance of the vacuolar H₂SO₄ may be due to the impermeability of the tonoplast, with little necessity for continued expenditure of energy.

     

Differential pH restoration after ammonia-elicited vacuolar alkalisation in rice and maize root hairs as measured by fluorescence ratio

Changes of vacuolar pH in hair cells of young rice (Oryza sativa L.) and maize (Zea mays L.) roots were measured after ammonia application at various levels of external pH. After loading the pH-sensitive, fluorescent dye Oregon green 488 carboxylic acid 6-isomer into the vacuoles of root hairs, ratiometric pH data of high statistical significance were obtained from root hair populations comprising hundreds of cells. The pH of the vacuole at external pH 5.0 was 5.32 ± 0.08 (±SD, n= 15) and 5.41 ± 0.13 (±SD, n= 15) in rice and maize, respectively. A moderate external ammonia concentration of 2 mM led to vacuolar alkalisation at both, low (pH 5.0) and high (pH 7.0–9.0) external pH, presumably due to NH₃ permeation into the vacuole. With increasing external pH, ammonia application did not cumulatively increase vacuolar pH. In rice, the increase in vacuolar pH ranged from 0.1–0.8 pH units; in maize a more constant increase of 0.5 pH units was observed. The vacuolar pH increase was efficiently depressed in rice (especially at high external pH), but not in maize. Inhibition of the tonoplast H⁺-ATPase by concanamycin A raised vacuolar pH and increased the ammonia-elicited vacuolar alkalisation in both species, proving that vacuolar H⁺-ATPase activity counters the ammonia-elicited alkalisation effect. However, even under conditions of vacuolar H⁺-ATPase inhibition, rice was still able to restore an ammonia-elicited pH increase. High vacuolar pH levels as found in maize under conditions of high NH₃ influx may derive from inefficient cytosolic ammonia assimilation and tonoplast proton pumping. Thus, in maize, prolonged reduction of the proton gradient between the cytosol and the vacuole may play an important role in NH₃ toxicity. Received: 12 September 1997 / Accepted: 19 January 1998     

Chloride channels in human platelets: Evidence for activation by internal calcium

Summary Whole-cell patch-clamp recordings were made from freshly isolated human platelets. The pipette contained a high concentration of divalent cations, which permitted easy disruption of cell-attached membrane patches by suction. Single-channel currents were measured when the pipette contained isotonic BaCl₂ or MgCl₂ saline; over 30 sec –5 min an increasing number of channels appeared until conductance steps through individual channels could no longer be distinguished. The current-voltage relationship was curvilinear; chord conductance at –35 mV was 25 pS increasing to 45 to 52 pS at +45 mV. Ion substitution experiments showed the current to be primarily carried by Cl^–.E _rev was shifted 30 mV/10-fold change in external Cl^– (replaced by gluconate), was similar with BaCl₂ or MgCl₂ in the pipette and was not significantly shifted by replacing external Na⁺ with K⁺. Addition of 1mm BAPTA to the MgCl₂ pipette saline prevented activation of Cl^– currents; with isotonic CaCl₂ internal saline, current appeared immediately upon patch rupture, suggesting that the Cl^– channels are dependent on internal Ca²⁺, 5-nitro-2-(3-phenylpropylamino)-benzoate, reported to block a Cl^– conductance in studies of rat epithelial cells, caused a potent flickery block and may be a useful tool with which to investigate the physiological role of Cl^– currents in human platelets.     

Branchial Cl transport, anion-stimulated ATPase and acid-base balance inAnguilla anguilla adapted to freshwater: Effects of hyperoxia

Summary Freshwater eel gills are notorious for their limited ability to pump chloride. As a result there is a considerable discrepancy between the Na⁺ and Cl^– plasma levels, and plasma HCO₃ ^– and blood pH are relatively high in this species.When eels are kept in tanks aerated with pure oxygen, significant alterations in blood acid-base balance, an increase in plasma pCO₂ and a decrease in blood pH, are observed. In fish studied after 3 weeks hyperoxia, the decrease in blood pH is compensated by an increase in plasma HCO₃ ^–. Such fish exhibit a Cl^– influx 5 times higher than that observed in normoxic fish. This Cl^– influx is readily inhibited by addition of SCN^– to the external medium.An anion-stimulated ATPase activated by HCO₃ ^– and by Cl^– and inhibited by SCN^– was recently described in membrane fractions of the gills ofCarassius auratus, a fish noted for its high Cl^– pumping rate. This enzyme is also found in the gills of the eel. While the maximal rates of enzyme activation by HCO₃ ^– and by Cl^– are similar inCarassius andAnguilla, the affinity of the enzyme for Cl^– is 25 times higher inCarassius. In the microsomal fraction of the hyperoxic eel gills, the maximal anionstimulated ATPase activity remains unchanged but HCO₃ ^– affinity decreases by 50%, while Cl^– affinity increases 5 times. Thus some characteristics of this ATPase seem to be closely related to the Cl^– pump activity exhibited by the gill in fresh water.     

Zinc inhibition of chloride efflux from skeletal muscle ofRana pipiens and its modification by external pH and chloride activity

Summary Efflux of³⁶Cl^– from frog sartorius muscles equilibrated in depolarizing solutions was measured. Cl^– efflux consists of a component present at low pH and a pH-dependent component which increases as external pH increases. In depolarized muscles fromRana pipiens, the pH-dependent Cl^– efflux has an apparent pK _a near 6.4.The reduction of Cl^– efflux by external Zn²⁺ was determined at different external pHs and chloride activities. The effect of external chloride activity on the pH-dependent Cl^– efflux was also examined.At pH 6.5 and a membrane potential of –22 mV, increasing external Cl^– activity from 0.108 to 0.28m decreased inhibition of the pH-dependent Cl^– efflux at all activities of Zn²⁺. The Zn²⁺ activity needed to reduce Cl^– efflux by half increased from 0.39×10^–3 to 2.09×10^–3 m. By contrast, external Cl^– activity had no measurable effect on the apparent pK _a of the pH-dependent efflux.At constant Cl^– activity less than 0.21m, increasing external pH from 6.5 to 7.5 decreased inhibition by low Zn²⁺ activities with either a slight increase or no change in the Zn²⁺ activity producing half-inhibition. In other words, for relatively low Cl^– activities, protection against inhibition of Cl^– efflux by low Zn²⁺ activities was obtained by raising, not lowering, external pH; this is not what is expected if H⁺ and Zn²⁺ ions compete at the same site to produce inhibition of Cl^– efflux. We conclude that Zn²⁺ and low pH inhibit Cl^– efflux by separate and distinct mechanisms.By contrast, the protection against Zn²⁺ inhibition produced by high external Cl^– activity (0.28m) was partially reversed by raising external pH from 6.5 to 7.5 at all Zn²⁺ activities. The half-inhibition Zn²⁺ activity decreased from 2.09×10^–3 to 0.68×10^–3 m.The results can be simulated quantitatively by a model in which single Cl^– channel elements are in equilibrium with sextets of associated single-channel elements, each sextet having a conductance six times that of a single-channel element. The association into sextets is promoted by OH^– or Cl^– binding to a control site on the single-channel elements. Both the single Cl^– channel element and the sextet of Cl^– channel elements are closed when this same control site instead binds ZnOH⁺. The sextet has a much higher affinity for ZnOH⁺ than does the single Cl^– channel element.     

Intracellular Concentrations of Potassium,Chloride, and Protons during Differentiation of Tobacco Male Gametophyte

Changes in intracellular pH, K⁺and Cl^–concentrations were measured in pollen grains, anther loculi, and whole anthers during in vivodifferentiation of male gametophyte of Nicotiana tabacumL. The effects of extracellular K⁺and Cl^–on intracellular pH regulation were also studied during development of pollen grains in vitro. Ion-selective electrodes and X-ray microanalysis were used to measure ion concentrations, and microfluorometry was used to measure pH. The intracellular pH and [K⁺] decreased at the mid- and late binucleate stages of pollen grain development, while [Cl^–] increased. At the same stages, K⁺and Cl^–concentrations in locular liquid were found to increase. The intracellular pH in pollen grains, isolated at the mid-binucleate stage, decreased during in vitrodevelopment in the medium containing 50 mM KCl. It was suggested that changes in ionic composition of the external medium can regulate the intracellular pH during development of pollen grain in vivo.