Erythrocyte Lii-Nao countertransport system Inhibition by N-ethylmaleimide probes for a conformational change of the transport system

Human erythrocytes were treated by a series of SH-reagents, including maleimides, iodo compounds, mercurials and oxidizing agents. Rates of Li efflux into Na-rich medium, Li leak and Li_i-Na_o countertransport were then determined. Of the 13 different reagents studied, only N-ethylmaleimide, iodoacetamide and iodoacetate inhibited selectively the countertransport activity. The effect of the various reagents indicates that the sensitive SH-groups of the countertransport system are not externally exposed. N-Ethylmaleimide was used to probe for changes elicited by substrate cations in Li_i-Na_o countertransport. In Na- and Li-free medium, inhibition of Li_i-Na_o countertransport by N-ethylmaleimide of 35% was reached within 2 s. In Na or Li medium, maximal inhibition was twice as great, but was attained much more slowly, within 10 min. Kinetic data and Hill plot analysis indicate the involvement of two classes of SH-groups: one expressed in the various media with and without substrate cations, and an additional one, which becomes specifically available to N-ethylmaleimide in the presence of external Na or Li. The affinity of Na to the site promoting inhibition by N-ethylmaleimide (apparent K_m  12 mM) is higher than the affinity of Na to its external countertransport site (apparent K_m  25 mM), as reported by Sarakadi, B., Alifimoff, J.K., Gunn, R.B. and Tosteson, D.C. (1978) J. Gen. Physiol. 72, 249–265). Reactivity of $\text{N-}\text{ethyl}\text{[}{}^{14}\text{C}\text{]}\text{maleimide}$ was not modified by the media tested. It is concluded that external Na and Li cause a conformational change in the protein(s) of the countertransport system in human erythrocytes.     

Elevated intracellular Ca2+ affects Lii-Nao countertransport in human red blood cells

Changes in cytoplasmic Ca2+ concentration and in Lii-Nao countertransport activity have been shown to be associated with essential hypertension. Elevated intracellular free [Ca2+], as well as abnormalities of Ca2+ binding and transport have been reported in cells from different tissues of hypertensive laboratory animals and essential hypertensive patients. Similarly, enhanced rates of Lii-Nao countertransport and the modified pattern of the temperature dependence of this activity in red blood cells from essential hypertensive patients have been previously demonstrated. The aim of the present study was to investigate possible interaction between changes in intracellular free [Ca2+] and the Lii-Nao exchange in human red blood cells. The ionophore ionomycin was used to allow Ca2+ incorporation into the cells in a dose-dependent manner. The elevation of intracellular [Ca2+], in turn, resulted in enhanced Li+ efflux from the cells. At 3 microM, ionomycin selectively and significantly enhanced the Lii-Nao countertransport but not Li+ leakage from the cells. EGTA totally abolished the effect of ionomycin, indicating that the effect is directly related to Ca2+. As low as 0.4 microM Ca2+ caused a statistically significant effect. The maximal effect of Ca2+ on the Lii-Nao countertransport was achieved around the external pH range of 6.8-7.5. In contrast, the leakage of Li+ was significantly enhanced by Ca2+ at a pH of 7.4 and above. Ca2+ did not affect the Km of the Lii-Nao countertransport for Li+. Amiloride, which inhibits Na+/H+ exchange, inhibited only 10% of the Ca2+-enhanced countertransport. It is concluded that Ca2+ may play a role in the regulation of Lii-Nao countertransport in erythrocytes.     

Lithium uptake rate and lithium: lithium exchange rate in human erythrocytes at a nearly pharmacologically normal level monitored by 7Li NMR

7Li NMR was used to follow the rate of uptake of Li+ and Li+:Li+ exchange rates in human erythrocytes at an external lithium concentration of 2 mM, marginally higher than used in therapeutic applications of lithium. The rate of Li+:Li+ exchange is approximately 16 times faster than the rate of Li uptake from the medium. The results are in agreement with lithium-sodium countertransport being the dominant mode for lithium uptake into erythrocytes and for the countertransport system having a greater affinity for Li+ than for Na+.     

Sulphydryl groups involved in Na+-Li+ exchange in human erythrocytes

Oxidative stress causes cellular injury that is thought to be due to increased cytosolic cation levels. Disturbances of a variety of mechanisms which normally maintain intracellular anion/cation homeostasis, occur during oxidative stress. Reactivity of the SH- groups essential for oubain-resistant Na(+)-Li(+) exchange by N-ethylmaleimide (NEM) and selenite was studied in human erythrocytes. In addition, the reactivity of the substances on SH- groups and Li(+) influx have been studied as a function of pH of the medium. The results show that NEM induces an irreversible inhibition of Li(+) influx. It diminishes progressively with the increasing pH of the medium. Whereas we obtain increasing intracellular Li(+) concentration with the rising selenite concentration in the medium. The maximum effect with this substance is reached at about pH 8.0. We can state that the -SH reagents (NEM and selenite) studied behave differently: NEM inhibits Li(+) influx by modifying the essential SH-groups of the membrane proteins in such a way that the exchange is reduced, whereas it maintains the Na(+) permeability almost unaltered. The slight increase in intracellular Na(+) induced by selenite suggests that the oxidative changes in the intracellular sulphydryl groups may constitute an important mechanism for the regulation of the intracellular cations.     

Anion/anion exchange in human neutrophils

Of the total one-way chloride fluxes (approximately 1.4 meq/liter cell water X min) in steady state human polymorphonuclear leukocytes bathed in 148 mM Cl media, approximately 70% behaves as self-exchange mediated by a nonselective anion carrier that is not inhibited by stilbene disulfonates. Five properties of this carrier-mediated exchange were investigated: substrate saturation is seen with respect to 36Cl influx as a function of the external Cl concentration [for normal-Cl cells, the apparent Km(Cl) is approximately 22 mM when Cl replaces para-amino- hippurate (PAH) and approximately 5 mM when Cl replaces glucuronate], and with respect to 36Cl efflux as a function of the concentration of internal Cl replacing PAH [apparent Km(Cl) congruent to 35 mM for cells bathed in 148 mM Cl]; there is trans stimulation of 36Cl influx by internal Cl (replacing PAH) with an apparent Km(Cl) congruent to 35 mM, and of 36Cl efflux by external Cl with an apparent Km(Cl) congruent to 22 mM (Cl replacing PAH) or approximately 5 mM (Cl replacing glucuronate); there is substrate competition between Cl and PAH, but the carrier appears devoid of affinity for glucuronate; influxes and effluxes mediated by the carrier are subject to competitive inhibition by extracellular alpha-cyano-4-hydroxycinnamate (CHC), with an apparent Ki congruent to 9 mM in Cl medium or approximately 1 mM in PAH medium (transport of the inhibitor itself is very slow); and internal Cl and external Cl or PAH undergo 1:1 countertransport, which is CHC sensitive. A simple equilibrium-competition model is proposed that accounts for all the extracellular ligand interactions presented for normal-Cl cells. Least-squares values of the carrier's true Michaelis constants for extracellular Cl, PAH, and CHC are 5.03 +/- 0.83, 50.3 +/- 14.9, and 0.29 +/- 0.09 mM, respectively.     

Intracellular acidification-induced alkali metal cation/H+ exchange in human neutrophils

Pretreatment of isolated human neutrophils (resting pHi congruent to 7.25 at pHo 7.40) with 30 mM NH4Cl for 30 min leads to an intracellular acidification (pHi congruen to 6.60) when the NH4Cl prepulse is removed. Thereafter, in 140 mM Na+ medium, pHi recovers exponentially with time (initial rate, approximately 0.12 pH/min) to reach the normal resting pHi by approximately 20 min, a process that is accomplished mainly, if not exclusively, though an exchange of internal H+ for external Na+. This Na+/H+ countertransport is stimulated by external Na+ (Km congruent to 21 mM) and by external Li+ (Km congruent to 14 mM), though the maximal transport rate for Na+ is about twice that for Li+. Both Na+ and Li+ compete as substrates for the same translocation sites on the exchange carrier. Other alkali metal cations, such as K+, Rb+, or Cs+, do not promote pHi recovery, owing to an apparent lack of affinity for the carrier. The exchange system is unaffected by ouabain or furosemide, but can be competitively inhibited by the diuretic amiloride (Ki congruent to 8 microM). The influx of Na+ or Li+ is accompanied by an equivalent counter-reflux of H+, indicating a 1:1 stoichiometry for the exchange reaction, a finding consistent with the lack of voltage sensitivity (i.e., electroneutrality) of pHi recovery. These studies indicate that the predominant mechanism in human neutrophils for pHi regulation after intracellular acidification is an amiloride-sensitive alkali metal cation/H+ exchange that shares a number of important features with similar recovery processes in a variety of other mammalian cell types.     

Characterisation of Ca2+ or Mg(2+)-dependent nucleoside triphosphatase from rat mesenteric small arteries.

When isolated rat mesenteric small arteries were submitted to 2 s of sonication, a nucleoside triphosphatase activity was released to the medium, mainly from the plasma membrane of the vascular smooth muscle cells. The activity was kinetically characterized: It hydrolysed ATP, UTP and GTP with the same substrate affinity and the same specific activity. CaATP, as well as MgATP were substrates for the enzyme with an apparent Km in the micromolar range. ATPase inhibitors: ouabain, vanadate, AlF4-, oligomycin and N-ethylmaleimide were without effect on the hydrolytic activity. Among other modifiers tested only N,N'-dicyclohexylcarbodiimide caused significant (greater than 30%) inhibition. In the presence of micromolecular concentrations of Ca2+ and Mg2+, small (less than 20 mM) concentrations of Na+, K+, Rb+, Cs+ and choline+, irrespective of the nature of the anion, activated the hydrolysis with an equilibrium ordered pattern, but concentrations of monovalent cation salts above 20 mM decreased the hydrolysis rate. No activation by monovalent cation salts was seen at millimolar concentrations of divalent cations and substrate. On the basis of the results a standard mixture is proposed, which allows a sensitive assay of the specific enzyme activity.     

Cation and harmaline interactions with Na(+)-independent dibasic amino acid transport system y+ in human erythrocytes and in erythrocytes from a primitive vertebrate the pacific hagfish (Eptatretus stouti).

Transport systems y+, asc and ASC exhibit dual interactions with dibasic and neutral amino acids. For conventional Na(+)-dependent neutral amino acid system ASC, side chain amino and guanido groups bind to the Na+ site on the transporter. The topographically equivalent recognition site on related system asc binds harmaline (a Na(+)-site inhibitor) with the same affinity as asc (apparent Ki range 1-4 mM), but exhibits no detectable affinity for Ha. Although also classified as Na(+)-independent, dibasic amino acid transport system y+ accepts neutral amino acids when Na+ or another acceptable cation is also present. This latter observation implies that the y+ translocation site binds Na+ and suggests possible functional and structural similarities with ASC/asc. In the present series of experiments with human erythrocytes, system y(+)-mediated lysine uptake (5 microM, 20 degrees C) was found to be 3-fold higher in isotonic sucrose medium than in normal 150 mM NaCl medium. This difference was not a secondary consequence of changes in membrane potential, but resulted from Na+ functioning as a competitive inhibitor of transport. Apparent Km and Vmax values for lysine transport at 20 degrees C were 15.2 microM and 183 mumol/l cells per h, respectively, in sucrose medium and 59.4 microM and 228 mumol/l cells per h in Na+ medium. Similar results were obtained with y+ in erythrocytes of a primitive vertebrate, the Pacific hagfish (Eptatretus stouti), indicating that Na(+)-inhibition is a general property of this class of amino acid transporter. At a permeant concentration of 5 microM, the IC50 value for Na(+)-inhibition of lysine uptake by human erythrocytes was 27 mM. Other inorganic and organic cations, including K+ and guanidinium+, also inhibited transport. In parallel with its actions on ASC/asc harmaline competitively inhibited lysine uptake by human cells in sucrose medium. As predicted from mutually competitive binding to the y+ translocation site, the presence of 150 mM Na+ increased the harmaline inhibition constant (Ki) from 0.23 mM in sucrose medium to 0.75 mM in NaCl medium. We interpret these observations as further evidence that y+, asc and ASC represent a family of closely related transporters with a common evolutionary origin.     

A kinetic analysis of Na-Li countertransport in human red blood cells

We examined the kinetic properties of the interactions between inner and outer cation sites of the Na-Li countertransport system in human red blood cells. Li-stimulated Na efflux [V(Na)] was measured as a function of external Li [(Li)o] and internal Na [(Na)i] contents. At each (Li)o, a Hanes plot of (Na)i/V(Na) vs. (Na)i allowed us to calculate the apparent dissociation constant for internal Na (KiNa) and the maximal rate of Na efflux [Vmax(Na)]. In erythrocytes from 10 different subjects, the Vmax(Na)/KiNa ratios were independent of the external Li concentrations. In other experiments, Na-stimulated Li efflux [V(Li)] was measured as a function of external Na and internal Li contents. In three subjects studied, the Vmax(Li)/KiLi ratios were independent of the external Na concentrations. The data strongly suggest that the countertransport mechanism is consecutive ("ping-pong").     

Mg2+ efflux is accomplished by an amiloride-sensitive Na+/Mg2+ antiport

Mg2+ efflux from Mg2+-preloaded chicken erythrocytes is caused by an electroneutral Na+/Mg2+ antiport. It depends specifically on extracellular Na+, according to Michaelis-Menten kinetics (Km = 25 mM), and is reversibly noncompetitively inhibited by amiloride (Ki = 0.59 mM). In contrast to Na+/H+ antiport, Li+, Ca2+ and N-ethylmaleimide do not interfere with Na+/Mg2+ antiport. The Na+/Mg2+ antiport is driven by the intracellular/extracellular Mg2+ gradient.     

Characterization of threonine transport into a kidney epithelial cell line (BSC-1). Evidence for the presence of Na(+)-independent system asc [corrected

The transport routes for threonine in a primate kidney epithelial cell line (BSC-1) grown as monolayer in continuous cell culture were studied. We discovered at least four different transport systems for threonine uptake. The Na(+)-dependent route shows biphasic kinetics with a low and high affinity parameter. The apparent kinetic constants for Km1 and Km2 were 0.3 and 36 mM with apparent Vmax values of 6.3 and 90 nmol/mg protein/min, respectively. The high affinity, low Km component resembles system ASC activity, with respect to substrate selectivity. The Na(+)-independent route also exhibits biphasic kinetics. A high affinity component (apparent Km of 1.0 mM, and apparent Vmax of 7.2 nmol/mg protein/min) is sensitive to inhibition by leucine and the aminoendolevo-rotatory isomer of 2-aminobicyclo[2,2,1]heptane-2-carboxylic acid, suggesting participation by system L. The low affinity component (apparent Km of 10.2 mM, and apparent Vmax of 71 nmol/mg protein/min) was specifically inhibited by threonine, serine, and alanine and could be assigned to system asc. The discrimination between system L and asc is based upon differences in pH sensitivity, trans stimulation, and Ki values. In addition, the effects of harmaline, a suspected sodium transport site inhibitor, have been studied. Harmaline noncompetitively inhibited Na(+)-dependent threonine uptake but had no effect on Na(+)-independent transport of threonine. This report is the first to present evidence for the presence of system asc in renal epithelial cells. The physiological and biochemical significance of our findings are discussed.     

Evidence indicating that pig renal phosphate-activated glutaminase has a functionally predominant external localization in the inner mitochondrial membrane

Phosphate-activated glutaminase in intact pig renal mitochondria was inhibited 50-70% by the sulfhydryl reagents mersalyl and N-ethylmaleimide (0.3-1.0 mM), when assayed at pH 7.4 in the presence of no or low phosphate (10 mM) and glutamine (2 mM). However, sulfhydryl reagents added to intact mitochondria did not inhibit the SH-enzyme beta-hydroxybutyrate dehydrogenase (a marker of the inner face of the inner mitochondrial membrane), but did so upon addition to sonicated mitochondria. This indicates that the sulfhydryl reagents are impermeable to the inner membrane and that regulatory sulfhydryl groups for glutaminase have an external localization here. The inhibition observed when sulfhydryl reagents were added to intact mitochondria could not be attributed to an effect on a phosphate carrier, but evidence was obtained that pig renal mitochondria have also a glutamine transporter, which is inhibited only by mersalyl and not by N-ethylmaleimide. Mersalyl and N-ethylmaleimide showed nondistinguishable effects on the kinetics of glutamine hydrolysis, affecting only the apparent Vmax for glutamine and not the apparent Km calculated from linear Hanes-Woolf plots. Furthermore, both calcium (which activates glutamine hydrolysis), as well as alanine (which has no effect on the hydrolytic rate), inhibited glutamine transport into the mitochondria, indicating that transport of glutamine is not rate-limiting for the glutaminase reaction. Desenzitation to inhibition by mersalyl and N-ethylmaleimide occurred when the assay was performed under optimal conditions for phosphate activated glutaminase (i.e. in the presence of 150 mM phosphate, 20 mM glutamine and at pH 8.6). Desenzitation also occurred when the enzyme was incubated with low concentrations of Triton X-100 which did not affect the rate of glutamine hydrolysis. Following incubation with [14C]glutamine and correction for glutamate in contaminating subcellular particles, the specific activity of [14C]glutamate in the mitochondria was much lower than that of the surrounding incubation medium. This indicates that glutamine-derived glutamate is released from the mitochondria without being mixed with the endogenous pool of glutamate. The results suggest that phosphate-activated glutaminase has a functionally predominant external localization in the inner mitochondrial membrane.     

The mitochondrial carnitine carrier: characterization of SH-groups relevant for its transport function.

The transport function of the purified and reconstituted carnitine carrier from rat liver mitochondria was correlated to modification of its SH-groups by various reagents. The exchange activity and the unidirectional transport, both catalyzed by the carnitine carrier, were effectively inhibited by N-ethylmaleimide and submicromolar concentrations of mercurial reagents, e.g., mersalyl and p-(chloromercuri)benzenesulfonate. When 1 microM HgCl2 or higher concentrations of the above mentioned mercurials were added, another transport mode of the carrier was induced. After this treatment, the reconstituted carnitine carrier catalyzed unidirectional substrate-efflux and -influx with significantly reduced substrate specificity. Control experiments in liposomes without carrier or with inactivated carrier protein proved the dependence of this transport activity on the presence of active carnitine carrier. The mercurial-induced uniport correlated with inhibition of the 'physiological' functions of the carrier, i.e., exchange and substrate specific unidirectional transport. The effect of consecutive additions of various reagents including N-ethylmaleimide, mercurials, Cu(2+)-phenanthroline and diamide on the transport function revealed the presence of at least two different classes of SH-groups. N-Ethylmaleimide blocked the carrier activity by binding to SH-groups of one of these classes. At least one of these SH-groups could be oxidized by the reagents forming S-S bridges. Besides binding to the class of SH-groups to which N-ethylmaleimide binds, mercurials also reacted with SH-groups of the other class. Modification of the latter led to the induction of the efflux-type of carrier activity characterized by loss of substrate specificity.     

Chemical modification of the Na+/H+ exchanger of thymic lymphocytes. Inhibition by N-ethylmaleimide

A Na+/H+ exchanger is involved in the regulation of cytoplasmic pH and cellular volume in a variety of cells. Little is known about the molecular nature of this exchanger. The purpose of this study was to survey a variety of group-specific covalent reagents as potential inhibitors of the exchanger. Na+/H+ countertransport activity was assayed as the amiloride-sensitive rate of Na+-induced alkalinization in acid-loaded lymphocytes, or as the rate of swelling in cells suspended in sodium propionate medium. Activity was not affected by proteinases or by carboxyl-group and amino-group specific reagents. A significant inhibition was produced by diethylpyrocarbonate, a histidine-specific reagent and by N-ethylmaleimide, a sulfhydryl group reagent. A similarly reactive but nonpermeating sulfhydryl agent, glutathione-maleimide, failed to inhibit Na+-H+ exchange. Moreover, the reaction with N-ethylmaleimide was sensitive to changes in the cytoplasmic pH. The data suggest that the chemically reactive groups of the Na+/H+ exchanger of lymphocytes have limited exposure to the extracellular medium but that an internally located sulfhydryl group is critical for the cation-exchange activity.     

Role of Na+ and Li+ in thiomethylgalactoside transport by the melibiose transport system of Escherichia coli.

Thiomethyl-beta-galactoside (TMG) accumulation via the melibiose transport system was studied in lactose transport-negative strains of Escherichia coli. TMG uptake by either intact cells or membrane vesicles was markedly stimulated by Na+ or Li+ between pH 5.5 and 8. The Km for uptake of TMG was approximately 0.2 mM at an external Na+ concentration of 5 mM (pH 7). The alpha-galactosides, melibiose, methyl-alpha-galactoside, and o-nitrophenyl-alpha-galactoside had a high affinity for this system whereas lactose, maltose and glucose had none. Evidence is presented for Li+-TMG or Na+-TMG cotransport.     

Mixed type inhibition of the renal Na+/H+ antiporter by Li+ and amiloride. Evidence for a modifier site

We studied the interactions of Na+, Li+, and amiloride on the Na+/H+ antiporter in brush-border membrane vesicles from rabbit renal cortex. Cation-mediated collapse of an outwardly directed proton gradient (pHin = 6.0; pHout = 7.5) was monitored with the fluorescent amine, acridine orange. Proton efflux resulting from external addition of Na+ or Li+ exhibited simple saturation kinetics with Hill coefficients of 1.0. However, kinetic parameters for Na+ and Li+ differed (Km for Li+ = 1.2 +/- 0.1 mM; Km for Na+ = 14.3 +/- 0.8 mM; Vmax for Li+ = 2.40 +/- 0.07 fluorescence units/s/mg of protein; Vmax for Na+ = 7.10 +/- 0.24 fluorescence units/s/mg of protein). Inhibition of Na+/H+ exchange by Li+ and amiloride was also studied. Li+ inhibited the Na+/H+ antiporter by two mechanisms. Na+ and Li+ competed with each other at the cation transport site. However, when [Na+] was markedly higher than [Li+], [( Na+] = 90 mM; [Li+] less than 1 mM), we observed noncompetitive inhibition (Vmax for Na+/H+ exchange reduced by 25%). The apparent Ki for this noncompetitive inhibition was congruent to 50 microM. In addition, 2-30 mM intravesicular Li+, but not Na+, resulted in trans inhibition of Na+/H+ exchange. Amiloride was a mixed inhibitor of Na+/H+ exchange (Ki = 30 microM, Ki' = 90 microM) but was only a simple competitive inhibitor of Li+/H+ exchange (Ki = 10 microM). At [Li] = 1 mM and [amiloride] less than 100 microM, inhibition of Na+/H+ exchange by a combination of the two inhibitors was always less than additive. These results suggest the presence of a cation-binding site (separate from the cation-transport site) which could be a modifier site of the Na+/H+ antiporter.     

Kinetic properties of the Na+/H+ antiport of heart mitochondria

The fluorescence of 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein (BCECF) has been used to follow the Na+/H+ antiport activity of isolated heart mitochondria as a Na+-dependent extrusion of matrix H+. The antiport activity measured in this way shows a hyperbolic dependence on external Na+ or Li+ concentration when the external pH (pHo) is 7.2 or higher. The apparent Km for Na+ decreases with increasing pHo to a limit of 4.6 mM. The Ki for external H+ as a competitive inhibitor of Na+/H+ antiport averages 3.0 nM (pHo 8.6). The Vmax at 24 degrees C is 160 ng ion of H+ min-1 (mg of protein)-1 and does not vary with pHo. Li+ reacts with the antiporter with higher affinity, but much lower Vmax, and is a competitive inhibitor of Na+/H+ antiport. The rate of Na+/H+ antiport is optimal when the pHi is near 7.2. When pHo is maintained constant, Na+-dependent extrusion of matrix H+ shows a hyperbolic dependence on [H+]i with an apparent Km corresponding to a pHi of 6.8. The Na+/H+ antiport is inhibited by benzamil and by 5-N-substituted amiloride analogues with I50 values in the range from 50 to 100 microM. The pH profile for this inhibition seems consistent with the availability of a matrix binding site for the amiloride analogues. The mitochondrial Na+/H+ antiport resembles the antiport found in the plasma membrane of mammalian cells in that Na+, Li+, and external H+ appear to compete for a common external binding site and both exchanges are inhibited by amiloride analogues.(ABSTRACT TRUNCATED AT 250 WORDS)     

Calcium-dependent 3':5'-cyclic nucleotide phosphodiesterase. Inhibition of basal activity at physiological levels of potassium ions.

A calcium-dependent cyclic nucleotide phosphodiesterase from rat cerebrum was, in the absence of activator protein, inhibited by various monovalent cations. The inhibition was rapid, readily reversible, and concentration-dependent, with 100 mM cesium, rubidium, or potassium ion inhibiting essentially all basal enzyme activity, while 100 mM sodium or lithium ions produced only moderate inhibition. The potency of the cations in inhibiting the enzyme was Cs greater than or equal to Rb greater than K greater than Na greater than or equal to Li. Potassium ions increased the apparent Km for cyclic GMP and cyclic AMP by 3- and 5-fold, respectively. At 100 mM, the monovalent cations inhibited enzyme activated by the calcium-dependent activator by only 15 to 30%, while at 55 mM no inhibition pertained. Potassium and sodium ions at 55 mM had no effect on the calcium-independent phosphodiesterase from rat cerebrum. The results indicate that at normal intracellular concentrations of potassium ions the activity of the calcium-dependent phosphodiesterase is virtually completely dependent on the presence of calcium plus activator protein.     

Na+ for H+ exchange in rabbit erythrocytes

The effect of a transmembrane pH gradient on the ouabain, bumetanide, and phloretin resistant H+ efflux was studied in rabbit erythrocytes. Proton equilibration was reduced by the use of DIDS (125 microM) and acetazolamide (1 mM). H+ efflux from acid loaded erythrocytes (pHi = 6.1) was measured in a K+ (145 mM) medium, pH0 = 8.0, in the presence and absence of 60 microM 5,N,N-dimethyl-amiloride (DMA). The H+ efflux rate in a K+-containing medium was 116.38 +/- 4.5 mmol/l cell X hr. Substitution of Nao+ for Ko+ strongly stimulated H+ efflux to 177.89 +/- 7.9 mmol/l cell X hr. The transtimulation of H+ efflux by Nao+ was completely abolished by DMA falling to values not different from controls with an ID50 of about 8.6 X 10(-7) M. The sequence of substrate selectivities for the external transport site were Na greater than greater than greater than Li greater than choline, Cs, K, and Glucamine. The transport system has no specific anion requirement, but is inhibited by NO3-. The DMA sensitive H+ efflux was a saturable function of [Na+]o, with an apparent Km and Vmax of about 14.75 +/- 1.99 mM and 85.37 +/- 7.68 mmol/l cell X hr, respectively. However, the Nao+-dependent and DMA-sensitive H+ efflux was sigmoidally activated by [H+]i, suggesting that Hi+ interacts at both transport and modifier sites. An outwardly directed H+ gradient (pHi 6.1, pH = 8.0) also promoted DMA sensitive Na+ entry (61.2 +/- 3.0 mmol/l cell X hr) which was abolished when pHo was reduced to 6.0. The data is therefore consistent with the presence of a Na+/H+ exchange system in rabbit erythrocytes.     

Mechanisms by which Li+ stimulates the (Na+ and K+)-dependent ATPase.

The addition of LiCl stimulated the (Na+ + K+)-dependent ATPase activity of a rat brain enzyme preparation. Stimulation was greatest in high Na+/low K+ media and at low Mg-ATP concentrations. Apparent affinities for Li+ were estimated at the alpha-sites (moderate-affinity sites for K+ demonstrable in terms of activation of the associated K+-dependent phosphatase reaction), at the beta-sites (high-affinity sites for K+ demonstrable in terms of activation of the overall ATPase reaction), and at the Na+ sites for activation. The relative efficacy of Li+ was estimated in terms of the apparent maximal velocity of the phosphatase and ATPase reactions when Li+ was substituted for K+, and also in terms of the relative effect of Li+ on the apparent Km for Mg-ATP. With these data, and previously determined values for the apparent affinities of K+ and Na+ at these same sites, quantitative kinetic models for the stimulation were examined. A composite model is required in which Li+ stimulates by relieving inhibition due to K+ and Na+ (i) by competing with K+ for the alpha-sites on the enzyme through which K+ decreases the apparent affinity for Mg-ATP and (ii) by competing with Na+ at low-affinity inhibitory sites, which may represent the external sites at which Na+ is discharged by the membrane Na+/K pump that this enzyme represents. Both these sites of action for Li+ would thus lie, in vivo, on the cell exterior.