Reversal of Na+-dependent glycine transport in sheep reticulocyte membrane vesicles

Inside-out membrane vesicles have been prepared from sheep reticulocytes. With these vesicles, Na⁺-dependent glycine uptake and net accumulation have been demonstrated to occur in reverse, i.e., from extravesicular (normal cytoplasmic) to intravesicular (normal extravesicular) surface. Uptake and accumulation are inhibited by energization of the sodium pump by ATP whereby the Na⁺ electrochemical gradient is dissipated. Glycine-dependent Na⁺ uptake was also observed, providing evidence that Na⁺-dependent glycine influx into these vesicles, equivalent to normal efflux, is characterized by Na⁺-glycine co-transport.     

Asymmetry of the Na+-succinate cotransporter in rabbit renal brush-border membranes

We have investigated the symmetry of Na⁺-succinate cotransport in rabbit renal brush-border membrane vesicles. Succinate influx and efflux kinetics were measured under voltage-clamped conditions using [¹⁴C]succinate and a rapid filtration procedure. Both influx and efflux were Na⁺-dependent, saturable, temperature-sensitive, and influenced by the trans Na⁺ and succinate concentrations. The system was judged to be asymmetric, since the maximal velocity for influx was 3-fold higher than that for efflux, and trans Na⁺ inhibited influx more than efflux. This may be due to the asymmetrical insertion of the transporter in the brush-border membrane, which leads to differences in either the forward and backward translocation rates of the fully loaded carrier or the Na⁺ and succinate binding constants at the inner and outer faces of the membrane.     

Fast tracer efflux from membrane vesicles; investigation by controlled elution

A method has been developed to study tracer efflux from membrane vesicles. Vesicles are trapped on filters, but in contrast to conventional filtration techniques tracer efflux is measured as such. A functional integration of a commercial fraction collector, a pulse generator, and a programmable repetitive pipet with a simple electronic circuit allows monitoring of complete efflux kinetics from seconds onward. The automatic control of discrete elution steps guarantees reproducible results and makes possible a correction for background release of tracer from the filter. The dependence of efflux data on selected combinations of filters is demonstrated. These experiments also shed some light on problems intrinsic to conventional filtration procedures. The performance of the controlled elution technique is shown with ²²Na efflux from Na channel-rich membrane vesicles.     

Sodium-calcium ion exchange in skeletal muscle sarcolemmal vesicles

Summary The Ca²⁺ permeability of rabbit skeletal muscle sarcolemmal vesicles was investigated by means of radioisotope flux measurements. A membrane vesicle fraction highly enriched in sarcolemma, as revealed by enzymatic markers, was obtained from the 22–27% region of sucrose gradients after isopycnic centrifugation. The ability of sarcolemmal vesicles to exchange Na⁺ for Ca²⁺ was investigated by measuring Ca²⁺ influx into and efflux from sarcolemmal vesicles in the presence and absence of a Na⁺ gradient. It was found that Ca²⁺ movements were enhanced in the direction of the higher Na⁺ concentration. When intra- and extravesicular Na⁺ concentrations were high, Na⁺–Na⁺ exchange predominated and Na⁺–Ca²⁺ exchange was low or absent. The presence of the Ca²⁺ ionophore A23187 in the dilution medium resulted in the rapid release of Ca²⁺ and the elimination of the Na⁺-enhanced efflux of Ca²⁺, suggesting that internal rather than bound external Ca²⁺ was exchanged with Na⁺. La³⁺ abolished Na⁺–Ca²⁺ exchange and decreased overall membrane permeability. Na⁺–Ca²⁺ exchange was not due to sarcoplasmic reticulum or mitochondrial contaminants. This investigation suggests that skeletal muscle, like cardiac muscle and neurons, is capable of a transmembranous Na⁺–Ca²⁺ exchange.     

Electrogenic transport of 5-oxoproline in rabbit renal brush-border membrane vesicles Effect of intravesicular potassium

The Na⁺-dependent transport of 5-oxoproline into rabbit renal brush-border vesicles was stimulated by a K⁺ diffusion potential (interior-negative) induced by valinomycin. Na⁺ salts of two anions of different epithelial permeabilities also affected 5-oxoproline transport. These results show that the Na⁺-dependent 5-oxoproline transport in renal brush-border vesicles is an electrogenic process which results in a net transfer of positive charge. Maximum transport of 5-oxoproline occurred at an extravesicular pH of 6.0 to 8.0 and over that pH range, 5-oxoproline exists completely as an anion with a negative charge. The simplest stoichiometry consistent with this process is, therefore, the cotransport of one 5-oxoproline anion with two sodium ions. The presence of K⁺ inside the vesicles stimulated the Na⁺-dependent transport of 5-oxoproline. This stimulatory effect was specific for K⁺ and required the presence of Na⁺. The presence of Na⁺ gradient was not mandatory for the K⁺ action. The stimulation by the intravesicular K⁺ was seen in the presence as well as in the absence of a K⁺ gradient. Therefore, the increased influx of 5-oxoproline was not coupled to the simultaneous efflux of K⁺. The presence of K⁺ in the extravesicular medium alone did not affect the Na⁺-dependent transport of 5-oxoproline, showing that the site of K⁺ action was intravesicular. Glutamate did not interact with the Na⁺-dependent 5-oxoproline transport even in the presence of an outward K⁺ gradient.     

Transport in halobacterium halobium: Light-induced cation-gradients,amino acid transport kinetics,and properties of transport carriers

Cell envelope vesicles prepared from H. halobium contain bacteriorhodopsin and upon illumination protons are ejected. Coupled to the proton motive force is the efflux of Na⁺. Measurements of ²²Na flux, exterior pH change, and membrane potential, ΔΨ (with the dye 3,3′-dipentyloxadicarbocyanine) indicate that the means of Na⁺ transport is sodium/proton exchange. The kinetics of the pH changes and other evidence suggests that the antiport is electrogenic (H⁺/Na⁺ > 1). The resulting large chemical gradient for Na⁺ (outside > inside), as well as the membrane potential, will drive the transport of 18 amino acids. The 19th, glutamate, is unique in that its accumulation is indifferent to ΔΨ: this amino acid is transported only when a chemical gradient for Na⁺ is present. Thus, when more and more NaCl is included in the vesicles glutamate transport proceeds with longer and longer lags. After illumination the gradient of H⁺ collapses within 1 min, while the large Na⁺ gradient and glutamate transporting activity persists for 10–15 min, indicating that proton motive force is not necessary for transport. A chemical gradient of Na⁺, arranged by suspending vesicles loaded with KCl in NaCl, drives glutamate transport in the dark without other sources of energy, with V_max and K_m comparable to light-induced transport. These and other lines of evidence suggest that the transport of glutamate is facilitated by symport with Na⁺, in an electrically neutral fashion, so that only the chemical component of the Na⁺ gradient is a driving force. The transport of all amino acids but glutamate is bidirectional. Actively driven efflux can be obtained with reversed Na⁺ gradients (inside > outside), and passive efflux is considerably enhanced by intravesicle Na⁺. These results suggest that the transport carriers are functionally symmetrical. On the other hand, noncompetitive inhibition of transport by cysteine (a specific inhibitor of several of the carriers) is only obtained from the vesicle exterior and only for influx: these results suggest that in some respects the carriers are asymmetrical. A protein fraction which binds glutamate has been found in cholate-solubilized H. halobium membranes, with an apparent molecular weight of 50,000. When this fraction (but not the others eluted from an Agarose column) is reconstituted with soybean lipids to yield lipoprotein vesicles, facilitated transport activity is regained. Neither binding nor reconstituted transport depend on the presence of Na⁺. The kinetics of the transport and of the competitive inhibition by glutamate analogs suggest that the protein fraction responsible is derived from the intact transport system.     

Characterization of Exchange Inhibitory Peptide Effects on Na+/Ca2+ Exchange in Rat and Human Brain Plasma Membrane Vesicles

Abstract: The inhibitory effects of Na⁺/Ca²⁺ exchange inhibitory peptide (XIP), which corresponds to residues 219–238 of the Na⁺/Ca²⁺ exchange protein from canine heart, were studied in both rat and human brain plasma membrane vesicles. XIP had very high potency with respect to the inhibition of the initial velocity of intravesicular Na⁺-dependent Ca²⁺ uptake in both rat brain [IC₅₀ = 3.05 ± 0.69 µM (mean ± SE)] and human brain (IC₅₀ = 3.58 ± 0.58 µM). The maximal inhibition seen in rat brain vesicles was ～80%, whereas human brain vesicles were inhibited 100%. XIP also inhibited extravesicular Na⁺-dependent Ca²⁺ release, and the inhibitory effect was enhanced by increasing the extravesicular Na⁺ concentration. In contrast, the inhibitory effect of bepridil was competitive with respect to extravesicular Na⁺. When XIP was added at steady state (5 min after the initiation of intravesicular Na⁺-dependent Ca²⁺ uptake), it was found that the intravesicular Ca²⁺ content declined with time. Analysis of unidirectional fluxes for Ca²⁺ at steady state showed that 50 µM XIP inhibited Ca²⁺ influx and efflux ～85 and 70%, respectively. This result suggested that XIP inhibited both Na⁺/Ca²⁺ exchange and Ca²⁺/Ca²⁺ exchange but had no effect on the passive release pathway for Ca²⁺. The results suggest structural homology among cardiac, rat, and human brain exchangers in the XIP binding domain and that the binding of Na⁺ or other monovalent cations, e.g., K⁺, is required for XIP to have its inhibitory effect on Ca²⁺ transport.     

Na+-independent l-arginine transport in rabbit renal brush border membrane vesicles

Na⁺-independent l-arginine uptake was studied in rabbit renal brush border membrane vesicles. The finding that steady-state uptake of l-arginine decreased with increasing extravesicular osmolality and the demonstration of accelerative exchange diffusion after preincubation of vesicles with l-arginine, but not d-arginine, indicated that the uptake of l-arginine in brush border vesicles was reflective of carrier-mediated transport into an intravesicular space. Accelerative exchange diffusion of l-arginine was demonstrated in vesicles preincubated with l-lysine and l-ornithine, but not l-alanine or l-proline, suggesting the presence of a dibasic amino acid transporter in the renal brush border membrane. Partial saturation of initial rates of l-arginine transport was found with extravesicular [arginine] varied from 0.005 to 1.0 mM. l-Arginine uptake was inhibited by extravesicular dibasic amino acids unlike the Na⁺-independent uptake of l-alanine, l-glutamate, glycine or l-proline in the presence of extravesicular amino acids of similar structure. l-Arginine uptake was increased by the imposition of an H⁺ gradient (intravesicular pH<extravesicular pH) and H⁺ gradient stimulated uptake was further increased by FCCP. These findings demonstrate membrane-potential-sensitive, Na⁺-independent transport of l-arginine in brush border membrane vesicles which differs from Na⁺-independent uptake of neutral and acidic amino acids. Na⁺-independent dibasic amino acid transport in membrane vesicles is likely reflective of Na⁺-independent transport of dibasic amino acids across the renal brush border membrane.     

K+/H+ antiporter in alkaliphilic Bacillus sp. no. 66 (JCM 9763)

A K⁺/H⁺ antiport system was detected for the first time in right-side-out membrane vesicles prepared from alkaliphilic Bacillus sp. no. 66 (JCM 9763). An outwardly directed K⁺ gradient (intravesicular K⁺ concentration, K_in, 100 mM; extravesicular K⁺ concentration, K_out, 0.25 mM) stimulated uphill H⁺ influx into right-side-out vesicles and created the inside-acidic pH gradient (ΔpH). This H⁺ influx was pH-dependent and increased as the pH increased from 6.8 to 8.4. Addition of 100 μM quinine inhibited the H⁺ influx by 75%. This exchange process was electroneutral, and the H⁺ influx was not stimulated by the imposition of the membrane potential (interior negative). Addition of K⁺ at the point of maximum ΔpH caused a rapid K⁺-dependent H⁺ eflux consistent with the inward exchange of external K⁺ for internal H⁺ by a K⁺/H⁺ antiporter. Rb⁺ and Cs⁺ could replace K⁺ but Na⁺ and Li⁺ could not. The H⁺ efflux rate was a hyperbolic function of K⁺ and increased with increasing extravesicular pH (pH_out) from 7.5 to 8.5. These findings were consistent with the presence of K⁺/H⁺ antiport activity in these membrane vesicles. Received: March 20, 1997 / Accepted: May 22, 1997     

NMR measurements of intra- and extravesicular sodium in renal microvilli

Previous attempts to separate the nuclear magnetic resonances of intra- and extravesicular Na⁺ in brush-border membrane vesicles (BBMV) were unsuccessful and led to the proposal of rapid exchange of Na⁺ via sodium channels in BBMV. However, passive conductance of Na⁺ in this membrane has been found to be relatively small. This inconsistency prompted us to use a different shift reagent to reassess the issue. In guinea pig renal BBMV (15–30 mg protein/ml) equilibrated with Na⁺ (130 mequiv. 1), using the impermeant Na⁺ shift reagent dysprosium tripolyphosphate (3 mM), the resonances of intra- (3.3%) and extravesicular (96.7%) Na⁺ were resolved by 6 ppm. Increases in Na⁺ conductance induced by gramicidin D did not alter the characteristics of intra- and extravesicular Na⁺ resonances. By contrast, addition of glucose caused a transient increase in the area of the intravesicular Na⁺ resonance. The clear separation between the intra- and the extravesicular Na⁺ resonances allowed us to measure the relaxation times of Na⁺, which depend on its interactions with its immediate environment. The longitudinal relaxation time of intravesicular Na⁺ (13 ± 1 ms) was much shorter than that of the extravesicular Na⁺ (44.0 ± 0.4 ms). Thus, in intact renal BBMV, as well as in membranes treated with the cationophore gramicidin D, the exchange of Na⁺ between the intra- and the extravesicular compartments is slow on the NMR time scale, consistent with the low Na⁺ channel density of this membrane. In contrast, the increase in intravesicular Na⁺ induced by glucose, is consistent with a significant contribution of the glucose cotransport pathway to Na⁺ flux across these membranes. The short longitudinal relaxation time of Na⁺ in the intravesicular space indicates interaction of Na⁺ with BBMV binding sites or ordering of these ions in the intravesicular compartment.     

Regulatory Processes on the Cytoplasmic Surface of the Na+/Ca2+ Exchanger from Lobster Exoskeletal Muscle

A partially purified preparation of the lobster muscle Na⁺/Ca²⁺ exchanger was reconstituted with, presumably, random orientation in liposomes. Ca²⁺ efflux from ⁴⁵Ca-loaded vesicles was studied in exchanger molecules in which the transporter cytoplasmic surface was exposed to the extravesicular (ev) medium. Extravesicular Na⁺ (Na _ev )-dependent Ca²⁺ efflux depended directly upon the extravesicular Ca²⁺ concentration ([Ca²⁺] _ev ) with a half-maximal activation at [Ca²⁺] _ev = 0.6 μm. This suggests that the lobster muscle exchanger is catalytically upregulated by cytoplasmic Ca²⁺, as in most other species. In contrast, at low [Na⁺] _ev , the Ca _ev -binding site (i.e., on the cytoplasmic surface) for Ca²⁺ transported via Ca²⁺/Ca²⁺ exchange was half-maximally activated by about 7.5 μm Ca²⁺. Mild proteolysis of the Na⁺/Ca²⁺ exchanger by α-chymotrypsin also upregulated the Na _ev -dependent Ca²⁺ efflux. Following proteolytic digestion in Ca-free medium, the exchanger was no longer regulated by nontransported ev Ca²⁺. Proteolytic digestion in the presence of 1.9 μm free ev Ca²⁺, however, induced only a 1.6-fold augmentation of Ca²⁺ efflux, whereas, after digestion in nominally Ca-free medium, a 2.3-fold augmentation was observed; Ca²⁺ also inhibited proteolytic degradation of the Na⁺/Ca²⁺ exchanger measured by immunoblotting. These data suggest that Ca²⁺, bound to a high affinity binding site, protects against the activation of the Na⁺/Ca²⁺ exchanger by α-chymotrypsin. Additionally, we observed a 6-fold increase in the Na⁺/Ca²⁺ exchange rate, on average, when the intra- and extravesicular salt concentrations were increased from 160 to 450 mm, suggesting that the lobster muscle exchanger is optimized for transport at the high salt concentration present in lobster body fluids. Received: 20 October 1999/Revised: 13 January 2000     

Permeability of reconstituted sarcoplasmic reticulum vesicles: Reconstitution of the K+, Na+ channel

Permeability properties of reconstituted rabbit skeletal muscle sarcoplasmic reticulum vesicles were characterized by measuring efflux rates of [³H]inulin, [³H]choline⁺, ⁸⁶Rb⁺, and ²²Na⁺, as well as membrane potential changes using the voltage-sensitive probe, 3,3′-dipentyl-2,2′-oxacarbocyanine. Native vesicles were dissociated with deoxycholate and were reconstituted by dialysis. Energized Ca²⁺ accumulation was partially restored. About $\text{1}\text{2}$ of the reconstituted vesicles were found to be ‘leaky’, i.e., permeable to choline⁺ or Tris⁺ but not to inulin. The remaining reconstituted vesicles were ‘sealed’, i.e., impermeable to choline⁺, Tris⁺ and inulin. Sealed reconstituted vesicles could be further subdivided according to their K⁺, Na⁺ permeability. About $\text{1}\text{2}$, previously designated Type I, were readily permeable to K⁺ and Na⁺, indicating the presence of the K⁺, Na⁺ channel of sarcoplasmic reticulum. The remaining sealed vesicles (Type II) formed a permeability barrier to K⁺ and Na⁺, suggesting that they lacked the K⁺, Na⁺ channel. These studies show that the K⁺, Na⁺ channel of sarcoplasmic reticulum can be solubilized with detergent and reconstituted with retention of activity. Furthermore, our results suggest that part or all of the decreased Ca²⁺-loading efficiency of reconstituted vesicles may be due to the presence of a significant fraction of leaky vesicles.     

Cl−, Na+, and H+ fluxes during the acidification of rabbit reticulocyte endocytic vesicles

The ionic fluxes associated with the ATP-dependent acidification of endocytic vesicles were studied in a preparation isolated from rabbit reticulocytes enriched for transferrin-transferrin receptor complexes. No vesicle acidification was observed in the absence of intra- and extravesicular ions (sucrose_in/sucrose_out), while maximal acidification was observed with NaCl_in/KCl_out·K _in ⁺ was a poor substitute for Na _in ⁺ , and Cl _out ^– could be replaced by other anions with the following efficacy of acidification: Cl^–>Br^–>I^–>PO ₄ ^3– >gluconate>SO ₄ ^2– . Flux studies using³⁶Cl^– and²²Na⁺ showed that the vesicles had a permeability for Cl^– and Na⁺, and that ATP-dependent H⁺ pumping was accompanied by a net influx of Cl^– and a net efflux of Na⁺ provided that there was a Na⁺ concentration gradient. After 3 mins, the time necessary to maximal acidification, the electrical charge generated by the entrance of H⁺ was countered to about 45% by the Cl^– influx and to about 42% by the Na⁺ efflux. These studies demonstrated that both Cl^– and Na⁺ fluxes are necessary for optimal endocytic vesicle acidification.     

Reconstitution of acetylcholine receptor from Torpedo californica with highly purified phospholipids: Effect of α-tocopherol,phylloquinone, and other terpenoid quinones

Acetylcholine receptor from $\text{Torpedo californica}$ can be incorporated by the cholate dialysis procedure into liposomes prepared with crude soybean phospholipids (asolectin). Vesicles reconstituted with asolectin depleted of neutral lipids or with a mixture of pure phospholipids, are less active in catalyzing carbamylcholine-sensitive Na⁺ flux. Inclusion of α-tocopherol or certain quinones such as coenzyme Q₁₀ or vitamin K₁ during reconstitution yields vesicles with carbamylcholine-sensitive Na⁺ flux which, under optimal conditions, was considerably higher than that observed with vesicles reconstituted with crude phospholipid mixtures.     

Modulation of Na+-Ca2+ exchange in cardiac sarcolemmal vesicles by Ca2+ antagonists

Summary The purpose of this study was to examine the effect of three classes of Ca²⁺ antagonists, diltiazem, verapamil and nifedipine on Na⁺-Ca²⁺ exchange mechanism in the sarcolemmal vesicles isolated from canine heart. Na⁺-Ca²⁺ exchange and Ca²⁺ pump (ATP-dependent Ca²⁺ uptake) activities were assessed using the Millipore filtration technique. sarcolemmal vesicles used in this study are estimated to consist of several subpopulations wherein 23% are inside-out and 55% are right side-out sealed vesicles in orientation. The affect of each Ca²⁺ antagonist on the Na⁺-dependent Ca²⁺ uptake was studied in the total population of sarcolemmal vesicles, in which none of the agents depressed the initial rate of Ca²⁺ uptake until concentrations of 10 M were incubated in the incubation medium. However, when sarcolemmal vesicles were preloaded with Ca²⁺ via ATP-dependent Ca²⁺ uptake, cellular Ca²⁺ influx was depressed only by verapamil (28%) at 1 M in the efflux medium with 8 mM Na⁺. Furthermore, inhibition of Ca²⁺ efflux by verapamil was more pronounced in the presence of 16 mM Na⁺ in the efflux medium. The order of inhibition was; verapamil > diltiazem > nifedipine. These results indicate that same forms of Ca²⁺-antagonist drugs may affect the Na⁺-Ca²⁺ exchange mechanism in the cardiac sarcolemmal vesicles and therefore we suggest this site of action may contribute to their effects on the myocardium.     

Acetylcholine receptor-mediated sodium ion efflux after rapid hypoosmotic loading of radiotracer

Torpedo membrane vesicles (microsacs) enriched in acetylcholine receptors can be loaded with radiotracer permeants such as ²²Na⁺ and [³H]sucrose in only a few minutes. The fast loading technique employs exposure of vesicles to hypoosmotic solutions containing the radiotracers. Subsequent to loading of permeants, their efflux from the vesicles can be determined by a Millipore filtration technique. Efflux rates following hypoosmotic loading are comparable to those following the conventional loading technique which employs isotonic solutions. Hence, efflux measurements can be begun immediately after vesicle preparation. Furthermore, simultaneous loading of ²²Na⁺ and [³H]sucrose allows a normalization of ²²Na⁺ efflux with respect to vesicle volume, since ²²Na⁺, but not [³H]sucrose, is released specifically by cholinergic effectors. Such double-isotope measurements increase the reliability of the data derived.     

Depolarization-induced release of l-glutamic acid from isolated-resealed synaptic membrane vesicles

l-Glutamic acid actively loaded into resealed brain synaptic membrane vesicles was rapidly released into the incubation medium following the introduction of KCl and CaCl₂, or nigericin, or veratridine into the external medium. The KCl-induced release was enhanced by the presence of low (0.1 mM), extravesicular [Ca²⁺]. Neither the KCl-induced nor the veratridine-stimulated l-glutamate efflux were carrier-mediated processes. Finally, the KCl-stimulated l-glutamate efflux was dependent on the ratio of intra- to extravesicular [K⁺]. The observations described in this study were indicative of depolarization-induced l-glutamate release from isolated synaptic plasma membrane vesicles.     

Effect of ouabain upon diuretic-sensitive K+ transport in cultured cells evidence for separate modes of operation of the transporter

(1) Unidirectional K⁺ (⁸⁶Rb) influx and efflux were measured in subconfluent layers of MDCK renal epithelial cells and HeLa carcinoma cells. (2) In both MDCK and HeLa cells, the furosemide-inhibitable and chloride-dependent component of K⁺ influx/efflux was stimulated 2-fold by a 30 min incubation in 1 · 10^?3 M ouabain. (3) Measurements of net K⁺ loss and Na⁺ gain in ouabain-treated cells at 1 h failed to show any diuretic sensitive component, confirming the exchange character of the diuretic-sensitive fluxes. (4) Prolonged incubations for 2.5 h in ouabain revealed a furosemide- and anion-dependent K⁺ (Cl^?) outward net flux uncoupled from net Na⁺ movement. Net K⁺ (Cl^?) outward flux was half-maximally inhibited by 2 μM furosemide. (5) After 2.5 h ouabain treatment, the anion and cation dependence of the diuretic-sensitive K⁺ influx/efflux were essentially unchanged when compared to untreated controls.     

Cation flux in the ehrlich ascites tumor cell evidence for Na-for-Na and K-for-K exchange diffusion

In a previous study, evidence was presented for an external Na⁺-dependent, ouabain-insensitive component of Na⁺ efflux and an external K⁺-dependent component of K⁺ efflux in the Ehrlich ascites tumor cell. Evidence is now presented that these components are inhibited by the diuretic furosemide and that under conditions of normal extracellular Na⁺ and K⁺ they represent Na⁺-for-Na⁺ and K-⁺for-K⁺ exchange mechanisms. Using ⁸⁶Rb to monitor K⁺ movements, furosemide is shown to inhibit an ouabain-insensitive component of Rb⁺ influx and a component of Rb⁺ efflux, both representing approx. 30% of the total fux. Inhibition of Rb⁺ efflux is greatly reduced by removal of extracellular K⁺. Furosemide does not alter steady-state levels of intracellular K⁺ and it does not prevent cells depleted of K⁺ by incubation in the cold from regaining K⁺ upon warming. Using ²²Na to monitor Na⁺ movements, furosemide is shown to inhibit an ouabain-insensitive component of unidirectional Na⁺ efflux which represents approx. 22% of total Na⁺ efflux. Furosemide does not alter steady-state levels of intracellular Na⁺ and does not prevent removal of intracellular Na⁺ upon warming from cells loaded with Na⁺ by preincubation in the cold. The ability of furosemide to affect unidirectional Na⁺ and K⁺ fluxes but not net fluxes is consistent with the conclusion that these components of cation movement across the cell membrane represent one-for-one exchange mechanisms. Data are also presented which demonstrate that the uptake of α-aminoisobutyrate is not affected by furosemide. This indicates that these components of cation flux are not directly involved in the Na⁺-dependent amino acid transport system A.     

Sodium-gradient-stimulated transport of l-alanine by plasma-membrane vesicles isolated from liver parenchymal cells of fed and starved rats. Crucial role of the adrenal glucocorticoids

The ability of liver efficiently to take up amino acids, particularly l-alanine, during starvation was studied in a cell-free system by isolating plasma-membrane vesicles in a transport-competent state from rat liver parenchymal cells. These membrane vesicles have the capacity to accumulate l-alanine against an apparent concentration gradient when exposed to an artificial and transient transmembrane Na⁺ gradient (extravesicular Na⁺ concentration greater than inside). The rate of accumulation of l-alanine is dependent on the plasma-membrane vesicle concentration, and the steady-state concentration attained is inversely related to the osmolarity of the medium. The Na⁺-mediated stimulation is not exhibited if the membrane vesicles are pre-equilibrated with NaCl, if K⁺ or Li⁺ are substituted for Na⁺, or if SO₄²⁻ replaces Cl⁻ as the counterion. The apparent active transport of l-alanine into the membrane vesicles appears to occur by an electrogenic mechanism: (1) the use of NaSCN significantly heightens the early concentrative phase of transport when compared with the effect of NaCl; (2) an enhanced active transport is also observed when a valinomycin-induced K⁺ efflux occurs concomitant with Na⁺ and l-alanine influx. Plasma-membrane vesicles isolated from liver parenchymal cells of a 24 h-starved rat exhibit an initial l-alanine transport rate that is 3–4 times that for membrane vesicles derived from a fed animal. The increased rate of l-alanine transport by plasma-membrane vesicles from starved animals can be obliterated by adrenalectomy and restored by administration of glucocorticoid. These results establish that stimulation of the gluconeogenic pathway by starvation involves a plasma-membrane-localized change affecting l-alanine transport which is regulated in part by the glucocorticoid hormones.