Na+-dependent transport of glycine in renal brush border membrane vesicles: Evidence for a single specific transport system

The uptake of glycine in rabbit renal brush border membrane vesicles was shown to consist of glycine transport into an intravesicular space. An Na⁺ electrochemical gradient (extravesicular>intravesicular) stimulated the initial rate of glycine uptake and effected a transient accumulation of intravesicular glycine above the steady-state value. This stimulation could not be induced by the imposition of a K⁺, Li⁺ or choline⁺ gradient and was enhanced as extravesicular Na⁺ was increased from 10 mM to 100 mM. Dissipation of the Na⁺ gradient by the ionophore gramicidin D resulted in diminished Na⁺-stimulated glycine uptake. Na⁺-stimulated uptake of glycine was electrogenic. Substrate-velocity analysis of Na⁺-dependent glycine uptake over the range of amino acid concentrations from 25 μM to 10 mM demonstrated a single saturable transport system with apparent K_m = 996 μM and V_max = 348 pmol glycine/mg protein per min. Inhibition observed when the Na⁺-dependent uptake of 25 μM glycine was inhibited by 5 mM extravesicular test amino acid segregated dibasic amino acids, which did not inhibit glycine uptake, from all other amino acid groups. The amino acids d-alanine, d-glutamic acid, and d-proline inhibited similarly to their l counterparts. Accelerative exchange of extravesicular [³H]glycine was demonstrated when brush border vesicles were preloaded with glycine, but not when they were preloaded with l-alanine, l-glutamic acid, or with l-proline. It is concluded that a single transport system exists at the level of the rabbit renal brush border membrane that functions to reabsorb glycine independently from other groups of amino acids.     

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.     

Analysis of two chloride requirements for sodium-dependent amino acid and glucose transport by intestinal brush-border membrane vesicles of fish

Intestinal brush border vesicles of a Mediterranean sea fish (Dicentrarchus labrax) were prepared using the Ca²⁺-sedimentation method. The transport of glucose, glycine and 2-aminoisobutyric acid is energized by an Na⁺ gradient ($\text{out > in}$). In addition, amino acid uptake requires Cl^? in the extravesicular medium (2-aminoisobutyric acid more than glycine). This Na⁺- and Cl^?-dependent uptake is electrogenic, since it can be stimulated by negative charges inside the vesicles. The specific Cl^? requirement of glycine and 2-aminoisobutyric acid transport is markedly influenced by pH, a change from 6.5 to 8.4 reducing the role played by Cl^?. In the presence of Cl^?, the $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ of 2-aminoisobutyric acid uptake is reduced and its $\text{V}{}_{\mathrm{<mtext>max</mtext>}}$ is enhanced. Cl^? affects also a non-saturable Na⁺-dependent component of this amino acid uptake. Amino acid transport is also increased by intravesicular Cl^? (2-aminoisobutyric acid less than glycine). This effect is more concerned with glucose uptake, which can be then multiplied by 2.3. A concentration gradient ($\text{in > out}$) as well as the presence of Na⁺ in the incubation medium seems to enter into this requirement. This intravesicular Cl^? effect is not influenced by pH between 6.5 and 8.4.     

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.     

Transport of β-alanine in renal brush border membrane vesicles

The findings that the equilibrium uptake of β-alanine decreased with increasing medium osmolarity and preincubation with β-alanine increased uptake of the amino acid indicate that the uptake of β-alanine by rabbit renal brush border membranes represents transport into membrane vesicles. A Na⁺ electrochemical gradient (extravesicular > intravesicular) stimulated the initial rate of β-alanine uptake about three times and effected a transient accumulation of the amino acid twice the equilibrium value. Stimulation of the uptake was specific for Na⁺. Gramicidin abolished the overshoot, presumably by dissipating the gradient by accelerating the electrogenic entrance of Na⁺ into the vesicle via a pathway not coupled to uptake of β-alanine. In K⁺-loaded vesicle, valinomycin enhanced the Na⁺ gradient-dependent uptake of β-alanine. These findings indicate that the Na⁺ gradient-dependent transport of β-alanine is an electrogenic process and suggest that the membrane potential is a determinant of β-analine transport. Uptake of β-aniline, at a given concentration, reflected the sum of contributions from Na⁺ gradient-dependent and -independent transport systems. The dependent system saturated at 100 μM. The independent system did not saturate. At physiological concentrations the rate of the Na⁺ gradient-dependent uptake was four times that in the absence of the gradient. The Na⁺ gradient-dependent rate of β-alanine uptake was strongly inhibited by taurine, suggesting that β-amino acids have a common transport system, α-Amino acids, i.e. l-arginine, l-glutamate, l-proline, and glycine, representing previously reported specific α-amino acid transport systems in the brush border membrane, did not inhibit the uptake of β-alanine. These findings indicate that the brush border membrane has a distinct transport system for β-amino acids.     

Effect of pH on the transport of Krebs cycle intermediates in renal brush border membranes

Lowering extravesicular pH stimulated Na⁺-dependent citrate transport in renal brush border membrane vesicles: e.g., at pH_out = 5.5, the initial rate of citrate uptake was increased 10-fold compared to parallel control experiments at pH 7.5. The same experimental conditions had little effect on succinate uptake. The influence of pH on citrate transport is a product of the extravesicular H⁺ concentration; pH gradients did not potentiate the effects nor were proton gradients capable of driving transport in the absence of Na⁺. The effect of pH is adequately explained if only the mono- and divalent species of citrate (Cit^1?, Cit^2?) are considered acceptable substrates for transport. The stimulatory influence of pH on transport correlated quite well with pH-related increases in the concentrations of Cit^1? and Cit^2?, and over the same pH range [Cit^3?] was inversely related to citrate uptake. A model of the Na⁺-dependent dicarboxylate transport system is discussed in which three sodium ions are translocated per molecule of dicarboxylic acid.     

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.     

Evidence against parallel operation of sodium/calcium antiport and ATP-driven calcium transport in plasma membrane vesicles from kidney tubule cells

The present study aimed to clarify the existence of a Na⁺/Ca²⁺ antiport device in kidney tubular epithelial cells discussed in the literature to represent the predominant mechanistic device for Ca²⁺ reabsorption in the kidney. (1) Inside-out oriented plasma membrane vesicles from tubular epithelial cells of guinea-pig kidney showed an ATP-driven Ca²⁺ transport machinery similar to that known to reside in the plasma membrane of numerous cell types. It was not affected by digitalis compounds which otherwise are well-documented inhibitors of Ca²⁺ reabsorption. (2) The vesicle preparation contained high, digitalis-sensitive (Na⁺+K⁺-ATPase activities indicating its origin from the basolateral portion of plasma membrane. (3) The operation of Na⁺/Ca²⁺ antiport device was excluded by the findings that steep Ca²⁺ gradients formed by ATP-dependent Ca²⁺ accumulation in the vesicles were not discharged by extravesicular Na⁺, and did not drive ⁴⁵Ca²⁺ uptake into the vesicles via a Ca²⁺-⁴⁵Ca²⁺ exchange. (4) The ATP-dependent Ca²⁺ uptake into the vesicles became increasingly depressed with time by extravesicular Na⁺. This was not due to an impairment of the Ca²⁺ pump itself, but caused by Na⁺/Ca²⁺ competition for binding sites on the intravesicular membrane surface shown to be important for high Ca²⁺ accumulation in the vesicles. (5) Earlier observations on Na⁺-induced release of Ca²⁺ from vesicles pre-equilibrated with Ca²⁺, seemingly favoring the existence of a Na⁺/Ca²⁺ antiporter in the basolateral plasma membrane, were likewise explained by the occurrence of Na⁺/Ca²⁺ competition for binding sites. The weight of our findings disfavors the transcellular pathway of Ca²⁺ reabsorption through tubule epithelium essentially depending on the operation of a Na⁺/Ca²⁺ antiport device.     

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.     

Na-linked cotransport of glycine in vesicles of ehrlich cells

Vesicles have been prepared from Ehrlich cells by using a method based on the early experiments of Forte et al. (Forte, J.G., Forte, T.M. and Heinz, E. (1973) Biochim. Biophys. Acta 298, 827–841) with some minor modifications, using the filter technique. From electron micrographs and from the sensitivity of these vesicles towards osmotic pressure changes in the medium induced by (nonpermeant) sucrose, it is concluded that the vesicles are closed. The counterflow phenomenon with glycine and Na⁺-linked cotransport of glycine appears to indicate that these vesicles are still functioning. The observation of the overshoot phenomenon interpreted in terms of theoretical predictions confirms that the active accumulation of glycine is energized by the Na⁺ electrochemical potential gradient. In particular, the contribution of the electrical components of these gradients is evidenced by the effects of the anion of the added sodium salt or of the addition of valinomycin. In contrast to observations by others, we found that ouabain does not directly affect Na⁺-linked cotransport of glycine whereas HgCl₂ does so. Nor could any significant overshoot be demonstrated in the absence of an Na gradient. Since these vesicles were not metabolically active, these experiments do not exclude the possibility that in intact cells glycine is in addition transported primarily or partially actively.     

Characteristics of dipeptide transport in normal and papain-treated brush border membrane vesicles from mouse intestine I. Uptake of glycyl-l-phenylalanine

Papain treatment of isolated brush border membrane vesicles was carried out to study peptide transport in the absence of hydrolytic events associated with the brush border membrane. Such a treatment allowed a 70% decrease in the activity of membrane-associated oligopeptidases and the study of peptide transport in the complete absence of free amino acids up to 1 min of incubation. A comparison between the time course curves of glycyl-l-phenylalanine uptake by normal and papain-treated vesicles showed that the overshoots seen in the presence of Na⁺ and K⁺ gradients (extravesicular intravesicular) when using normal vesicles were no longer evident after papain treatment. This result, together with the demonstration of uptake into an osmotically reactive intravesicular space and the analysis of uptake of free phenylalanine, allowed the coclusion that peptide transport was the result of two complementary mechanisms, uptake of free amino acids following hydrolysis by the membrane-bound oligopeptidases, and intact peptide transport down a concentration gradient by a non-Na⁺ (and non-K⁺)-dependent process. These results also showed the non-involvement of γ-glutamyltransferase and the γ-glutamyl cycle in peptide absorption. A linear relationship has been established between initial dipeptide uptake and glycyl-l-phenylalanine concentration for the intact peptide transport process. However, this process can be inhibited to various extents by other di- and tripeptides but the inhibition never exceeded 43%. These results are consistent with both passive and facilitated diffusion mechanisms of intact peptide transport, the latter occuring by either a low affinity-high capacity or a high affinity-low capacity system.     

Transport of d-glucose by brush border membranes isolated from the renal cortex

The transport of d-glucose by brush border membranes isolated from the rabbit renal cortex was studied. At concentrations less than 2 mM, the rate of d-glucose uptake increased linearly with the concentration of the sugar. No evidence was found for a “high-affinity” (μM) saturable site. Saturation was indicated at concentrations of d-glucose greater than 5 mM. The uptake of d-glucose was stereospecific and selectively inhibited by d-galactose and other sugars. Phlorizin inhibited the uptake of d-glucose in the presence and absence of Na⁺. The glycoside was a potent inhibitor of the efflux of d-glucose. Preloading the brush border membrane vesicles with d-glucose, but not with l-glucose, accelerated exchange diffusion of d-glucose. These results demonstrate that the uptake of d-glucose by renal brush borders represents transport into an intravesicular space rather than solely binding. The rate of d-glucose uptake was increased when the Na⁺ in the extravesicular medium was high and the membranes were preloaded with a Na⁺-free medium. The rate of d-glucose uptake was inhibited by preloading the brush border membranes with Na⁺. These results are consistent with the Na⁺ gradient hypothesis for d-glucose transport in the kidney. Thus, the presence of a Na⁺-dependent facilitated transport of d-glucose in isolated renal brush border membranes is indicated. This finding is consistent with what is known of the transport of the sugar in more physiologically intact preparations and suggests that the membranes serve as an effective model system in examining the mechanism of d-glucose transport in the kidney.     

Sodium transport measured in plasma membrane vesicles isolated from wheat genotypes with differing K+/Na+ discrimination traits

Right-side-out plasma membrane vesicles were isolated from wheat roots using an aqueous polymer two-phase system. The purity and orientation of the vesicles were confirmed by marker enzyme analysis. Membrane potential (Ψ)-dependent ²²Na⁺ influx and sodium/proton (Na⁺/ H⁺) antiport-mediated efflux across the plasma membrane were studied using these vesicles. Membrane potentials were imposed on the vesicles using either K⁺ gradients in the presence of valinomycin or H⁺ gradients. The ΔΨ was quantified by the uptake of the lipophilic cation tetraphenylphosphonium. Uptake of Na⁺ into the vesicles was stimulated by a negative ΔΨ and had a K_m for extrav-esicular Na⁺ of 34.8 ± 5.9 mol m³. The ΔΨ-dependent uptake of Na⁺ was similar in vesicles from roots of hexaploid (cv. Troy) and tetraploid (cv. Langdon) wheat differing in a K⁺/Na⁺ discrimination trait, and was also unaffected by growth in 50 mol m^?3 NaCl. Inhibition of ΔΨ-dependent Na⁺ uptake by Ca²⁺ was greater in the hexaploid than in the tetraploid. Sodium/proton antiport was measured as Na⁺-dependent, amiloride-inhibited pH gradient formation in the vesicles. Acidification of the vesicle interior was measured by the uptake of ¹⁴C-methylamine. The Na⁺/H⁺ antiport had a K_m, for intravesicular Na⁺ of between 13 and 19 mol m^?3. In the hexaploid, Na⁺/H⁺ antiport activity was greater when roots were grown in the presence of 50 mol m^?3NaCl, and was also greater than the activity in salt-grown tetraploid wheat roots. Antiport activity was not increased in a Langdon 4D chromosome substitution line which carries a trait for K⁺/Na⁺ discrimination. It is concluded that neither of the transport processes measured is responsible for the Na⁺/K⁺ discrimination trait located on the 4D chromosome of wheat.     

Functional characterization of two distinct Mg2+ extrusion mechanisms in cardiac sarcolemmal vesicles

Cardiac ventricular myocytes extrude a sizeable amount of their total Mg²⁺ content upon stimulation by β-adrenergic agonists. This extrusion occurs within a few minutes from the application of the agonist, suggesting the operation of rapid and abundantly represented Mg²⁺ transport mechanisms in the cardiac sarcolemma. The present study was aimed at characterizing the operation of these transport mechanisms under well defined conditions. Male Sprague-Dawley rats were used to purify a biochemical standardized preparation of sealed rat cardiac sarcolemmal vesicles. This experimental model has the advantage that trans-sarcolemmal cation transport can be studied under specific extra- and intra-vesicular ionic conditions, in the absence of intracellular organelles, and buffering or signaling components. Magnesium ion (Mg²⁺) transport was assessed by atomic absorbance spectrophotometry. The results reported here indicate that: (1) sarcolemma vesicles retained trapped intravesicular Mg²⁺ in the absence of extravesicular counter-ions; (2) the addition of Na⁺ or Ca²⁺ induced a rapid and concentration-dependent Mg²⁺ extrusion from the vesicles; (3) co-addition of maximal concentrations of Na⁺ and Ca²⁺ resulted in an additive Mg²⁺ extrusion; (4) Mg²⁺ extrusion was blocked by addition of amiloride or imipramine; (5) pre-treatment of sarcolemma vesicles with alkaline phosphatase at the time of preparation completely abolished Na⁺- but not Ca²⁺-induced Mg²⁺ extrusion; (6) Na⁺-dependent Mg²⁺ transport could be restored by stimulating vesicles loaded with protein kinase A catalytic subunit and ATP with membrane-permeant cyclic-AMP analog; (7) extra-vesicular Mg²⁺ could be accumulated in exchange for intravesicular Na⁺ via a mechanism inhibited by amiloride or alkaline phosphatase treatment; (8) Mg²⁺ accumulation could be restored via cAMP/protein kinase A protocol. Overall, these data provide compelling evidence for the operation of distinct Na⁺- and Ca²⁺-dependent Mg²⁺ extrusion mechanisms in sarcolemma vesicles. The Na⁺-dependent mechanism appears to be specifically activated via protein kinase A/cAMP-dependent phosphorylation process, and can operate in either direction based upon the cation concentration gradient across the sarcolemma. The Ca²⁺-dependent mechanism, instead, only mediates Mg²⁺ extrusion in a cAMP-independent manner.     

Mechanisms of phosphate uptake into brush-border membrane vesicles from goat jejunum

This study concerns the uptake of inorganic phosphate into brush-border membrane vesicles prepared from jejunal tissues of either control or Ca-and/or P-depleted goats. The brush-border membrane vesicles showed a time-dependent accumulation of inorganic phosphate with a typical overshoot phenomenon in the presence of an inwardly directed Na⁺ gradient. The Na⁺-dependent inorganic phosphate uptake was completely inhibited by application of 5 mmol·l^-1 sodium arsenate. Half-maximal stimulation of inorganic phosphate uptake into brush-border membrane vesicles was found with Na⁺ concentrations in the order of 5 mmol·l^-1. Inorganic phosphate accumulation was not affected by a K⁺ diffusion potential (inside negative), suggesting an electroneutral transport process. Stoichiometry suggested an interaction of two or more Na ions with one inorganic phosphate ion at pH 7.4. Na⁺-dependent inorganic phosphate uptake into jejunal brush-border membrane vesicles from normal goats as a function of inorganic phosphate concentration showed typical Michaelis-Menten kinetic with V _max=0.42±0.08 nmol·mg^-1 protein per 15 s^-1 and K _m=0.03±0.01 mmol·l^-1 (n=4, x ±SEM). Long-term P depletion had no effect on these kinetic parameters. Increased plasma calcitriol concentrations in Ca-depleted goats, however, were associated with significant increases of V _max by 35–80%, irrespective of the level of P intake. In the presence of an inwardly directed Na⁺ gradient inorganic phosphate uptake was significantly stimulated by almost 60% when the external pH was decreased to 5.4 (pH_out/pH_in=5.4/7.4). The proton gradient had no effect on inorganic phosphate uptake in absence of Na⁺. In summary, in goats Na⁺ and calcitriol-dependent mechanisms are involved in inorganic phosphate transport into jejunal brush-border membrane vesicles which can be stimulated by protons.Abbreviations AP activity of alkaline phosphatase - BBMV brush-border membrane vesicles - EGTA ethyleneglycol-triacetic acid - n _app apparent Hill coefficient - P _i inorganic phosphate - PTH parathyroid hormone     

Na+-transporting ATPase in the plasma membrane of halotolerant microalga Dunaliella maritima operates as a Na+ uniporter

A fraction of inside-out membrane vesicles enriched in plasma membranes (PM) was isolated from Dunaliella maritima cells. Attempts were made to reveal ATP-driven Na⁺-dependent H⁺ efflux from the PM vesicles to external medium, as detected by alkalization of the vesicle lumen. In parallel experiments, ATP-dependent Na⁺ uptake and electric potential generation in PM vesicles were investigated. The alkalization of the vesicle lumen was monitored with an impermeant pH-sensitive optical probe pyranine (8-hydroxy-1,3,6-pyrenetrisulfonic acid), which was loaded into vesicles during the isolation procedure. Sodium uptake was measured with ²²Na⁺ radioactive label. The generation of electric potential in PM vesicles (positive inside) was recorded with a voltage-sensitive probe oxonol VI. Appreciable Na⁺-and ATP-dependent alkalization of vesicle lumen was only observed in the presence of a protonophore CCCP (carbonyl cyanide-chlorophenylhydrazone). In parallel experiments, CCCP accelerated the ATP-dependent ²²Na⁺ uptake and abolished the electric potential generated by the Na⁺-ATPase at the vesicle membrane. A permeant anion NO^? ₃ accelerated ATP-dependent ²²Na⁺ uptake and promoted dissipation of the electric potential like CCCP did. At the same time, NO^? ₃ inhibited the ATP-and Na⁺-dependent alkalization of the vesicle lumen. The results clearly show that the ATP-and Na⁺-dependent H⁺ efflux from PM vesicles of D. maritima is driven by the electric potential generated at the vesicle membrane by the Na⁺-ATPase. Hence, the Na⁺-transporting ATPase of D. maritima carries only one ion species, i.e., Na⁺. Proton is not involved as a counter-ion in the catalytic cycle of this enzyme.     

The role of potassium and chloride ions on the Na+/acidic amino acid cotransport system in rat intestinal brush-border membrane vesicles

The Na⁺/l-glutamate (l-aspartate) cotransport system present at the level of rat intestinal brush-border membrane vesicles is specifically activated by the ions K⁺ and Cl^?. The presence of 100 mM K⁺ inside the vesicles drastically enhances the uptake rate and the transient intravesicular accumulation (overshoot) of the two acidic amino acids. It has been demonstrated that the activation of the transport system depended only in the intravesicular K⁺ concentration and that in the absence of any sodium gradient, an outward K⁺ gradient was unable to influence the Na⁺/acidic amino acid transport system. It was also found that Cl^? could specifically activate the Na⁺-dependent l-glutamate (l-aspartate) uptake either in the presence or in the absence of K⁺. Also the effect of Cl^? was observed only in the presence of an inward Na⁺ gradient and it was noted to be higher when chloride ion was present on both sides of the membrane vesicles. No influence (activation or accumulation) was observed in the absence of the Na⁺ gradient and in the presence of chloride gradient. l-Glutamate uptake measured in the presence of an imposed diffusion potential and in the presence of K⁺ or Cl^? did not show any translocation of net charge.     

DEVELOPMENTAL TRANSITIONS IN UPTAKE OF AMINO ACIDS BY SYNAPTOSOMAL FRACTIONS ISOLATED FROM RAT CEREBRAL CORTEX

Developmental changes in mechanisms of synaptosomal amino acid transport have been studied in rat cerebral cortex. Well-defined changes over an age continuum could be observed in both the rates of amino acid accumulation and the effects of Na⁺ on the accumulation. The uptakes of five amino acids (threonine, serine and valine in Na⁺-free medium, aspartic acid and proline in Na⁺-containing medium) increased progressively with the age of the animal, whereas the uptakes of leucine and arginine (in Na⁺-free medium) decreased steadily. The uptake of serine or threonine by synaptosomal fractions prepared from newborn rats was markedly dependent on the presence of Na⁺in the incubation media. Na⁺exerted progressively less effect on the accumulation process with continuing postnatal development and to some extent inhibited uptake by fractions obtained from rats older than about 15 days. Na⁺significantly enhanced the accumulation of glycine in fractions from newborn and adult rats, but had only a slight effect in fractions prepared from 12 to 17-day old rats. A detailed study of the accumulation of glycine indicated that the synaptosomal transport of this amino acid proceeded by two independent systems, one of which was totally dependent on external Na⁺and the and adult animals than in fractions from 12 to 17-day-old rats, wheras the Na⁺-independent system was most active during this latter period of development. The decline in the Na⁺-independent accumulation of glycine from about the 15th day to adulthood was characterized by a decrease in the V_max. and an increase in the K_m.     

l-Arginine uptake into renal brush border membrane vesicles

The uphill uptake of l-arginine by renal brush border membrane vesicles was found to be energized by a Na⁺ gradient (extravesicular > intravesicular) in the presence of a membrane potential (inside negative). The uptake was specific for Na⁺. Either a K⁺-diffusion potential, generated by valinomycin, or a H⁺-diffusion potential, generated by the mitochondrial uncoupler, carbonyl cyanide p-trifluoromethoxyphenylhydrazone, provided the electrical driving force. The Na⁺ gradient-dependent l-arginine transport system was shared by specific basic amino acids and l-cystine, but not by d-arginine nor other classes of amino acids. The molecular structure of the basic amino acid recognized by the carrier was postulated.     

The effects of potassium and membrane potential on sodium-dependent glutamic acid uptake

The uptake of l-glutamic acid into brush-border membrane vesicles isolated from rat renal proximal tubules is Na⁺-dependent. In contrast to Na⁺-dependent uptake of d-glucose, pre-equilibration of the vesicles with K⁺ stimulates l-glutamic acid uptake. Imposition of a K⁺ gradient ($\text{[}\text{K}{}_{\mathrm{i}}{}^{\mathrm{+}}\text{] > [}\text{K}{}_{\mathrm{o}}{}^{\mathrm{+}}\text{]}$) further enhances Na⁺-dependent l-glutamic acid uptake, but leaves K⁺-dependent glucose transport unchanged. If K⁺ is present only at the outside of the vesicles, transport is inhibited. Intravesicular Rb⁺ and, to a lesser extent, Cs⁺ can replace intravesicular K⁺ to stimulate l-glutamic acid uptake. Changes in membrane potential incurred by the imposition of an H⁺-diffusion potential or anion replacement markedly affect Na⁺-dependent glutamic acid uptake only in the presence of K⁺. Experiments with a potential-sensitive cyanine dye also indicate that, in the presence of intravesicular K⁺ a charge movement is involved in Na⁺-dependent transport of l-glutamic acid.The data indicate that Na⁺-dependent l-glutamic acid transport can be additionally energized by a K⁺ gradient. Furthermore, intravesicular K⁺ renders Na⁺-dependent l-glutamic acid transport sensitive to changes in the transmembrane electrical potential difference.