Leucine transport in Xenopus laevis oocytes: Functional and morphological analysis of different defolliculation procedures

l-leucine uptake in stage V Xenopus laevis oocytes was affected by the specific methods used to remove the follicle cells. In the presence of 100 mM NaCl, l-leucine uptake was reduced by 67.5%±5.7 when defolliculation was performed enzymatically by collagenase treatment, whereas the reduction was 30.5%±6.4 after mechanical defolliculation. The Na⁺-dependent uptake of 0.1 mM l-leucine was 18.6±4.6 pmol oocyte⁻¹ 40 min⁻¹ in folliculated oocytes and 5.6±1.9 in collagenase defolliculated oocytes (means±SE). l-leucine uptake was not affected by the removal of the follicular layer if defolliculation occurred after the transport period; radiolabeled l-leucine is therefore not taken up into a compartment that is removed by the defolliculation process. The different l-leucine uptake rates observed in folliculated and defolliculated oocytes were not due to non-specific l-leucine binding to membranes. l-leucine kinetics showed that the l-leucine V_max and K_m values were lower in oocytes deprived of the follicular layer than in control oocytes enveloped in intact follicular layers. The V_max and K_m values of Na⁺-dependent l-leucine transport, calculated from data obtained the day after defolliculation by collagenase treatment, were: 16±1.5 pmol oocyte⁻¹ 40 min⁻¹ and 57±21 μmol (mean±SD). The Na⁺-activation curve of 0.1 mM l-leucine was hyperbolic in folliculated oocytes and sigmoidal in defolliculated oocytes. The morphological analysis performed in parallel with the transport experiments showed that after defolliculation, the fibers forming the vitelline membrane tended to be arranged in a more regular orthogonal array, and the number of oocyte microvilli was reduced after collagenase treatment. Mechanical defolliculation did not appreciably affect the oocyte microvilli, however this procedure did not completely remove all follicle cells. The damage to collagenase treated oocytes was reversible, and the functional and structural features of most oocytes improved upon subsequent in vitro incubation. The recovery process seemed to involve protein synthesis in view of the increased value of l-leucine V_max, and microscopic observation showing recovery of the microvillar apparatus.     

Uptake of lysine and prolinevia separate α-neutral amino acid transport pathways inMytilus gill brush border membranes

Summary Brush border membrane vesicles (BBMV) were prepared from the gills of the marine mussel,Mytilus edulis. These membranes contained two distinct pathways for cotransport of Na⁺ and -neutral amino acids. The major pathway in mussel gill BBMV was the alanine-lysine (AK) pathway, which had a high affinity for alanine and for the cationic amino acid, lysine. The AK pathway was inhibited by nonpolar -neutral amino acids and cationic amino acids, but was not affected by -neutral amino acids or imino acids. The kinetics of lysine transport were consistent with a single saturable process, with aJ _max of 550 pmol/mg-min and aK _t of 5 m. The AK pathway did not have a strict requirement for Na⁺, and concentrative transport of lysine was seen in the presence of inwardly directed gradients of Li⁺ and K⁺, as well as Na⁺. Harmaline inhibited the transport of lysine in solutions containing either Na⁺ or K⁺. The alanine-proline (AP) pathway transported both alanine and proline in mussel gill BBMV. The AP pathway was strongly inhibited by nonpolar -neutral amino acids, proline, and -(methylamino)isobutyric acid (Me-AIB). The kinetics of proline transport were described by a single saturable process, with aJ _max of 180 pmol/mg-min andK _t of 4 m. In contrast to the AK pathway, the AP pathway appeared to have a strict requirement for Na⁺. Na⁺-activation experiments with lysine and proline revealed sigmoid kinetics, indicating that multiple Na⁺ ions are involved in the transport of these substrates. The transport of both lysine and proline was affected by membrane potential in a manner consistent with electrogenic transport.     

Sodium-coupled electrogenic transport of pyroglutamate (5-oxoproline) via SLC5A8, a monocarboxylate transporter

Pyroglutamate, also known as 5-oxoproline, is a structural analog of proline. This amino acid derivative is a byproduct of glutathione metabolism, and is reabsorbed efficiently in kidney by Na⁺-coupled transport mechanisms. Previous studies have focused on potential participation of amino acid transport systems in renal reabsorption of this compound. Here we show that it is not the amino acid transport systems but instead the Na⁺-coupled monocarboxylate transporter SLC5A8 that plays a predominant role in this reabsorptive process. Expression of cloned human and mouse SLC5A8 in mammalian cells induces Na⁺-dependent transport of pyroglutamate that is inhibitable by various SLC5A8 substrates. SLC5A8-mediated transport of pyroglutamate is saturable with a Michaelis constant of 0.36 ± 0.04 mM. Na⁺-activation of the transport process exhibits sigmoidal kinetics with a Hill coefficient of 1.8 ± 0.4, indicating involvement of more than one Na⁺ in the activation process. Expression of SLC5A8 in Xenopuslaevis oocytes induces Na⁺-dependent inward currents in the presence of pyroglutamate under voltage-clamp conditions. The concentration of pyroglutamate necessary for induction of half-maximal current is 0.19 ± 0.01 mM. The Na⁺-activation kinetics is sigmoidal with a Hill coefficient of 2.3 ± 0.2. Ibuprofen, a blocker of SLC5A8, suppressed pyroglutamate-induced currents in SLC5A8-expressing oocytes; the concentration of the blocker necessary for causing half-maximal inhibition is 14 ± 1 μM. The involvement of SLC5A8 can be demonstrated in rabbit renal brush border membrane vesicles by showing that the Na⁺-dependent uptake of pyroglutamate in these vesicles is inhibitable by known substrates of SLC5A8. The Na⁺ gradient-driven pyroglutamate uptake was stimulated by an inside-negative K⁺ diffusion potential induced by valinomycin, showing that the uptake process is electrogenic.     

Energetic basis of development of salt-tolerant transport in a moderately halophilic bacterium,Vibrio costicola

Active transport of -aminoisobutyric acid (AIB) in Vibrio costicola utilizes a system with affinity for glycine, alanine and, to some extent, methionine. AIB transport was more tolerant of high salt concentrations (3–4 M NaCl) in cells grown in the presence of 1.0 M NaCl than in those grown in the presence of 0.5 M NaCl. The former cells could also maintain much higher ATP contents than the latter in high salt concentrations.Transport kinetic studies performed with bacteria grown in 1.0 M NaCl revealed three effects of the Na⁺ ion: the first effect is to increase the apparent affinity (K _t) of the transport system for AIB at Na⁺ concentrations <0.2 M, the second to increase the maximum velocity (V _max) of transport (Na⁺ concentrations between 0.2 and 1.0 M), and the third to decrease the V _max without affectig K _t (Na⁺ concentrations >1.0 M). Cells grown in the presence of 0.5 M or 1.0 M NaCl had similar affinity for AIV. Thus, the differences in salt response of transport in these cells do not seem due to differences in AIB binding. Large, transport-inhibitory concentrations of NaCl resulted in efflux of AIB from cells preloaded in 0.5 M or 1.0 M NaCl, with most dramatic efflux occurring from the cells whose AIB transport was more salt-sensitive. Our results suggest that the degree to which high salt concentrations affect the transmembrane electrochemical energy source used for transport and ATP synthesis is an important determinant of salt tolerance.Abbreviations AIB -aminoisobutyric acid - pmf proton motive force     

Kinetics of the Reverse Mode of the Na<Superscript>+</Superscript>/Glucose Cotransporter

This study investigates the reverse mode of the Na⁺/glucose cotransporter (SGLT1). In giant excised inside-out membrane patches from Xenopus laevis oocytes expressing rabbit SGLT1, application of α-methyl-D-glucopyranoside (αMDG) to the cytoplasmic solution induced an outward current from cytosolic to external membrane surface. The outward current was Na⁺- and sugar-dependent, and was blocked by phlorizin, a specific inhibitor of SGLT1. The current-voltage relationship saturated at positive membrane voltages (30–50 mV), and approached zero at −150 mV. The half-maximal concentration for αMDG-evoked outward current (K_0.5^αMDG) was 35 mM (at 0 mV). In comparison, K_0.5^αMDG for forward sugar transport was 0.15 mM (at 0 mV). K_0.5^Na was similar for forward and reverse transport (≈35 mM at 0 mV). Specificity of SGLT1 for reverse transport was: αMDG (1.0) > D-galactose (0.84) > 3-O-methyl-glucose (0.55) > D-glucose (0.38), whereas for forward transport, specificity was: αMDG ≈ D-glucose ≈ D-galactose > 3-O-methyl-glucose. Thus there is an asymmetry in sugar kinetics and specificity between forward and reverse modes. Computer simulations showed that a 6-state kinetic model for SGLT1 can account for Na⁺/sugar cotransport and its voltage dependence in both the forward and reverse modes at saturating sodium concentrations. Our data indicate that under physiological conditions, the transporter is poised to accumulate sugar efficiently in the enterocyte.     

Workshop 7: 2

Glutamine, the preferred precursor for neurotransmitter glutamate, is likely to be the principal substrate for the neuronal System A transporter SAT1 in vivo. By measuring currents associated with SAT1 expression in Xenopus oocytes, we found that SAT1 mediates transport of small, neutral, aliphatic amino acids including glutamine, alanine and the System A‐specific analogue 2‐(methylamino) isobutyrate, each with K_0.5 of 0.3–0.5 mm . Amino acid transport is driven by the Na⁺ electrochemical gradient. Kinetic data indicates that Na⁺/cotransport comprises the ordered binding first of Na⁺ (a voltage‐dependent step), then alanine, then simultaneous translocation. Li⁺ (but not H⁺) can substitute for Na⁺ but results in reduced V_max. In the absence of amino acid, SAT1 mediates a cation leak with selectivity Na⁺, Li⁺, H⁺, K⁺. The temperature‐dependence of the leak current (E_a = 17 ± 3 kcal/mol) is consistent with carrier‐mediated Na⁺ uniport activity (cf 13 ± 2 kcal/mol for Na⁺/alanine cotransport) but the leak does not saturate at physiological [Na⁺], suggesting channel activity. Despite a Na⁺ Hill coefficient of 1, we obtained Na⁺/amino acid coupling coefficients greater than 1 from simultaneous measurement of charge and [³H]alanine or [³H]glutamine uptake. Interpretation of these data is model‐dependent and consistent with either (1) an all‐carrier model in which Na⁺/amino acid cotransport is thermodynamically coupled 2 : 1, cotransport is preferred over Na⁺ uniport, and in which there is little cooperativity between Na⁺ binding events, or (2) 1 : 1 coupling in parallel with an always‐on Na⁺ channel activity. In either scenario, the presence of SAT1 at the plasma membrane and resultant Na⁺ fluxes will place a significant energy burden on the cell.     

Regulation of Na+-coupled glucose carrier SGLT1 by AMP-activated protein kinase

Abstract

AMP-activated protein kinase (AMPK), a serine/threonine kinase activated upon energy depletion, stimulates energy production and limits energy utilization. It has previously been shown to enhance cellular glucose uptake through the GLUT family of facilitative glucose transporters. The present study explored the possibility that AMPK may regulate Na⁺-coupled glucose transport through SGLT1 (SLC5A1). To this end, SGLT1 was expressed in Xenopus oocytes with and without AMPK and electrogenic glucose transport determined by dual electrode voltage clamping experiments. In SGLT1-expressing oocytes but not in oocytes injected with water or expressing constitutively active ^γR70QAMPK (α1β1γ1(R70Q)) alone, the addition of glucose to the extracellular bath generated a current (I_g), which was half maximal (K_M) at ≈ 650 μM glucose concentration. Coexpression of ^γR70QAMPK did not affect K_M but significantly enhanced the maximal current (≈ 1.7 fold). Coexpression of wild type AMPK or the kinase dead ^αK45RAMPK mutant (α1(K45R)β1γ1) did not appreciably affect I_g. According to confocal microscopy and Western Blotting, AICAR (1 mM), phenformin (1 mM) and A-769662 (10 μM) enhanced the SGLT1 protein abundance in the cell membrane of Caco2 cells suggesting that AMPK activity may increase membrane translocation of SGLT1. These observations support a role for AMPK in the regulation of Na⁺-coupled glucose transport.     

Transport of glutamine inXenopus laevis oocytes: Relationship with transport of other amino acids

Summary We have investigated transport of the amino acid glutamine across the surface membranes of prophase-arrestedXenopus laevis oocytes. Glutamine accumulation was linear with time for 30 min; it was stereospecific with aK _m of 0.12±0.02mm andV _max of 0.92±0.17 pmol/oocyte · min forl-glutamine. Transport ofl-glutamine was Na⁺-dependent, the cation not being replaceable with Li⁺, K⁺, choline, tris(hydroxymethyl)-aminomethane (Tris), tetramethylammonium (TMA) or N-methyld-glucamine NMDG); external Cl^– appeared to be necessary for full activation of Na⁺-dependent glutamine transport. Two external Na⁺ may be required for the transport of one glutamine molecule.l-glutamine transport (at 50 m glutamine) was inhibited by the presence of other amino acids:l-alanine,d-alanine,l-leucine,l-asparagine andl-arginine (about 60% inhibition at 1mm);l-histidine,l-valine and glycine (25 to 40% inhibition at 1mm);l-serine,l-lysine,l-phenylalanine andl-glutamate (45 to 55% inhibition at 10mm). N-methylaminoisobutyric acid (meAIB) had no effect at 10mm, but 2-aminobicyclo[2,2,1]heptane-2-carboxylic acid (BCH) inhibited Na⁺/glutamine transport by about 50% at 10mm.l-glutamine was a competitive inhibitor of the Na⁺-dependent transport ofl-alanine,d-alanine andl-arginine; this evidence is consistent with the existence of a single system transporting all four amino acids. Glutamine uptake in oocytes appears to be catalyzed by a transport system distinct from the cotransport Systems A, ASC, N and Gly, although it resembles System B^0,+.     

Properties of the kainate channel in rat brain mRNA injected Xenopus oocytes: ionic selectivity and blockage

The properties of kainate receptor/channels were studied in Xenopus oocytes injected with mRNA that was isolated from adult rat striatum and cerebellum and partially purified by sucrose gradient fractionation. Kainate (3–1000 µ.M) induced a smooth inward current that was competitively inhibted by gamma-D-glutamyl-aminomethanesulfonate (GAMS, 300 µM). In striatal mRNA-injected oocytes, the kainate current displayed nearly linear voltage-dependence and mean reversal potential (E_r) of -6.1 ± 0.5 mV In cerebellar mRNA-injected oocytes; E_r was nearly identical (-5.1 ± 1.2 mV) but there was marked inward rectification of the kainate current. Ion replacement studies reveal that the kainate channel is selective for cations over anions, but relatively non-selective among small monovalent cations. Large monovalent cations such as tetrabutylammonium are impermeant and induce a non-competitive block of kainate current that is strongly voltage-dependent. Divalent cations are relatively impermeant in the kainate channel and Cd⁺⁺ and other polyvalent metals were shown to block kainate current by a mechanism that is only weakly voltage-dependent. A model of the kainate channel is proposed based upon these observations.     

l-Alanine uptake in brush border membrane vesicles from the gill of a marine bivalve

Summary Brush border membrane vesicles were prepared from mussel gills using differential and sucrose density gradient centrifugation. These vesicles contained both the maximal Na⁺-dependent alanine transport activity found in the gradient and the maximal activities of -glutamyl transpeptidase and alkaline phosphatase. Electron micrographs showed closed vesicles of approximately 0.1–0.5 m diameter. Transport experiments using these vesicles demonstrated a transient 18-fold overshoot in intravesicular alanine concentration in the presence of an inwardly directed Na⁺ gradient, but not under Na⁺ equilibrium conditions. A reduced overshoot (10-fold) was seen with an inwardly directed K⁺ gradient. Further studies revealed a broad cation selectivity, with preference for Na⁺, which was characteristic of alanine transport but not glucose transport in these membranes. The apparent amino acid specificity of the uptake pathway(s) was similar to that of intact gills and supported the idea of at least four separate pathways for amino acid transport in mussel gill brush border membranes. The apparent Michaelis constant for alanine uptake was approximately 7m, consistent with values forK _t determined with intact tissue.     

Single-Channel Activities of the Human Epithelial Ca2+ Transport Proteins CaT1 and CaT2

The human epithelial channels, CaT1 and CaT2, were expressed in oocytes, and their single-channel characteristics were compared. In the presence of Na⁺ and K⁺ as charge carriers in the pipette solutions, channel activities were observed only when the the extracellular sides of the patches were exposed to nominally Ca²⁺- and Mg²⁺-free solutions. In patches of both CaT1- and CaT2-expressing oocytes, multiple channel openings were observed, but the current levels were higher in CaT2-expressing oocytes, particularly at more negative voltages. With K⁺ as a charge carrier in patches of CaT1-expressing oocytes, the channel activity was low at −10 to −60 mV, but increased dramatically at more negative potentials. This voltage dependence was observed in the presence of both Na⁺ and K⁺. The channel activity with Na⁺, however, was higher at all potentials. Differences between the voltage dependencies for the two cations were also observed in CaT2-expressing oocytes, but the channel activities were higher than those in CaT1-expressing oocytes, particularly in the presence of Na⁺. We also found that low concentrations of extracellular Mg²⁺ (5–50 μm) elicited a strong inhibitory action on the CaT channels. Activation of the CaT1 and CaT2 channels by hyperpolarization and other factors may promote increased Ca²⁺ entry that participates in stimulation of intestinal absorption and renal reabsorption and/or other Ca²⁺ transport mechanisms in epithelial cells. Received: 8 March 2001/Revised: 24 July 2001     

Transport and membrane binding of the glutamine analogue 6-diazo-5-oxo-L-norleucine (DON) in Xenopus laevis oocytes

Summary We have examined transport and membrane binding of 6-diazo-5-oxo-l-norleucine (DON, a photoactive diazo-analogue of glutamine) and their relationships to glutamine transport in Xenopus laevis oocytes. DON uptake was stereospecific and saturable (V _max of 0.44 pmol/oocyte · min and a K _m of 0.065 mm). DON uptake was largely Na^u+ dependent (80% at 50 m DON) and inhibited (>75%) by glutamine and arginine (substrates of the System B^0,+ transporter) at 1 mm. Glutamine and DON show mutual competitive inhibition of Na⁺-dependent transport. Preincubation of oocytes in medium containing 0.1 mm DON for 24 or 48 hr depressed the V _max for System B^0,+ transport (as measured by Na⁺-dependent glutamine uptake), this effect was highly specific (neither d-DON nor the System B^0,+ substrates glutamine and d-alanine showed any independent effect) and required Na⁺ ions. Glutamine (1 mm in preincubation medium) protected transport from inhibition by DON. The possibility that specific inactivation of System B^0,+ by DON reflects attachment of DON to the transporter was tested by examining the binding of [¹⁴C]DON to Xenopus oocyte membranes. Oocytes incubated in 100 mm NaCl in the presence of [¹⁴C]DON for up to 48 hr showed 2.4-fold higher ¹⁴C-binding to membranes than oocytes incubated in choline chloride. Na⁺-dependent DON binding (31 ± 11 fmol/g membrane protein) was suppressed by external glutamine, arginine or alanine and was largely confined to a membrane protein fraction of 48–65 kDa (as assessed by SDS-polyacrylamide gel electrophoresis). The present studies indicate that DON and glutamine uptake in oocytes are both mediated by System B^0,+ and demonstrate that DON binding to a particular membrane protein fraction is associated with inactivation of the transporter, offering the prospect of using [¹⁴C]DON as a covalent label for the transport protein in order to facilitate its isolation and subsequent biochemical characterization.This work was supported by The Wellcome Trust, Action Research for the Crippled Child, Ajinomoto GmbH, Pfrimmer GmbH, the Rank Prize Funds, the Medical Research Council and the University of Dundee. We are grateful to Dr. C.I. Pogson (Wellcome Research Laboratories) and Drs. J.C. Ellory and B. Elford (University of Oxford) for gifts of [¹⁴C]DON.     

Na+-Coupled Alanine Transport in LLC-PK1 Cells: The Relationship Between the K m for Na+ at Low [Alanine] and Potential Dependence for the System

Analysis of the mechanistic basis by which sodium-coupled transport systems respond to changes in membrane potential is inherently complex. Algebraic expressions for the primary kinetic parameters (K _m and V _max ) consist of multiple terms that encompass most rate constants in the transport cycle. Even for a relatively simple cotransport system such as the Na⁺/alanine cotransporter in LLC-PK₁ cells (1:1 Na⁺ to substrate coupling, and an ordered binding sequence), the algebraic expressions for K _m for either substrate includes ten of the twelve rate constants necessary for modeling the full transport cycle. We show here that the expression of K _m of the first-bound substrate (Na⁺) simplifies markedly if the second-bound substrate (alanine) is held at a low concentration so that its' binding becomes the rate limiting step. Under these conditions, the expression for the K ^Na _m includes rate constants for only two steps in the full cycle: (i) binding/dissociation of Na⁺, and (ii) conformational `translocation' of the substrate-free protein. The influence of imposed changes in membrane potential on the apparent K ^Na _m for the LLC-PK₁ alanine cotransporter at low alanine thus provides insight to potential dependence at these sites. The data show no potential dependence for K ^Na _m at 5 μm alanine, despite marked potential dependence at 2 mm alanine when the full algebraic expression applies. The results suggest that neither translocation of the substrate-free form of the transporter nor binding/dissociation of extracellular sodium are potential dependent events for this transport system. Received: 10 April 1998/Revised: 6 July 1998     

Muscarinic activation causes biphasic inotropic response and decreases cellular Na+ activity in canine cardiac purkinje fibers

In this study, the effects of carbachol (CCh) on twitch tension, intracellular Na⁺ activity (a _Na ⁱ ), and action potential were simultaneously measured in canine cardiac Purkinje fibers in order to examine the regulation of inotropy through muscarinic receptors and its relation to a _Na ⁱ . In fibers driven at 1 Hz, CCh (10 µM) initially and transiently decreased and then increased the twitch tension by 36±8%. The action potential showed a significant elevation of the plateau and a significant shortening of the duration at 90% repolarization (APD₉₀), from 403±7 to 389±7 ms. The a _Na ⁱ decreased from 7.4±0.4 to 6.7±0.3 mM (n=23, p<0.05). Atropine (1 µM) decreased the twitch tension by 21±6% (n=7, p<0.05) without significant effects on the action potential and a _Na ⁱ , and inhibited the effects of CCh. Cs⁺ (20 mM) increased the plateau height and APD₉₀, enhanced the twitch tension by 66±24%, but decreased a _Na ⁱ from 7.3±0.3 to 6.3±0.4 mM (n=6, p<0.05). In the presence of 20 mM Cs⁺, some fibers generated slow responses. The addition of 10 µM CCh further increased the twitch tension and APD₉₀, and decreased a _Na ⁱ from 6.3±0.4 to 5.3±0.3 mM. Ouabain (0.3 µM) increased the twitch tension and a _Na ⁱ , and inhibited the CCh-induced decrease of a _Na ⁱ . In the presence of ouabain, 20 mM Cs⁺ depolarized the fiber and generated slow responses with a decreased a _Na ⁱ . The addition of 10 µM CCh enhanced the slow action potential, and increased a _Na ⁱ although there was a transient decrease during early exposure. These results suggest that activation of muscarinic receptors in canine Purkinje fibers results in an enhancement of the Na⁺-K⁺ pump activity and a biphasic inotropic response, probably via different receptor subtypes. The inhibitory effect, most likely through M₂ receptors, is associated with the activation of K⁺ channels. The stimulatory effect, on the other hand, is probably due to the action on the M₁ receptors, resulting in increases in Ca²⁺ currents.     

Functional Characterization of Na<Superscript>+</Superscript>/H<Superscript>+</Superscript> Exchangers in Primary Cultures of Prairie Dog Gallbladder

Gallbladder Na⁺ absorption is linked to gallstone formation in prairie dogs. We previously reported Na⁺/H⁺ exchanger (NHE1-3) expression in native gallbladder tissues. Here we report the functional characterization of NHE1, NHE2 and NHE3 in primary cultures of prairie dog gallbladder epithelial cells (GBECs). Immunohistochemical studies showed that GBECs grown to confluency are homogeneous epithelial cells of gastrointestinal origin. Electron microscopic analysis of GBECs demonstrated that the cells form polarized monolayers characterized by tight junctions and apical microvilli. GBECs grown on Snapwells exhibited polarity and developed transepithelial short-circuit current, I_sc, (11.6 ± 0.5 µA · cm^–2), potential differences, V_t (2.1 ± 0.2 mV), and resistance, R_t (169 ± 12 · cm²). NHE activity in GBECs assessed by measuring dimethylamiloride-inhibitable ²²Na⁺ uptake under a H⁺ gradient was the same whether grown on permeable Snapwells or plastic wells. The basal rate of ²²Na⁺ uptake was 21.4 ± 1.3 nmol · mg prot^–1 · min^–1, of which 9.5 ± 0.7 (~45%) was mediated through apically-restricted NHE. Selective inhibition with HOE-694 revealed that NHE1, NHE2 and NHE3 accounted for ~6%, ~66% and ~28% of GBECs total NHE activity, respectively. GBECs exhibited saturable NHE kinetics (V_max 9.2 ± 0.3 nmol · mg prot^–1 · min^–1; K_m 11.4 ± 1.4 mM Na⁺). Expression of NHE1, NHE2 and NHE3 mRNAs was confirmed by RT-PCR analysis. These results demonstrate that the primary cultures of GBECs exhibit Na⁺ transport characteristics similar to native gallbladder tissues, suggesting that these cells can be used as a tool for studying the mechanisms of gallbladder ion transport both under physiologic conditions and during gallstone formation.     

Lanthanide/proline cotransport across rabbit renal brush borders

Summary It has been suggested previously that La³⁺ can replace Na⁺ on various cotransport systems in renal brush border membranes. In the present study, we used rabbit renal brush border membrane vesicles to examine the specificity and kinetics of Ln³⁺/proline cotransport. Experiments were carried out under zero-trans, voltage clamped conditions using a rapid-mix/filtration technique. Initial experiments confirmed that La³⁺ produced the classical overshoot phenomenon. The initial rates of proline uptake relative to Na⁺ were Eu³⁺, Tb³⁺, Nd³⁺, Pr³⁺, Ho³⁺ (3.3)>Na⁺ (1.0)>La³⁺ (0.86) > choline⁺ (0.1). At a saturating salt concentration, uptake saturated with increasing proline concentration: theK _t andJ _max were 0.05mm and 17 pmol mg^–1 sec^–1 in Na⁺; and 0.28mm and 73 pmol mg^–1 sec^–1 in Tb³⁺. The higherJ _max in Tb³⁺ indicates that the Tb³⁺-proline loaded carrier is more effective than the Na⁺-proline loaded carrier in overcoming some rate-limiting barriers in the transport process. Na⁺ activated proline uptake with a Hill coefficient of 1.6 and aK _0.5 of 21mm, while Tb³⁺ activated with a Hill coefficient of 0.88 and aK _0.5 of 28mm. The Hill coefficient for Na⁺ suggests two binding sites, whereas the Hill coefficient for Tb³⁺ may indicate negative cooperativity between the trivalent ligands at the binding sites. We conclude that lanthanides are able to substitute for Na⁺ on the brush border proline carrier and that the lanthanides may serve as useful probes for the ligand binding sites.     

Nitrogen and phosphorus uptake by the Brazilian kelp Laminaria abyssalis (Phaeophyta) in culture

The uptake of ammonium, nitrate and phosphate by laboratory-grown young sporophytes of Laminaria abyssalis was measured in a perturbed system (batch mode) at 18 °C and 35 ± 5 µE m^–2 s^–1 photon flux density. Uptake of all appeared to follow saturation-type nutrient uptake kinetics. The NO _inf3 ^sup– (K _s = 14.0 µM, V _max = 5.0 µmol h^–1 g^–1 dry wt) and NH _inf4 ^sup+ (K _s = 4.6 µM, V _max= 2.0 µmol h^–1 g^–1 dry wt) were taken up simultaneously, although NH _inf4 ^sup+ was taken up more rapidly. Values of K ₃ and V _max for phosphate were, respectively, 2.21 µM and 0.83 µmol h^–1 g^–1 dry wt. Nitrate and phosphate were both consumed in similar rates (V _max /Ks 0.37) at low concentrations. NH _inf4 ^sup+ , thus, might be a more efficient form of N fertilizer if artificial enrichment of seawater is used.     

The discovery of slowness: low-capacity transport and slow anion channel gating by the glutamate transporter EAAT5

Excitatory amino acid transporters (EAATs) control the glutamate concentration in the synaptic cleft by glial and neuronal glutamate uptake. Uphill glutamate transport is achieved by the co-/countertransport of Na⁺ and other ions down their concentration gradients. Glutamate transporters also display an anion conductance that is activated by the binding of Na⁺ and glutamate but is not thermodynamically coupled to the transport process. Of the five known glutamate transporter subtypes, the retina-specific subtype EAAT5 has the largest conductance relative to glutamate uptake activity. Our results suggest that EAAT5 behaves as a slow-gated anion channel with little glutamate transport activity. At steady state, EAAT5 was activated by glutamate, with a K_m= 61 ± 11 μM. Binding of Na⁺ to the empty transporter is associated with a K_m = 229 ± 37 mM, and binding to the glutamate-bound form is associated with a K_m = 76 ± 40 mM. Using laser-pulse photolysis of caged glutamate, we determined the pre-steady-state kinetics of the glutamate-induced anion current of EAAT5. This was characterized by two exponential components with time constants of 30 ± 1 ms and 200 ± 15 ms, which is an order of magnitude slower than those observed in other glutamate transporters. A voltage-jump analysis of the anion currents indicates that the slow activation behavior is caused by two slow, rate-limiting steps in the transport cycle, Na⁺ binding to the empty transporter, and translocation of the fully loaded transporter. We propose a kinetic transport scheme that includes these two slow steps and can account for the experimentally observed data. Overall, our results suggest that EAAT5 may not act as a classical high-capacity glutamate transporter in the retina; rather, it may function as a slow-gated glutamate receptor and/or glutamate buffering system.     

Neutral amino acid transport by marine fish intestine: role of the side chain

This work was devoted to the study of the structure-affinity relationships in neutral amino acid transport by intestinal brush border of marine fish (Dicentrarchus labrax). The effects of the length of the side chain on kinetics of glycine, alanine, methionine and amino isobutyric acid were investigated. In the presence of K⁺ two components were characterized: one is saturable by increased substrate concentrations, whereas the other can be described by simple diffusion mechanism. Simple diffusion, a passive, non-saturable, Na⁺-independent route, contributes largely to the transport of methionine and to a much lesser extend to alanine, glycine or alphaaminoisobutyric acid uptakes. If a branched chain is present, as in the case of amino isobutyric acid, diffusion is low. A Na⁺-independent, saturable system has been fully characterized for methionine, but not for branched amino acids such as amino isobutyric acid. In the presence of Na⁺ saturable components were shown. Two distinct Na⁺-dependent pathways have been characterized for glycine uptake, with low and high affinities. For alanine and methionine only one Na⁺-dependent high affinity system exists with the same half-saturation concentration and the same maximum uptake at saturable concentrations. Glycine high affinity system has the same half-saturation concentration as methionine or alanine uptake, whereas maximum uptake is lower. The substitution of the hydrogen by a methyl group results in a severe decrease of uptake (aminoisobutyric acid). Mutual inhibition experiments indicate that the same carriers could be responsible for methionine and alanine uptakes and probably glycine Na⁺-dependent uptake. The influence of Na⁺ concentrations (100^-1 mol·l^-1) on amino acid uptake was examined. Glycine, alanine, methionine and amino isobutyric acid transport can be described by a hyperbolic function, with a saturation uptake which is highly increased for methionine. However, the half-saturation concentration does not seem to be strongly affected by the amino acid structure. The effect of Na⁺ concentration (25 and 100 mmol·l^-1) on the kinetics of methionine uptake have been also examined. The maximum uptake of the saturable system clearly shows a typical relationship with concentration.Abbreviations [AA] amino acid concentration - AIB aminoisobutyric acid - [I] Inhibitor amino acid concentration - J _i uptake in the presence of inhibitor - J _o uptake without inhibitor - K _d passive diffusion constant - K _i inhibitor constant - K _t concentration of test amino acid for half-maximal flux - MES 2[N-morpholino]ethanesulphonic acid - V _max maximum uptake at saturable amino acid concentrations - V _tot total amino acid uptake     

Ion transport across leech integument

The dorsal skin of the leech Hirudo medicinalis was used for electrophysiological measurements performed in Ussing chambers. The leech skin is a tight epithelium (transepithelial resistance = 10.5±0.5 k· cm^-2) with an initial short-circuit current of 29.0±2.9 A·cm^-2. Removal of Na⁺ from the apical bath medium reduced short-circuit current about 55%. Ouabain (50mol·l^-1) added to the basolateral solution, depressed the short-circuit current completely. The Na⁺ current saturated at a concentration of 90 mmol Na⁺·l^-1 in the apical solution (K _M=11.2±1.8 mmol·l^-1). Amiloride (100 mol·l^-1) on the apical side inhibited ca. 40% of the Na⁺ current and indicated the presence of Na⁺ channels. The dependence of Na⁺ current on the amiloride concentration followed Michaclis-Menten kinetics (K _i=2.9±0.4 mol·l^-1). The amiloride analogue benzamil had a higher affinity to the Na⁺ channel (K _i=0.7±0.2 mol·l^-1). Thus, Na⁺ channels in leech integument are less sensitive to amiloride than channels known from vertebrate epithelia. With 20 mmol Na⁺·l^-1 in the mucosal solution the tissue showed an optimum amiloride-inhibitable current, and the amiloride-sensitive current under this condition was 86.8±2.3% of total short-circuit current. Higher Na⁺ concentrations lead to a decrease in amiloride-blockade short-circuit current. Sitmulation of the tissue with cyclic adenosine monophosphate (100 mol·l^-1) and isobutylmethylxanthine (1 mmol·l^-1) nearly doubled short-circuit current and increased amiloride-sensitive Na⁺ currents by 50%. By current fluctuation analysis we estimated single Na⁺ channel current (2.7±0.9 pA) and Na⁺ channel density (3.6±0.6 channels·m^-2) under control conditions. After cyclic adenosine monophosphate stimulation Na⁺ channel density increased to 5.4±1.1 channels·m^-2, whereas single Na⁺ channel current showed no significant change (1.9±0.2 pA). These data present a detailed investigation of an invertebrate epithelial Na⁺ channel, and show the similarities and differences to vertebrate Na⁺ channels. Whereas the channel properties are different from the classical vertebrate Na⁺ channel, the regulation by cyclic adenosine monophosphate seems similar. Stimulation of Na⁺ uptake by cyclic adenosine monophosphate is mediated by an increasing number of Na⁺ channels.Abbreviations slope of the background noise component - ADH antidiuretic hormone - cAMP cyclic adenosine monophosphate - f frequency - f _c coner frequency of the Lorentzian noise component - Hepes N-hydroxyethylpiperazine-N-ethanesulphonic acid - BMX isobutyl-methylxanthine - i _Na single Na⁺ channel current - I _Na max, maximal inhibitable Na⁺ current - I _SC short circuit current - K _i half maximal blocker concentration - K _M Michaelis constandard error of the mean - S _(f) power density of the Lorentzian noise component - S ₀ plateau value of the Lorentzian noise component - TMA tetramethylammonium - Trizma TRIS-hydroxymethyl-amino-methane - V _max maximal reaction velocity - V _T transepithelial potential - K half maximal blocker concentration