Volume-activated trimethylamine oxide efflux in red blood cells of spiny dogfish (Squalus acanthias)

The aims of this study were to determine the pathway of swelling-activated trimethylamine oxide (TMAO) efflux and its regulation in spiny dogfish (Squalus acanthias) red blood cells and compare the characteristics of this efflux pathway with the volume-activated osmolyte (taurine) channel present in erythrocytes of fishes. The characteristics of the TMAO efflux pathway were similar to those of the taurine efflux pathway. The swelling-activated effluxes of both TMAO and taurine were significantly inhibited by known anion transport inhibitors (DIDS and niflumic acid) and by the general channel inhibitor quinine. Volume expansion by hypotonicity, ethylene glycol, and diethyl urea activated both TMAO and taurine effluxes similarly. Volume expansion by hypotonicity, ethylene glycol, and diethyl urea also stimulated the activity of tyrosine kinases p72syk and p56lyn, although the stimulations by the latter two treatments were less than by hypotonicity. The volume activations of both TMAO and taurine effluxes were inhibited by tyrosine kinase inhibitors, suggesting that activation of tyrosine kinases may play a role in activating the osmolyte effluxes. These results indicate that the volume-activated TMAO efflux occurs via the organic osmolyte (taurine) channel and may be regulated by the volume activation of tyrosine kinases.     

Characterization of D-Aspartic Acid Uptake by Rat Hippocampal Slices and Effect of Ischemic Conditions

The cellular uptake of D-aspartic acid (D-Asp) as a model compound for glutamic acid transport was studied in rat hippocampal slices. D-Asp is accumulated by both Na(+)-dependent and Na(+)-independent processes in hippocampal slices, and both processes are dependent on temperature. The Na(+)-dependent uptake is assumed to be high in affinity (apparent Km = 0.17 mM), but low in capacity, whereas the Na(+)-independent uptake is much lower in affinity (Km = 2.86 mM), but higher in capacity. L-Aspartic acid, L-glutamic acid, dihydrokainic acid, and threo-3-hydroxy-DL-aspartic acid markedly inhibited the uptake of D-Asp with Na+ in the medium, whereas D-glutamic acid, glycine, and L-lysine had no significant effect. The Na(+)-dependent uptake of D-Asp was significantly reduced under "hypoglycemic," "anoxic," and "ischemic" conditions, whereas the Na(+)-independent uptake was unaffected. Metabolic inhibitors such as NaCN and ICH2COOH significantly inhibited the Na(+)-dependent uptake, but not the Na(+)-independent uptake. These results suggest that the Na(+)-dependent component of D-Asp transport in rat hippocampal cells is inactivated under ischemic conditions, whereas the Na(+)-independent component is unaffected.     

Interaction of cations with phosphate uptake by Saccharomyces cerevisiae. Effects of surface potential.

The effect of bivalent cations on phosphate uptake by Saccharomyces cerevisiae was investigated. Phosphate uptake via the Na+-dependent transport system at pH 7.2 is stimulated by bivalent cations. The apparent affinity of phosphate for the transport mechanism is increased, but the apparent affinity for Na+ is decreased. Uptake of phosphate via the Na+-independent transport system is accompanied by a net proton influx of 2H+ and an efflux of 1 K+ for each phosphate ion taken up. At pH 4.5 phosphate uptake via the Na+-independent system is stimulated by bivalent cations, whereas at pH 7.2 uptake is inhibited. The effect of bivalent cations on phosphate uptake can be ascribed to a decrease in the surface potential.     

D-mannose transport and metabolism in isolated enterocytes

D-mannose transport and metabolism has been studied in enterocytes isolated from chicken small intestine. In the presence of Na(+), the mannose taken up by the cells either remains free, is phosphorylated, is catabolized to H(2)O, or becomes part of membrane components. The mannose remaining free in the cytosol is released when the cells are transferred to an ice bath. The Na(+)-dependent D-mannose transport is electrogenic and inhibited by ouabain and dinitrophenol; its substrate specificity differs from SGLT-1 transporter. The Glut2 transporter inhibitors phloretin and cytochalasin B added following 30-min mannose uptake reduced the previously accumulated D-mannose, whereas these two agents increased the cell to external medium 3-O-methyl-glucose (3-OMG) concentration ratio. D-mannose efflux rate from preloaded D-[2-(3)H]-mannose enterocytes is Na(+)-independent. Phloretin did not affect D-mannose efflux rate, whereas it inhibited that of 3-OMG. Neither mannose uptake nor efflux rate were affected by fructose. It is concluded that part of the mannose taken up by the enterocytes is rapidly metabolized and that enterocytes have two D- mannose transport systems: one is concentrative and Na(+)-dependent and the other is Na(+)-independent and passive.     

Characterization of Mg2+ efflux from human, rat and chicken erythrocytes

Net Mg2+ efflux from Mg2+-loaded, human, rat and chicken erythrocytes was measured in sucrose, NaCl and choline Cl medium. Thus, Na+-dependent (NaCl minus choline Cl) and Na+-independent Mg2+ efflux (in sucrose) were determined. Na+-dependent Mg2+ efflux amounted to 0.16, 8.9 and 1.57 mmol/l cells x 30 min, Na+-independent Mg2+ efflux amounted to 0.89, 1.55 and 0.37 mmol/l cells x 30 min for human, rat and chicken erythrocytes. Na+-dependent Mg2+ efflux was inhibited by quinidine. Na+-independent Mg2+ efflux was inhibited by SITS and Cl-. A small fraction of Na+-independent Mg2+ efflux (in choline Cl) was resistant to SITS and Cl-. Ca2+ loading increased Mg2+ efflux similar to K+ efflux (Gardos effect). This effect was differently expressed in human and chicken erythrocytes.     

Nucleoside transport in L1210 murine leukemia cells. Evidence for three transporters

L1210 murine leukemia cells have two nucleoside transport activities that differ in their sensitivity to nitrobenzylmercaptopurine riboside (NBMPR). This study re-examines NBMPR-insensitive nucleoside transport in these cells and finds that it is mediated by two components, one Na(+)-dependent and the other Na(+)-independent. A mutant selected previously for loss of NBMPR-insensitive transport lacks only the Na(+)-independent activity. When NBMPR is used to block efflux via the NBMPR-sensitive transporter, uptake of formycin B (a nonmetabolized analog of inosine) is concentrative in both the parental and mutant cells, but the intracellular concentration of the nucleoside is 5-fold lower in the parental cells. Decreased accumulation of formycin B in the parental cells is due to efflux of the nucleoside via the NBMPR-insensitive, Na(+)-independent transporter that the mutant lacks. The Na(+)-dependent transporter appears to accept most purine, but not pyrimidine, nucleosides as substrates. Two exceptions are uridine, a good substrate, and 7-deazaadenosine, a poor substrate. In contrast, all of the nucleosides tested are substrates for the Na(+)-independent transporter. We conclude that L1210 cells have three distinct nucleoside transporters and that the specificity of the Na(+)-dependent transporter is similar to that of one of the two Na(+)-dependent nucleoside transporters seen in mouse intestinal epithelial cells.     

Stereoselective transport of histidine in rat lung microvascular endothelial cells

The transport characteristics of L- and D-histidine through the blood-lung barrier were studied in cultured rat lung microvascular endothelial cells (LMECs). L-Histidine uptake was a saturable process. The addition of metabolic inhibitors [2,4-dinitrophenol (DNP) and rotenone] reduced the uptake rate of L-histidine. Ouabain, an inhibitor of Na(+)-K(+)-ATPase, also reduced uptake of L-histidine. Moreover, the initial L-histidine uptake rate was reduced by the substitution of Na(+) with choline chloride and choline bicarbonate in the incubation buffer. The system N substrate, L-glutamic acid gamma-monohydroxamate, also inhibited uptake of L-histidine. However, system N-mediated transport was not pH sensitive. These results demonstrated that L-histidine is actively taken up by a system N transport mechanism into rat LMECs, with energy supplied by Na(+). Moreover, the Na(+)-independent system L substrate, 2-amino-2-norbornanecarboxylic acid (BCH), had an inhibitory effect on L-histidine uptake in Na(+) removal, indicating facilitated diffusion by a Na(+)-independent system L transport into the rat LMECs. These results provide evidence for there being at least two pathways for L-histidine uptake into rat LMECs, a Na(+)-dependent system N and Na(+)-independent system L process. On the other hand, the uptake of D-histidine into rat LMECs was not reduced by the addition of DNP, rotenone, or ouabain, or by Na(+) replacement. Although the uptake of D-histidine was reduced in the presence of BCH, the addition of L-glutamic acid gamma-monohydroxamate did not significantly decrease uptake of D-histidine. These results suggest that the uptake of D-histidine by rat LMECs has different characteristics compared with its isomer, L-histidine, indicating that system N transport did not involve D-histidine uptake.     

Polarized distribution of Na+/H+ antiport and Na+/HCO3- cotransport in primary cultures of renal inner medullary collecting duct cells.

Primary cultures of rat renal inner medullary collecting duct cells were grown to confluence on glass coverslips and treated permeant supports, and the pH-sensitive fluorescent probe 2,7-biscarboxyethyl-5,6-carboxyfluorescein was employed to delineate the nature of the transport pathways that allowed for recovery from an imposed acid load in a HCO3-/CO2-buffered solution. The H+ efflux rate of acid-loaded cells was 13.44 +/- 0.94 mM/min. Addition of amiloride, 10(-4) M, to the recovery solution reduced the H+ efflux rate to 4.06 +/- 0.63 mM/min. The amiloride-resistant pHi recovery mechanism displayed an absolute requirement for Na+ but was Cl(-)-independent. Studies performed on permeable supports demonstrated that the latter pathway was located primarily on the basolateral-equivalent (BE) cell surface and was inhibited by 50 microM 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS). In a Na(+)-replete solution containing DIDS (50 microM) and amiloride (10(-4) M), acid-loaded cells failed to return to basal pHi. To delineate further the amiloride-inhibitable component of pHi recovery, monolayers were studied in the nominal absence of HCO3-/CO2. In 70% of monolayers studied, Na(+)-dependent, amiloride-inhibitable H+ efflux was the sole mechanism whereby acid-loaded cells returned to basal pHi. A Na(+)-independent pathway was observed in 30% of monolayers examined and represented only a minor component of the pHi recovery process. In studies performed on permeable supports, the Na(+)-dependent amiloride-inhibitable pathway was found to be confined exclusively to the BE cell surface. In summary, confluent monolayers of rat renal inner medullary collecting duct cells in primary culture possess two major mechanisms that contribute toward recovery from an imposed acid load, namely, Na+/H+ antiport and Na+/HCO3- cotransport. Na(+)-independent pHi recovery mechanisms represent a minor component of the pHi recovery process in the cultured cell. Both the Na+/H+ antiporter and Na+/HCO3- cotransporter are located primarily on the BE cell surface.     

Relationship of hepatic cholate transport to regulation of intracellular pH and potassium.

Modulation of hepatic cholate transport by transmembrane pH-gradients and during interferences with the homeostatic regulation of intracellular pH and K+ was studied in the isolated perfused rat liver. Within the concentration range studied uptake into the liver was saturable and appeared to be associated with release of OH- and uptake of K+. Perfusate acidification ineffectually stimulated uptake. Application of NH4Cl caused intracellular alkalinization, release of K+ and stimulation of cholate uptake, withdrawal of NH4Cl resulted in intracellular acidification, regain of K+ and inhibition of cholate uptake. Inhibition of Na+/H(+)-exchange with amiloride reduced basal release of acid equivalents into the perfusate, initiated K(+)-release, and inhibited both, control cholate uptake and its recovery following intracellular acidification. K(+)-free perfusion caused K(+)-release and inhibited cholate uptake. K(+)-readmission resulted in brisk K(+)-uptake and recovery of cholate transport. Both effects were inhibited by amiloride. Interference with cholate transport through modulation of pH homeostasis by diisothiocyanostilbenedisulfonate (DIDS) could not be demonstrated because DIDS affected bile acid transport directly. Biliary bile acid secretion was stimulated by intracellular alkalinization and by activation of K(+)-transport. Uncoupling of the mutual interference between pH-dependent cholate uptake and K(+)-transport by amiloride indicates tertiary active transport of cholate. In this, Na+/K(+)-ATPase provides the transmembrane Na(+)-gradient to sustain Na+/H(+)-exchange which maintains the transmembrane pH-gradient and thus supports cholate uptake. Effects of canalicular bile acid secretion are consistent with a saturable, electrogenic transport.     

Dicarboxylate transport in renal basolateral and brush-border membrane vesicles.

Characteristics of succinate transport were determined in basolateral and brush-border membrane vesicles (BLMV and BBMV, respectively) isolated in parallel from rabbit renal cortex. The uptake of succinate was markedly stimulated by the imposition of an inwardly directed Na+ gradient, showing an "overshoot" phenomenon in both membrane preparations. The stimulation of succinate uptake by an inwardly directed Na+ gradient was not significantly affected by pH clamp or inhibition of Na(+)-H+ exchange. The Na(+)-dependent and -independent succinate uptakes were not stimulated by an outwardly directed pH gradient. The Na dependence of succinate uptake exhibited sigmoidal kinetics, with Hill coefficients of 2.17 and 2.38 in BLMV and BBMV, respectively. The Na(+)-dependent succinate uptake by BLMV and BBMV was stimulated by a valinomycin-induced inside-negative potential. The Na(+)-dependent succinate uptake by BLMV and BBMV followed a simple Michaelis-Menten kinetics, with an apparent Km of 22.20 +/- 4.08 and 71.52 +/- 0.14 microM and a Vmax of 39.0 +/- 3.72 and 70.20 +/- 0.96 nmol/(mg.min), respectively. The substrate specificity and the inhibitor sensitivity of the succinate transport system appeared to be very similar in both membranes. These results indicate that both the renal brush-border and basolateral membranes possess the Na(+)-dependent dicarboxylate transport system with very similar properties but with different substrate affinity and transport capacity.     

Characterization of Mg(2+) efflux from rat erythrocytes non-loaded with Mg(2+).

Non-Mg(2+)-loaded rat erythrocytes with a physiological level of Mg(2+)(i) exhibited Mg(2+) efflux when incubated in nominally Mg(2+)-free media. Two types of Mg(2+) efflux were shown: (1) An Na(+)-dependent Mg(2+) efflux in NaCl and Na gluconate medium, which was inhibited by amiloride and quinidine, as was Na(2+)/Mg(2+) antiport in Mg(2+)-loaded rat erythrocytes; and (2) an Na(+)-independent Mg(2+) efflux in sucrose medium and choline Cl medium, which may be differentiated into SITS-sensitive Mg(2+) efflux at low Cl(-)(o) (in sucrose) and into SITS-insensitive Mg(2+) efflux at high Cl(-)(o) (in 150 mmol/l choline Cl).     

Role of the choline exchanger in Na(+)-independent Mg(2+) efflux from rat erythrocytes

Two types of Na(+)-independent Mg(2+) efflux exist in erythrocytes: (1) Mg(2+) efflux in sucrose medium and (2) Mg(2+) efflux in high Cl(-) media such as KCl-, LiCl- or choline Cl-medium. The mechanism of Na(+)-independent Mg(2+) efflux in choline Cl medium was investigated in this study. Non-selective transport by the following transport mechanisms has been excluded: K(+),Cl(-)- and Na(+),K(+),Cl(-)-symport, Na(+)/H(+)-, Na(+)/Mg(2+)-, Na(+)/Ca(2+)- and K(+)(Na(+))/H(+) antiport, Ca(2+)-activated K(+) channel and Mg(2+) leak flux. We suggest that, in choline Cl medium, Na(+)-independent Mg(2+) efflux can be performed by non-selective transport via the choline exchanger. This was supported through inhibition of Mg(2+) efflux by hemicholinum-3 (HC-3), dodecyltrimethylammonium bromide (DoTMA) and cinchona alkaloids, which are inhibitors of the choline exchanger. Increasing concentrations of HC-3 inhibited the efflux of choline and efflux of Mg(2+) to the same degree. The K(d) value for inhibition of [(14)C]choline efflux and for inhibition of Mg(2+) efflux by HC-3 were the same within the experimental error. Inhibition of choline efflux and of Mg(2+) efflux in choline medium occurred as follows: quinine>cinchonine>HC-3>DoTMA. Mg(2+) efflux was reduced to the same degree by these inhibitors as was the [(14)C]choline efflux.     

Intracellular pH regulation in colonocytes of rat proximal colon

The regulation of intracellular pH (pH(i)) in colonocytes of the rat proximal colon has been investigated using the pH-sensitive dye BCECF and compared with the regulation of pH(i) in the colonocytes of the distal colon. The proximal colonocytes in a HEPES-buffered solution had pH(i)=7.24+/-0.04 and removal of extracellular Na(+) lowered pH(i) by 0.24 pH units. Acid-loaded colonocytes by an NH(3)/NH(4)(+) prepulse exhibited a spontaneous recovery that was partially Na(+)-dependent and could be inhibited by ethylisopropylamiloride (EIPA). The Na(+)-dependent recovery rate was enhanced by increasing the extracellular Na(+) concentration and was further stimulated by aldosterone. In an Na(+)- and K(+)-free HEPES-buffered solution, the recovery rate from the acid load was significantly stimulated by addition of K(+) and this K(+)-dependent recovery was partially blocked by ouabain. The intrinsic buffer capacity of proximal colonocytes at physiological pH(i) exhibited a nearly 2-fold higher value than in distal colonocytes. Butyrate induced immediate colonocyte acidification that was smaller in proximal than in distal colonocytes. This acidification was followed by a recovery phase that was both EIPA-sensitive and -insensitive and was similar in both groups of colonocytes. In a HCO(3)(-)/CO(2)-containing solution, pH(i) of the proximal colonocytes was 7.20+/-0.04. Removal of external Cl(-) caused alkalinization that was inhibited by DIDS. The recovery from an alkaline load induced by removal of HCO(3)(-)/CO(2) from the medium was Cl(-)-dependent, Na(+)-independent and blocked by DIDS. Recovery from an acid load in EIPA-containing Na(+)-free HCO(3)(-)/CO(2)-containing solution was accelerated by addition of Na(+). Removal of Cl(-) inhibited the effect of Na(+). In summary, the freshly isolated proximal colonocytes of rats express Na(+)/H(+) exchanger, H(+)/K(+) exchanger ((H(+)-K(+))-ATPase) and Na(+)-dependent Cl(-)/HCO(3)(-) exchanger that contribute to acid extrusion and Na(+)-independent Cl(-)/HCO(3)(-) exchanger contributing to alkali extrusion. All of these are likely involved in the regulation of pH(i) in vivo. Proximal colonocytes are able to maintain a more stable pH(i) than distal cells, which seems to be facilitated by their higher intrinsic buffer capacity.     

Characterization of nucleoside transport systems in cultured rat epididymal epithelium

The nucleoside transport systems in cultured epididymal epithelium were characterized and found to be similar between the proximal (caput and corpus) and distal (cauda) regions of the epididymis. Functional studies revealed that 70% of the total nucleoside uptake was Na(+) dependent, while 30% was Na(+) independent. The Na(+)-independent nucleoside transport was mediated by both the equilibrative nitrobenzylthioinosine (NBMPR)-sensitive system (40%) and the NBMPR-insensitive system (60%), which was supported by a biphasic dose response to NBMPR inhibition. The Na(+)-dependent [(3)H]uridine uptake was selectively inhibited 80% by purine nucleosides, indicating that the purine nucleoside-selective N1 system is predominant. Since Na(+)-dependent [(3)H]guanosine uptake was inhibited by thymidine by 20% and Na(+)-dependent [(3)H]thymidine uptake was broadly inhibited by purine and pyrimidine nucleosides, this suggested the presence of the broadly selective N3 system accounting for 20% of Na(+)-dependent nucleoside uptake. Results of RT-PCR confirmed the presence of mRNA for equilibrative nucleoside transporter (ENT) 1, ENT2, and concentrative nucleoside transporter (CNT) 2 and the absence of CNT1. It is suggested that the nucleoside transporters in epididymis may be important for sperm maturation by regulating the extracellular concentration of adenosine in epididymal plasma.     

Inhibition of transport system b0,+ in blastocysts by inorganic and organic cations yields insight into the structure of its amino acid receptor site

The most conspicuous, Na(+)-independent amino acid transport process in preimplantation mouse blastocysts was provisionally designated system b0,+ because it accepts some cationic and zwitterionic amino acids about equally well as substrates. Although system b0,+ is not Na(+)-stimulated, it has not been determined if it is inhibited by Na+, or if its activity is affected by most other ions. Therefore, we measured uptake of amino acids by blastocysts in isotonic solutions of different ionic and nonionic osmolites. Na(+)-independent L-leucine uptake was unaffected by the ion concentration, but L-lysine transport was several-fold faster in isotonic solutions of non-electrolytes than in similar solutions of inorganic and organic salts or zwitterions. The Km value for 'Na(+)-independent' L-lysine transport was about 10-fold higher in isotonic salt solutions than in solutions of nonionic osmolites, whereas the Km value for L-leucine transport was about the same in either type of solution. Therefore, inorganic and organic cations and the cationic portions of zwitterions appear to compete with cationic but not zwitterionic amino acids for system b0,+ receptor sites. The cation, harmaline, was a particularly strong competitive inhibitor of 'Na(+)-independent' L-lysine uptake by system b0,+, even in isotonic salt solutions, whereas it inhibited L-leucine uptake noncompetitively. Moreover, harmaline appeared to compete with inorganic cations for the lysine receptor sites of system b0,+. Harmaline also has been found by other investigators to competitively inhibit L-lysine uptake by the Na(+)-independent system asc1 in horse erythrocytes, whereas it noncompetitively inhibits alanine uptake by the same system. Similarly, harmaline noncompetitively inhibits L-alanine uptake by the Na(+)-dependent system ASC in human erythrocytes, but it appears to compete for binding with L-alanine's cosubstrate, Na+. In addition, others have found that the positively-charged side chains of cationic amino acids seem to take the place of Na+ needed near side chains in order for zwitterionic amino acids to be transported by systems ASC and y+. We conclude that system b0,+ may be similar to systems asc1, ASC and y+, and that each of these systems may be a variant of the same ancestral transport process. We speculate that since it appears to accept a broader scope of substrates and to interact with a wider variety of cations than do systems asc1, ASC or y+, system b0,+ may more closely resemble the proposed ancestral transport process than any of the other contemporary systems.     

Cell volume regulation in the perfused liver of a freshwater air-breathing catfishClarias batrachus under aniso-osmotic conditions: Roles of inorganic ions and taurine

The roles of various inorganic ions and taurine, an organic osmolyte, in cell volume regulation were investigated in the perfused liver of a freshwater air-breathing catfishClarias batrachus under aniso-osmotic conditions. There was a transient increase and decrease of liver cell volume following hypotonic (-80 mOsmol/l) and hypertonic (+80 mOsmol/l) exposures, respectively, which gradually decreased/increased near to the control level due to release/ uptake of water within a period of 25–30 min. Liver volume decrease was accompanied by enhanced efflux of K⁺ (9.45 ± 0.54 μmol/g liver) due to activation of Ba²⁺- and quinidine-sensitive K⁺ channel, and to a lesser extent due to enhanced efflux of Cl^- (4.35 ± 0.25 μmol/g liver) and Na⁺ (3.68 ± 0.37 μmol/g liver). Conversely, upon hypertonic exposure, there was amiloride- and ouabain-sensitive uptake of K⁺(9.78 ± 0.65 μmol/g liver), and also Cl^- (3.72 ± 0.25 μmol/g liver). The alkalization/acidification of the liver effluents under hypo-/hypertonicity was mainly due to movement of various ions during volume regulatory processes. Taurine, an important organic osmolyte, appears also to play a very important role in hepatocyte cell volume regulation in the walking catfish as evidenced by the fact that hypo- and hyper-osmolarity caused transient efflux (5.68 ± 0.38 μmol/g liver) and uptake (6.38 ± 0.45 μmol/g liver) of taurine, respectively. The taurine efflux was sensitive to 4,4′-di-isothiocyanatostilbene-2,2′-disulphonic acid (DIDS, an anion channel blocker), but the uptake was insensitive to DIDS, thus indicating that the release and uptake of taurine during volume regulatory processes are unidirectional. Although the liver of walking catfish possesses the RVD and RVI mechanisms, it is to be noted that liver cells remain partly swollen and shrunken during anisotonic exposures, thereby possibly causing various volume-sensitive metabolic changes in the liver as reported earlier.     

Expression of the Skate (<Emphasis Type="Italic">Raja erinacea</Emphasis>) AE1 Osmolyte Channel in <Emphasis Type="Italic">Xenopus laevis</Emphasis> Oocytes: Monovalent Cation Permeability

The aim of this study was to express the cloned skate anion exchanger 1 (skAE1) in Xenopus oocytes and determine whether the differences in monovalent cation permeabilities in hypotonically stimulated skate and trout erythrocytes could be due to differences in the presence or absence of intracellular channel regulators between the two species or in the intrinsic permeability properties of the channels themselves. The expressed protein (skAE1) was inserted into the oocyte cell membrane and facilitated both Cl⁻ exchange and taurine transport. Expression of skAE1 in oocytes showed similar monovalent cation permeabilities as previously reported for skate erythrocytes and different from both trout erythrocytes and trAE1 expressed in Xenopus oocytes. These results show that the skAE1 expressed in oocytes functions in a manner similar to that of the osmolyte channel in hypotonically activated skate erythrocytes and supports the hypothesis that differences in the monovalent cation permeabilities of the osmolyte channels in skate and trout RBCs resides in the differences in permeability properties of the channels between the two species.This revised version was published online in August 2005 with a corrected cover date.     

Amino acid-dependent increase in hepatic system N activity is linked to cell swelling

Treatment of cultured rat hepatocytes with certain amino acids stimulates the activity of the System N transporter. The present report investigates the mechanism by which the stimulatory amino acids elicit their effect. Activation of System N-mediated transport by amino acids is rapid, cycloheximide-insensitive, and involves neither trans-stimulation nor recruitment of additional carriers to the plasma membrane. In addition, the activation is Na(+)-dependent, supporting the related observation that the most effective stimulatory amino acids are substrates of Na(+)-dependent transport Systems A, ASC, and N whereas substrates of Na(+)-independent System L and non-amino acid metabolites are ineffective. The data suggest that active accumulation of amino acids via Na(+)-dependent carriers is necessary for the activation to occur. The amino acid-dependent stimulation is blocked in a concentration-dependent manner by increasing extracellular K+. Treatment of hepatocytes with an amino acid such as asparagine causes cell swelling and stimulation of System N activity; both of these effects are reduced by hypertonic media. Furthermore, swelling of rat hepatocytes with hypotonic media mimics the System N-stimulatory effects of asparagine. Among the Na(+)-dependent amino acid transport systems present in rat hepatocytes, System N is stimulated preferentially by amino acid-containing or hypotonic media. Collectively, these results demonstrate that cell swelling is a prerequisite for the amino acid-dependent activation of the hepatic System N transporter.     

Iodide transport in lactating rat mammary tissue via a pathway independent from the Na+/I- cotransporter: evidence for sulfate/iodide exchange

Although it is beyond doubt that mammary cells accumulate iodide via a Na+-dependent transport mechanism, it is not clear if this is the only pathway for iodide transport in mammary tissue. In view of this, experiments were designed to test for the presence of an anion-exchange pathway which could mediate the transport of iodide into mammary cells; thus, the effect of external iodide on sulfate efflux from rat mammary tissue has been investigated. Iodide trans-stimulated sulfate efflux from mammary tissue explants in a dose-dependent manner: 0.1, 1.0 and 10.0 mM iodide stimulated the fractional release of iodide by 56 +/- 2.2, 166.5 +/- 17.5, and 302.9 +/- 29.8%, respectively. The stimulation of sulfate efflux by external iodide was completely inhibited by DIDS (4.4'-diisothiocyanatostilbene 2,2'-disulfonic acid). Perchlorate (1 mM) also trans-stimulated sulfate efflux in a manner that was inhibited by DIDS. Furthermore, iodide trans-accelerated sulfate efflux from rat mammary acini via a DIDS-sensitive mechanism. The results are consistent with the presence of a DIDS-sensitive anion-exchange mechanism which can accept iodide as a substrate. It appears that the iodide-sulfate exchange mechanism is independent from the sodium-dependent iodide transporter given that sulfate is not a substrate of the latter system. The iodide-sulfate exchanger may operate in parallel with the sodium-dependent iodide transporter to mediate iodide uptake into mammary cells.