Taurine Fluxes Research Articles

Rubidium fluxes in Xenopus laevis (Amphibia) erythrocytes induced by swelling and relationship with taurine pathway

Rubidium (86Rb+) fluxes were used to probe for K+ uptake in Xenopus erythrocytes in vitro following exposure to various ambient osmolalities. Rb+ uptake is composed of two major components, one which is ouabain-sensitive and linearly related to changes in medium osmolarity, and a smaller (1/10 of total) that was ouabain-insensitive. The latter component that was activated when medium osmolarity was diluted 40% to 166 mOsm/l increased 2.5 times. The ouabain-insensitive K+ uptake was reduced to one-third on replacement of Cl– by other anions and was not influenced by DIDS, an anion transport inhibitor. Cl– uptake that was probed from SO4 2– uptake was tripled on medium dilution and was almost completely inhibited by DIDS (4, 4 diisothiocyanatostilbene-2, 2-disulfonic acid). The β-adrenergic stimulating agonist, isoproterenol, had no effect on these processes. Parallel measurements of Rb+ and taurine uptake in relation to medium osmolarity show different kinetics. Parallel measurements of 86Rb+ and taurine fluxes were made on erythrocytes from Bufo viridis. Based on the dissimilarity of responses on inhibitors and the different kinetics, it is concluded that the two solutes that are engaged in cellular volume regulation are transported separately.

Osmoregulation of ceroid neuronal lipofuscinosis type 3 in the renal medulla

Recessive inheritance of mutations in ceroid neuronal lipofuscinosis type 3 (CLN3) results in juvenile neuronal ceroid lipofuscinosis (JNCL), a childhood neurodegenerative disease with symptoms including loss of vision, seizures, and motor and mental decline. CLN3p is a transmembrane protein with undefined function. Using a Cln3 reporter mouse harboring a nuclear-localized bacterial beta-galactosidase (beta-Gal) gene driven by the native Cln3 promoter, we detected beta-Gal most prominently in epithelial cells of skin, colon, lung, and kidney. In the kidney, beta-Gal-positive nuclei were predominant in medullary collecting duct principal cells, with increased expression along the medullary osmotic gradient. Quantification of Cln3 transcript levels from kidneys of wild-type (Cln3(+/+)) mice corroborated this expression gradient. Reporter mouse-derived renal epithelial cultures demonstrated a tonicity-dependent increase in beta-Gal expression. RT-quantitative PCR determination of Cln3 transcript levels further supported osmoregulation at the Cln3 locus. In vivo, osmoresponsiveness of Cln3 was demonstrated by reduction of medullary Cln3 transcript abundance after furosemide administration. Primary cultures of epithelial cells of the inner medulla from Cln3(lacZ/lacZ) (CLN3p-null) mice showed no defect in osmolyte accumulation or taurine flux, arguing against a requirement for CLN3p in osmolyte import or synthesis. CLN3p-deficient mice with free access to water showed a mild urine-concentrating defect but, upon water deprivation, were able to concentrate their urine normally. Unexpectedly, we found that CLN3p-deficient mice were hyperkalemic and had a low fractional excretion of K(+). Together, these findings suggest an osmoregulated role for CLN3p in renal control of water and K(+) balance.

Transepithelial Taurine Transport in Caco-2 Cell Monolayers

Here we characterized transepithelial taurine transport in monolayers of cultured human intestinal Caco-2 cells by analyzing kinetic apical and basolateral uptake and efflux parameters. Basolateral uptake was Na(+)- and Cl(-)- dependent and was inhibited by beta-amino acids. Uptake by this membrane showed properties similar to those of the apical TauT system. In both membranes, taurine uptake fitted a model consisting of a non-saturable plus a saturable component, with a higher half-saturation constant and transport capacity at the apical membrane (K(m), 17.1 micromol/L; V(max), 28.4 pmol.cm(-2).5 min(-1)) than in the basolateral domain (K(m), 9.46 micromol/L; V(max), 5.59 pmol.cm(-2).5 min(-1)). The non-saturable influx component, estimated in the absence of Na(+) and Cl(-), showed no significant differences between apical and basolateral membranes (K(D), 89.2 and 114.7 nL.cm(-2) . 5 min(-1), respectively). Taurine efflux from the cells is a diffusive process, as shown in experiments using preloaded cells and in trans-stimulation studies (apical K(D),72.7 and basolateral K(D), 50.1 nL.cm(-2).5 min(-1)). Basolateral efflux rates were significantly lower than passive influx rates. We conclude that basolateral taurine uptake in Caco-2 cells is mediated by a transport mechanism that shares some properties with the apical system TauT. Moreover, calculation of unidirectional and transepithelial taurine fluxes reveals that apical influx of this amino acid is higher than basolateral efflux rates, thereby enabling epithelial cells to accumulate taurine against a concentration gradient.

Taurine enhances volume regulation in hippocampal slices swollen osmotically

Cell volume regulation has been studied in neuronal and glial cultures but little is known about volume regulation in brain tissue with an intact extracellular space. We investigated volume regulation in hippocampal slices maintained in an interface chamber and exposed to hypo-osmotic medium. Relative changes in intracellular and extracellular volume were measured respectively as changes in light transmittance and extracellular resistance. Slices exposed to hypo-osmotic medium (200–240 mOsm/L) showed a decrease in light transmittance, which occasionally was preceded by a brief transient increase. However, hypo-osmotic exposure was always accompanied by a monotonic increase in extracellular resistance. Peak changes in light transmittance and extracellular resistance occurred at 15–20 min following exposure to hypo-osmotic medium. Optical evidence of volume regulation (RVD) was observed in six of 12 slices and occurred over the next 60–90 min. We hypothesized that the relatively low incidence of RVD was related to depletion of taurine, an osmolyte known to play an important role in volume regulation, during preparation of the slices. Indeed, taurine levels in freshly prepared slices were <50% of those reported in intact hippocampus. Incubation of slices in 1 mM taurine restored taurine to levels observed in situ and increased both the likelihood and magnitude of RVD in hypo-osmotic medium. Inhibition of taurine flux with 100 μM 5-nitro-2-(3 phenylpropylamino) benzoic acid blocked both RVD and the transient undershoot of volume commonly associated with return of swollen slices to iso-osmotic medium. Taurine treatment had no effect on levels of several other amino acids but preserved slice potassium content. The results indicate a critical role for cellular taurine during hypo-osmotic volume regulation in hippocampal slices. Inconsistencies between optical measurements of cellular volume changes and electrical measurements of extracellular space are likely to result from the complex nature of light transmittance in the interface slice preparation.

Plasma taurine concentrations increase after enteral glutamine supplementation in trauma patients and stressed rats

Taurine is a unique amino acid with antioxidant and osmolytic properties. Glutamine serves as the preferred fuel for the gut, liver, and immune cells and as a precursor for antioxidants. Trauma patients have low glutamine concentrations. We investigated the effect of glutamine-enriched enteral nutrition on plasma taurine concentrations in patients with severe trauma (injury severity score >20). Additionally, plasma taurine concentrations and organ fluxes were studied in a stressed rat model. Twenty-nine patients with multiple trauma received glutamine-enriched nutrition and 31 patients received isocaloric, isonitrogenous control solution for 5 d. Plasma taurine and glutamine concentrations were measured. Male Wistar rats (250-300 g) received a glutamine-enriched diet (12%, by wt) or a control solution for 2 wk. Plasma taurine concentrations were measured. Taurine fluxes and fractional extraction rates in the liver, kidneys, and gut were assessed with a radioactive microsphere technique. Both patient groups had low taurine concentrations on day 1. From day 3 onward, the glutamine-fed patients had significantly higher taurine concentrations. Rats fed a glutamine-enriched diet had significantly higher plasma taurine concentrations than did the controls. A high taurine uptake was found in the liver, kidneys, and gut of the glutamine-fed rats. Fractional extraction rates were not significantly different between the rat groups. Glutamine enrichment increases plasma taurine in trauma patients and in stressed rats. Because of increased availability, organ fluxes showed a higher taurine uptake in the liver, kidneys, and gut. The reduction in morbidity with glutamine enrichment could be explained in part by increased taurine availability.

Hypotonic-induced transport pathways in Xenopus laevis erythrocytes: taurine fluxes

Taurine fluxes in Xenopus laevis red cells were studied in vitro in media of different tonicities. Both influx and efflux increased 3–10 times reversibly when dilution of the medium exceeded 30%. The absolute values of uptake ranged between 5 and 30 μmol/l cells·h at extracellular taurine concentration of 1 mmol/l, but is poorly selective as almost the same uptake was measured for choline and sucrose. Q 10 of 2.77 and an activation energy of 71.90±7.37 kJ/mol were calculated for the uptake process. Taurine uptake was reduced 50% in the absence of Cl −, whereas the alkali cations (Na +, K +, Li + and Rb +) supported it similarly. Taurine uptake was greatly increased in Ca 2+-free solution, and was inhibited by alkaline pH. The inhibitor of anion exchange protein, 4,4′-diisothiocyanatostilbene-2,2′-disulphonic acid (IC 50=25 μM) and the Cl − channel blockers 5-nitro-2-(3-phenylpropylamino) benzoic acid and [(dihydro-indenyl) oxy] alkanoic acid (IC 50<20 μM) inhibited taurine uptake effectively. Isoproterenol did not affect taurine uptake in isotonic, nor in hypotonic solution. The uptake was reduced slowly to near the original, control level within 15–30 min in hypotonic solutions, indicating deactivation of the hypotonic-induced taurine pathway.

Influence of protein tyrosine kinases on cell volume changeinduced taurine release

Taurine efflux occurs in association with cell swelling in both hyposmotic and isosmotic conditions and during cell shrinkage in apoptotic death. Release occurs through a leak pathway, is largely Ca2+-independent and is sensitive to Cl- channel blockers. Taurine efflux elicited by hyposmolarity is reduced or suppressed by tyrosine kinase blockers and increased by tyrosine phosphatase inhibitors. The specific kinases involved are still unknown and may be different in the various cell types. Non-receptor and scr-related protein kinases have been identified in some cells as elements that directly phosphorylate the taurine efflux pathway. Possible tyrosine kinase targets are the phosphinositide kinase (PI3K), which if inhibited, prevents the osmosensitive taurine efflux in brain cells, or the small GTP-binding proteins associated with remodeling of the cytoskeleton. The similar effects of tyrosine kinase modulators on volume-activated taurine fluxes and Cl- currents are suggestive of either a shared translocation pathway or a common step in the signaling network. The effects of tyrosine kinases on taurine efflux activated in isosmotic swelling and in the release associated with apoptosis are essentially unexplored.

Effects of osmotic and light stimulation on 3H-taurine efflux from isolated rod outer segments and synthesis of tauret in the frog retina.

After injection of 3H-taurine into eyeballs of frogs and maintenance for 3 h in darkness by a gentle shaking, an almost homogenous fraction of rod outer segments (ROS) was prepared. About a 22% decrease in tonicity caused by reducing NaCl in isotonic 225 mOsm normal solution caused a rapid increase in the rate coefficient of efflux of 3H-taurine from the ROS fraction. The peak level of increased efflux rate coefficient was 7-times higher than the basal isotonic level. This indicates that taurine could contribute essentially to the volume regulation, either via selective channels or a carrier transporter-mediated pathways. For further clarifying if taurine fluxes in the ROS are sensitive to the light, other experiments were performed. Neither light stimulation of dark-adapted ROSs fractions or dark stimulation of weakly illuminated ROSs revealed any detectable changes in the efflux rate coefficient of 3H-taurine. These results indicate that light-induced taurine efflux, if present in the ROS, must be small, compared with hypoosmotic induced efflux. Thus the question of light-induced release of taurine from ROS still remains to be clarified. In the second part of this study, using TLC (thin layer chromatography) in combination with 3H-taurine measurements we have tried to clarify whether frogs (Rana ridibunda) eye structures can synthesize tauret (retinylidenetaurine). In isolated retinal preparations almost no any noticeable radioactivity was detected compared with background level. The capability of the eye structures to synthesize tauret from 3H-taurine was revealed in the second whole eye injection experiment. About 0.3% of the total 3H-taurine pool taken up was converted into 3H-tauret in the dark-adapted frog retina. In the retina of frogs adapted to light compared with those which were dark adapted tauret quantities were remarkable lower--on average about half. These results are in agreement with our recent data obtained by HPLC, which indicate tauret levels several times higher in the dark-adapted frog retinae compared with those after long lasting light adaption. Taking into account these results one can conclude that the main structure able to synthesize 3H-tauret is probably pigment epithelium rather than retina.

Reduction of phospholemman expression decreases osmosensitive taurine efflux in astrocytes

The role of phospholemman (PLM) in taurine and Cl − efflux elicited by 30% hyposmotic solution was studied in cultured cerebellar astrocytes with reduced PLM expression by antisense oligonucleotide (AO) treatment. PLM, a substrate for protein kinases (PK) C and A, is a protein that increases an anion current in Xenopus oocytes and forms taurine-selective channels in lipid bilayers. Taurine contributes as an osmolyte to regulatory volume decrease (RVD) and is highly permeable through PLM channels in bilayers. Two antisense oligonucleotides (AO1 and AO2) effectively decreased the expression of the PLM protein by 40% and 30%, respectively, and markedly reduced [ 3H]taurine efflux by 67% and 62%. AO treatment also decreased the osmosensitive release of Cl −, followed as 125I. The inhibition of Cl − efflux (23% for AO1 and 13% for AO2) was notably lower than for [ 3H]taurine. The contribution of PKC and PKA in the function of PLM was also evaluated in astrocytes. Pharmacological activation or inhibition of PKC and PKA revealed that the osmosensitive taurine efflux is essentially PKC-independent while 125I efflux is reduced by the PKC blockers H-7 (21%) and Gö6983 (41%). The PKA activator forskolin and dbcAMP increased taurine efflux by 66–70% and 125I efflux by 21–45%. Norepinephrine increased the osmosensitive taurine efflux at about the same extent as dbcAMP and forskolin, and this was reduced by PKA blockers. These results suggest that PLM plays a role in RVD in astrocytes by predominantly influencing taurine fluxes, which are modulated by PKA but not PKC.

Taurine secretion in primary monolayer cultures of flounder renal epithelium: stimulation by low osmolality.

Transepithelial taurine fluxes determined in short-circuited monolayer cultures of flounder renal proximal cells in Ussing chambers revealed net taurine secretion. Both unidirectional secretory and reabsorptive taurine fluxes exhibited saturation kinetics contributed by two distinct saturable transepithelial taurine transport systems operating at different taurine concentration ranges. The taurine secretory system operating below 0. 5 mM had lower affinity but higher capacity than the reabsorptive system, whereas the one operating at high concentrations (0.5-3.0 mM) had higher affinity but the same capacity as the corresponding reabsorptive system. Exposure (2 h) of the cultures to hyposmotic medium in the presence of taurine increased taurine secretory flux twofold with no effect on the reabsorptive flux. The hyposmolality-induced increase in taurine secretion was associated with a decreased peritubular taurine efflux and a concurrent increased luminal taurine efflux; the latter occurred via a pathway that was not affected by 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid but inhibited by probenecid. The culture response in hyposmotic medium mimics the in vivo response of the intact marine fish kidney to dilution.

The relationship between hypotonically-induced taurine and K fluxes in trout red blood cells.

Hypotonic swelling of teleost erythrocytes activates multiple transport systems leading to the regulatory decrease of cell volume. We have examined using pharmacological manipulation the swelling-induced taurine flux pathway in red blood cells of the rainbow trout and its relationship to swelling-induced K flux pathways. We show that the activation and deactivation of taurine flux is rapid and that the flux is a sigmoidal function of cell volume. N-ethylmaleimide (NEM) and the non-specific protein kinase inhibitor, staurosporine, both inactivated the hypotonically-induced taurine flux with concentrations eliciting half-maximal inhibition (IC50s) of 212 and 17 micromol(-1), respectively. The low taurine fluxes under isotonic conditions were unaffected. By contrast, the tyrosine kinase inhibitor, genistein, partially inhibited taurine flux under both isotonic and hypotonic conditions. The specific phosphatase inhibitor, calyculin A, had no inhibitory or stimulatory effect under either condition whilst the less-specific phosphatase inhibitor, ortho-vanadate, reduced taurine flux only under hypotonic conditions. In these respects the regulatory control of the taurine pathway differs from the Cl-dependent K flux. However, NEM and staurosporine also inhibited the Cl-independent K flux, both with similar IC50s to those observed for taurine fluxes. This supports the idea of the hypotonically-induced taurine flux and the Cl-independent K flux sharing the same transport pathway.

Volume Expansion Stimulates p72syk and p56lyn in Skate Erythrocytes

Hypotonic volume expansion of skate erythrocytes rapidly stimulates the tyrosine phosphorylation of band 3, the membrane protein thought to mediate the osmotically sensitive taurine efflux. Skate erythrocytes possess numerous tyrosine kinases including p59fyn, p56lyn, pp60(src), and p72(syk), demonstrated by immune complex assays measuring autocatalytic kinase activity. Inclusion of the cytoplasmic domain of band 3 in this assay showed that only Syk and Lyn can directly phosphorylate the cytoplasmic domain of band 3. Upon cell volume expansion, Syk activity was increased as assessed by three different assays (immune complex assay measuring autophosphorylation, assay of the level of phosphotyrosine of the immunoprecipitated kinase, and assay of level of 32P in the kinase immunoprecipitated from cells prelabeled with 32PO4 and then volume-expanded). The tyrosine kinase Lyn was also stimulated by volume expansion, most notably when analyzed by the latter two methods. Volume expansion stimulated a large increase in the ability of Syk to phosphorylate band 3 at times that coincide with the stimulation of taurine flux. The stilbene piceatannol inhibited Syk preferentially over Lyn and other tyrosine kinases and inhibited volume-stimulated taurine efflux in a concentration-dependent manner similar to that for the inhibition of Syk. Two major phosphorylation peaks were detected in tryptic digests of cdb3 separated by reverse phase HPLC. Edman degradation demonstrated a phosphotyrosine in a YXXL motif. In conclusion, p72(syk) appears to be a strong candidate as a pivotal signal-transducing step in the volume-activated taurine efflux in skate red cells. The level of band-3 phosphorylation may be regulated, in addition, by a protein-tyrosine phosphatase of the 1B variety.

Intrauterine Growth Restriction Is Associated with a Reduced Activity of Placental Taurine Transporters

Taurine is an essential amino acid during fetal life and appears to be vital for the growth of the fetus and for the development of the CNS. In intrauterine growth restriction (IUGR), fetal plasma concentrations of taurine are reduced, and we tested the hypothesis that this is caused by altered placental transport of taurine. Syncytiotrophoblast microvillous membrane (MVM) and basal membrane (BM) vesicles were isolated from control (fetal weight, 3068+/-191 g; gestational age, 37.0+/-0.7 wk; n=13) and IUGR pregnancies (fetal weight, 1724+/-118 g; gestational age, 35.8+/-0.7 wk; n=11). Uptake of [3H]taurine (0.5 microM) was studied at 22 degrees C using rapid filtration techniques. Sodium stimulated taurine uptake 35-fold in MVM, confirming Na+-dependent transport in this membrane. A Na+-dependent taurine transport could also be demonstrated in BM; however, the activity was only 6% of that in MVM. Na+-independent transport activities were similar in MVM and BM. In IUGR, MVM Na+-dependent taurine transport was reduced by 34% (p < 0.05), whereas Na+-independent uptake was unaltered. In contrast to MVM, Na+-dependent taurine uptake in BM was unaffected by IUGR, whereas Na+-independent transport was decreased by 33% (p < 0.05). The highly polarized distribution of the Na+/taurine cotransporter to the MVM in conjunction with similar Na+-independent transport rates for taurine in MVM and BM provides the basis for net taurine flux from the mother to the fetus. These data suggest that the low plasma concentrations of taurine in IUGR fetuses are caused by a reduced activity of placental taurine transporters.

Hypotonic-stimulated taurine efflux in skate erythrocytes: regulation by tyrosine phosphatase activity.

Treatment of skate erythrocytes with FCCP, dinitrophenol, or sodium azide lowers ATP levels and inhibits Na+-independent taurine uptake after hypotonic volume expansion. Inside-out vesicles isolated from hypotonic volume-expanded cells demonstrate greater Na+-independent taurine uptake, and pretreatment of cells with FCCP abolishes this stimulation. Addition of ATP to the vesicles does not restore stimulated taurine uptake, suggesting that ATP does not act as a ligand modulator on the transporter. Therefore the role of protein phosphorylation was investigated. Because known protein kinase inhibitors have previously been found to have little effect on taurine fluxes in skate erythrocytes, we focused on the effects of protein phosphatase inhibition. When volume-expanded cells were returned to isotonic medium, taurine flux returned to basal values more slowly after treatment with the tyrosine phosphatase inhibitor pervanadate, suggesting that dephosphorylation may regulate inactivation. A similar effect of phosphatase inhibitors was observed in the inside-out vesicles from volume-expanded cells: the reversal of stimulated taurine uptake takes place more slowly in vesicles prepared from cells that had been incubated with pervanadate. Band 3, a major protein involved in the taurine transport pathway, shows increased tyrosine phosphorylation after hypotonic volume expansion. Pervanadate treatment of the cells potentiates and prolongs the increased phosphorylation. Therefore tyrosine phosphorylation of band 3 may play an important role in the activation of taurine fluxes after volume expansion.

Interleukin-1 and tumor necrosis factor alter plasma concentration and interorgan fluxes of taurine in dogs.

We examined the effects of interleukin-1 beta (IL-1), tumor necrosis factor (TNF), and alanylglutamine (Ala-Gln) infusion on the plasma concentrations and interorgan fluxes of taurine and taurine precursors, including methionine and serine, using chronically catheterized awake dogs. In the first study, the dogs received 5 micrograms/kg/h of either human recombinant IL-1 or TNF intravenously for 2 h. Taurine fluxes in the liver and gut were calculated by blood flows and arteriovenous differences during infusion and for 2 h after discontinuation of the cytokine infusions. The 2 h continuous infusions of TNF and IL-1 resulted in 60 and 90% increases, respectively, in the arterial plasma taurine concentration. Hepatic taurine flux changed from uptake to release after 2 h of continuous IL-1 infusion. In the second study, we investigated whether Ala-Gln infusion affects taurine metabolism under normal and stress conditions. The dogs were given a constant 2 h intravenous infusion of IL-1 or saline. Ala-Gln (6 mumol/kg/min) was infused simultaneously during the second hour. Plasma concentrations and fluxes, across the liver, gut, and lung, of taurine and taurine precursors were studied. IL-1 administration increased the plasma concentration, hepatic release, and lung uptake of taurine. Ala-Gln infusion did not affect either plasma concentrations or organ fluxes of taurine. These data suggest that cytokines play a role in taurine metabolism under stress conditions.

Anion, cation, and zwitterion selectivity of phospholemman channel molecules

Phospholemman (PLM), a 72-amino acid membrane protein with a single transmembrane domain, forms taurine-selective ion channels in lipid bilayers. Because taurine forms zwitterions, a taurine-selective channel might have binding sites for both anions and cations. Here we show that PLM channels indeed allow fluxes of both cations and anions, making instantaneous and voltage-dependent transitions among conformations with drastically different ion selectivity characteristics. This surprising and novel ion channel behavior offers a molecular explanation for selective taurine flux across cell membranes and may explain why molecules in the phospholemman family can induce cation- or anion-selective conductances when expressed in Xenopus oocytes.

Cl channel blockers inhibit the volume-activated efflux of Cl and taurine in cultured neurons.

The effects of the Cl channel blockers 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB), 1,9-dideoxyforskolin (DDF), dipyridamole, and niflumic acid and of the polyunsaturated fatty acids arachidonic, linolenic, and linoleic acids on regulatory volume decrease (RVD) and associated 125I and [3H]taurine fluxes in cultured rat cerebellar granule neurons were examined. Dose-response curves of NPPB, DDF, and dipyridamole showed 20-100% inhibition of RVD and osmolyte fluxes. Niflumic acid was less potent, requiring 150-600 microM to show effects of this magnitude. The polyunsaturated fatty acids (5-20 microM) inhibited 80-90% RVD and osmolyte fluxes, with arachidonic acid exhibiting the most potent effect. The volume-associated taurine efflux was somewhat higher in younger neurons, but the pharmacological sensitivity was essentially the same in immature and mature cells. The effects of all tested drugs on 125I and [3H]taurine fluxes were remarkably similar, indicating a close pharmacological sensitivity of the transport mechanism for the two osmolytes. This is in line with the suggestion of a common pathway for the volume-associated release of Cl and amino acids functioning as osmolytes.

Stimulation of taurine efflux from human placental tissue by a hypoosmotic challenge.

The fractional release of taurine from preloaded human placental tissue fragments was stimulated by a hypoosmotic challenge. This stimulation could not be attributed to a change in the Na+ gradient or the ionic strength of the medium. We suggest that taurine fluxes may play a role in placental cell volume regulation.

Volume-sensitive KCl co-transport and taurine fluxes in horse red blood cells.

Potassium (using 86Rb+ as a tracer), amino acid and taurine fluxes were measured in horse red blood cells (RBCs). No volume-sensitive component of alanine and glycine transport was observed, and although volume-sensitive taurine fluxes were observed in most animals, their absolute magnitudes were small. K+ fluxes, however, were shown to be particularly volume sensitive; they were stimulated by cell swelling and inhibited by cell shrinkage. Sizeable fluxes were present at normal cell volumes. The volume-sensitive K+ flux was Cl- dependent and was abolished by Cl- replacement with methylsulphate. The Cl(-)-dependent K+ fluxes in horse red blood cells were stimulated by lowering in external pH to 6.9 and by treatment with the sulphydryl-reacting agent, N-ethylmaleimide. They were inhibited by the potent K(+)-Cl- co-transport inhibitor, DIOA, ([(dihydroindenyl)oxy]alkanoic acid) but were insensitive to the Na(+)-K(+)-Cl- co-transport inhibitors, frusemide and bumetanide. A Cl- channel inhibitor, 5-nitro-2-(phenylpropyl-amino)-benzoate (NPPB), produced partial inhibition. These results suggest that regulatory volume decrease in horse red blood cells is achieved predominantly by volume-sensitive K+ efflux mediated via a K(+)-Cl- co-transport system with similar properties to those observed in the red blood cells of other species. The significance of these findings and their rheological consequences are discussed.

Polarized nature of taurine transport in LLC-PK1 and MDCK cells: Further characterization of divergent transport models

Taurine transport was measured in cultured epithelial cells-LLC-PK1 and MDCK-grown on permeable membrane supports. Taurine transport by LLC-PK1 cells was greater on the apical surface compared to the basolateral surface. MDCK cells exhibited greater taurine uptake from the basolateral side. Transepithelial taurine flux was in the direction of apical to basolateral in the LLC-PK1 monolayers. There was no net transepithelial movement of taurine in the MDCK monolayers. Efflux of taurine from the apical and the basolateral membrane surfaces of LLC-PK1 cell monolayers was stimulated by externalβ-alanine but not L-alanine. Efflux of taurine from MDCK cell monolayers was stimulated byβ-alanine on the basolateral surface. While the competitive inhibitor guainidinoeithane sulfonate (GES) competitively inhibited taurine uptake to a similar degree on the apical and basolateral surface of LLC-PK1 cell monolayers, GES had a more potent inhibitory effect on the basolateral taurine uptake in MDCK cells when compared to its inhibition of apical taurine transport. We conclude that there are characteristic differences in transport of taurine by apical and basolateral surfaces of LLC-PK1 and MDCK cells which may be the consequence of asymmetric distribution or unique structural properties of the taurine transporter.