Effects of cations on taurine, hypotaurine, and GABA uptake in mouse brain slices

Characteristics of ischemia-induced taurine release in the developing mouse hippocampus

Taurine release in the developing hippocampus is markedly potentiated in ischemia. The mechanisms of the ischemia-induced release were studied in hippocampal slices from seven-day-old mice using a superfusion system. The basal release of [3H]taurine was significantly increased in media under normal conditions, but the ischemia-evoked release decreased in Na+ -free media, indicating the participation of Na+ -dependent transport processes. The involvement of taurine transporters in the release was confirmed with the structural analogs, hypotaurine and beta-alanine. These amino acids potentiated the release by trans-stimulation, but not in Na+ -free media. In the absence of Ca2+, the basal taurine release was markedly increased in normoxia but diminished in ischemia, indicating that a part of basal taurine release in ischemia is Ca2+ dependent. On the other hand, the K+ stimulation of taurine release was preserved in Ca2+ -free medium. The phospholipase and protein kinase inhibitors had no effect on ischemia-induced taurine release, nor did the chloride channel blockers 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonate (2 mM) and diisothiocyanostilbene-2,2'-disulfonate (0.1 mM) affect the release in ischemia. The increase in extracellular levels of taurine in the immature hippocampus in ischemia may serve as an important protective mechanism against excitotoxicity, to which the developing brain is particularly vulnerable, and contribute to the resistance of the immature brain to hypoxia.

Mechanisms of ischemia-induced taurine release in mouse hippocampal slices

Taurine release in the hippocampus is markedly potentiated in various cell-damaging conditions, including ischemia and excitotoxic damage produced by glutamate. The increase in the levels of taurine may provide an important protective mechanism against excitotoxicity. The mechanisms of the enhanced release were now studied in mouse hippocampal slices using a superfusion system. The basal release of [3H]taurine was significantly increased in Na+-deficient media in normal conditions, whereas the ischemia-evoked release was decreased, indicating the participation of Na+-dependent transport processes. The involvement of taurine transport carriers in the release was confirmed with the structural analogs, hypotaurine and beta-alanine. These amino acids potentiated the release by trans-stimulation in normoxia. In Na+-free conditions, this heteroexchange was not discernible, the carriers not being functional without Na+. In ischemia, the marked potentiation of taurine release by hypotaurine and beta-alanine further indicates that the Na+-requiring transporters also operate in ischemia. The effects of membrane disruption on taurine release due to activation of phospholipases were estimated using phospholipase and protein kinase inhibitors, which had no marked effects on hippocampal taurine release. The chloride channel blockers, 4-acetamido-4'-isothiocyanostilbene-2, 2'-disulphonate (SITS) and diisothiocyanostilbene-2,2'-disulphonate (DIDS), reduced the ischemia-induced release, suggesting that taurine diffusion through an anion channel is partially responsible for the enhanced release in ischemia.

Dual role of K+ and Na+ on the transport of [3H]-gamma-aminobutyric acid by synaptic plasma membrane vesicles

The influence of the monovalent cations (Na+ and K+) and of the electrical gradient on the high-affinity [3H]-gamma-aminobutyric acid ([3H]GABA) transport was investigated in synaptic plasma membrane (SPM) vesicles isolated from sheep brain cortex. This process specifically requires internal K+, since when it is replaced by Li+, the delta psi remains of the same order of magnitude, but no uptake of [3H]GABA occurs. The influence of the external Na+ concentration on the rate of [3H]GABA uptake suggests that this mechanism exhibits two components, whose characteristics are determined by the delta psi. Depolarization reduces the Jmax of [3H]GABA influx and enhances the binding of Na+ associated to [3H]GABA transport. Nevertheless, depolarization does not affect the K0.5 of binding sites for Na+ and the stoichiometry of translocation. These results suggest that intravesicular K+ and external Na+ have a dual role on the mechanism of [3H]GABA uptake: K+ acts directly on the carrier and determines the membrane polarization; Na+ is cotransported with GABA and, according to the polarization state of the membrane, it modulates the operation of the carrier in its inward GABA translocation.

Characterization of the carrier-mediated [3H]GABA release from isolated synaptic plasma membrane vesicles

Synaptic plasma membrane (SPM) vesicles were isolated under conditions which preserve most of their biochemical properties. Therefore, they appeared particularly useful to study the cytoplasmic GABA release mechanism through its neuronal transporter without interference of the exocytotic mechanism. In this work, we utilized SPM vesicles isolated from sheep brain cortex to investigate the process of [3H]GABA release induced by ouabain, veratridine and Na+ substitution by other monovalent cations (K+, Rb+, Li+, and choline). We observed that ouabain is unable to release [3H]GABA previously accumulated in the vesicles and, in our experimental conditions, it does not act as a depolarizing agent. In contrast, synaptic plasma membrane vesicles release [3H]GABA when veratridine is present in the external medium, and this process is sensitive to extravesicular Na+ and it is inhibited by extravesicular Ca2+ (1mM) under conditions which appear to permit its entry. However, veratridine-induced [3H]GABA release does not require membrane depolarization, since this drug does not induce any significant alteration in the membrane potential, which is determined by the magnitude of the ionic gradients artificially imposed to the vesicles. The substitution of Na+ by other monovalent cations promotes [3H]GABA release by altering the Na+ concentration gradient and the membrane potential of SPM vesicles. In the case of choline and Li+, we observed that the fraction of [3H]GABA released relatively to the total amount of neurotransmitter released by K+ or Rb+ is about 28% and 68%, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Taurine release and swelling of cerebral cortex slices from adult and developing mice in media of different ionic compositions

The release of preloaded radiolabeled taurine was studied in superfused cerebral cortex slices obtained from adult and 3-day-old mice in media of varying ionic composition. Our aim was to establish whether the release of taurine from slices evokable by high concentrations of K+ could be attributed solely to cell volume changes or whether it results directly from depolarization of cell membranes. In both age groups hypoosmotic media enhanced the release of taurine. The enhancement was greater in 3-day-old than in adult mice. The K(+)-evoked release of taurine was likewise greater in slices from 3-day-old mice than in slices from adult mice. The K+ stimulation was totally preserved in adult mice and partially preserved in 3-day-old mice when the slices were superfused with Cl(-)-free media, with media in which the K+ x Cl- ionic product was kept constant and with hyperosmotic high-K+ media. The results were practically the same when the permeant anion acetate and the impermeant anion gluconate were used to replace the Cl- deficit. The unstimulated release of preloaded taurine was greatly enhanced in Cl(-)-free media in both age groups. There obtained no statistically significant correlation between the intracellular swelling of slices and the magnitude of taurine release under the present different experimental conditions in either age group. The results show that the K(+)-evoked release of taurine from superfused cerebral cortex slices cannot be solely attributed to depolarization-induced cell swelling. At least a part of the release results directly from membrane depolarization which besides exocytosis apparently also enhances the carrier-mediated release of taurine and inhibits the reuptake of taurine liberated from intracellular compartments.

The identification and characterization of an uptake system for taurine into rat lung slices

The objective of this study was to determine whether taurine was accumulated by rat lung slices and if so, to establish the role of this uptake as a source of pulmonary taurine. We have shown that taurine is accumulated into rat lung by an active uptake process that was both ATP and Na(+)-dependent and obeyed saturation kinetics, exhibiting an apparent Km of 186 microM and Vmax of 970 nmol/g wet wt/hr. Substrate specificity of the system was high and only compounds possessing anionic and cationic groups separated by two methylene groups were able to competitively inhibit taurine uptake. Subsequent to its uptake, taurine was not significantly metabolized, and since the apparent Km for the uptake process is similar to the known plasma concentration of taurine, it can be inferred that this system will contribute to pulmonary taurine uptake in vivo. Taurine has been suggested to possess antioxidant and antiinflammatory properties, and we suggest that this uptake system may contribute to the defence of pulmonary tissue against oxidative stress.

In vivo substitution of choline for sodium evokes a selective osmoinsensitive increase of extracellular taurine in the rat hippocampus

Recent investigations have demonstrated that taurine and phosphoethanolamine (PEA) are the amino acids most sensitive to microdialysis-perfusion with reduced concentrations of NaCl. The aim of the present work was to assess the importance of Na+ deficiency in evoking this response. Further, the previously described selectivity of replacement of Cl- with acetate with respect to amino acid release was reinvestigated. The hippocampus of urethane-anesthetized rats was dialyzed with Krebs-Ringer bicarbonate buffer, and amino acid concentrations of the perfusate were determined. Choline chloride was then stepwise substituted for NaCl, and, in some cases, mannitol (122 mM) was included in low sodium-containing media. In other experiments, NaCl was replaced with sodium acetate. The dialysate levels of taurine increased selectively in response to Na+ substitution. The elevation of taurine was linearly related to the increase in choline chloride, and maximal levels amounted to 335% of basal levels. The increase in extracellular taurine was not inhibited by perfusion with medium made hyperosmotic with mannitol. Replacement of Cl- with acetate stimulated the release of taurine to 652% of resting levels. In addition, PEA levels increased to 250% of control concentration. Other amino acids were unaffected by Cl- substitution. The results show that taurine transport is considerably more sensitive to Na+ depletion than glutamate transport, which also is known to be Na+ dependent. The taurine increase evoked by low Na+ is not caused by cellular swelling as it was unaffected by hyperosmolar medium. Finally, substitution of acetate for Cl- causes a specific elevation of extracellular taurine and PEA, possibly as a result of cytotoxic edema.

Effects of microdialysis-perfusion with anisoosmotic media on extracellular amino acids in the rat hippocampus and skeletal muscle

Changes in the levels of amino acids have been implicated as being important in osmoregulation both within and outside the CNS. The present study addressed the question of whether changes in osmolarity affect the extracellular concentration of amino acids in the rat hippocampus and femoral biceps muscle (FBM). Microdialysis probes were implanted in these tissues and perfused with standard physiological saline. Amino acid concentrations in the dialysate were determined with HPLC separation of o-phthaldialdehyde derivatives and fluorescence detection. The osmolarity of the perfusion buffer was gradually decreased by reduction of the concentration of NaCl from 122 to 61 to 0 mM. In other experiments, the osmolarity was increased by elevation of the NaCl level from 122 to 183 to 244 mM or by addition of mannitol. Glutamate, aspartate, gamma-aminobutyrate, and alanine levels in dialysate from the hippocampus increased when the concentration of NaCl was decreased by 61 mM, and they were further elevated when NaCl was omitted. Taurine and phosphoethanolamine (PEA) levels were maximally elevated at the intermediary decrease of NaCl concentration, and glutamine in particular but also methionine and leucine were suppressed by perfusion with hypoosmolar medium. The amino acid response of the FBM differed substantially from that of the hippocampus. The aspartate content increased slightly, and there was a marginal transient increase in PEA level. Perfusion with media containing high concentrations of NaCl induced diminished dialysate levels of taurine, PEA, and glutamate, whereas levels of other amino acids were either unaffected or increased. Mannitol administration via the perfusion fluid led to reduced levels of taurine, PEA, glutamate, and aspartate. In contrast to the effects of high NaCl levels, hyperosmotic mannitol did not induce increases in level of any of the amino acids detected. The results suggest that taurine and PEA are involved in osmoregulation in the mammalian brain. From a quantitative viewpoint, taurine seems to be most important. Transmitter amino acids may also be involved in the maintenance of the volume of neural cells subjected to severe disturbances in osmotic equilibrium.

Taurine and beta-alanine uptake in primary astrocytes differentiating in culture: effects of ions

The effects of ions on taurine and beta-alanine uptake were studied in astrocytes during cellular differentiation in primary cultures. The uptakes were strictly Na+-dependent and also inhibited by the omission of K+ and in the presence of ouabain suggesting that their transport is fuelled mainly by these cation gradients. Two sodium ions were associated in the transport of one taurine and beta-alanine molecule across cell membranes. A reduction in Cl- concentration also markedly inhibited the uptake of both amino acids, indicating that this anion is of importance in the transport processes. The similar ion dependency profiles of taurine and beta-alanine uptake corroborate the assumption that the uptake of these amino acids in astrocytes is mediated by the same carrier. In Na+- and K+-free media both taurine and beta-alanine uptakes were reduced significantly more in 14-day-old or older than in 7-day-old cultures. No significant changes occurred in the coupling ratio between Na+ and taurine or beta-alanine as a function of spontaneous cellular differentiation or upon dBcAMP treatment. These results suggest that the uptake systems of these structurally related amino acids in astrocytes have reached a relatively high degree of functional maturity by two weeks in culture.

Effects of taurine on the influx and efflux of calcium in brain slices of adult and developing mice

45Ca2+ influx was reduced by 10-mM taurine during a 5-min incubation in slices from the cerebral cortex, cerebellum and brainstem of adult mice. In both adult and developing cerebral cortex and cerebellar slices a 30-min exposure to 1.0-mM taurine was likewise effective on resting Ca2+ influx whereas in slices depolarized by 50 mM K+ the influx was not affected. Ca2+ efflux from adult mouse cerebral cortex slices was affected by extracellular Na+ (0-180 mM) but not by K+ (50 mM) or taurine (1 mM). In cerebral cortex slices of 3-day-old mice K+ depolarization stimulated Ca2+ efflux, which effect was antagonized by 1.0 mM taurine. The results suggest that taurine is able to modify Ca2+ influx and efflux in both adult and developing brain but only at relatively high concentrations.

The relationship between sodium and high-affinity taurine uptake in hypothalamic crude P2 synaptosomal preparations

Two uptake systems for taurine transport in a rat hypothalamic crude synaptosomal preparation were identified. The true transport constants were, for the high-affinity uptake system, Km = 240 microM and V (maximum velocity) = 400 nmol/g protein/min, and for the low-affinity uptake system, Km = 5290 microM and V = 1640 nmol/g protein/min. The initial velocity of high-affinity taurine uptake by the crude synaptosomal preparation was studied as a function of sodium and taurine concentration. Hill plots were constructed from these data. The requirement of high-affinity taurine uptake on a sodium gradient was examined by utilizing monensin, and the metabolic poisons, 2,4-dinitrophenol and ouabain. The major findings are as follows: 1) One sodium ion is co-transported with each taurine molecule; 2) the high-affinity uptake process is driven by the sodium concentration gradient across the membrane; 3) sodium increases the maximal velocity rather than the affinity of the high-affinity taurine carrier for the taurine molecule; 4) one taurine molecule is transported per carrier for both the high- and low-affinity taurine uptake systems; and 5) high-affinity taurine uptake is an energy-dependent process.

Is taurine a hypothalamic neurotransmitter?: A model of the differential uptake and compartmentalization of taurine by neuronal and glial cell particles from the rat hypothalamus

Although taurine has been postulated to be a neurotransmitter or neuromodulator in the mammalian CNS, little is known concerning its role in brain function. Evidence suggesting that taurine may influence endocrine and homeostatic mechanisms via the hypothalamus resulted in our investigations into its function in this brain region. The main objectives of the research were to characterize the specific binding, uptake, and release of taurine in the hypothalamus. A specific aim was to examine the proposed neurotransmitter role for taurine in the hypothalamus. This was accomplished by comparing the characteristics and properties of the binding, uptake, and release of taurine with those for the classical neurotransmitters which satisfy the criteria for a neurotransmitter. On such a comparative basis, the characteristics of taurine uptake satisfy the neurotransmitter criterion of inactivation of taurine in the hypothalamus. However, the observed characteristics of taurine binding and release in the hypothalamus do not satisfy the respective neurotransmitter criteria of specific receptors and Ca2+-dependent evoked release. Therefore, solely on the basis of the experimental observations reported herein, we must conclude that taurine apparently does not function as a neurotransmitter in the hypothalamus. Two uptake systems were found in the P2 fraction, a high affinity uptake system and a low affinity uptake system. Uptake systems for taurine have previously been reported in glial and nerve cell homogenates, and therefore, because of the known contamination of crude synaptosomal preparations with glial particles, we sought to determine the cellular origin of the two taurine uptake systems in our crude preparation. Using a variety of diverse biochemical techniques such as hypo-osmotic shock, release experiments and Arrhenius plots, we determined that physical changes of the media or depolarizing stimuli which would influence neuronal and glial cell particles differently, also had differing effects on high and low affinity taurine uptake or its release from the respective uptake compartments. We conclude that the high affinity taurine uptake system/compartment is located on/in neuronal membranes/particles/particles and that the low affinity taurine uptake system/compartment is located on/in neuronal membranes/particles and that model for the differential cellular transport and compartmentalization of taurine into neuronal and glial cells has important implications concerning its possible role in the CNS.

Taurine and GABA release from mouse cerebral cortex slices: effects of structural analogues and drugs

The effects of structural analogues, excitatory amino acids and certain drugs on spontaneous and potassium-stimulated exogenous taurine and GABA release were investigated in mouse cerebral cortex slices using a superfusion system. Spontaneous efflux of both amino acids was rather slow but could be enhanced by their uptake inhibitors. Taurine efflux was facilitated by exogenous taurine, hypotaurine, beta-alanine and GABA, whereas GABA, nipecotic acid and homotaurine effectively enhanced GABA release. The stimulatory potency of the analogues closely corresponded to their ability to inhibit taurine and GABA uptake, respectively, indicating that these efflux processes could be mediated by the carriers operating outwards. Glutamate induced GABA release, whereas taurine efflux was potentiated by aspartate, glutamate, cysteate, homocysteate and kainate. The centrally acting drugs, including GABA agonists and antagonists, as well as the proposed taurine antagonist TAG (6-aminomethyl-3-methyl-4H-1,2,4-benzothiadiazine-1,1-dioxide), had no marked effects on spontaneous taurine and GABA release. Potassium ions stimulated dose-dependently both taurine and GABA release from the slices, the responses of taurine being strikingly slow but sustained. Exogenous GABA and nipecotic acid accelerated the potassium-stimulated GABA release, whereas picrotoxin and bicuculline were ineffective. The potassium-stimulated taurine release was unaltered or suppressed by exogenous taurine and analogues, differing in this respect from GABA release. The apparent magnitude of the depolarization-induced GABA release is thus influenced by the function of membrane transport sites, but the same conclusion cannot be drawn with regard to taurine. Haloperidol and imipramine were able to affect the evoked release of both taurine and GABA.

Taurine in hippocampus: localization and postsynaptic action

Both immunocytochemical and electrophysiological methods have been employed to determine whether the localization of the taurine synthetic enzyme, cysteine sulfinic acid decarboxylase, (CSAD) and the postsynaptic action of taurine in the CA1 region of rat hippocampus are consistent with the hypothesis that taurine may be used as a neurotransmitter by some hippocampal neurons. At the light microscopic level, CSAD-immunoreactivity (CSAD-IR) was found in the pyramidal basket cells, and around pyramidal cells in stratum pyramidale and stratum radiatum. At the electron microscopic level, CSAD-IR was seen most often in the soma and the dendrites and was rather infrequent in the axon or the nerve terminals. Electrophysiological observations on the in vitro hippocampal slice demonstrated that pyramidal neurons respond to artificially applied taurine with inhibition that depended in large part upon an increased chloride conductance. Although electrophysiological observations are consistent with a neurotransmitter role for taurine, results from immunocytochemical studies suggest a minor role for taurine as a neurotransmitter. In fact, immunocytochemical observations suggested that taurine may be used as a neurotransmitter only by a small number of pyramidal basket interneurons, the vast majority of CSAD-positive neurons may use taurine for other functions.

Mutual interactions in the transport of taurine, hypotaurine, and GABA in brain slices

The mutual interactions and the effects of GABA on the saturable transport components of taurine and hypotaurine were investigated with mouse brain slices. The low-affinity taurine transport was competitively inhibited by both hypotaurine and GABA. Hypotaurine did not alter the kinetic parameters of high-affinity taurine uptake, whereas there occurred some stimulation with GABA, possibly by heteroexchange. Taurine had no significant effects on high-affinity hypotaurine uptake, whereas the low-affinity component was reduced by both taurine and GABA, GABA strongly interfered with the high-affinity hypotaurine uptake, being the preferred substrate in simultaneous uptake experiments. The results confirm that taurine, hypotaurine, and GABA are transported into brain slices by only one two-component system with affinities highest for GABA and lowest for taurine.

Hypotaurine transport in mouse brain synaptosomal preparations

The transport of hypotaurine, the precursor of the probable neuromodulator taurine, was investigated using mouse brain synaptosomal preparations. Hypotaurine uptake was concentrative, energy- and sodium-dependent and strongly inhibited by GABA, L-DABA (L-2,4-diaminobutyric acid) and beta-alanine, suggesting interactions with GABA uptake systems. The uptake consisted of only one saturable transport component both in adult and in 6-day-old brain, being more efficient in the latter.

beta-Alanine uptake by mouse brain slices

beta-[3H]Alanine uptake by mouse brain slices was studied in Krebs-Ringer-HEPES-glucose medium (pH 7.4) under O2. The uptake was temperature-sensitive and consisted of two saturable transport components, high- and low-affinity, with kinetic parameters comparable to those of amino acid neurotransmitter candidates. beta-Alanine uptake was strictly sodium-dependent and also inhibited by the omission of potassium and presence of ouabain, suggesting that the transport is mainly fuelled by cation gradients. Sodium ions showed positive cooperative effects in beta-alanine uptake, indicating the association of at least two sodium ions in the transfer of one molecule of beta-alanine. The uptake was strongly inhibited by gamma-aminobutyrate and hypotaurine, the high-affinity uptake component completely disappearing in the presence of hypotaurine. Taurine had no measurable effect. The results suggest that the high-affinity transports of beta-alanine and hypotaurine may be mediated by the same system.