Release of Endogenous Taurine and γ-Aminobutyric Acid from Brain Slices from the Adult and Developing Mouse

The spontaneous and potassium-stimulated release of endogenous taurine and gamma-aminobutyric acid (GABA) from cerebral cortex and cerebellum slices from adult and developing mice was studied in a superfusion system. The spontaneous release of GABA was of the same magnitude in slices from adult and developing mice, but the spontaneous release of taurine was considerably greater in the adults. The potassium-stimulated release of GABA from cerebral cortex slices was about five times greater in adult than in 3-day-old mice, but the potassium-stimulated release of taurine was more than six times greater in 3-day-old than in adult mice. In cerebellar slices from 7-day-old mice, potassium stimulation also evoked a massive release of taurine, whereas the evoked release from slices from adult mice was rather negligible. Also in cerebellar slices the potassium-stimulated release of GABA exhibited the opposite quantitative pattern. The stimulated release of both GABA and taurine was partially calcium dependent. The results suggest that taurine may be an important regulator of excitability in the developing brain.     

Taurine as a Modulator of Excitatory and Inhibitory Neurotransmission

We present data that summarize our findings on the role of taurine in the central nervous system and in particular taurine's interaction with the inhibitory and excitatory systems. In taurine-fed mice, the expression level of glutamic acid decarboxylase (GAD), the enzyme responsible for GABA synthesis, is elevated. Increased expression of GAD was accompanied by increased levels of GABA. We also found in vitro, that taurine regulates neuronal calcium homeostasis and calcium-dependent processes, such as protein kinase C (PKC) activity. This calcium-dependent kinase was regulated by taurine, whereas the activity of protein kinase A (PKA), a cAMP-dependent, calcium-independent kinase, was not affected. Furthermore, as a consequence of calcium regulation, taurine counteracted glutamate-induced mitochondrial damage and cell death.     

Cardiac and skeletal muscle abnormality in taurine transporter-knockout mice

Taurine, a sulfur-containing β-amino acid, is highly contained in heart and skeletal muscle. Taurine has a variety of biological actions, such as ion movement, calcium handling and cytoprotection in the cardiac and skeletal muscles. Meanwhile, taurine deficiency leads various pathologies, including dilated cardiomyopathy, in cat and fox. However, the essential role of taurine depletion on pathogenesis has not been fully clarified. To address the physiological role of taurine in mammalian tissues, taurine transporter-(TauT-) knockout models were recently generated. TauTKO mice exhibited loss of body weight, abnormal cardiac function and the reduced exercise capacity with tissue taurine depletion. In this chapter, we summarize pathological profile and histological feature of heart and skeletal muscle in TauTKO mice.     

Effects of ATP and Taurine on Calcium Uptake by Membrane Preparations of the Rat Retina

Abstract: The effects of ATP and taurine on the kinetics of calcium uptake in rat retinal membrane preparations were determined. ATP increased calcium uptake at low calcium ion concentrations. Addition of ATP plus taurine further increased calcium uptake. Cooperative relationships were observed for calcium uptake in the absence of ATP and taurine. In the presence of phosphate ions reciprocal plots demonstrated upward deflections from linear ty, while in the absence of phosphate ions downward deflections were noted. Addition of ATP plus taurine to the incubation system appeared to obliterate the cooperativity. Two uptake systems for calcium were observed.     

The Role of Taurine in the Central Nervous System and the Modulation of Intracellular Calcium Homeostasis

The effects of taurine in the mammalian nervous system are numerous and varied. There has been great difficulty in determining the specific targets of taurine action. The authors present a review of accepted taurine action and highlight recent discoveries regarding taurine and calcium homeostasis in neurons. In general there is a consensus that taurine is a powerful agent in regulating and reducing the intracellular calcium levels in neurons. After prolonged L-glutamate stimulation, neurons lose the ability to effectively regulate intracellular calcium. This condition can lead to acute swelling and lysis of the cell, or culminate in apoptosis. Under these conditions, significant amounts of taurine (mM range) are released from the excited neuron. This extracellular taurine acts to slow the influx of calcium into the cytosol through both transmembrane ion transporters and intracellular storage pools. Two specific targets of taurine action are discussed: Na⁺-Ca²⁺ exchangers, and metabotropic receptors mediating phospholipase-C.     

Taurine's possible protective role in age-dependent response to calcium paradox

When hearts were reperfused with Ca++ after a short period of Ca++-free perfusion, irreversible loss of electrical and mechanical activity was observed. This phenomenon, first described by Zimmerman and Hulsmann, was termed the "calcium paradox". Chizzonite and Zak recently reported that rat hearts exhibited an age-dependent response in a calcium paradox model. The taurine (2-aminoethanesulfonic acid) content of hearts in the newborn animal is high, and decreases rapidly during the first few days of life. The present experiments were performed to test whether the myocardial taurine content was closely linked to an age-dependent response in the calcium paradox model, using post-hatched chicks. The mechanical dysfunction of the heart was much more severe in 9-day-old post-hatched chicks than in 2-day-old chicks when the hearts were subjected to the calcium paradox. Myocardial taurine content was lower in the 9-day-old chicks than in the 2-day-old chicks. The age-related response to the calcium paradox was partially protected by oral pretreatment with taurine, and there was a small increase in myocardial taurine level. It is proposed that myocardial taurine is one factor in the protection against the calcium paradox phenomenon.     

Regulation of calcium transport in drug-induced taurine-depleted hearts

Drug-induced taurine depletion of rat heart led to the accumulation of free CoA, free carnitine and long-chain acylcarnitine, but a small decrease in long-chain fatty acyl-CoA. Although elevations in total tissue long-chain acylcarnitine levels have been linked to defective membrane function and the association of long-chain acylcarnitines with extramitochondrial membranes, these effects were absent in isolated sarcoplasmic reticulum prepared from taurine-depleted hearts. In contrast to the sarcoplasmic reticulum data, taurine depletion was associated with a significant decrease in ATP-dependent calcium uptake by isolated sarcolemmal vesicles. The major effect of taurine depletion on the sarcolemma was a 2-fold decrease in both the Vmax of calcium transport and the activity of the Ca2+ -stimulated ATPase. Sarcolemmal vesicles prepared from taurine-depleted hearts also exhibited a decreased capacity to transport calcium in exchange for sodium, although the initial rate of the process was unaffected by taurine depletion. Since incubation of sarcolemma from taurine-depleted hearts with taurine could not overcome the effects of taurine depletion, it was concluded that the effects of taurine were not caused by a direct interaction of it with the calcium pump. Possible mechanisms of taurine action are discussed.     

牛磺酸对乳鼠心肌细胞内钙浓度的影响

研究低氧、复氧对乳鼠心肌细胞内钙离子浓度的影响,以及牛磺酸在模拟心肌缺血/再灌注(I/R)过程中对细胞内钙的调节作用。采用SD大鼠乳鼠进行心肌细胞培养,建立模拟I/R模型。以Fluo-4/AM荧光指示剂负载,应用激光共聚焦显微镜技术(confocal laser scanning microscope,CLSM)检测心肌细胞钙离子浓度的变化。对照组心肌细胞内钙离子荧光强度(23.71±2.37U)较低;低氧180 min后复氧即刻,钙离子荧光强度开始增加(57.52±8.31U),复氧180 min后钙离子荧光强度(71.13±4.74U)显著增高(P<0.01vs对照组)。而牛磺酸组细胞内钙离子荧光强度较模拟I/R组显著降低[(42.42±4.17U)vs(71.13±4.74U),P<0.01]。心肌细胞缺血/缺氧导致Ca2+超载;模拟I/R Ca2+超载加剧,而牛磺酸有明显减轻心肌细胞模拟I/R时Ca2+超载的作用。     

Taurine-Induced Regeneration of Goldfish Retina in Culture May Involve a Calcium-Mediated Mechanism

Abstract: A possible mechanism of action of taurine as a trophic substance was studied in goldfish retina by investigating the effect of extracellular and intracellular calcium chelators on in vitro outgrowth, and the effect of taurine on calcium influx into postcrush retinal cells in culture. The amino acid stimulated the outgrowth from goldfish retinal explants, an effect that was blocked by EGTA and 1,2-bis ( o aminophenoxy)ethane- N,N,N',N' -tetraacetic acid methyl ester (BAPTA). The influx of calcium into cultured cells from postcrush retina was increased by taurine by day 5 in culture, but not by day 10, supporting previous results indicating a critical period in which taurine stimulates out-growth. The present results suggest that taurine partially exerts its regenerative effect on postcrush retinal explants by increasing calcium influx.     

Modulation of Calcium Channels by Taurine Acting Via a Metabotropic-like Glycine Receptor

Taurine is one of the most abundant free amino acids in the central nervous system, where it displays several functions. However, its molecular targets remain unknown. It is well known that taurine can activate GABA-A and strychnine-sensitive glycine receptors, which increases a chloride conductance. In this study, we describe that acute application of taurine induces a dose-dependent inhibition of voltage-dependent calcium channels in chromaffin cells from bovine adrenal medullae. This taurine effect was not explained by the activation of either GABA-A, GABA-B or strychnine-sensitive glycine receptors. Interestingly, glycine mimicked the modulatory action exerted by taurine on calcium channels, although the acute application of glycine did not elicit any ionic current in these cells. Additionally, the modulation of calcium channels exerted by both taurine and glycine was prevented by the intracellular dialysis of GDP-β-S. Thus, the modulation of voltage-dependent calcium channels by taurine seems to be mediated by a metabotropic-like glycinergic receptor coupled to G-protein activation in a membrane delimited pathway.     

13C nuclear magnetic resonance study of the complexation of calcium by taurine

¹³C Nuclear magnetic resonance chemical shifts, ¹J_C-C scalar coupling constants, spin-lattice relaxation times, and nuclear Overhauser effects were determined for taurine-[1, 2 ¹³C] and a taurine-[1 ¹³C] and taurine-[2 ¹³C] mixture in the presence and absence of calcium. Ionization constants for taurine amino and sulfonic acid groups and chemical shifts of N-methylene and S-methylene carbons of the taurine cation, zwitterion, and anion were obtained from simultaneous least squares analysis of ¹³C titration curves of both taurine carbons. Comparison of taurine titration shifts to values for related compounds reveals some unusual electronic properties of the taurine molecule. Stability constants of 1:1 calcium complexes with taurine zwitterions and anions, as well as their ¹³C chemical shifts, were obtained by least squares analysis of titration curves measured in the presence of calcium. The stability constants of calcium-taurine complexes were significantly lower than previous values and led to estimates that only approximately one percent of intracellular calcium of mammalian myocardial cells would exist in a taurine complex. The implications of these results with respect to the effect of taurine on calcium ion flux are discussed.     

Taurine increases mitochondrial buffering of calcium: role in neuroprotection

Summary. We have determined the role of mitochondria in the sequestration of calcium after stimulation of cerebellar granule cells with glutamate. In addition we have evaluated the neuroprotective role of taurine in excitotoxic cell death. Mitochondrial inhibitors were used to determine the calcium buffering capacity of mitochondria, as well as how taurine regulates the ability of mitochondria to buffer intracellular calcium during glutamate depolarization and excitotoxicity. We report here that pre-treatment of cerebellar granule cells with taurine (1 mM, 24 h) significantly counteracted glutamate excitotoxicity. The neuroprotective role of taurine was mediated through regulation of cytoplasmic free calcium ([Ca²⁺] _i ), and intra-mitochondrial calcium homeostasis, as determined by fluo-3 and ⁴⁵Ca²⁺-uptake. Furthermore, the overall mitochondrial function was increased in the presence of taurine, as assessed by rhodamine accumulation into mitochondria and total cellular ATP levels. We specifically tested the hypothesis that taurine reduces glutamate excitotoxicity through both the enhancement of mitochondrial function and the regulation of intracellular (cytoplasmic and intra-mitochondrial) calcium homeostasis. The role of taurine in modulating mitochondrial calcium homeostasis could be of particular importance under pathological conditions that are characterized by excessive calcium overloads. Taurine may serve as an endogenous neuroprotective molecule against brain insults. Authors’ address: Abdeslem El Idrissi, Biology Department and Center for Developmental Neuroscience, College of Staten Island/CUNY, 6S-134 Staten Island, NY 10314, U.S.A.     

Taurine enhancement of calcium binding to rat heart sarcolemma.

The effect of taurine on calcium binding to isolated rat heart sarcolemmal membrane was examined. Taurine was observed to increase calcium binding to the low affinity sites in both high sodium-low potassium and low sodium-high potassium buffers. Taurine was also seen to antagonize the inhibition of calcium binding to the sarcolemma caused by both verapamil and lanthanum. Nevertheless, membrane structural changes due to taurine could not be detected using the spin label ESR probe 2N14. A possible regulatory role of taurine is discussed.     

Specific timing of taurine supplementation affects learning ability in mice

The effects of taurine supplementation on visual discrimination in mice were examined. Taurine, 2-aminoethane-sulphonic acid, found in high concentrations in the central nervous system of mammals and in human milk, has been shown to be essential for development. Male mice were divided into four groups according to taurine supplementation periods. 1) Lifelong: taurine (400 mg/kg/day) was dissolved in distilled water and provided as drinking water. In the prenatal period, taurine was given via the mother. After weaning mice were administered taurine in drinking water. 2) Pre-weaning: mice were exposed to taurine prior to weaning, 3) Post-weaning: mice were exposed to taurine after weaning. 4) Control: no supplementation of taurine. It was shown that the Lifelong group required a longer period of time to acquire visual discrimination than the Control group. Conversely, in the Post-weaning group, mice learned the task faster than Controls. Visual discrimination learning time in the Pre-weaning group showed no significant difference compared with that in the Control group. From these results, we suggest that the perinatal to early postnatal period is a “sensitive period” where taurine supplementation can result in retardation of learning in later life. At the same time, taurine supplementation after weaning improved visual discrimination learning. Thus, timing of taurine supplementation affected learning.     

Taurine deficiency,synthesis and transport in the mdx mouse model for Duchenne Muscular Dystrophy

The amino acid taurine is essential for the function of skeletal muscle and administration is proposed as a treatment for Duchenne Muscular Dystrophy (DMD). Taurine homeostasis is dependent on multiple processes including absorption of taurine from food, endogenous synthesis from cysteine and reabsorption in the kidney. This study investigates the cause of reported taurine deficiency in the dystrophic mdx mouse model of DMD. Levels of metabolites (taurine, cysteine, cysteine sulfinate and hypotaurine) and proteins (taurine transporter [TauT], cysteine deoxygenase and cysteine sulfinate dehydrogenase) were quantified in juvenile control C57 and dystrophic mdx mice aged 18 days, 4 and 6 weeks. In C57 mice, taurine content was much higher in both liver and plasma at 18 days, and both cysteine and cysteine deoxygenase were increased. As taurine levels decreased in maturing C57 mice, there was increased transport (reabsorption) of taurine in the kidney and muscle. In mdx mice, taurine and cysteine levels were much lower in liver and plasma at 18 days, and in muscle cysteine was low at 18 days, whereas taurine was lower at 4: these changes were associated with perturbations in taurine transport in liver, kidney and muscle and altered metabolism in liver and kidney. These data suggest that the maintenance of adequate body taurine relies on sufficient dietary intake of taurine and cysteine availability and metabolism, as well as retention of taurine by the kidney. This research indicates dystrophin deficiency not only perturbs taurine metabolism in the muscle but also affects taurine metabolism in the liver and kidney, and supports targeting cysteine and taurine deficiency as a potential therapy for DMD.     

Effect of taurine on Ca, Mg-ATPase activity in human platelets and on their aggregation

Effect of taurine (25 mM) on calcium metabolism in human platelets was studied. Ca, Mg-ATPase activity is significantly increased upon addition of 25 mM of taurine to the incubation medium. The activation is absent or reduced in the presence of trifluoroperazine and beta-alanine and after preincubation of platelets with colchicine and verapamil. The rate of ADP (3.5 X 10(-6) M)-induced platelet aggregation is reduced by half upon taurine addition to platelet-rich plasma. The possible role of taurine in intracellular calcium translocation and the following alteration of platelet activity is suggested.     

Taurine transport rates between plasma and tissues in adult and 7-day-old mice.

Transport rates for taurine from plasma to liver, kidney, heart, spleen and femoral muscle were evaluated in adult and 7-day-old mice in vivo. The mice were injected with [35S]taurine and the specific radioactivity of taurine was determined in the above tissues at varying intervals from 10 min up to 48 hr after the injection. A multicompartment model was fitted to the data and the transport rates with their confidence limits were estimated using a digital computer. The tissue-plasma exchange rate was generally faster in adult mice than in 7-day-old mice. The transport rates between the plasma and the brain or muscle were low, while taurine penetrated into the liver and kidneys very rapidly. There was no distinct correlation between the calculated transport rates and the tissue taurine concentrations. The metabolic breakdown of taurine in the tissues was slow, since only negligible amounts of radioactivity were recovered in the metabolites of taurine, isethionic acid and inorganic sulphate. It seems unlikely that either the magnitudes of the transport rates between the plasma and the tissues or taurine breakdown rates in situ act as the primary factor determining the taurine levels in tissues.     

Taurine and Skeletal Muscle Disorders

Taurine is abundantly present in skeletal muscle. We give evidence that this amino acid exerts both short-term and long-term actions in the control of ion channel function and calcium homeostasis in striated fibers. Short-term actions can be estimated as the ability of this amino acid to acutely modulate both ion channel gating and the function of the structures involved in calcium handling. Long-term effects can be disclosed in situations of tissue taurine depletion and are likely related to the ability of the intracellular taurine to control transducing pathways as well as homeostatic and osmotic equilibrium in the tissue. The two activities are strictly linked because the intracellular level of taurine modulates the sensitivity of skeletal muscle to the exogenous application of taurine. Myopathies in which ion channels are directly or indirectly involved, as well as inherited or acquired pathologies characterized by metabolic alterations and change in calcium homeostasis, are often correlated with change in muscle taurine concentration and consequently with an enhanced therapeutic activity of this amino acid. We discuss both in vivo and in vitro evidence that taurine, through its ability to control sarcolemmal excitability and muscle contractility, can prove beneficial effects in many muscle dysfunctions.     

Effect of taurine on passive ion transport in rat brain synaptosomes.

Taurine, in concentrations greater than 10 mM, was found to have an inhibitory effect on passive calcium uptake and release in rat brain synaptosomal preparations. Amino acids similar to that of taurine in chemical structure, β-alanine, hypotaurine, homotaurine and γ-amino-butyric acid were also shown to inhibit calcium uptake in this preparation. Taurine, though, did not alter the permeability of these preparations to sodium or potassium. It thus appears that taurine and chemically related amino acids can alter calcium movements in these preparations. It is postulated that this effect is due to binding to specific taurine sites in the synaptosomal membranes.     

Increased taurine excretion in hereditary hyperprolinemia of the mouse

The concentration of taurine in fresh urine samples of hyperprolinemic PRO/Re mice taken daily for five days was about 18.0 μmoles per ml urine compared to 3.2 for CBA/J mice. The concentration of taurine in plasma of PRO/Re mice was not elevated compared to CBA/J or C57BL/6J mice. When CBA/J mice are treated with proline the concentration of taurine in the urine increased.