Journal List > Nutr Res Pract > v.7(1) > 1051291

Choi, Yoo, Shin, and Chung: Effects of taurine on cadmium exposure in muscle, gill, and bone tissues of Carassius auratus

Abstract

This study was performed in order to investigate the effects of taurine on cadmium poisoning in muscle, gill, and bone tissues of wild goldfish. For this experiment, 80 wild goldfish were divided into four experimental groups: 0.3 mg/L of cadmium and 0 mg/L of taurine (Group I), 0.3 mg/L of cadmium and 20 mg/kg of taurine (Group II), 0.3 mg/L of cadmium and 40 mg/L of taurine (Group III), and 0.3 mg/L of cadmium and 80 mg/L of taurine (Group IV). The results were as follows: The cadmium concentration in muscle tissue of wild goldfish was 0.65-3.21 mg/kg wet wt in Group I, whereas it decreased in Group IV. Levels of cadmium in gill tissue of wild goldfish were 16.57-42.39 mg/kg wet wt in Group I, 15.23-43.01 mg/kg wet wt in Group II, 15.11-39.56 mg/kg wet wt in Group III, and 13.15-38.55 mg/kg wet wt in Group IV (P < 0.05), suggesting that the cadmium concentration decreased in the experimental groups compared to control. The cadmium concentration in bone tissue of wild goldfish after 28 days was 0.52-9.75 mg/kg in Group II, whereas it increased in Group III (P < 0.05). In conclusion, taurine may have a preventive effect against cadmium accumulation in biological tissues.

Introduction

Cadmium is a metal widely used in electric plating, plastic stabilizers, batteries, etc. However, widespread application of cadmium has resulted in pollution of water, air, and soil, along with increased accumulation in livestock, fish, and shellfish. Cadmium accumulated in drinking water and air eventually accumulates in the body, causing a number of diseases such as hypertension, osteomalacia, gastric dysfunction, CNS dysfunction, and endocrine disorders [1-6].
Taurine is a β-amino acid in which the carboxyl group on the α-carbon is substituted for sulfonic acid, and it exists as a free amino acid in animal tissues and biological fluids. Biosynthesis of taurine is achieved by the process in which cysteine is converted into cysteine sulfinate by cysteine deoxygenase, followed by hypotaurine and cysteric acid formation by decarboxylase and oxidase. In a previous experiment, the concentrations of GABA (gamma-aminobutyric acid) and taurine were measured in the hypothalamus, median eminence, striatum, and prefrontal cortex of mice following cadmium exposure. The authors observed decreased GABA levels in every area of the brain except the striatum, and similar levels of taurine were measured in all areas except the mediobasal hypothalamus and striatum [7].
Taurine is a sulfur-containing amino acid that combines with bile acid in the liver. It has been reported to have a chemical structure similar to that of acetylcysteine with heavy-metal detoxifying effects. In a study on the effects of ascorbic acid, garlic extract, and taurine on cadmium chelation in catfish, the cadmium concentration significantly decreased [8,9].
Therefore, in this study, we investigated the effects of taurine on cadmium accumulation in muscle, gill, and bone tissues of exposed wild goldfish.

Materials and Methods

Experimental design

Carassius auratus, or wild goldfish, was captured in Kyungchun reservoir located in Wanju-gun, Jeollabuk-do. After 15 days in the laboratory, healthy-looking fish with a size of 51-62 mm and weight of 4.2-9.2 g were selected. Cadmium chloride (CaCl2.H2C), ammonium citrate, nitric acid, ammonium sulfate, hydrochloric acid, ammonium hydroxide sodium dimethyl dithiocarbamate, and methyl isobuthyl ketone were of analytical grade (Sigma Co, USA). Taurine was obtained from DongA Pharmaceutical Co.

Feeding conditions and analysis

The size of the water reservoir was 60 × 30 × 30 cm, and pH, dissolved oxygen (DO), and water temperature levels were maintained at 7.0 ± 0.3, 7.3 ± 1.5 mg/L, and 17-21℃, respectively. Fish were maintained at room temperature. Cadmium chloride (CaCl2.H2C) was added to the water reservoir at a concentration of 0.3 mg/kg, whereas taurine (Donga Pharm.) was added at concentrations of 0 mg/kg, 20 mg/kg, 40 mg/kg, and 80 mg/kg for groups I-IV, respectively. During the experiment, test groups were fed tetas bits (Tetra Germany) twice a day at the same amount. Glass plasticware that were used in storage of samples and analysis for Cd were cleansed in 3.2 N nitric acid (for 24 h) and rinsed at least five times with distilled deionizd water. For analyses of diets and tissues, samples were placed in Erlenmeyer flasks and 2-4 ml of 12 N nitric acid was added. Samples were digested (100℃) and then evaporated and diluted with distilled deionized water to appropriate volumes. Cd was determined by from atomic absorption spectrophotometry (Varian spectro AA-30, at wave length 228.8 nm).

Statistical analysis

Statistical analyses were performed using SPSS (Ver. 18.0), and Duncan's multiple-range tests were used to examine differences among each experimental group (P < 0.05).

Results

Cadmium contents in musele, gill, and bone without taurine

In our study, cadmium levels in wild goldfish were 0.02 ± 0.02 mg/kg in muscle, 0.15 ± 0.05 mg/kg in gill, and 0.05 ± 0.02 mg/kg in bone tissues (Table 1). In group I, the cadmium concentrations in muscle were 0.65 ± 0.11 mg/kg in the 7-day treatment group and 3.21 ± 0.27 mg/kg in the 28-day treatment group. In gill, cadmium concentrations were 16.57 ± 2.72 mg/kg in the 7-day treatment group and 27.15 ± 3.11 mg/kg in the 28-day treatment group. In bone, cadmium concentrations were 1.97 ± 0.16 mg/kg in the 14-day treatment group and 9.86 ± 2.16 mg/kg in the 28-day treatment group. These results show increased cadmium accumulation in tissues in proportion to the period of cadmium exposure (P < 0.05).

Cadmium contents in musele, gill, and bone fed 20 mg/L taurine

In group II, the cadmium concentration in muscle was 0.51 ± 0.05 mg/kg in the 7-day treatment group, which is a decrease compared to that of group I over the same treatment period. However, in the 21-day treatment group, no significant difference in cadmium concentration was observed between the taurine and non-treated groups (2.09 ± 0.41 mg/kg in taurine group and 2.08 ± 0.26 mg/kg in non-treated group) (Table 2). In gill, cadmium concentrations were 24.69 ± 6.15 mg/kg in the 14-day treatment group and 43.01 ± 3.16 mg/kg in the 28-day treatment group, which were particularly remarkable compared to other organs. The cadmium concentration in bone was not significant until after week 1, whereas a rapid increase was observed from 3 weeks (P < 0.05).

Cadmium contents in musele, gill, and bone fed 40 mg/L taurine

In group III, the cadmium concentration in muscle was 0.49 ± 0.12 mg/kg in the 7-day treatment group, which was slightly lower than that of group II. On the other hand, the cadmium level in muscle was 2.11 ± 0.35 mg/kg in the 21-day treatment group, which was slightly higher than that of group II (P < 0.05) (Table 3). In gill, cadmium concentrations were 15.11 ± 1.97 mg/kg and 39.56 ± 5.37 mg/kg in the 7- and 28-day treatment groups, respectively (P < 0.05). This result demonstrates increased cadmium levels in gill tissue in proportion to exposure time.

Cadmium contents in musele, gill, and bone fed 80 mg/L taurine

In group IV, cadmium levels in muscle were 0.51 ± 0.11 mg/kg, 0.55 ± 0.17 mg/kg, 1.85 ± 0.21 mg/kg, and 2.89 ± 0.33 mg/kg in the 7-, 14-, 21-, and 28-day treatment groups, respectively (Table 4). The cadmium concentration in gill was 16.57 ± 2.72 mg/kg in the non-treated group, whereas it slightly decreased to 15.23 ± 3.51 mg/kg, 15.11 ± 1.97 mg/kg, and 13.15 ± 2.09 mg/kg in groups II-IV, respectively, with increasing taurine concentration. However, there was no statistically significant difference between the groups (P < 0.05).

Discussion

In recent times, there has been an increase in pollutants in river and coastal waters with the development of industry. Emission of heavy metals contaminates water and plankton populations, which are the main feed for fish. As a result, heavy metals in fish and shells progress through the food chain, accumulating in the human body and causing various diseases. Cadmium is absorbed mainly through the respiratory and digestive systems, and target organs have been reported to be the lung and kidney. Further, it has been reported that cadmium may cause lung cancer and kidney dysfunction [10,11]. In particular, fish may partially absorb heavy metals through the skin, but most heavy metals are absorbed through the gills, resulting in respiratory organ damage. It was reported that absorbed heavy metals interact with the base and phosphate groups of nucleic acids, resulting in nuclear dysfunction and cancer [12]. Moreover, it has been reported that taurine alters the phospholipid and fatty acid contents of the liver, thereby affecting lipid metabolism and reducing the level of cholesterol in the blood. It has also been shown that taurine alters the lipid content of the liver as well as inhibits changes in fatty acid composition induced by ingestion of cholesterol [13]. Taurine is known to impact the development of tissues and organs in animal cells, and it was shown that taurine deficiency increases the probability of stillborn or aborted fetuses. Especially, taurine is closely related to brain function as it is present in the central nervous system [14]. Taurine is a sulfur-containing amino acid abundant in animal tissues. It is known that taurine is synthesized from cysteine intermediates in the liver [15]. It has been shown that protein excretion is higher with an abundance of cysteine, as a higher amount of metallothionein-Cd in the renal tubules decreases adsorption of metallothionein-Cd in the blood [10]. In addition, taurine is abundant in the skeletal muscle, pituitary gland, and retina, and mediates various physiological functions such as calcium metabolism, facilitation of glucose metabolism, and stabilization of cell membranes.
Taurine is a sulfur-containing β-amino acid synthesized in the liver from methionine and cysteine and has been reported to mediate neural regulation, cell membrane stabilization, and osmotic pressure control [16]. Cadmium exists in two forms in vivo, metallothionein-Cd and non-metallothionein-Cd, the former of which is minimally toxic due to the stability of cadmium, unless decomposed. On the other hand, non-metallothionein-Cd is reportedly very toxic [17]. Fish commonly used in experiments on heavy metal exposure or toxicity include minnow, crucian carp, carp, goldfish, and loach [18]. Taurine has further been reported to be an effective therapy for chronic dysfunction of cadmium-exposed mice. In other words, taurine affects a number of enzymes in tissues exposed to cadmium, including superoxide dismutase, catalase, glutathione-S-transferase, glutathione reductase, and glutathione superoxide [19]. Taurine is excreted via urine or bile contained in bile acid, and amount of injection affects biosynthesis of taurine in vivo, to increase the activity of cholesterol 7a-hydroxylase and LDL receptor, facilitating cholesterol metabolism in the liver [20]. The interaction between taurine and metal is an electrical interaction between the sulfonate ion of taurine and metal cations. Further, the metal and chelation product is reported to be protective against metal-induced toxicity [21]. Especially, taurine plays an important role in estrogen deficiency, which inhibits reduction of bone mass after menopause [22]. A previous study examined the effects of ascorbic acid, garlic extract, and taurine on oxidative stress induced by cadmium by measuring cadmium levels in the kidney and liver of catfish. The results showed that cadmium levels in the liver and kidney of catfish significantly increased upon exposure to cadmium. However, the levels of cadmium in organs decreased upon treatment with ascorbic acid, garlic extract, and taurine [9]. In a report that examined the effect of taurine treatment on oxidative stress induced by cadmium in the liver, rats were exposed to cadmium chloride and their organ weights measured. The results showed that cadmium levels rapidly increased in the liver, whereas liver organ weights decreased. However, it was found that ingestion of taurine reversed the liver damage in rats induced by cadmium [23]. Thus, taurine is effective for the detoxification of cadmium. In this study, carp were treated with different concentrations of taurine (0 mg/kg, 20 mg/kg, 40 mg/kg, and 80 mg/kg) after exposure to cadmium, followed by measurement of cadmium levels in various tissues. According to our results, as the concentration of taurine increased, cadmium levels decreased in muscle, gill, and bone tissues of carp.

Figures and Tables

Table 1
Contents of cadmium of wild goldfish muscle, gill and bone exposed cadmium, 0.3 mg/L and treated without taurine (unit : mg/kg)
nrp-7-22-i001

Values are the mean ± SD.

*P < 0.05

Table 2
Contents of cadmium of wild goldfish muscle, gill and bone exposed cadmium, 0.3 mg/L and treated with 20 mg/L taurine (unit : mg/kg)
nrp-7-22-i002

Values are the mean ± SD.

*P < 0.05

Table 3
Contents of cadmium of wild goldfish muscle, gill and bone exposed cadmium, 0.3 mg/L and treated with 40 mg/L taurine (unit : mg/kg)
nrp-7-22-i003

Values are the mean ± SD.

*P < 0.05

Table 4
Contents of cadmium of wild goldfish muscle, gill and bone exposed cadmium, 0.3 mg/L and treated with 80 mg/L taurine (unit : mg/kg)
nrp-7-22-i004

Values are the mean ± SD.

*P < 0.05

Notes

This paper was supported by the Sahmyook University Research Fund in 2010.

References

1. Cherian MG, Nordberg M. Cellular adaptation in metal toxicology and metallothionein. Toxicology. 1983. 28:1–15.
crossref
2. Eaton DL, Toal BF. Evaluation of the Cd/hemoglobin affinity assay for the rapid determination of metallothionein in biological tissues. Toxicol Appl Pharmacol. 1982. 66:134–142.
crossref
3. Kagi JH, Vallee BL. Metallothionein: a cadmium and zinc-containign protein from equine renal cortex. II. Physico-chemical properties. J Biol Chem. 1961. 236:2435–2442.
4. Kotsonis FN, Klaassen CD. Toxicity and distribution of cadmium administered to rats at sublethal doses. Toxicol Appl Pharmacol. 1977. 41:667–680.
crossref
5. Park TS. Taurine: its physiological roles and nutritional significance. Korean J Nutr. 2001. 34:597–607.
6. Ahn CS. Effects of taurine supplementation on serum lipidperoxide levels in middle-aged women. Korean J Food Nutr. 2007. 20:440–449.
7. Esquifino AI, Seara R, Fernández-Rey E, Lafuente A. Alternate cadmium exposure differentially affects the content of gamma-aminobutyric acid (GABA) and taurine within the hypothalamus, median eminence, striatum and prefrontal cortex of male rats. Arch Toxicol. 2001. 75:127–133.
crossref
8. Hwang DF, Wang LC. Effect of taurine on toxicity of cadmium in rats. Toxicology. 2001. 167:173–180.
crossref
9. Kumar P, Prasad Y, Patra AK, Ranjan R, Swarup D, Patra RC, Pal S. Ascorbic acid, garlic extract and taurine alleviate cadmium-induced oxidative stress in freshwater catfish (Clarias batrachus). Sci Total Environ. 2009. 407:5024–5030.
crossref
10. Kim MK, Pak JY. Effect of dietary protein and cysteine levels on cadmium toxicity in rats. Korean J Nutr. 1996. 29:461–471.
11. Kim HY, Kim JC, Kim SY, Lee JH, Jang YM, Lee MS, Park JS, Lee KH. Monitoring of heavy metals in fishes in Korea. -As, Cd, Cu, Pb, Mn, Zn, Total Hg-. Korean J Food Sci Technol. 2007. 39:353–359.
12. Choi MS, Kinae N. Toxic effect of micropollutants on coastal organisms. I. Toxicity on some marine fishes. Bull Korean Fish Soc. 1994. 27:529–534.
13. Park T, Oh JY, Kim IS, Um YS. Changes of fatty acid compositions in hepatic total lipids and phospholipids of rats supplemented with cholesterol and taurine. J Korean Soc Food Sci Nutr. 1998. 27:1253–1261.
14. Kim SJ, Ha TY, Han CK, Kim NY, Ahn HS, Shin HK, Lim JK. Effects supplementation of folic acid, multiminerals, DHA on fertility rate of rats and growth and learning ability of their offsprings. Korean J Obstet Gynecol. 2002. 45:1588–1594.
15. Ahn CS, Lee YJ. Correlations of plasma taurine, homocysteine and serum lipid levels of elderly women. Korean J Food Nutr. 2010. 23:501–510.
16. Kang YS. The change on brain transport of choline and taurine by aging. J Pharm Sci. 2004. 20:37–41.
17. Kwon OR, Kim MK. The effect of dietary protein and calcium levels on the cadmium detoxication in rats. J Korean Home Econ Assoc. 1992. 30:99–113.
18. Shin MJ, Kwon OC, Lee JE, Seo EW. Effects of cadmium exposure on tissues of Carassius auratus. J Life Sci. 2010. 20:1490–1497.
19. Manna P, Sinha M, Sil PC. Amelioration of cadmium-induced cardiac impairment by taurine. Chem Biol Interact. 2008. 174:88–97.
crossref
20. Murakami S, Kondo Y, Toda Y, Kitajima H, Kameo K, Sakono M, Fukuda N. Effect of taurine on cholesterol metabolism in hamsters: up-regulation of low density lipoprotein (LDL) receptor by taurine. Life Sci. 2002. 70:2355–2366.
crossref
21. Manna P, Sinha M, Sil PC. Cadmium induced testicular pathophysiology: prophylactic role of taurine. Reprod Toxicol. 2008. 26:282–291.
crossref
22. Chung YH. The effect of dietary taurine on skeletal metabolism in ovariectomized rats. Korean J Hum Ecol. 2001. 4:84–93.
23. Sinha M, Manna P, Sil PC. Induction of necrosis in cadmium-induced hepatic oxidative stress and its prevention by the prophylactic properties of taurine. J Trace Elem Med Biol. 2009. 23:300–313.
crossref
TOOLS
Similar articles