Abstract
The importance of photoperiod and ambient temperature on the accumulation of cadmium in the liver and kidneys of bank voles was determined in the present study. Males and females, aged 1 month, were given 3.0 μg Cd ml−1 drinking water and divided into four groups according to photoperiod (16 h light/8 h dark and 8 h light/16 h dark) and ambient temperature (20 or 5°C); liver and kidneys were removed for cadmium as well as copper, iron and zinc analyses at the end of 6 weeks. Bank voles exposed to 5°C in both photoperiods consumed approximately 30% less water containing cadmium than those kept at 20°C. However, the total accumulation of cadmium in the liver and kidneys of males and females exposed to the low temperatures was 4.3–4.8 and 2.2–3.3 times less than that in animals maintained at room temperature in the long and short photoperiod, respectively. Simultaneously, the low temperature brought about an increase in the copper concentrations in the liver (12–43%) and kidneys (47–78%), giving rise to an inverse correlation between the cadmium accumulation and the tissue copper concentration. In contrast to cadmium and copper, the concentrations of iron and zinc were affected primarily by photoperiod. These findings indicate that ambient temperature is an important determinant of cadmium retention in the bank vole. It appears that low temperature decreases tissue cadmium accumulation not only by reducing cadmium intake but also through changes in copper metabolism.
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References
Bremner I, Campbel JK. 1980 The influence of dietary copper intake on toxicity of cadmium. Annu NY Acad Sci 355, 319–332.
Buchalczyk A. 1970 Reproduction, mortality and longevity of the bank vole under laboratory conditions. Acta Theriol 15, 153–176.
Chmielnicka J, Cherian GM. 1986 Environmental exposure to cadmium and factors affecting trace element metabolism and metal toxicity. Biol Trace Elem Res 10, 243–262.
Elsehans B, Schmolke G, Kolb K, Stokes J, Forth W. 1987 Metal-metal interactions among dietary toxic metals and essential trace metals. Ecotoxicol Environ Safety 14, 275–287.
Felley-Bosco E, Diezi J. 1992 Dietary calcium restriction enhances cadmium-induced metallothionein synthesis in rats. Toxicol Lett 60, 139–144.
Flanagan PR, McLellan JS, Haist J. et al. 1978 Increased dietary cadmium absorption in mice and human subjects with iron deficiency. Gastroenterology 74, 841–846.
Foulkes EC. 1985 Interactions between metals in rat jejunum: implications on the nature of cadmium uptake. Toxicology 37, 117–125.
Fox MRS, Tao SH, Stone CL, Fry BE. 1984 The effects of zinc, iron and copper deficiencies on cadmium levels in tissues of Japanese quail. Environ Health Perspect 54, 57–65.
Groten JP, Sinkeldam EJ, Luten JB, van Bladeren PJ. 1991a Cadmium accumulation and metallothionein concentrations after 4-week dietary exposure to cadmium chloride or cadmium-metallothionein in rats. Toxicol Appl Pharmacol 111, 504–513.
Groten JP, Sinkeldam EJ, Luten JB, Muys T, van Bladeren PJ. 1991b Interaction of dietary Ca, P, Mg, Mn, Cu, Fe, Zn and Se with the accumulation and oral toxicity of cadmium in rats. Food Chem Toxicol 29, 249–258.
Hyvärinen H. 1972 Seasonal changes in the copper content of the liver of the common shrew, Sorex araneus over a two-year period. J Zool (Lond) 166, 411–416.
Jacobs RM, Jones AOL, Fox MRS, Lener J. 1983 Effects of dietary zinc, manganese and copper on tissue accumulation of cadmium by Japanese quail. Proc Soc Exp Biol Med 172, 34–38.
Kotsonis FN, Klaassen CD. 1978 The relationship of metallothionein to the toxicity of cadmium after prolonged oral administration to rats. Toxicol Appl Pharmacol 46, 39–54.
Leon L, Johnson DR. 1985 Role of iron in jejunal uptake of cadmium in the newborn rat. J Toxicol Environ Health 15, 687–696.
Meese GB. 1971 Some aspects of energy balance in the bank vole Clethrionomys glareolus. J Zool (Lond) 163, 305–317.
Nordberg GF, Kjellström T, Nordberg M. 1985 Kinetics and metabolism. In: Friberg L, Elinder CG, Kjellström T, Nordberg GF, eds. Cadmium and Health. Vols 1 and 2. Boca Raton, FL: CRC Press: 103–179.
Panemangalore M. 1993 Interaction among zinc, copper and cadmium in rats: effects of low zinc and copper diets and oral cadmium exposure. J Trace Elem Exp Med 6. 125–139.
Revis NW. 1981 The relationship of dietary protein to metallothionein and cadmium-induced renal damage. Toxicology 20, 323–333.
Rimbach G, Brandt K, Most E, Pallauf J. 1995 Supplemental phytic acid and microbial phytase change zinc bioavailability and cadmium accumulation in growing rats. J Trace Elem Med Biol 9, 117–122.
Rummler HG, Classen HG, Schimatschek HF, et al. 1989 Age-dependent accumulation of cadmium in rats exposed to contaminated drinking water; interactions with zinc and copper and subcellular Cd distribution in kidney cells. J Trace Elem Electrolytes Health Dis 3, 217–223.
Sawicka-Kapusta K, Górecki A. Świergosz R, et al. 1987 Effect of metabolic rate on the rate of elimination of high and low concentrations of cadmium and lead in the bank vole. Ekol Pol 35, 399–430.
Schenkel H. 1994 Toxicokinetics and toxicodynamic behavior of cadmium. Proc Soc Nutr Physiol 2, 17–29.
Shaikh ZA, Jordan SA. Tewari PC. 1993 Cadmium disposition and metallothionein induction in mice: strain-, sex-, age- and dose-dependent differences. Toxicology 80, 51–70.
Tahka KM. 1978 A histochemical study on the effects of photoperiod on gonadal and adrenal function in the male bank vole (Clethrionomys glareolus). J Reprod Fertil 54, 57–66.
Washko PW, Cousins RJ. 1977 Role of dietary calcium and calcium binding protein in cadmium toxicity in rats. J Nutr 107, 920–928.
Wlostowski T. 1992 Seasonal changes in subcellular distribution of zinc, copper, cadmium and metallothionein in the liver of bank vole (Clethrionomys glareolus): a possible essential role of cadmium and metallothionein in the hepatic metabolism of copper. Comp Biochem Physiol 101C, 155–162.
Wlostowski T, Chętnicki W, Gierlachowska-Baldyga W, Chycak B. 1988 Zinc, iron, copper, manganese, calcium and magnesium supply status of free-living bank voles. Acta Theriol 33, 555–573.
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Wŀostowski, T., Krasowska, A. & Dworakowski, W. Low ambient temperature decreases cadmium accumulation in the liver and kidneys of the bank vole (Clethrionomys glareolus). Biometals 9, 363–369 (1996). https://doi.org/10.1007/BF00140605
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DOI: https://doi.org/10.1007/BF00140605