EFFECTS OF HOUSEHOLD POLLUTANTS ON THE METALLOTHIONEINS IN TISSUES OF BIVALVE MOLLUSCS UNIO TUMIDUS
DOI: http://dx.doi.org/10.30970/sbi.0901.395
Abstract
Personal care products and pharmaceuticals are the most common novel water pollutants, and it is difficult to predict the effects. It is expected that they can modulate the activity of molecular detoxification systems. Since the production of the metal-binding proteins, metallothioneins (MTs) are activated by a wide range of stress factors, the aim of the study was to compare the functional characteristics of the MTs from digestive gland (DG) of male bivalve mollusc Unio tumidus from reference pond, polluted by sewage effluents pond and after the exposure to widespread water personal care pollutants ibuprofen (I, 250 ng / L), triclosan (T, 500 ng / L) or estrone (E1, 100 ng / L) for 14 days (overall term of staying in the laboratory aquaria – 21 days). The elevation of the content of zinc, copper and cadmium in bivalves’ tissues of DG, gonads and MTs as well as total level of MTs was noted in polluted pond compared to the reference one. Exposure factors and chronic pollution caused an increase of level of Zn-binding MT form on a background of reduced (I-, T-group) or increased (E1 group) total protein content of MTs and constant total level of zinc and copper in tissue. Under the effect of I, T and E1, marked decreasing in copper level and increasing (in 2.2–3 times) in zinc level were observed in the gonads. Thus, we should assume that the elevation of the content of zinc-MT in the bivalves DG can be considerded as the compound of the unspecific supporting strategy of the signaling function of these ions under the harmful efects.
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1. Amiard J.-C., Amiard-Triquet C., Barka S. et al. Metallothioneins in aquatic invertebrates: Their role in metal detoxification and their use as biomarkers. Aquatic Toxicology, 2006; 76(2): 160-202. | |
| |
2. Bigot A., Doyen P., Vasseur P., Rodius F. Metallothionein coding sequence identification and seasonal mRNA expression of detoxification genes in the bivalve Corbicula fluminea. Ecotoxicology and Environmental Safety, 2009; 72(2): 382-387. | |
| |
3. Binelli A., Riva C., Provini A. Biomarkers in Zebra mussel for monitoring and quality assessment of Lake Maggiore (Italy). Biomarkers, 2007; 12(4): 349-368. | |
| |
4. Blaise C., Gagne F., Eullaffroy P., Ferard J.-F. Ecotoxicity of selected pharmaceuticals of urban origin discharged to the Saint-Lawrence river (Quebec, Canada): a review. Brazilian Journal of Aquatic Science and Technology, 2006; 10(2): 29-51. | |
| |
5. Cheung M.-S., Wang W.-X. Uses of subcellular metal distribution in prey to predict metal bioaccumulation and internal exposure in a predator. Environmental Toxicology and Chemistry, 2008; 27(5): 1160-1166. | |
| |
6. Doyen P., Bigot A., Vasseur P. Molecular cloning and expression study of pi-class glutathione S-transferase (pi-GST) and selenium-dependent glutathione peroxidase (Se-GPx) transcripts in the freshwater bivalve Dreissena polymorpha. Comparative Biochemistry and Physiology, 2008; 147 C(1): 69-77. | |
| |
7. Falfushynska H., Gnatyshyna L., Yurchak I. et al. Habitat pollution and thermal regime modify molecular stress responses to elevated temperature in freshwater mussels (Anodonta anatina: Unionidae). Science of The Total Environment, 2014; 500-501: 339-350. | |
| |
8. Falfushynska H.I., Gnatyshyna L.L., Farkas A. et al. Vulnerability of biomarkers in the indigenous mollusc Anodonta cygnea to spontaneous pollution in a transition country. Chemosphere, 2010; 81(10): 1342-1351. | |
| |
9. Falfushynska H.I., Gnatyshyna L.L., Osadchuk O.Y. et al. Diversity of the molecular responses to separate wastewater effluents in freshwater mussels. Comparative Biochemistry and Physiology, 2014; 164 C: 51-58. | |
| |
10. Falfushynska H.I., Gnatyshyna L.L., Stoliar O.B. Effect of in situ exposure history on the molecular responses of freshwater bivalve Anodonta anatina (Unionidae) to trace metals. Ecotoxicology and Environmental Safety, 2013; 89: 73-83. | |
| |
11. Falfushynska H.I., Gnatyshyna L.L., Stoliar O.B. In situ exposure history modulates the molecular responses to carbamate fungicide Tattoo in bivalve mollusc. Ecotoxicology, 2013; 22(3): 433-445. | |
| |
12. Fent K., Weston A.A., Caminada D. Ecotoxicology of human pharmaceuticals. Aquatic Toxicology, 2006; 76(2): 122-159. | |
| |
13. Gagné F., Blaise C., André C. et al. Neuroendocrine disruption and health effects in Elliptio complanata mussels exposed to aeration lagoons for wastewater treatment. Chemosphere, 2007; 68(4): 731-743. | |
| |
14. Kagi J.H.R., Schaffer A. Biochemistry of metallothionein. Biochemistry, 1988; 27(23): 8509-8515. | |
| |
15. Kolpin D.W., Furlong E.T., Meyer M.T. et al. Pharmaceuticals, hormones, and other organic wastewater contaminants in U.S. streams 1999-2000: a national reconnaissance. Environmental Science and Technology, 2002; 36(6): 1202-1211. | |
| |
16. Nielson K.B., Winge D.R. Preferential binding of copper to the beta domain of metallothionein. Journal of Biological Chemistry, 1984; 259(8): 4941-4946. | |
| |
17. Olsson P.E., Zafarullah M., Gedamu Z. A role of metallothionein in zinc regulation after oestradiol induction of vitellogenin synthesis in rainbow trout, Salmo gairderi. Biochemical Journal, 1989; 257(2): 555-559. | |
| |
18. Paíga P., Santos L.H., Amorim C.G. et al. Pilot monitoring study of ibuprofen in surface waters of north of Portugal. Environmental Science and Pollution Research, 2013; 20(4): 2410-2420. | |
| |
19. Paris-Palacios S., Biagianti-Risbourg S., Fouley A., Vernet G. Metallothioneins in liver of Rutilus rutilus exposed to Cu2+. Analysis by metal summation, SH determination and spectrofluorimetry. Comparative Biochemistry and Physiology, 2000; 126 C (2): 113-122. | |
| |
20. Parvez S., Raisuddin S. Effects of paraquat on the freshwater fish Channa punctata (Bloch): non-enzymatic antioxidants as biomarkers of exposure. Archives of Environmental Contamination and Toxicology, 2006; 50(3): 392-397. | |
| |
21. Podrug M., Raspor B., Erk M., Dragun Z. Protein and metal concentrations in two fractions of hepatic cytosol of the European chub (Squalius cephalus L.). Chemosphere, 2009; 75(7): 843-849. | |
| |
22. Viarengo A., Lowe D., Bolognesi C. et al. The use of biomarkers in biomonitoring: a 2-tier approach assessing the level of pollutant-induced stress syndrome in sentinel organisms. Comparative Biochemistry and Physiology, 2007; 146 C(3): 281-300. | |
| |
23. Viarengo A., Ponzano E., Dondero F., Fabbri R. A simple spectrophotometric method for metallothionein evaluation in marine organisms: an application to Mediterranean and Antarctic Molluscs. Marine Environmental Research, 1997; 44(1): 69-84. | |
| |
24. Wilhelmsen T.W., Olsvik P.A., Hansen B.H., Andersen R.A. Evidence for oligomerization of metallothioneins in their functional state. Journal of Chromatography A, 2002; 979(1-2): 249-254. | |
| |
25. Yang Y., Maret W., Vallee B.L. Differential fluorescence labelling of cysteinyl clusters uncovers high tissue levels of thionein. Proceedings of National Academy of Science of USA, 2001; 98: 5556-5559. | |
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