Physiological reaction of common osier (salix viminialis l.) Var. Jorr to the presence of lead in the subsoil

• Autorzy: Malinowska K. , Malinowski R. , Stera A.

Identyfikatory

DOI

10,12911/22998993/1864

• Języki publikacji: EN

Abstrakty

EN

The effect of lead ions of the concentrations within the range of 15–1000 m dm^-3 on the physiological reaction of common osier var. Jorr was examined. The content of assimilation pigments, the rate the CO₂Water assimilation, transpiration, the indices of relative water content and the deficit of water saturation and the content of lead in the nutrient solution. The studied physiological parameters in common osier var. Jorr were differentiated by the rate of lead ions in the nutrient solution. The Jorr variety of common osier was characterised by good values of the determined physiological parameters under stressful conditions at a large accumulation of lead. This suggests that it shows quite a high tolerance to the stress caused by contamination of the subsoil with lead.

Słowa kluczowe

EN

lead; photosynthetic pigments; CO2 assimilation; transpiration; common osier

• Wydawca: Polskie Towarzystwo Inżynierii Ekologicznej ; Lublin University of Technology
• Czasopismo: Journal of Ecological Engineering
• Rocznik: 2015
• Tom: Vol. 16, nr 2
• Strony: 110--115
• Opis fizyczny: Bibliogr. 27 poz., tab., rys.

Twórcy

autor

Malinowska K.

• Department of Plant Physiology and Biochemistry, Faculty of Environmental Management and Agriculture, West Pomeranian University of Technology in Szczecin, 17 Słowackiego Str., 71-434 Szczecin, Poland

autor

Malinowski R.

• Department of Soil Science, Faculty of Environmental Management and Agriculture, West Pomeranian University of Technology in Szczecin, 17 Słowackiego Str., 71-434 Szczecin, Poland

autor

Stera A.

• Department of Plant Physiology and Biochemistry, Faculty of Environmental Management and Agriculture, West Pomeranian University of Technology in Szczecin, 17 Słowackiego Str., 71-434 Szczecin, Poland

Bibliografia

• 1. Arnon D.J., Allen M.B., Whatley F. 1956. Photosynthesis by isolated chloroplast. IV General concept and comparison of three photochemical reactions. Biochim. Biophys. Acta. 20, 449–461.
• 2. Bandurska H. 1991. The effect of proline on nitra te reductase activity in water – stressed baryle leaves. Acta Physiol. Plant., 1, 3–11.
• 3. Baran S. 2000. Ocena stanu degradacji i rekultywacji gleb. Lublin.
• 4. Becerril J.M., Munoz-Rueda A., Aparicio-Tejo P., Gonzales-Murua C. 1988. The effects of cadmium and lead on photosynthetic elektron transport In clover and lucerne. Plant Physiol. Biochem., 26, 357–363.
• 5. Deng H., Ye Z.H., Wong M.H. 2006. Lead and zinc accumulation and tolerance in populations of six wetland plants”, Enviromental Pollution., 141, 69–80.
• 6. Eltop L., Bron G., Joachim O., Brinkmann K. 1991. Lead tolerance of Betula and Salix in themining area of mechernich. Plant and Soil., 131, 275–285.
• 7. Górny A.G., Garczyński S. 2002. Genotypie and nutrition-dependent variation in water use efficiency and photosythetic activity of leaves in winter wheat (Triticum aesativum L.). J. Appl. Genet., 43(2), 145–160.
• 8. Hager A., Mayer-Berthenrath T. 1966. Die Isolierung und quanttative Bestimung der Carotenoide und Chlorophyll von Blatern, Algen und isolierten Chloroplasten mit Hilfe Dunnschicht-chromatographischer Methoden. Planta., 69, 198–217.
• 9. Hall J.L. 2002. Cellular mechanism for heavy metal detoxification and tolerance. J. of Exp. Bot., 53, 1–11.
• 10. Hermle S., Günthardt-Goerg M., Schulin R. 2006. Effects of metal-contaminated soil on the performance of Young trees growing in model ecosystems under field conditions. Enviromental Pollution, 144, 703–714.
• 11. Hinckly T.M., Braatne J.H. 1994. Stomata. [In:] R. Wilkinson, K. Marcel (Eds.), Plant – environment interaction. New York, 323–355.
• 12. Laloi C., Apel K., Danon A. 2004. Reactive oxygen signaling: the latest news. Curr. Opin. Plant Biol., 7, 323–328.
• 13. Lichtenthaler H.K. 1987. Chlorophylls and carotenoids: Pigments of photosynthetic biomembranes. Methods Enzymol., 148, 350–380.
• 14. Malinowska K., Wróbel J., Malinowski R., Stera A. 2010a The toxic impact of lead on the physiological parameters of basket willow (Salix viminalis L.). Agricultural Sciences, 2(4), 45–49.
• 15. Malinowska K., Mikiciuk M., Berdzik A. 2010b. Zmiany wybranych parametrów fizjologicznych wierzby wiciowej (Salix viminalis L.) wywołane zróżnicowanym stężeniem kadmu w podłożu. Ochr. Środ. i Zasob. Natur., 42, 24–32.
• 16. Malinowska K., Mikiciuk M., Wróbel J., Czyżyk E. 2011. Influence of cadmium on physiological parameters of clone Jorr of basket willow (Salix viminalis L.) from aquatic cultures. Ecol. Chem. and Eng. A., 18(5-6), 763–770.
• 17. Malinowska K., Smolik B. 2011. Physiological and biochemical activity of spring wheat (Triticum vulgare) under the conditions of stress caused by cadmium. Envir. Prot. Eng., 37(1), 73–81.
• 18. Mott K.A., Parkhurst D.F. 1991. Stomatal responsem to humidity In Ir and helom. Plant Cell Environ., 14, 509–515.
• 19. Panda S., Chaudhury I., Khan M. 2003. Heavy metals induce lipid peroxidation and affect antioxi 115 dants in wheat leaves. Biol. Plant., 46(2), 289–294.
• 20. Schützendübel A., Schwanz P., Teichmann T., Gross K., Langenfeld-Heyser R., Godbol D.L., Polle A. 2001. Cadmium-induced changes in antioxidative systems, hydrogen peroxide content, and differentiation in Scots Pine roots. Plant Physiol., 127, 887–898.
• 21. Šottniková A., Lunáčková L., Masarovičová E., Lux A., Streško V. 2003. Changes in the rooting and growth of willows and populars induced by cadmium. Biologia Plantarum., 46(1), 129–131.
• 22. Starck Z. 2002. Mechanizmy integracji procesów fotosyntezy i dystrybucji biomasy w niekorzystnych warunkach środowiska. Zesz. Prob. Post. Nauk Rol., 481, 113–123.
• 23. Wróbel J., Mikiciuk M., Stolarska A. 2006. Wpływ warunków zasolenia gleby na aktywność wymiany gazowej u trzech klonów wierzby wiciowej (Salix viminalis L.). Zesz. Prob. Post. Nauk Rol., 509, 269–281.
• 24. Wrzosek J., Gawroński S., Gworek B. 2008. Zastosowanie roślin energetycznych w technologii fitoremediacji. Ochr. Środ. i Zasob. Natur., 37, 139–151.
• 25. Zemleduch A., Tomaszewska B. 2007. Mechanizmy, procesy i oddziaływanie w fitoremediacji. Kosmos, Prob. Nauk Biol., 56(3-4), 393–407.
• 26. Zenk M. 1966. Heavy metal detoxification in plants – a review. Gene., 179, 21–30.
• 27. Verma S., Dubey R.S. 2003. Lead toxicity induces lipid peroxidation and alters the activities of antioxidant enzymes in growing rice plants. Plant Sci., 164(4), 645–655.