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Year 2008, Volume: 21 Issue: 1, 1 - 7, 24.03.2010

Abstract

References

  • McGrath, S.P., “Phytoextraction for soil reclamation. In Brooks, R.R. (Ed.), Plants that hyperaccumulate heavy metal. Their role in phytoremediation” Microbiology, Archaeology, Mineral Exploration and Phytomining, CAE International, Wallingford, 261-287 (1998).
  • Yang, X.E., Lang, X.X., Ni, W.Z., He, Z.L., Stoffella, P.J. and Calvest, D.V., “Assessing copper thresholds for phytotoxicity and potential toxicity in selected crops”, J. Environ. Sci. Health B., 37: 625-635 (2002).
  • Jiang, L.Y., Yang, X.E. and He, Z.L., “Growth response and phytoextraction of copper at different levels in soils by Elsholtzia splendens”, Chemosphere, 55:1179-1187 (2004).
  • Lanaras, T., Moustakas, M., Symeonidis, L., Diomantoglov, S. and Karataglis, S., “Plant metal content growth responses and some photosynthetic measurements of field-cultivated wheat growing on one bodies enriched in Cu”, Physiol. Plant., 88: 307-314 (1993).
  • Clijters, H. and Van Assche, F., “Inhibition of photosynthesis by heavy metals”, Photosynth. Res., 7: 31-40 (1985).
  • Mohan, B.S. and Hosetti, B.B., “Potential phytotoxicity of lead and cadmium to Lemna minor grown in sewage stabilization ponds”, Environ. Pollut., 98: 233-238 (1997).
  • Somashekaraiah, B.V., Padmaja, K. and Prasad, A.R.K., “Phytotoxicity of cadmium ions on germinating seedlings of mung bean (Phaseolus vulgaris) involvement of lipid peroxides in chlorophyll degradation”, Physiol. Plant., 85: 85- 89 (1992).
  • Greger, M. and Ogren, E., “Direct and indirect effect of Cd on photosynthesis in sugar beet (Beta vulgaris)”, Physiol. Plant., 83: 129-135 (1991).
  • Fernandes, J.C. and Henriques, F.S., “Biochemical, physiological and structural effect of excess copper in plants”, The Bot. Revi., 57: 246-273 (1991).
  • Munzuroglu, O. and Geckil, H., “Effects of metals on seed germination, root elongation, and coleoptile and hypocotyl growth in Triticum aestivum and Cucumis sativus” Environ. Cont. and Toxi., 43: 203-213 (2002).
  • Seo, M. and Koshiba, T., “Complex regulation of ABA biosynthesis in plants”, Trends Plant Science, 7: 1 41-48 (2002).
  • Monni, S., Uhling, C., Hansen, E. and Magel, E., “Ecophysiological responses of Empetrum nigrum to heavy metal pollution”, Environ. Pollut., 112: 121-129 (2001).
  • Rauser, W.E. and Dumbroff, E.R., “Effects of excess cobalt nickel and zinc on the water relations of Phaseolus vulgaris”, Env. and Exp. Bot., 21: 249-255 (1981).
  • Poschenrieder, C., Gunsé, B. and Barceló, J., “Influence of cadmium on water relations, stomal resistance and abscisic acid content in expanding bean leaves”, Plant Physiol., 90: 1365-1371 (1989).
  • Cabot, C., Poschenrieder, Ch. and Barcelo, J., “A
  • rapid method for extraction and estimation of
  • abscisic acid from plant tissue using high
  • performance liquid chromatography”, J. of Liquid
  • Chrom., 9 (13): 2977-2986 (1986).
  • Zenk, M.H., “Heavy metal detoxification in higher plants- a review”, Gene, 179: 21-30 (1996).
  • Pang, J., Chan, G.S.Y., Zhang, J., Liang, J. and Wong, M.H., “Physiological aspects of vetiver grass for rehabilitation in abandoned metalliferous mine wastes”, Chemosphere, 52: 1559-1570 (2003). [
  • Bellaire, B.A., Carmody, J., Braud. J., Gossett, D.R., Banks, S.W., Lucas, M.C. and Fowler, M., “Involvement of abscisic acid- dependent and – independent pathways in the up-regulation of antioxidant enzyme activity during NaCl stress in cotton callus tissue”, Free Radical Res., 33: 531- 545 (2000).
  • Cutler, A.J. and Krochko, J.E., “Formation and breakdown of ABA”, Trends Plant Science, 12: 472-478 (1999).
  • Sharma, S.S. and Kumar, V., “Responses of wild type and abscisic acid mutants of Arabidopsis thaliana to cadmium.” J. Plant Physiol., 159: 1323-1327 (2002).
  • Addicott, F.T. and Van Steveninck, R.F.M., “Summary: Signifinance of abscisic acid in the life of plants. In FT Addicott, ed, Abscisic Acid”, Praeger, New York, 581-586, (1983).
  • Campalans, A., Messeguer, R., Goday, A. and Pages, M., “Plant Responses to drought, from ABA signal transduction events to action of the induced proteins” Plant Physiol. Biochem., 37 (5): 327-340 (1999). [
  • Baker, A.J.M., “Metal tolerance”, New Phytol., 106: 93-111 (1987).
  • Gomez-Cadenas, A., Tadeo, F.R., Primo-Millo, E. and Talon, M., “Involvement of abscisic acid and ethylene in the responses of citrus seedlings to salt shock”, Plant Physiol., 103: 475-484 (1998). [
  • Talanova, V.V., Titov, A.F. and Boeva, N.P., “Effect of increasing concentrations of lead and cadmium on cucumber seedlings”, Biol. Plantarum., 43 (3): 441-444 (2000).
  • Atıcı, Ö. , Ağar, G. And Battal, P., “Changes in phytohormone contents in chickpea seeds germinating under lead or zinc stress”, Biol. Plantarum, 49 (2): 215-222 (2005).

The Abscisic Acid Levels of Wheat (Triticum aestivum L. cv. Çakmak 79) Seeds that were Germinated under Heavy Metal(Hg++,Cd++,Cu++)Stress

Year 2008, Volume: 21 Issue: 1, 1 - 7, 24.03.2010

Abstract

The purpose of this study was to investigate the level of endogenous abscisic acid of wheat seeds germinated in the presence of 60, 90 and 120 ppm of mercury, cadmium and copper salt solutions for 16 hours in order to see their effects on the germination. The levels of abscisic acid were analysed by High Performance Liquid Chromatography (HPLC). The results indicated that abscisic acid levels were affected by the kind and level of heavy metals used in the experiments. The effects of these toxic ions on abscisic acid content were found to be highest for mercury and lowest for copper. Regarding the correlation between the concentrations of the toxic elements, applied changes in endogenous abscisic acid levels in the seeds and germination development indicated that inhibition of germination was related with abscisic acid accumulation in the seeds.

References

  • McGrath, S.P., “Phytoextraction for soil reclamation. In Brooks, R.R. (Ed.), Plants that hyperaccumulate heavy metal. Their role in phytoremediation” Microbiology, Archaeology, Mineral Exploration and Phytomining, CAE International, Wallingford, 261-287 (1998).
  • Yang, X.E., Lang, X.X., Ni, W.Z., He, Z.L., Stoffella, P.J. and Calvest, D.V., “Assessing copper thresholds for phytotoxicity and potential toxicity in selected crops”, J. Environ. Sci. Health B., 37: 625-635 (2002).
  • Jiang, L.Y., Yang, X.E. and He, Z.L., “Growth response and phytoextraction of copper at different levels in soils by Elsholtzia splendens”, Chemosphere, 55:1179-1187 (2004).
  • Lanaras, T., Moustakas, M., Symeonidis, L., Diomantoglov, S. and Karataglis, S., “Plant metal content growth responses and some photosynthetic measurements of field-cultivated wheat growing on one bodies enriched in Cu”, Physiol. Plant., 88: 307-314 (1993).
  • Clijters, H. and Van Assche, F., “Inhibition of photosynthesis by heavy metals”, Photosynth. Res., 7: 31-40 (1985).
  • Mohan, B.S. and Hosetti, B.B., “Potential phytotoxicity of lead and cadmium to Lemna minor grown in sewage stabilization ponds”, Environ. Pollut., 98: 233-238 (1997).
  • Somashekaraiah, B.V., Padmaja, K. and Prasad, A.R.K., “Phytotoxicity of cadmium ions on germinating seedlings of mung bean (Phaseolus vulgaris) involvement of lipid peroxides in chlorophyll degradation”, Physiol. Plant., 85: 85- 89 (1992).
  • Greger, M. and Ogren, E., “Direct and indirect effect of Cd on photosynthesis in sugar beet (Beta vulgaris)”, Physiol. Plant., 83: 129-135 (1991).
  • Fernandes, J.C. and Henriques, F.S., “Biochemical, physiological and structural effect of excess copper in plants”, The Bot. Revi., 57: 246-273 (1991).
  • Munzuroglu, O. and Geckil, H., “Effects of metals on seed germination, root elongation, and coleoptile and hypocotyl growth in Triticum aestivum and Cucumis sativus” Environ. Cont. and Toxi., 43: 203-213 (2002).
  • Seo, M. and Koshiba, T., “Complex regulation of ABA biosynthesis in plants”, Trends Plant Science, 7: 1 41-48 (2002).
  • Monni, S., Uhling, C., Hansen, E. and Magel, E., “Ecophysiological responses of Empetrum nigrum to heavy metal pollution”, Environ. Pollut., 112: 121-129 (2001).
  • Rauser, W.E. and Dumbroff, E.R., “Effects of excess cobalt nickel and zinc on the water relations of Phaseolus vulgaris”, Env. and Exp. Bot., 21: 249-255 (1981).
  • Poschenrieder, C., Gunsé, B. and Barceló, J., “Influence of cadmium on water relations, stomal resistance and abscisic acid content in expanding bean leaves”, Plant Physiol., 90: 1365-1371 (1989).
  • Cabot, C., Poschenrieder, Ch. and Barcelo, J., “A
  • rapid method for extraction and estimation of
  • abscisic acid from plant tissue using high
  • performance liquid chromatography”, J. of Liquid
  • Chrom., 9 (13): 2977-2986 (1986).
  • Zenk, M.H., “Heavy metal detoxification in higher plants- a review”, Gene, 179: 21-30 (1996).
  • Pang, J., Chan, G.S.Y., Zhang, J., Liang, J. and Wong, M.H., “Physiological aspects of vetiver grass for rehabilitation in abandoned metalliferous mine wastes”, Chemosphere, 52: 1559-1570 (2003). [
  • Bellaire, B.A., Carmody, J., Braud. J., Gossett, D.R., Banks, S.W., Lucas, M.C. and Fowler, M., “Involvement of abscisic acid- dependent and – independent pathways in the up-regulation of antioxidant enzyme activity during NaCl stress in cotton callus tissue”, Free Radical Res., 33: 531- 545 (2000).
  • Cutler, A.J. and Krochko, J.E., “Formation and breakdown of ABA”, Trends Plant Science, 12: 472-478 (1999).
  • Sharma, S.S. and Kumar, V., “Responses of wild type and abscisic acid mutants of Arabidopsis thaliana to cadmium.” J. Plant Physiol., 159: 1323-1327 (2002).
  • Addicott, F.T. and Van Steveninck, R.F.M., “Summary: Signifinance of abscisic acid in the life of plants. In FT Addicott, ed, Abscisic Acid”, Praeger, New York, 581-586, (1983).
  • Campalans, A., Messeguer, R., Goday, A. and Pages, M., “Plant Responses to drought, from ABA signal transduction events to action of the induced proteins” Plant Physiol. Biochem., 37 (5): 327-340 (1999). [
  • Baker, A.J.M., “Metal tolerance”, New Phytol., 106: 93-111 (1987).
  • Gomez-Cadenas, A., Tadeo, F.R., Primo-Millo, E. and Talon, M., “Involvement of abscisic acid and ethylene in the responses of citrus seedlings to salt shock”, Plant Physiol., 103: 475-484 (1998). [
  • Talanova, V.V., Titov, A.F. and Boeva, N.P., “Effect of increasing concentrations of lead and cadmium on cucumber seedlings”, Biol. Plantarum., 43 (3): 441-444 (2000).
  • Atıcı, Ö. , Ağar, G. And Battal, P., “Changes in phytohormone contents in chickpea seeds germinating under lead or zinc stress”, Biol. Plantarum, 49 (2): 215-222 (2005).
There are 30 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Biology
Authors

Ömer Munzuroğlu This is me

Fikriye Kırbağ Zengin

Zübeyde Yahyagil This is me

Publication Date March 24, 2010
Published in Issue Year 2008 Volume: 21 Issue: 1

Cite

APA Munzuroğlu, Ö., Kırbağ Zengin, F., & Yahyagil, Z. (2010). The Abscisic Acid Levels of Wheat (Triticum aestivum L. cv. Çakmak 79) Seeds that were Germinated under Heavy Metal(Hg++,Cd++,Cu++)Stress. Gazi University Journal of Science, 21(1), 1-7.
AMA Munzuroğlu Ö, Kırbağ Zengin F, Yahyagil Z. The Abscisic Acid Levels of Wheat (Triticum aestivum L. cv. Çakmak 79) Seeds that were Germinated under Heavy Metal(Hg++,Cd++,Cu++)Stress. Gazi University Journal of Science. March 2010;21(1):1-7.
Chicago Munzuroğlu, Ömer, Fikriye Kırbağ Zengin, and Zübeyde Yahyagil. “The Abscisic Acid Levels of Wheat (Triticum Aestivum L. Cv. Çakmak 79) Seeds That Were Germinated under Heavy Metal(Hg++,Cd++,Cu++)Stress”. Gazi University Journal of Science 21, no. 1 (March 2010): 1-7.
EndNote Munzuroğlu Ö, Kırbağ Zengin F, Yahyagil Z (March 1, 2010) The Abscisic Acid Levels of Wheat (Triticum aestivum L. cv. Çakmak 79) Seeds that were Germinated under Heavy Metal(Hg++,Cd++,Cu++)Stress. Gazi University Journal of Science 21 1 1–7.
IEEE Ö. Munzuroğlu, F. Kırbağ Zengin, and Z. Yahyagil, “The Abscisic Acid Levels of Wheat (Triticum aestivum L. cv. Çakmak 79) Seeds that were Germinated under Heavy Metal(Hg++,Cd++,Cu++)Stress”, Gazi University Journal of Science, vol. 21, no. 1, pp. 1–7, 2010.
ISNAD Munzuroğlu, Ömer et al. “The Abscisic Acid Levels of Wheat (Triticum Aestivum L. Cv. Çakmak 79) Seeds That Were Germinated under Heavy Metal(Hg++,Cd++,Cu++)Stress”. Gazi University Journal of Science 21/1 (March 2010), 1-7.
JAMA Munzuroğlu Ö, Kırbağ Zengin F, Yahyagil Z. The Abscisic Acid Levels of Wheat (Triticum aestivum L. cv. Çakmak 79) Seeds that were Germinated under Heavy Metal(Hg++,Cd++,Cu++)Stress. Gazi University Journal of Science. 2010;21:1–7.
MLA Munzuroğlu, Ömer et al. “The Abscisic Acid Levels of Wheat (Triticum Aestivum L. Cv. Çakmak 79) Seeds That Were Germinated under Heavy Metal(Hg++,Cd++,Cu++)Stress”. Gazi University Journal of Science, vol. 21, no. 1, 2010, pp. 1-7.
Vancouver Munzuroğlu Ö, Kırbağ Zengin F, Yahyagil Z. The Abscisic Acid Levels of Wheat (Triticum aestivum L. cv. Çakmak 79) Seeds that were Germinated under Heavy Metal(Hg++,Cd++,Cu++)Stress. Gazi University Journal of Science. 2010;21(1):1-7.