Abstract
Since agricultural crops contribute >70% of human cadmium (Cd) intake, modification of crops to reduce accumulation of this pollutant metal during plant growth is desirable. Here we describe Cd accumulation characteristics of seedlings and field grown tobacco plants expressing the Cd-chelating protein, mouse metallothionein I. The objective of the transformation is to entrap Cd in roots as Cd-metallothionein and thereby reduce its accumulation in the shoot. Transformed and control seedlings were exposed for 15 days in liquid culture at a field soil-solution-like Cd concentration of 0.02 μm. Transformed seedlings ofNicotiana tabacum cultivar KY 14 contained about 24% lower Cd concentration in shoots and about 5% higher Cd concentration in roots than control seedlings. Dry weights of transformed and control tissues did not differ significantly. In the field in 1990, mature transformedN. tabacum cv. KY 14 plants exposed only to endogenous soil Cd contained about 14% lower leaf lamina Cd concentration than did controls. Differences were significant at thep≤0.1 level in 13 of 16 leaf positions. Leaf dry weight did not differ significantly but transformed field plants had 12% fewer leaves and were 9% shorter than the controls. Copper (Cu) concentration was significantly higher (ca10%) in the bottom nine leaf positions of transformed plants suggesting that reduced leaf number and plant height may be due to Cu deficiency or toxicity. Alternatively, somaclonal variation or gene position effects may be involved. No differences were found in zinc levels. WithN. tabacum cv. Petit Havana, transformed seedlings contained no less Cd in shoots but 48% higher Cd concentration in roots. However, dry weights of shoots and roots of transformed seedlings were 25% and 26%, respectively, greater than in controls. In the field, transformed and control plants of this cultivar showed little significant differences in leaf Cd content, plant height or leaf number. Although comparison of additional metallothionein-expressing tobaccos and other plants is needed, results obtained with cultivar KY 14 support the hypothesis that sequestration of Cd in roots as Cd-metallothionein may have potential for reducing Cd content of above root tissues of certain plants.
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References
Hamer, D.H. (1986) Metallothionein.Ann. Rev. Biochem. 55, 913–51.
Joshi, R.L. and Joshi, V. (1991) Strategies for expression of foreign genes in plants.FEBS Lett. 281, 1–8.
Krotz, R.M., Evangelou, B.P. and Wagner, G.J. (1989) Relationships between cadmium, zinc, cadmium-peptide and organic acid in tobacco suspension cells.Plant Physiol. 91, 780–7.
Larkin, P.J. and Scowcroft, W.R. (1981) Somaclonal variation—a novel source of variability from cell cultures for plant improvement.Theor. Appl. Genet. 60, 197–214.
Lefebvre, D.D., Miki, B.L. and Laliberte, J.F. (1987) Mammalian metallothionein functions in plants.Biotechnology 5, 1053–6.
Maiti, I.B., Hunt, A.G. and Wagner, G.J. (1988) Seed transmisible expression of mammalian metaloothionein in transgenic tobacco.Biochem. Biophys. Res. Commun. 150, 640–7.
Maiti, I.B., Wagner, G.J., Yeargan, R. and Hunt, A.G. (1989) Inheritance and expression of the mouse metallothionein gene in tobacco. Impact on cadmium tolerance and tissue cadmium distribution in seedlings.Plant Physiol. 91, 1020–4.
Maiti, I.B., Wagner, G.J. and Hunt, A.G. (1991) Light inducible and tissue-specific expression of a chimeric mouse metallothionein cDNA gene in tobacco.Plant Sci. 76, 99–107.
Misra, S. and Gedamu, L. (1989) Heavy metal tolerant transgenicBrassica napus L. andNicotiana tabacum L. plants.Theor. Appl. Genet. 78, 161–8.
Pautot, V., Brzeniski, R. and Tepfer, M. (1989) Expression of mouse metallothionein gene in transgenic plant tissues.Gene 77, 133–40.
Ryan, J.A., Pahren, H.R. and Lucas, J.B. (1982) Controlling cadmium in the human chain: Review and rationale based on health effects.Environ. Res. 28, 251–302.
Samarawickram, G. (1988) Cadmium in animal and human health. In Rose, J. ed.,Trace Elements in Health, pp. 21–43. New York: Butterworths Press.
Schardl, C.L., Byrd, A.D., Benzion, G., Altschuler, M.A., Hildebrand, D.F. and Hunt, A.G. (1987) Design and construction of a versatile system for the expression of foreign genes in plants.Gene 61, 1–11.
Voegeli-Lange, R. and Wagner, G.J. (1990) Subcellular localization of cadmium and cadmium-binding peptides in tobacco leaves.Plant Physiol. 92, 1086–93.
Wagner, G.J. and Yeargan, R. (1986) Variation in Cd accumulation potential and tissue distribution of Cd in tobacco.Plant Physiol. 82, 274–9.
Wagner, G.J., Sutton, T.G. and Yeargan, R. (1988) Root control of leaf cadmium accumulation in tobacco.Tob. Sci. 190, 64–8.
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Yeargan, R., Maiti, I.B., Nielsen, M.T. et al. Tissue partitioning of cadmium in transgenic tobacco seedlings and field grown plants expressing the mouse metallothionein I gene. Transgenic Research 1, 261–267 (1992). https://doi.org/10.1007/BF02525167
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DOI: https://doi.org/10.1007/BF02525167