Abstract
Wetland plants have a capacity for metal sequestration and have been used to remediate such environmental contaminants. How this capacity will be affected by a warming environment is not well-known. Our objective was to identify the effect of small environmentally realistic increases in temperature on metal (cadmium, zinc, lead, and copper) accumulation in Typha latifolia as compared with Scirpus acutus. These common wetland plant species were grown in metal-contaminated sediments at 13°C, 16°C, and 18°C for 3 months to determine the effect of environmentally realistic temperatures on metal accumulation. Cd109 was used as a radiotracer to study the effect of temperature on uptake kinetics. Growth of the two wetland plants differed markedly; S. acutus displayed linear growth reaching a maximum height of ca. 100 cm; by contrast, T. latifolia grew to ca. 40 cm by day 60 with no further growth occurring over the remainder of the 105-day growth period. S. acutus accumulated more cadmium, lead, and zinc from contaminated sediments than T. latifolia, but only within roots and rhizomes. Although not significant, uptake of cadmium, lead, and zinc by both plants was enhanced under warmer conditions and was most pronounced in S. acutus. This was supported by the radiotracer studies which indicated that under the higher temperatures, there was increased rates of Cd109 uptake by shoots of S. acutus. By contrast, temperature did not affect Cd109 uptake rate constants in T. latifolia. S. acutus appears to be more effective at sequestering metals from contaminated sediments; this species as compared to T. latifolia may also be more affected by a warming climate. In the design of wetlands for metal remediation, differences in how these two plants sequester metals from their environment should be considered.
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References
Almas, A. R., & Singh, B. R. (2001). Plant uptake of cadmium-109 and zinc-65 at different temperature and organic matter levels. Journal of Environmental Quality, 30, 869–877.
Chen, M., & Ma, L. Q. (2001). Comparison of three aqua regia digestion methods for twenty florida soils. Soil Science Society of America Journal, 65, 491–499.
Foiles, M. W. (1965). Grand fir, Abies grandis (Dougl.) Lindl. In Silvics of forest trees of the United States. pp. 19–24. H. A. Fowells, comp. U.S. Department of Agriculture, Agriculture Handbook 271. Washington, DC.
Fritioff, A., Kautsky, L., & Greger, M. (2005). Influence of temperature and salinity on heavy metal uptake by submersed plants. Environmental Pollution, 133, 265–274.
Garnham, G. W., Codd, G. A., & Gadd, G. M. (1992). Kinetics of uptake and intracellular location of cobalt, manganese, and zinc in the estuarine green alga Chlorella salina. Applied Microbiology and Biotechnology, 37, 270–276.
Golder. (2007). Summary of Wetlands investigations for the teck Cominco area of interest: Final Report. Prepared for Teck Cominco. Prepared by Golder Associates. August 2007.
Ghaly, A. E., Snow, A., & Kamal, M. (2008). Kinetics of manganese uptake by wetland plants. American Journal of Applied Sciences, 5, 1415–1423.
Government of B.C. (Gov. B.C.). 2003. Part D soil and sediment sampling. Province of British Columbia.
Hammer, D. A. (Ed.). (1989). Constructed wetlands for wastewater treatment: Municipal, industrial, and agricultural. Michigan: Lewis Publishers Inc.
Harris, C. S. (1999). Bioaccumulation of zinc in periphyton and invertebrates: Lotic field and microcosm studies. Master of Science Thesis. Craig S. Harris. April 1999.
Harris, N. S., & Taylor, G. J. (2004). Cadmium uptake and translocation in seedlings of near isogenic lines of duram wheat that differ in grain cadmium accumulation. BMC Plant Biology 4:4. http://www.biomedcentral.com/1471-2229/4/4
Kadlec, R. H., & Knight, R. L. (1996). Treatment wetlands. USA: CRC.
Kalra, Y. P. (1998). Handbook of reference methods for plant analysis. USA: CRC.
Li, Z., Tang, S., Deng, X., Want, R., & Song, Z. (2010). Contrasting effects of elevated CO2 on Cu and Cd uptake by different rice varieties grown on contaminated soils with two levels of metals: Implications for phytoextraction and food safety. Journal of Hazardous Materials, 177, 352–361.
MacKenzie, W. H., & Moran, J. R. (2004). Wetlands of British Columbia: A guide to identification. Ministry of Forest Research Program. Victoria, B.C. Land Management Handbook 52.
Mander, U., & Jessen, P. D. (2002). Constructed wetlands for wastewater treatment in cold climates. Newton: Boston.
Mitsch, W. J., & Gosselink, J. G. (1993). Wetlands (2nd ed.). USA: Van Nostrand Reinhold.
Natural Resources Canada (NRC). (2006). Climate change impacts and adaptation: A Canadian perspective projected climate change. Accessed from: http://adaptation.nrcan.gc.ca/perspective/summary_2_e.php
O’Keeffe, J., & Bendell-Young, L. I. (2002). Uptake of cadmium by the invasive perennial weeds, Ranunculus repens and Geranium robertianum under laboratory conditions. Journal of Environmental Monitoring, 4, 413–416.
Peer, A. W., Baxter, I. R., Richards, E. L., Freeman, J. L., Murphy, A. S. (2006). Phytoremediation and hyperaccumulator plants. Molecular Biology of Metal Homeostasis and Detoxification. Springer Berlin and Heidelberg, pp. 299–340.
Perkin-Elmer. (1996). Analytical methods: Atomic absorption spectroscopy. The Perkin-Elmer Corporation.
Reddy, A. R., Rasineni, G. K., & Raghavendra, A. S. (2010). Impact of global elevated CO2 concentrations on photosynthesis and plant productivity. Current Science, 99, 46–57.
Rehbein, C. (2004). Remedial agriculture: Reconciling ecological restoration and agriculture in the design of a Wetland Complex. Rehbein, Christina. Masters of Environmental Studies.
Robert, F., Risser, G., & Petel, G. (1999). Photoperoid and temperature effect on growth of strawberry plant (Fragaria × ananassa Dutch) development of a morphological test to assess the dormancy induction. Scientia Horticulturae, 82, 217–226.
Ross, S.M. 1994. Toxic Metals in Soil Plant Systems. (ed) John Wiley and Sons. England.
Singh, J., Viswanathan, P. N., Guptas, M., & Devi, S. (1993). Uptake and translocation of Cd109 by two aquatic ferns in relation to relative toxic response. Bulletin of Environmental Contamination and Toxicology, 51, 914–919.
Salisbury, F. B., & Ross, C. W. (1992). Plant physiology, 4th Edn. Belmont, CA: Wadsworth, Inc.
Sasmaz, A., Obek, E., & Hasar, H. (2008). The accumulation of heavy metals in Typha latifolia in a stream carrying secondary effluent. Journal of Ecological Engineering, 33, 278–284.
Spittlehouse, D. L. (2008). Climate change, impacts, and adaptation scenarios: Climate change and forest and range management in British Columbia. Ministry of Forests and Range. Forest Sciences Program. Technical Report 045.
Went, F. W. (1953). The effect of temperature on plant growth. Annual Review of Plant Physiology, 4, 347–362.
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The authors gratefully acknowledge the financial and logistical support of B. Duncan of Teck Cominco. Funding in part was through an NSERC discovery grant to LB.
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Brunham, W., Bendell, L.I. The Effect of Temperature on the Accumulation of Cadmium, Copper, Zinc, and Lead by Scirpus acutus and Typha latifolia: A Comparative Analysis. Water Air Soil Pollut 219, 417–428 (2011). https://doi.org/10.1007/s11270-010-0717-1
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DOI: https://doi.org/10.1007/s11270-010-0717-1