Abstract
Effects of heavy metal contamination on growth, leaf turnover, biomass allocation and leaf and root structure of Leucanthemum vulgare Lam. were investigated. Plants were grown in two outdoor experiments, for 5 weeks or for 3 months, respectively, on sand with different additions of slag containing elevated levels of heavy metals, especially Cu and Ni. In the 3-month experiment nutrients were provided as composted manure, in the 5-week experiment as a solution. Slag contamination reduced plant growth, biomass allocation to roots, specific root length and specific leaf area, while root tissue density and leaf dry matter content increased. Fine root diameter increased, whereas coarse root diameters showed a non-significant decreasing trend. Toxicity of slag was lower in the 3-month experiment, probably due to organic matter in the substrate. We conclude that heavy metals in the soil around Cu–Ni smelters may, besides directly reducing growth of the plants, increase their susceptibility to other stresses such as drought, by reducing the root length to leaf area ratio. Fine and coarse roots show distinct responses, indicating that different root diameter classes should be regarded separately to fully understand stress responses of root systems.
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Adamo P, Dudka S, Wilson MJ, McHardy WJ (2002) Distribution of trace elements in soils from the Sudbury smelting area (Ontario, Canada). Water Air Soil Pollut 137:95–116
Ahonen-Jonnarth U, Finlay RD (2001) Effects of elevated nickel and cadmium concentrations on growth and nutrient uptake of mycorrhizal and non-mycorrhizal Pinus sylvestris seedlings. Plant Soil 236:129–138
Alam MM, Hayat S, Ali B, Ahmad A (2007) Effect of 28-homobrassinolide treatment on nickel toxicity in Brassica juncea. Photosynthetica 45:139–142
Archambault DJ, Winterhalder K (1995) Metal tolerance in Agrostis scabra from the Sudbury, Ontario area. Can J Bot 73:766–775
Arduini I, Godbold DL, Onnis A (1995) Influence of copper on root growth and morphology of Pinus pinea L. and Pinus pinaster Ait. seedlings. Tree Physiol 15:411–415
Arduini I, Ercoli L, Masoni A (2006) Response of Miscanthus sinensis to prolonged applications of chromium in hydroponics. Agrochimica 50:187–199
Barceló J, Poschenrieder C (2004) Structural and ultrastructural changes in heavy metal exposed plants. In: Prasad MNV (ed) Heavy metal stress in plants. Springer, Berlin, Germany, pp 223–248
Bernal M, Cases R, Picorel R, Yruela I (2007) Foliar and root Cu supply affect differently Fe- and Zn-uptake and photosynthetic activity in soybean plants. Environ Exp Bot 60:145–150
Boot RGA, Mensink M (1990) Size and morphology of root systems of perennial grasses from contrasting habitats as affected by nitrogen supply. Plant Soil 129:291–299
Bradshaw AD (1952) Populations of Agrostis tenuis resistant to lead and zinc poisoning. Nature 169:1098
Brun LA, Le Corff J, Maillet J (2003) Effects of elevated soil copper on phenology, growth and reproduction of five ruderal plant species. Environ Pollut 122:361–368
Burzynski M, Kłobus G (2004) Changes of photosynthetic parameters in cucumber leaves under Cu, Cd, and Pb stress. Photosynthetica 42:505–510
Bushamuka VN, Zobel RW (1998) Maize and soybean tap, basal and lateral root responses to stratified acid, aluminum-toxic soil. Crop Sci 38:416–421
Chen YX, Shi JY, Zhang WD, Lin Q, Tian GM (2004) EDTA and industrial waste water improving the bioavailability of different Cu forms in contaminated soil. Plant Soil 161:117–125
Clark LJ, Whalley WR, Barraclough PB (2003) How do roots penetrate strong soil? Plant Soil 255:93–104
Dresler W, Sommerville ID, Krofchak D (1997) Metal recovery from slags and wastes. In: Mostaghaci H (ed) Material solutions for environmental problems. Canadian Institute of Mining, Metallurgy and Petroleum, Montreal, Canada, pp 117–127
Environment Canada (2007) Climate data online. http://www.climate.weatheroffice.ec.gc.ca/climateData/canada_e.html. Accessed September 11, 2007
Evans LJ, Sengdy B, Lumsdon DG, Stanbury DA (2003) Cadmium adsorption by an organic soil: a comparison of some humic-metal complexation models. Chem Spec Bioavailab 15:93–100
Fuhrer J (1983) Phytotoxic effects of cadmium in leaf segments of Avena sativa L., and the protective role of calcium. Experentia 39:525–526
Gajewska E, Skłodowska M, Słaba M, Mazur J (2006) Effect of nickel on antioxidative enzyme activities, proline and chlorophyll contents in wheat shoots. Biol Plant 50:653–659
Helmisaari H-S, Makkonen K, Olsson M, Viksna A, Mälkönen E (1999) Fine-root growth, mortality and heavy metal concentrations in limed and fertilized Pinus silvestris (L.) stands in the vicinity of a Cu–Ni smelter in SW Finland. Plant Soil 209:193–200
Jana S, Choudhuri MA (1982) Senescence in submerged aquatic angiosperms: effects of heavy metals. New Phytol 90:477–484
Jansons KJ, Rousell DH (2002) Geotechnical properties and construction in bedrock and soil. In: Rousell DH, Jansons KJ (eds) The physical environment of the city of Greater Sudbury. Ontario Geological Survey, Toronto, Canada, pp 87–100
Kalapos T, van den Boogaard R, Lambers H (1996) Effect of soil drying on growth, biomass allocation and leaf gas exchange of two annual grass species. Plant Soil 185:137–149
Kjær C, Elmegaard N (1996) Effects of copper sulfate on black bindweed (Polygonum convolvulus L). Ecotoxicol Environ Saf 33:110–117
Kopittke PM, Menzies NW (2006) Effect of Cu toxicity on growth of cowpea (Vigna unguiculata). Plant Soil 279:287–296
Kukkola E, Rautio P, Huttunen S (2000) Stress indications in copper- and nickel-exposed Scots pine seedlings. Environ Exp Bot 43:197–210
Larbi A, Morales F, Abadia A, Gogorcena Y, Lucena J, Abadia J (2002) Effects of Cd and Pb in sugar beet plants grown in nutrient solution: induced Fe deficiency and growth inhibition. Functional Plant Biology 29:1453–1464
Lind BB, Fallman A-M, Larsson LB (2001) Environmental impact of ferrochrome slag in road construction. Waste Manage 21:255–264
Maksymiec W, Krupa Z (2007) Effects of methyl jasmonate and excess copper on root and leaf growth. Biol Plant 51:322–326
Martins LL, Mourato MP (2006) Effect of excess copper on tomato plants: growth parameters, enzyme activities, chlorophyll, and mineral content. J Plant Nutr 29:2179–2198
McNear DH Jr, Chaney RL, Sparks DL (2007) The effects of soil type and chemical treatment on nickel speciation in refinery enriched soils: a multi-technique investigation. Geochim Cosmochim Acta 71:2190–2208
Newman EI (1966) A method of estimating the total length of root in a sample. J Appl Ecol 3:139–145
Nieminen TM (2005) Response of Scots pine (Pinus sylvestris L) to a long-term Cu and Ni exposure. Finnish Forest Research Institute, Research Papers 942:1–63
Ouzounidou G, Moustakas M, Symeonidis L, Karataglis S (2006) Response of wheat seedlings to Ni stress: effects of supplemental calcium. Arch Environ Contam Toxicol 50:346–352
Potters G, Pasternak TP, Guisez Y, Palme KJ, Jansen MAK (2007) Stress-induced morphogenetic responses: growing out of trouble? Trends Plant Sci 12:98–105
Rauser WE, Winterhalder EK (1985) Evaluating copper, nickel, and zinc tolerances in four grass species. Can J Bot 63:58–63
Ryser P (1998) Intra- and interspecific variation in root length, root turnover and the underlying parameters. In: Lambers H, Poorter H, Van Vuuren MMI (eds) Variation in plant growth. Backhuys Publishers, Leiden, The Netherlands, pp 441–465
Ryser P, Lambers H (1995) Root and leaf attributes accounting for the performance of fast- and slow-growing grasses at different nutrient supply. Plant Soil 170:251–265
Ryser P, Sauder W (2006) Effects of heavy-metal-contaminated soil on growth, phenology and biomass turnover of Hieracium piloselloides. Environ Pollut 140:52–61
SARA-Group (2004) Summary report: 2001 Sudbury soils data. Sudbury Area Risk Assessment, Sudbury, Ontario, Canada
Shaw BP, Sahu SK, Mishra RK (2004) Heavy metal induced oxidative damage in terrestrial plants In: Prasad MNV (ed) Heavy metal stress in plants. Springer, Berlin, Germany, pp 84–126
Sheldon AR, Menzies NW (2005) The effect of copper toxicity on the growth and root morphology of Rhodes grass (Chloris gayana Knuth.) in resin buffered solution culture. Plant Soil 278:341–349
Tanyolaç D, Ekmekçi Y, Ünalan S (2007) Changes in photochemical and antioxidant enzyme activities in maize (Zea mays L) leaves exposed to excess copper. Chemosphere 67:89–98
Taylor JG, Blamey FPC, Edwards DG (1998) Antagonistic and synergistic interactions between aluminum and manganese on growth of Vigna unguiculata at low ionic strength. Physiol Plant 104:183–194
Tennant D (1975) A test of a modified line intersect method of estimating root length. J Ecol 63:995–1001
Wallace A, Berry WL (1989) Dose–response curves for zinc, cadmium, and nickel in combinations of one, two, or three. Soil Sci 147:401–410
Wilkins DA (1957) A technique for the measurement of lead tolerance in plants. Nature 180:37–38
Woolhouse HW (1983) Toxicity and tolerance in the responses of plants to metals. In: Lange OL, Nobel PS, Osmond CB, Ziegler H (eds) Encyclopedia of plant physiology, vol 12C: physiological plant ecology. Springer, Berlin, Germany, pp 245–300
Xiong Z-T, Liu C, Geng B (2006) Phytotoxic effects of copper on nitrogen metabolism and plant growth in Brassica pekinensis Rupr. Ecotoxicol Environ Saf 64:273–280
Zheng YB, Wang LQ, Dixon M (2005) Greenhouse pepper growth and yield response to copper application. Hortscience 40:2132–2134
Zobel RW, Kinraide TB, Baligar VC (2007) Fine root diameters can change in response to changes in nutrient concentrations. Plant Soil 297:243–254
Acknowledgements
We thank Fisher-Wavy (Sudbury, Ontario, Canada) for allowing us to use slag from their slag crushing operations, Joinal Abedin and Graeme Spiers for the elemental analysis of the substrates, and Werner Dresler for the advice on slag. We are grateful for Frank Mallory for allowing the use of his land for the experimental garden. We acknowledge the financial support by the NSERC (253246) and the Laurentian University Research Fund.
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Ryser, P., Emerson, P. Growth, root and leaf structure, and biomass allocation in Leucanthemum vulgare Lam. (Asteraceae) as influenced by heavy-metal-containing slag. Plant Soil 301, 315–324 (2007). https://doi.org/10.1007/s11104-007-9451-x
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DOI: https://doi.org/10.1007/s11104-007-9451-x