Abstract
A greenhouse experiment was conducted to study the accumulation of selenium by some vegetable crops commonly grown in the Indian Punjab. Eleven vegetable crops were raised in an alkaline clay loam soil treated with different levels of selenate-Se, i.e., 0, 1.25, 2.5 and 5.0 mg·kg−1 soil. Dry matter yield of both edible and inedible portions of different vegetable crops decreased with increasing Se level in soil except potato (Solanum tuberosum), radish (Raphanus sativus) and cauliflower (Brassica oleracea var. botrytis) which recorded 10%–21% increase in inedible dry matter at 1.25 mg·kg−1 Se soil. Application of 5 mg·kg−1 selenate-Se soil resulted in complete mortality in the case of radish, turnip (Brassica rapa) and brinjal (Solanum melongena). Some vegetable crops including tomato (Lycopersicum esculentum), cauliflower and pea (Pisum sativum), though, survived the toxic effect at the highest concentration of Se yet did not bear any fruit. Potato and spinach (Spinacea oleracea) proved to be highly tolerant crops. Selenium concentration in the edible as well as inedible portions of all the vegetables increased with an increase in the level of applied Se. Selenium accumulation in the edible portion of vegetable crops in the no-Se control ranged from 2.2 to 4.9 mg·kg−1 Se dry weight. At 1.25 mg·kg−1 Se soil, the edible portion of radish accumulated the greatest concentration of Se (38 mg·kg−1 Se dry weight) with that of onion (Allium cepa) bulb the lowest (9 mg·kg−1 Se dry weight). Inedible portions of vegetables accumulated Se 2–5 times more than that absorbed by edible portions. Total Se uptake by edible portions of different vegetables was the greatest at 1.25 mg·kg−1 Se soil, ranging from 7 to 485 μg·pot−1. The results suggest that vegetable crops vary in their sensitivity to the presence of selenate-Se in soil. Vegetative portions were several times richer in Se than other parts of vegetable crops.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Anderson J W, Scarf A R (1983). Selenium and plant metabolism. In: Robb D A, Pierpoint W S, eds. Metals and Micronutrient: Uptake and Utilization by Plants. New York: Academic Press, 241–275
Arvy M P (1993). Selenate and selenite uptake and translocation in bean plants (Phaseolusvulgaris L.). Journal of Experimental Botany, 44: 1083–1087
Asher C J, Butler G W, Peterson P J (1977). Selenium transport in root system of tomato. Journal of Experimental Botany, 28: 279–291
Banuelos G S, Meek D W (1989). Selenium accumulation in selected vegetables. Journal of Plant Nutrition, 12: 1255–1272
Brown T A, Shrift A (1981). Exclusion of selenium from protein of selenium-tolerant Astragalus species. Plant Physiology, 67: 1051–1053
Brown T A, Shrift A (1982). Selenium: toxicity and tolerance in higher plants. Biological Reviews, 57: 59–84
Bureau R G, McDonald A, Jacobson A, May D, Grattan S, Shenan C, Swanton B, Sherer D, Abrams M, Epstein E, Rendig V (1988). Selenium in tissues of crops sampled from the west side of the San Joaquin valley, California. In: Tanji K K, Valoppi L, Woodring R C, eds. Selenium contents in animal and human food crops grown in California, USA Publication number 3330, University of California, and Oakland, USA, 61–66
Cantor A H, Scott M L, Naguchi T (1975). Biological availability of selenium in feedstuffs and selenium compounds for prevention of exudative diathesis in chicks. Journal of Nutrition, 105: 96–101
Cartes P, Gianfreda L, Mora M L (2005). Uptake of selenium and its antioxidant activity in ryegrass when applied as selenate and selenite forms. Plant and Soil, 276: 359–367
Dhillon K S, Dhillon S K (1991). Selenium toxicity in soils, plants and animals in some parts of Punjab, India. International Journal of Environmental Studies, 37: 15–24
Dhillon K S, Dhillon S K (1997). Distribution of seleniferous soils in north-west India and associated toxicity problems in the soil-plantanimal-human continuum. Land Contamination and Reclamation, 5: 313–322
Dhillon K S, Dhillon S K (2003). Distribution and management of seleniferous soils. Advances in Agronomy, 79: 119–184
Duffield-Lillico A J, Dalkin B L, Reid M E (2003). Selenium supplementation, baseline plasma selenium status and incidence of prostate cancer: An analysis of the complete treatment period of the Nutritional Prevention of Cancer Trial. BJU International, 91: 608–612
Epstein E (1955). Passive permeation and active transport of ions in plant roots. Plant Physiology, 30: 529–535
Ferri T, Petruzelli G, Pezzarossa B, Santaroni P, Brunori C, Morabito R (2003). Study of the influence of carboxymethylcellulose on the absorption of selenium (and selected metals) in a target plant. Microchemical Journal, 74: 257–265
Finley JW, Ip C, Lisk D J, Davis C D, Hintze K J, Whanger P D (2001). Cancer protective properties of high-selenium broccoli. Journal of Agriculture and Food Chemistry, 49: 2679–2683
Food and Nutrition Board, Institute of Medicine (2000). Selenium-Dietary Reference Intakes Vitamin C, Vitamin E, Selenium and Carotenoids. Washington, DC: National Academy Press, 284–324
Furr A K, Parkinson T F, GutenmannWH, Pakkala I S, Lisk D J (1978). Elemental content of vegetables, grains, and forages field-grown on fly ash amended soil. Journal of Agriculture and Food Chemistry, 26: 357–359
Germ M, Stibilj V (2007). Selenium and plants. Acta Agricultura Slovenica, 89: 65–71
Hambuckers A, Dotreppe O, Hornick J, Istasse L, Dufrasne I (2008). Soil-applied selenium effects on tissue selenium concentrations in cultivated and adventitious grassland and pasture plant species. Communications in Soil Science and Plant Analysis, 39: 800–811
Hamilton J W, Beath O A (1964). Amount and chemical form of selenium in vegetable plants. Journal of Agriculture and Food Chemistry, 12: 371–374
Hartikainen H, Xue T, Piironen V (2000). Selenium as an antioxidant and pro-oxidant in ryegrass. Plant and Soil, 225: 193–200
Hopper J L, Parker D R (1999). Plant availability of selenite and selenate as influenced by the competing ions phosphate and sulphate. Plant and Soil, 210: 199–207
Ip C, Lisk D J (1994). Enrichment of selenium in allium vegetables for cancer prevention. Carcinogenesis, 15: 1881–1885
Jump R K, Sabey B R (1989). Soil test extractants for predicting selenium in plants. In: Jacobs LW, ed. Selenium in Agriculture and the Environment. Special Publication No. 23, Soil Science Society of America, Madison, WI, USA, 95–105
Levesque M, Vandette E D (1971). Selenium determination in soil and plant materials. Canadian Journal of Soil Science, 51: 85–93
Longnecker M P, Taylor P R, Levander O A, Howe S M, Veillon C, McAdam P A, Patterson K Y, Holden J M, Stampfer M, Morris J S, Willett W C (1991). Selenium in diet, blood, and toenails in relation to human health in a seleniferous area. American Journal of Clinical Nutrition, 53: 1288–1294
Mian Z P (1998). Status of selenium in food and population of Lahore city and cantonment area-Correlation of selenium level with heart and cancer diseases. Dissertation for the Doctoral Degree. Lahore: University of the Punjab
Patrick L (2004). Selenium biochemistry and cancer: A review of the literature. Alternative Medicine Reviews, 9: 239–258
Pezzarossa B, Malorgio F, Tonutti P (1999). Effects of selenium uptake by tomato plants on senescence, ripening and ethylene evolution. In: Kanellis A K, Chang C, Klee H, Bleeker A B, Pech J C, Grierson D, eds. Biology and Biotechnology of the Plant Hormone Ethylene II. Dordrecht: Kluwer Academic Publishers, 275–276
Pezzarossa B, Petruzelli G, Petacco F, Malorgio F, Ferri T (2007). Absorption of selenium by Lactuca sativa as affected by carboxymethylcellulose. Chemosphere, 67: 322–329
Rani N, Dhillon K S, Dhillon S K (2005). Critical levels of selenium in different crops grown in an alkaline silty loam soil treated with selenite-Se. Plant and Soil, 277: 367–374
Rayman M P, Clark L C (2000). Selenium in cancer prevention. In: Roussel A M, ed. Trace Elements in Man and Animals. New York: Plenum Press, 575–580
Saggoo M I S, Dhillon K S, Dhillon S K, Kour J (2004). Evaluation of consumability potentials of leafy vegetables harvested from selenium rich soil. Environmental Information Archives, 2: 479–489
Sakurai H, Tsuchiya K A (1975). A tentative recommendation for the maximum daily intake of selenium. Environmental Physiology and Biochemistry, 5: 107–118
Shamberger R J (1985). The genotoxicity of selenium. Mut Res, 154: 29–48.
Wang Z, Gao Y (2001). Biogeochemical cycling of selenium in Chinese environments. Applied Geochemistry, 16: 1345–1351
Warman P R, Muizelaar T, Termeer W C (1995). Bioavailability of As, Cd, Co, Cr, Cu, Hg, Mo, Ni, Pb, Se and Zn from biosolids amended compost. Compost Science and Utilization, 3: 40–50
Wu L, Huang Z Z, Bureau R G (1988). Selenium accumulation and selenium-salt cotolerance in five grass species. Crop Science, 28: 517–522
Xue T, Hartikainen H, Piironen V (2001). Antioxidative and growthpromoting effect of selenium on senescing lettuce. Plant and Soil, 237: 55–61
Yang G Q, Wang S Z, Zhou R H, Sun S Z (1983). Endemic selenium intoxication of humans in China. American Journal of Clinical Nutrition, 37: 872–881
Author information
Authors and Affiliations
Corresponding author
About this article
Cite this article
Dhillon, K.S., Dhillon, S.K. Accumulation and distribution of selenium in some vegetable crops grown in selenate-Se treated clay loam soil. Front. Agric. China 3, 366–373 (2009). https://doi.org/10.1007/s11703-009-0070-6
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11703-009-0070-6