Abstract
A detailed survey showed that groundwater fluoride was 6.1ppm in the Talupula area of the Anantapur district in southern India which is higher than is normally observed in groundwater elsewhere in India but not so extreme as that reported in Andhra Pradesh (up to 21 mg L-1). Groundwater is used for irrigating agricultural crops as well as for drinking which may expose its population to higher concentrations of fluoride through their diet. A preliminary study examined the concentrations of fluoride in five agricultural crops in the Talupula area and the soil beneath agricultural crops. The stem and leaves of Heliathusannuas, Arachishypogaea, Morusalba, Lychopersiconesculantum, and Phaseolus vulgaris were examined for fluoride and heavy metal accumulation. Heavy metal (Zn, Cu and Pb) accumulation in the stem and leaves were examined to determine if there was any correlation between their uptake and that of fluoride. In the soil beneath the crops, fluoride concentrations ranged from 6.53±0.44 to 8.23±1.22 ppm and a significant accumulation of fluoride was observed in the stems (13.2±2.0 to 23.9±3.6 ppm; p < 0.001) and leaves (16.4±1.9 to 61.5±4.5 ppm) of the agricultural plants. A significant accumulation of fluoride was observed from the stem to the leaves for all plants (p < 0.03) except Helianthus annuas. Copper also displayed significant accumulation from the soil to the stems in some of the plants tested but there was no significant accumulation of zinc or lead. A significant translocation from the stem and accumulation in the leaves was not observed for Cu or Pb but there was significantly higher zinc in the leaves of Arachishypogaea and Morusalba when compared to their stems. This study demonstrated that agricultural plants grown under field conditions and irrigated with groundwater high in fluoride will accumulate fluoride, but that fluoride is unlikely to have a significant effect on Cu, Zn or Pb accumulation in the stems and leaves of agricultural plants of the area. While drinking water is still the major cause of fluorosis in southern India, consumption of foods with high fluoride concentrations may also increase the risk of fluorosis.
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References
Allen, S.E. (1989) Chemical analysis of ecological materials (2nd ed.,), Blackwell Scientific Publ., Oxford, UK, 565p.
Alloway, B.J. (2009) Soil factors associated with zinc deficiencies in crops and humans. Environ Geochem Health, v.31, pp.537–548.
Ando, M., Tadano, M., Asanuma, S., Tamura, K., Matsushima, S., Watanabe, T. Kondo, T. Sakurai, S., Liang, R. Ji. C and Cao, S. (1998) Health Effects of Indoor Fluoride Pollution from Coal burning in China. Environ. Health Persp., v.106(5), pp.239–244.
Arnesen, A.K.M. (1997) Availability of fluoride to plants grown in contaminated soils. Plant Soil, v.191, pp.13–25.
Arnesen, A.K.M. (1998). Effects of fluoride pollution on pH and solubility of Al, Fe, Ca, Mg, K and organic matter in soil from Ardal (Western Norway). Water Air Soil Pollution, v.103, pp.375–88.
Awashthi, S.K. (2000) Prevention of Food Adulteration Act no 37 of 1954. Central and State Rules as Amended for 1999. Ashoka Law House, New Delhi.
Aweng, E.R., Karimah, M. and Suhaimi, O. (2011) Heavy metals concentration of irrigation water, soils and fruit vegetables in Kota Bharu area, Kelantan, Malaysia. Jour. Appld. Sci. Environ. Sanitation, v.6, pp.463–470.
Baker, A.J.M. (1981) Accumulators and excluders–strategies in the response of plants to heavy metals. Jour. Plant Nutrition, v.3, pp.643–654.
Bichi, M.H. and Bello, U.F. (2013). Heavy metal pollution in surface and ground waters used for irrigation along river Tatsawarki in the Kano, Nigeria. IOSR Jour. Engg., v.3(8), pp.1–9.
Brewer, R.F. (1965). Fluorine. In: Black, C.A. (ed.), Methods of Soil Analysis: Agronomy Monograph, (Part 2). Madison, WI, USA.
Brindha, K., Rajesh, R., Murugan, R. and Elango, L. (2011) Fluoride contamination in ground water in parts of Nalgonda District, Andhra Pradesh, India. Environ. Monit. Assess., v.172, pp.481–492.
Brindha, K and Elango, L. (2011) Fluoride in groundwater: Causes, implications and mitigation measures. In: Monroy, S.D. (Ed.), Fluoride Properties, Applications and Environmental Management, pp.111–136.
Brooks, R.R. (1983) Biological methods of prospecting for minerals. Wiley and Sons, New York.
Brooks, R.R., Reeves, R.D., Morrison, R.S. and Malaisse, F. (1980) Hyperaccumulation of copper and cobalt — a review. Royal Botanical Society of Belgium, v.113, pp.166–172.
Cakmak, I. (2010) Biofortification of durum wheat with zinc and iron. Cereal Chem., v.87, pp.10–20.
Chakrabarti, S., Patra, P.K. and Mondal, B. (2013) Uptake of fluoride by two paddy (Oryza sativa L.) varieties treated with fluoride-contaminated water. Paddy Water Environment, v.11, pp.619–623.
Chang, C.Y., Yu, H.Y., Chen, J.J., Li, F.B., Zhang, H.H. and Liu, C.P. (2014) Accumulation of heavy metals in leaf vegetables from agricultural soils and associated potential health risks in the Pearl River Delta, South China. Environ. Monit. Assess., v.186, pp.1547–1560.
Chatterjee, C., Gopal, R. and Dube, B.K. (2006) Physiological and biochemical responses of French bean to excess cobalt. Jour. Plant Nutrition, v.29, pp.127–136.
Chen, Y., Huang, B., Hu, W., Weindorf, D.C. Liu, X., and Yang, L. (2014) Accumulation and ecological effects of soil heavy metals in conventional and organic greenhouse production systems in Nanjing, China. Environ. Earth Sci., v.71(8), pp.3605–3616.
De Lacerda, L.D. (1998) Trace metals in mangrove plants: why such low concentrations? In: Lacerda, L.D.; Diop, H.S. (eds.), Mangrove Ecosystem Studies in Latin America and Africa. UNESCO, pp.171–178.
Elloumi, N., Abdallab, F.B., Mezghani, I., Rhouma, A., Boukhris, M. and Tunisia, S. (2005) Effect of fluoride on almond seedling in culture solution. Fluoride, v.38, pp.193–198.
FoodAndAgriculture Orgnaisation (FAO) (1985) Water Quality for Agriculture. Paper No. 29 (Rev. 1) UNESCO, Publication, Rome
Fung, K.F., Zhang, Z.Q., Wong, J.W.C. and Wong, M.H. (1999) Fluoride contents in tea and soil from tea plantations and the release of fluoride into tea liquor during infusion. Environ Pollut., v.104(2), pp.197–205.
Gao, H.J., Zhao, Q., Zhang, X.C., Wan, X.C. and Mao, J.D. (2014) Localization of fluoride and aluminum in subcellular fractions of tea leaves and roots. Jour. Agricul. Food Chem., v.62, pp.2313–2319.
Gautam, R., Bhardwaj, N., and Saini, Y. (2010) Fluoride accumulation by vegetables and crops grown in Nawa Tehsil of Nagaur district (Rajasthan, India). Jour. Phytology, v.2, pp.80–85.
Ghosh, A., Mukherjee, K., Ghosh, S.K. and Saha, B. (2013) Sources and toxicity of fluoride in the environment. Res. Chem. Intermediates, v.39 (7), pp.2881–2915.
Gomes, M.V.T., De Souza, R.R., Teles, V.S. and Araujo Mendes, E. (2014) Phytoremediation of water contaminated with mercury using Typhadomingensis in constructed wetland. Chemosphere, v.103, pp.228–233.
Gupta, S., and Banerjee, S. (2011) Fluoride accumulation in crops and vegetables and dietary intake in a fluoride-endemic area of West Bengal. Fluoride, v.44, pp.153–157.
Hart, J.J., Norvell, W.A., Welch, R.M., Sullivan, L.A. and Kochian, L.V. (1998) Characterization of zinc uptake, binding, and translocation in intact seedlings of bread and Durum wheat cultivars. Plant Physiol., v.118, pp.219–226).
Impa, S.M., Morete, M.J., Ismail, A.M., Schulin, R., and Johnson-Beebout, S.E. (2013) Zn uptake, translocation and grain Zn loading in rice (Oryza sativa L) genotypes selected for Zn deficiency tolerance and high grain Zn. Jour Exp. Bot. doi: 10.1093/jxb/ert118.
Jones, J.B. Jr., (1972) In: Mortvedt, J.J., Giordano, P.M. and Lindsay, W.L. (Editors). Micronutrients in Agriculture. Soil Sci. Soc. Am. Inc, Madison, WI, USA. pp.319–346.
Kabasakalis, A. T. (1994). Fluoride content of vegetables irrigated with water of high fluoride levels. Fresenius Environ. Bull., v.3, pp.337–380.
Kabata-Pendias, A. and Piotrowska, M. (1984) Zanieczyszceniegle, roslin uprawnychpiewiastkamisladowymi, cbr-opracowaneieprobemoe, warszawa, Poland.
Kabata-Pendias, A. (2001) Trace Elements in soil and plants, Third edition, CRC Press Inc, Boca Raton, Florida.
Kamaluddin, M. and Zwiazek, J.J. (2003). Fluoride inhibits root water transport and affects leaf expansion and gas exchange in aspen (Populustremuloides) seedlings. Physiol. Plantarum, v.117, pp.368–375.
Kostyshina, S.S., Perepelitsa, O.O. and Smetanyukb, O. I. (2011) Peculiarities of fluoride accumulation in the plants of Meadow Biotopes of Northern Bukovyna. Contemporary Problems of Ecology, v.4, pp.621–625.
Kundu, M.C., and Mandal, B.(2009). Agricultural activities influence nitrate and fluoride contamination in drinking groundwater of an intensively cultivated district in India. Water Air Soil Pollut. v.198, pp.243–252.
Kusa, Z., Wardas, W., Sochacka, J., and Pawlowska-Goral, K. (2004). Fluoride accumulation in selected vegetables during their vegetation. Polish Jour. Environ. Studies, v.13, pp.55–58.
Lee, M., Lee, K., Lee, J., Noh, E.W, and Lee, Y. (2005). AtPDR12 contributes to lead resistance in Arabidopsis. Plant Physiology, v.138, pp.827–836.
Leonard, H., Weinstein, A. and Davison, A.W. (2004) Fluorides in the environment: Effects on plants and animals. CAB Internat. Wallingford, Oxon, UK.
Mahmood, T. and Islam, K.R. (2006) Response of rice seedlings to copper toxicity and acidity. Jour. Plant Nutrition, v.29, pp.943–957.
Markert, B. (1994). Plants as biomonitors–potential advantages and problems. In: Adriano, D.C., Chen, Z.S. and Yang, S.S. (Eds.), Biogeochemistry of trace elements. Sci. Tech. Lett., Northwood, NY, USA. pp.601–613.
Marschner, H. (1993) Zn uptake from soil. In: Rosson, A.D. (Ed.), Zinc in Soils and Plants. Springer, Netherlands, pp.59–77.
McQuaker, N.R. and Gurney, M. (1977) Determination of total fluoride in soil and vegetation using an alkali fusion-selective ion electrode technique. Analytical Chemistry, v.49(1), pp.53–56.
Mezghani, I., Elloumi, N., Ben Abdallah, F., Chaieb, M., and Boukhris, M (2005) Fluoride accumulation by vegetation in the vicinity of a phosphate fertilizer plant in Tunisia. Fluoride, v.38(1), pp.69–75.
Nagaraja Rao, B.K., Rajurkar, S.T., Ramlingaswamy, G., and Ravindra Babu, B. (1987) Stratigraphy, structure and evolution of the Cuddapah basin: Purana Basins of Peninsular India (Middle to Late Proterozoic. Mem. Geol. Soc. India, no.6, pp.33–86.
Nagaraju, A., Sarma, M.R.S., Aitkenhead-Peterson, J.A. and Sunil, K. (2011) Fluoride incidence in groundwater: A case study from Talupula, Andhra Pradesh, India. Environ. Monit. Assess., v.172(1-4), pp.427–443.
Nagaraju, A., Sunil Kumar, K and Thejaswi, A (2013) Evaluation of plants growing on lead mine spoils: Significance for abandoned mine reclamation in Andhra Pradesh, India. Resources Environ. v.3, pp.155–162.
Nagata, T., Hayatsu, M., and Kosuge, N. (1993) Aluminium kinetics in the tea plant using 27Al and 19F NMR. Phytochemistry, v.32, pp.771–775.
National Research Council (2006) Fluoride in Drinking Water: A Scientific Review of EPA’s Standards. National Academies Press, Washington, DC, USA.
Njenga, L.W. and Kariuki, D.N. (1994) Accumulation of fluoride by plants and vegetables. International Jour. Biochemistry Physics, v.3, pp.33–35.
Pal, K.C., Mondal, N.K., Bhaumik, R., Banerjee, A., and Datta, J.K. (2012) Incorporation of fluoride in vegetation and associated biochemical changes due to fluoride contamination in water and soil: A comparative field study. Annals Environ. Sci., v.6, pp.123–139.
Pant, S., Pant, P. and Bhiravamurthy, P.V. (2008) Effects of fluoride on early root and shoot growth of typical crop plants of India. Fluoride, v.41(1), pp.57–60.
Petersen, P.E., and Lennon, M.A. (2004) Effective use of fluorides for the prevention of dental caries in the 21st century: The WHO approach. Community Dent Oral Epidemiology, v.32, pp.319–321.
Rathore, S. (1987) Effect of Fluoride toxicity on chlorophyll content of Viciafaba and Allium cepa under modified conditions of NPK nutrition. Fluoride, v.20, pp.183–188.
Ruan, J., Ma, L, Shi, Y and Han W. (2003) Uptake of fluoride by tea plant (Camellia sinensis L.) and the impact of aluminum. Joir. Sci. Food and Ag., v.83, pp1342-1348.
Ruan J., Ma, L., Shi, Y and Han, W (2004) The impact of pH and calcium on the uptake of Fluoride by tea plants (Camellia sinensis L.). Ann Bot. v.93, pp.97–105. doi: 10.1093/aob/mch010.
Rycewicz-Borecki, M., Mclean, J.E., and Dupont, R.R. (2016) Bioaccumulation of copper, lead and zinc in six macrophyte species grown in simulated storm water bioretention systems. Jour. Environ. Managmt. v.166, pp.267–275.
Saini, P., Khan, S., Baunthiyal, M. and Sharma V (2013) Mapping of fluoride endemic area and assessment of F-1 accumulation in soil and vegetation. Environ. Monit. Assess., v.185, pp.2001–2008.
Sêkara, A., Poniedziaek, M., Ciura, J. and Jêdrszczyk, E. (2005) Zinc and Copper Accumulation and Distribution in the Tissues of Nine Crops: Implications for Phytoremediation. Polish Jour. Environ. Studies, v.14(6), pp.829–835.
Singh, V., Gupta, M.K., Rajwanshi, P., Mishra, S., Srivastava R., Srivastava, M.M., Prakash, S. and Dass, S. (1995) Plant uptake of fluoride in irrigation water by Ladyfinger (Abelmorchusesculentus). Food and Chemical Toxicology, v.33(5), pp.399–402.
Singh K. (2008) Effect of High Fluoride Content on Flora and Fauna of Phagi Tehsil. Ph.D. Thesis. University of Rajasthan, Jaipur.
Stevens, D.P., Mclaughlin, M.J. and Alston, A.M. (1997) Phytotoxicity of aluminium-fluoride complexes culture by Avena sativa and Lycopersicon es clentum. Plant Soil, v.192(1), pp.81–93.
Susheela, A.K. (Ed.), (1993) Prevention and control of fluorosis. Vol I, Health Aspects. Government of India Publication.
Susheela, A.K., Mondal, N.K., Rashmi, G., Ganesh, K., Bhasin, S. and Gupta, G. (2007) Fluoride ingestion and health hazards with focus on anaemia in pregnancy and low birth weight babies: guidelines for rectification. Fluoride, v.40, pp.259–292.
Suthar, S., Garg, V.K., Sushma, S., et al. (2008) Fluoride contamination in drinking water in rural habitations of Northern Rajasthan, India. Environ. Monit. Assess., v.145, pp.1–6.
Takmaz-Nisancioglu, S., and Davison, A.W. (1988) Effects of aluminum on fluoride uptake by plants. New Phytol., v.109, pp.149–155.
Thornton, I. (1983) Applied Environmental Geochemistry. Academic Press, London, UK.
US EPA (1996) Sources of lead in soil: A literature review Volume II Study Abstracts. Final Report EPA 747-R-98-001b.
Verbree, C.L., Aitkenhead-Peterson, J.A., Loeppert, R.G., Awika, J.M. and Payne, W.A. (2014) Shea (Vitellariaparadoxa) tree and soil parent material effects on soil properties and intercropped sorghum grain-Zn in southern Mali, West Africa. Plant Soil DOI 10.1007/s11104-014-2244-0.
World Health Organisation. (1994) Expert Committee on Oral Health Status and Fluoride Use. Fluorides and oral health. WHOTechnical Report Series No.846. World Health Organisation, Geneva.
Xie, Z., Chen, Z., Sun, W., Guo, X., Yin, B., Wang J. (2007) Distribution of aluminum and fluoride in tea plant and soil of tea garden in Central and Southwest China. Chinese Geographical Sci., v.17, pp.376–382.
Xiong, Z.T. (1997) Bioaccumulation and physiological effects of excess lead in a roadside pioneer species Sonchusoleraceus L. Environmental Pollution, v.97(3), pp.275–279.
Yadav, R.M., Sharma, S., Bansal, M., Singh A., Panday, V. and Maheshwari, R., (2012) Effects of Fluoride accumulation on growth of vegetables and crops in Dausa district, Rajasthan, India. Adv. Bioresearch v.3, pp.14–16.
Yumada, H., and Hattori, T. (1977) Investigation of the relationship between aluminium and fluorine in plants (Part I). Relationship between aluminium and fluorine in tea leaves. Japanese Jour. Soil Sci. Plant Nutr., v.48, pp.253–261.
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Nagaraju, A., Thejaswi, A. & Aitkenhead-Peterson, J.A. Fluoride and heavy metal accumulation by vegetation in the fluoride affected area of Talupula, Anantapur district, Andhra Pradesh. J Geol Soc India 89, 27–32 (2017). https://doi.org/10.1007/s12594-017-0555-5
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DOI: https://doi.org/10.1007/s12594-017-0555-5