Abstract
Sugarcane is one of the world’s largest and extremely important crop. It plays a major role in the world economy and is the main source for sugar and ethanol production. The effect on crop growth and development due to soil and water contamination with toxic heavy metals is a serious environmental problem. Heavy metal accumulation in agricultural land is a threat to crop productivity and quality. Heavy metals such as As, Cd, Cu, Cr, Pb, Ni, Zn, Hg, etc., and their various sources like industrial effluents, wastewater irrigation, polluted soil, sewage sludge, and use of pesticides and excessive fertilizers are responsible for the contamination. Increasing levels of heavy metals in soil are absorbed by growing sugarcane, where they reach phytotoxic levels and could lead to severe impacts on plant development. Heavy metals have adverse effects on the ecosystem. The consumption of contaminated crop and juice also causes health issues in humans as the edible parts of crop show a higher accumulation of these toxic metals. This chapter highlights the impact of heavy metal toxicity on sugarcane growth, development and productivity. The focus is laid on sources of heavy metal exposure to sugarcane, their route of exposure, bio uptake, and mechanism of toxicity in the crop. The various toxic effects, symptoms of some heavy metals on sugarcane, and health risks are also discussed.
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References
Abdus-salam N, Adekola FA, Bolorunduro OJ (2008) Environmental assessment of the impact of feed water on the quality of sugarcane juice. Int J Chem 18(3):129–135
Alejandro S, Holler S, Meier B, Peiter E (2020) Manganese in plants: from acquisition to subcellular allocation. Front Plant Sci. https://doi.org/10.3389/fpls.2020.00300
Alghobar MA, Suresha S (2015) Evaluation of nutrients and trace metals and their enrichment factors in soil and sugarcane crop irrigated with wastewater. J Geosci Environ Prot 3:46–56
Arduini I, Godbold DL, Onnis A (1994) Cadmium and copper change root growth and morphology of Pinus pinea and Pinus pineaster seedlings. Physiol Plant 92:675–680
Asati A, Pichhode M, Kumar N (2016) Effect of heavy metals on plants: an overview. Int J App Innov Engg Mang 5(3):56–66
Azevedo AR, Carvalho FR, Cia CM, Gratão LP (2011) Sugarcane under pressure: an overview of biochemical and physiological studies of abiotic stress. Trop Plant Biol 4:42–51
Chandra R, Bharagava R, Yadav S, Mohan D (2008) Accumulation and distribution of toxic metals in wheat (Triticum aestivum L.) and Indian mustard (Brassica campestris L.) irrigated with distillery and tannery effluents. J Haz Mat 162:1514–1521
Chaoui A, Mazhoudi S, Ghorbal MH, Elferjani E (1997) Cadmium and zinc induction of lipid peroxidation and effects on antioxidant enzyme activities in bean (Phaseolus vulgaris L.). Plant Sci 127:139–147
Collin B, Doelsch E (2010) Impact of high natural soilborne heavy metal concentrations on the mobility and phytoavailability of these elements for sugarcane. Geoderma 159:452–458
Cui YJ, Zhu YG, Zhai RH, Chen DY, Huang YZ, Qiu Y et al (2004) Transfer of metals from soil to vegetables in an area near a smelter in Nanning, China. Environ Int 30:785–791
Di Toppi LS, Gabbrielli R (1999) Response to cadmium in higher plants. Environ Exp Bot 41(2):105–130
Du Y, Gao B, Zhou H, Ju X, Hao H, Yin S (2013) Health risk assessment of heavy metals in road dusts in urban parks of Bei**g, China. Procedia Environ Sci 18:299–309
Ebbs SD, Kochian LV (1997) Toxicity of zinc and copper to Brassica species: implications for phytoremediation. J Environ Qual 26:776–781
Elik A (2003) Heavy metal accumulation in street dust samples in Sivas. Comm Soil Sci Plant Anal 34:145–156
Fernandes JC, Henriques FS (1991) Biochemical, physiological and structural effects of excess copper in plants. Bot Rev 57:246–273
Fornazier RF, Ferreira RR, Vitoria AP, Molina SMG, Lea PJ, Azevedo RA (2002) Effects of cadmium on antioxidant enzyme activities in sugar cane. Biol Plant 45:91–97
Gonçalves CA, de Camargo R, de Sousa RTX, Soares NS, de Oliveira RC, Stanger MC et al (2021) Chemical and technological attributes of sugarcane as functions of organomineral fertilizer based on filter cake or sewage sludge as organic matter sources. PLoS One 16(12):e0236852. https://doi.org/10.1371/journal.pone.0236852
Hewitt EJ (1983) Essential and functional methods in plants. In: Robb DA, Pierpoint WS (eds) Metals and micronutrients: uptake and utilization by plants. Academic Press, New York, pp 313–315
Huang YL, Yang S, Long GX, Zhao ZK, Li XF, Gu MH (2016) Manganese toxicity in sugarcane plantlets grown on acidic soils of southern China. PLoS One 11(3):e0148956
Jain R, Srivastava S (2006) Effect of cadmium on growth, mineral composition and enzyme activity of sugarcane. Ind J Plant Physiol 11(3):306–309
Jain R, Srivastava S, Madan VK (2000) Influence of chromium on growth and cell division of sugarcane. Ind J Plant Physiol 5:228–231
Jain R, Srivastava S, Solomon S, Shrivastava AK, Chandra A (2010) Impact of excess zinc on growth parameters, cell division, nutrient accumulation, photosynthetic pigments and oxidative stress of Sugarcane (Saccharum spp.). Acta Physiol Plant 32:979–986
Lakshmanan P, Geijskes RJ, Aitken KS, Grof CLP, Bonnett GD, Smith GR (2005) Sugarcane biotechnology: the challenges and opportunities. In Vitro Cell Dev Biol Plant 41:345–363
Lee CW, Choi JM, Pak CH (1996) Micronutrient toxicity in seed geranium (Pelargonium 9 hortorum Baley). J Am Soc Horti Sci 121:77–82
Lerda D (1992) The effects of lead on Allium cepa L. Mutat Res 281:89–92
Li MS, Luo YP, Su ZY (2007) Heavy metal concentrations in soils and plant accumulation in a restored manganese mineland in Guangxi, South China. Environ Poll 147:168–175
Madhumita JM, Sharma A (1991) Manganese in cell metabolism of higher plants. Bot Rev 57(2):117–149
MartĂneza FR, Larios R, GĂłmez-Pinilla I, GĂłmez-Mancebo B, LĂłpez-AndrĂ©s S, Lored J, Ordóñez A, Rucandio I (2015) Mercury accumulation and speciation in plants and soils from abandoned cinnabar mines. Geoderma 253–254:30–38
Mishra VK, Upadhyay AR, Tripathi BD (2009) Bioaccumulation of heavy metals and two organochlorine pesticides (DDT and BHC) in crops irrigated with secondary treated wastewater. Environ Monit Assess 156:99–107
Misra P, Nath K, Tandon PK (2010) Effect of heavy metals (Ni and Pb) stress on sugarcane (Saccharum officinarum L.). Res Environ. Life Sci 3(4):183–188
Nandi S (1985) Studies on the cytogenetic effect of some mercuric fungicides. Cytologia 50:921–926
Nyatwere DM (2014) The potential of bioaccumulation and translocation of heavy metals in plant species growing around the tailing dam in Tanzania. Int J Sci Technol 3(10):690–697
Ouariti O, Gouia H, Ghorbal MH (1997) Responses of bean and tomato plants to cadmium: growth, mineral nutrition and nitrate reduction. Plant Physiol Biochem 35:347–354
Pichhode M, Kumar N (2015) Effect of copper mining dust on the soil and vegetation in India: a critical review. Int J Mod Sci Engg Technol 2:73–76
Rai PK, Lee SS, Zhang M, Tsang YFKKH (2019) Heavy metals in food crops: health risks, fate, mechanisms, and management. Environ Int 125:365–385
Sampanpanish P, Tantitheerasak N (2015) Effect of EDTA on cadmium and zinc uptake by sugarcane grown in contaminated soil. Am J Environ Sci 11(3):166
Santos C, Monteiro M, Dias MC (2010) Cadmium toxicity in crops—a review. In: Environmental science, engineering and technology. Nova Science Publishers Inc., New York, NY
Schreck E, Foucault Y, Sarret G, Sobanska S, Cecillon L, Castrec RM, Uzu G, Dumat C (2012) Metal and metalloid foliar uptake by various plant species exposed to atmospheric industrial fallout: mechanisms involved for lead. Sci Total Environ 427–428:253–262
Schreck E, Laplanche C, Guedard ML, Bessoule JJ, Austruy A, **ong T, Foucault Y, Dumat C (2013) Influence of fine process particles enriched with metals and metalloids on Lactuca sativa L. leaf fatty acid composition following air and/or soil plant field exposure. Environ Poll 179:242–249
Schreck E, Dappe V, Sarret G, Sobanska S, Nowak D, Nowak J, Stefaniak EA, Magnin V, Ranieri V, Dumat C (2014) Foliar or root exposures to smelter particles: consequences for lead compartmentalization and speciation in plant leaves. Sci Total Environ 476–477:667–676
Sereno ML, Almeida RS, Nishimura DS, Figueira A (2007) Response of sugarcane to increasing concentrations of copper and cadmium and expression of metallothionein genes. J Plant Physiol 164(11):1499–1515
Shanker AK, Djanaguiraman M, Pathmanabhan G, Sudhagar R, Avudainayagam S (2003) Uptake and phytoaccumulation of chromium by selected tree species. In: Proceedings of the Int Conf on Water and Environ held in Bhopal, India
Singh A, Gupta AK, Srivastava RN, Lal K (2002) Response of zinc and manganese to sugarcane. Sugar Tech 4(1):74–76
Singh S, Parihar P, Singh R, Singh VP, Prasad SM (2016) Heavy metal tolerance in plants: role of transcriptomics, proteomics, metabolomics, and ionomics. Front Plant Sci 6:1143
Sinha P, Chatterjee C (2015) Disturbances in growth, yield, sucrose concentration and antioxidative defense system by excess cobalt in sugarcane. J Plant Nutr 38:541–550
Thompson CM, Markesbery WR, Ehmann WD, Mao YX, Vance DE (1988) Regional brain trace-element studies in Alzheimer’s disease. Neurotoxicol 9:1–7
Trichopoulos D (1997) Epidemiology of cancer. In: DeVita VT (ed) Cancer: principles and practice of oncology. Lippincott Company, Philadelphia, pp 231–258
US EPA (2000) Supplementary guidance for conducting health risk assessment of chemical mixtures. In: Risk assessment forum technical panel. [EPA/630/R-00/002]
Van Assche F, Clijsters H (1986) Inhibition of photosynthesis in Phaseolus vulgaris by treatment with toxic concentration of zinc: effect on ribulose-1, 5-biphosphate carboxylase/oxygenase. J Plant Physiol 125:355–360
Verma KK, Wu K-C, Singh P, Malviya MK, Singh RK, Song X-P, Li YR (2019) The protective role of silicon in sugarcane under water stress: photosynthesis and antioxidant enzymes. Biomed J Sci Tech Res 15:002685. https://doi.org/10.26717/BJSTR.2019.15.002685
Verma KK, Anas M, Chen Z, Rajput VD, Malviya MK, Verma CL, Singh RK, Singh P, Song XP, Li YR (2020) Silicon supply improves leaf gas exchange, antioxidant defense system and growth in sugarcane responsive to water limitation. Plan Theory 9:1032. https://doi.org/10.3390/plants9081032
Verma KK, Song XP, Tian DD, Singh M, Verma CL, Rajput VD, Singh RK, Sharma A, Singh P, Malviya MK, Li YR (2021a) Investigation of defensive role of silicon during drought stress induced by irrigation capacity in sugarcane: physiological and biochemical characteristics. ACS Omega 6:19811–19821
Verma KK, Song XP, Verma CL, Chen ZL, Rajput VD, Wu KC, Liao F, Chen GL, Li YR (2021b) Functional relationship between photosynthetic leaf gas exchange in response to silicon application and water stress mitigation in sugarcane. Biol Res 54:15. https://doi.org/10.1186/s40659-021-00338-2
Verma KK, Song XP, Zeng Y, Guo DJ, Sing M, Rajput VD, Malviya MK, Wei KJ, Sharma A, Li DP, Chen GL, Li YR (2021c) Foliar application of silicon boosts growth, photosynthetic leaf gas exchange, antioxidative response and resistance to limited water irrigation in sugarcane (Saccharum officinarum L.). Plant Physiol Biochem 166:582–592
Wallace A, Romney EM (1975) Roots of higher plants as a barrier to translocation of some metals to shoots of plants. In: United States: N. Conf: 15. Hanford life sciences symposium, Richland, WA, USA, 25 Sep 1975
Zeng Q, Ling Q, Wu J et al (2019) Excess copper-induced changes in antioxidative enzyme activity, mineral nutrient uptake and translocation in sugarcane seedlings. Bull Environ Contam Toxicol 103:834–840
Zhang X, Zhu Y, Zhang Y, Liu Y, Liu S, Guo J (2014) Growth and metal uptake of energy sugarcane (Saccharum spp.) in different metal mine tailings with soil amendments. J Environ Sci 26:1080–1089
Zhao H, **a B, Chen F, Zhao P, Shen S (2012) Human health risk from soil heavy metal contamination under different land uses near Dabaoshan mine, Southern China. Sci Total Environ 417-418:45–54
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Misra, S., Singh, B.P. (2022). Impact of Heavy Metal Toxicity on Sugarcane Growth, Development and Productivity. In: Verma, K.K., Song, XP., Rajput, V.D., Solomon, S., Li, YR., Rao, G.P. (eds) Agro-industrial Perspectives on Sugarcane Production under Environmental Stress. Springer, Singapore. https://doi.org/10.1007/978-981-19-3955-6_9
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