Fly-ash augmented soil enhances heavy metal accumulation and phytotoxicity in rice (Oryza sativa L.); A concern for fly-ash amendments in agriculture sector

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• 作者：Pradyumna Kumar Singh ; Preeti Tripathi ; Sanjay Dwivedi…
• 关键词：Antioxidant ; Fly ; ash ; Heavy metals ; Isozymes ; Rice
• 刊名：Plant Growth Regulation
• 出版年：2016
• 出版时间：January 2016
• 年：2016
• 卷：78
• 期：1
• 页码：21-30
• 全文大小：782 KB
• 参考文献：Adriano DC, Page AL, Elseewi AA, Chang AC, Satraughan IA (1980) Utilisation and disposal of flyash and other coal residue in terrestrial ecosystem. A Rev J Environ Qual 9:333–344CrossRef
  Alef K (1995) Dehydrogenase activity. In: Alef K, Nannipieri P (eds) Methods in applied soil microbiology and biochemistry. Academic Press, San Diego, pp 228–231
  Anderson MD, Prasad TK, Stewart CR (1995) Changes in the isozyme profiles of catalase, peroxidase and glutathione reductase during acclimation to chilling in mesocotyls of maize seedlings. Plant Physiol 109:1247–1257PubMed PubMedCentral
  Basu M, Pande M, Bhadoria PBS, Mahapatra SC (2009) Potential fly-ash utilization in agriculture: a global review. Prog Nat Sci 19:1173–1186CrossRef
  Beauchamp C, Fridovich I (1971) Superoxide dismutase: improved assays and an assay applicable to acrylamide gels. Anal Biochem 44:276–287CrossRef PubMed
  Black CA (1965) Methods of soil analysis. Part 2, 2nd edn. Agronomy Monograph ASA, Madison
  Bradford MM (1976) A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein–dye binding. Anal Biochem 72:248–254CrossRef PubMed
  Brännvall E, Nilsson M, Sjöblom R, Skoglund N, Kumpiene J (2014) Effect of residue combinations on plant uptake of nutrients and potentially toxic elements. J Environ Manag 132:287–295CrossRef
  Chattopadhyay GN, Bhattacharya SS (2010) Use of coal ash in agriculture. Bull 1. Coal Ash Institute of India, Kolkata
  Dwivedi S, Tripathi RD, Srivastava S, Mishra S, Shukla MK, Tiwari KK, Singh R, Rai UN (2007) Growth performance and biochemical responses of three rice (Oryza sativa L.) cultivars grown in fly-ash amended soil. Chemosphere 67:140–151CrossRef PubMed
  Eivazi F, Tabatabai MA (1977) Phosphatases in soils. Soil Biol Biochem 9:167–172CrossRef
  Eivazi F, Tabatabai MA (1988) Glucosidases and agalactosidases in soils. Soil Biol Biochem 20:601–606CrossRef
  Environmental Protection Agency (2001) Integrated risk information system. IRIS from US. http://​www.​epa.​govyirisygloss8.​htm . Accessed 29 Oct 2005
  Garau MA, Dalmau JL, Felipo MT (1991) Nitrogen mineralization in soil amended with sewage sludge and flyash. Biol Fertil Soils 12:199–201CrossRef
  Gupta AK, Sinha S (2009) Growth and metal accumulation response of Vigna radiata L. var PDM 54 (mung bean) grown on fly ash-amended soil: effect on dietary intake. Environ Geochem Heal 31:463–473CrossRef
  Heath RL, Packer L (1968) Photoperoxidation in isolated chloroplasts. 1. Kinetics and stoichiometry of fatty acid peroxidation. Arch Biochem Biophys 125:189–198CrossRef PubMed
  Hodgson DR, Holliday R (1966) The agronomic properties of pulverized fuel ash. Chem Ind 20:785–790
  Jackson ML (1962) Soil chemical analysis. Prentice Hall Inc, Englewood Cliffs
  Jala S, Goyal D (2006) Fly ash as a soil ameliorant for improving crop production—a review. Bioresour Technol 97:1136–1147CrossRef PubMed
  Kandeler E, Gerber H (1988) Short-term assay of soil urease activity using colorimetric determination of ammonium. Biol Fertil Soils 6:68–72CrossRef
  Kumar A, Nayak AK, Shukla AK, Panda BB, Raja R, Shahid M, Tripathi R, Mohanty S, Rath PC (2012) Microbial biomass and carbon mineralization in agricultural soils as affected by pesticide addition. Bull Environ Contam Toxicol 88:538–542CrossRef PubMed
  Kumar S, Chaudhuri S, Maiti SK (2013) Soil dehydrogenase enzyme activity in natural and mine soil—a review. Middle-East J Sci Res 13:898–906
  Laemmli UK (1970) Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature 227:680–685CrossRef PubMed
  Lee H, Ha HS, Lee CH, Lee YB, Kim PJ (2006) Fly-ash effect on improving soil properties and rice productivity in Korean paddy soils. Bioresour Technol 97:1490–1497CrossRef PubMed
  Lee SB, Lee YB, Lee CH, Hong CO, Kim PJ, Yu C (2008) Characteristics of boron accumulation by fly ash application in paddy soil. Bioresour Technol 99:5928–5932CrossRef PubMed
  Martinez CE, Tabatabai MA (1997) Decomposition of biotechnology by-products in soils. J Environ Qual 26:625–632CrossRef
  Mishra S, Srivastava S, Tripathi RD, Kumar R, Seth CS, Gupta DK (2006) Lead detoxification by coontail (Ceratophyllum demersum L.) involves induction of phytochelatins and antioxidant system in response to its accumulation. Chemosphere 65:1027–1039CrossRef PubMed
  Mishra M, Sahu RK, Padhy RN (2007) Growth, yield and elemental status of rice (Oryza sativa) grown in fly-ash amended soil. Ecotoxicology 16:271–278CrossRef PubMed
  Mittler R, Zilinskas BA (1993) Detection of ascorbate peroxidase activity in native gels by inhibition of the ascorbate dependent reduction of nitroblue tetrazolium. Anal Biochem 212:540–546CrossRef PubMed
  Narayana ST, Mishra M, Sahu RK, Padhy RN (2010) Growth, yield and metabolism of rice (Oryza sativa L.) during repeated applications of fly-ash on soil. Adv Food Sci 32:110–117
  Nayak AK, Raja R, Rao KS, Shukla AK, Mohanty S, Shahid M, Swain CK (2014) Effect of fly ash application on soil microbial response and heavy metal accumulation in soil and rice plant. Ecotoxicol Environ Safe. doi:10.​1016/​j.​ecoenv.​2014.​03.​033
  Ndiaye EL, Sandeno JM, McGrath D, Dick RP (2000) Integrative biological indicators for detecting change in soil quality. Am J Altern Agric 15:26–36CrossRef
  Olsen S, Watanabe FS, Bowman RA (1983) Evaluation of fertilizer phosphate residues by plant uptake and extractable phosphorus. Soil Sci Soc Am J 47:952–958CrossRef
  Pandey VC, Abhilash PC, Singh N (2009) The Indian perspective of utilizing fly ash in phytoremediation, phytomanagement and biomass production. J Environ Manag 10:2943–2958CrossRef
  Pandey P, Srivastava RK, Dubey RS (2013) Salicylic acid alleviates aluminum toxicity in rice seedlings better than magnesium and calcium by reducing aluminum uptake, suppressing oxidative damage and increasing antioxidative defense. Ecotoxicology 22:656–670CrossRef PubMed
  Patra KC, Rautray TR, Nayak P (2012) Analysis of grains grown on fly ash treated soils. Appl Radiat Isot 70:1797–1802CrossRef PubMed
  Pitchel JR, Hayes JM (1990) Influence of fly ash on soil microbial activity and populations. J Environ Qual 19:593–597
  Préstamo G, Manzano P (1993) Peroxidases of selected fruits and vegetables and the possible use of ascorbic acid as an antioxidant. Hortic Sci 28:48–49
  Rai A, Tripathi P, Dwivedi S, Dubey S, Shri M, Kumar S, Tripathi PK, Dave R, Kumar A, Singh R, Adhikari B, Bag M, Tripathi RD, Trivedi PK, Chakrabarty D, Tuli R (2011) Arsenic tolerances in rice (Oryza sativa) have a predominant role in transcriptional regulation of a set of genes including sulphur assimilation pathway and antioxidant system. Chemosphere 82:986–995CrossRef PubMed
  Raja R, Nayak AK, Rao KS, Puree C, Shahid M et al (2014) Effect of fly ash deposition on photosynthesis, growth and yield of rice. Environ Contam Toxicol. doi:10.​1007/​s00128-014-1282-x
  Ram LC, Jha SK, Tripathi RC, Masto RE, Selvi VA (2008) Remediation of fly ash landfills through plantation. Remediat J 18:71–90CrossRef
  Roy G, Joy VC (2011) Dose-related effect of fly ash on edaphic properties in laterite cropland soil. Ecotoxicol Environ Safe 74:769–775CrossRef
  Sadasivan S, Negi BS (1991) Chemical characterization of fly ash from coal fired thermal power plants in India. Sci Tot Environ 103:151–158CrossRef
  Sharma SK, Kalra N (2006) Effect of fly ash incorporation on soil properties and productivity of crops: a review. J Sci Ind Res 65:383–390
  Singh JS, Pandey VC (2013) Fly ash application in nutrient poor agriculture soils: impact on methanotrophs population dynamics and paddy yields. Ecotoxicol Environ Safe 89:43–51CrossRef
  Singh RP, Tripathi RD, Sinha SK, Maheshwari R, Srivastava HS (1997) Response of higher plants to lead contaminated environment. Chemosphere 34:2467–2493CrossRef PubMed
  Sinha S, Rai UN, Bhatt K, Pandey K, Gupta AK (2005) Flyash induced oxidative stress and tolerance in Prosopis juliflora L. grown on different amended substrates. Environ Monit Assess 102:447–457CrossRef PubMed
  Stanford G, Smith SJ (1978) Oxidative release of potentially mineralizable soil nitrogen by acid permanganate extraction. Soil Sci 126:210–218CrossRef
  Tabatabai MA (1982) Sulfur. In: Page AL, Miller RH, Keeney (eds) Methods of soil analysis, Part 2, chemical and micro-biological properties, 2nd edn. Agronomy Monograph no. 9 ASA-SSSA, Madison
  Tripathi RD, Dwivedi S, Shukla MK, Mishra S, Srivastava S, Singh R, Rai UN, Gupat DK (2008) Role of blue green algae biofertilizer in ameliorating the nitrogen demand and fly-ash stress to the growth and yield of rice (Oryza sativa L.) plants. Chemosphere 70:1919–1929CrossRef PubMed
  Tripathi P, Mishra A, Dwivedi S, Chakrabarty D, Trivedi PK, Singh RP, Tripathi RD (2012) Differential response of oxidative stress and thiol metabolism in contrasting rice genotypes for arsenic tolerance. Ecotoxicol Environ Safe 79:189–198CrossRef
  Tripathi P, Tripathi RD, Singh RP, Dwivedi S, Goutam D, Shri M, Chakrabarty D (2013) Silicon mediates arsenic tolerance in rice (Oryza sativa L.) through lowering of arsenic uptake and improved antioxidant defence system. Ecol Eng 52:96–103CrossRef
  Wang-da C, Guo-ping Z, Hai-gen Y, Mei-ling T (2005) Effect of grain position within a panicle and variety on As, Cd, Cr, Ni, Pb concentrations in japonica rice. Rice Sci 12:48–56
  Williams LE, Pittman JK, Hall JL (2000) Emerging mechanisms for heavy metal transport in plants. Biochim Biophys Acta 1465:104–126CrossRef PubMed
  World Health Organization (1993) Evaluation of certain food additives and contaminants. Forty-first report of the joint FAO WHO expert committee on food additives. WHO Technical series no 837 Geneva
  World Health Organization (1996) Trace elements in human nutrition and health. (NLM Classification: QU 130)
  Yu QG, Ye J, Yang SN, Fu JR, Ma JW et al (2013) Effects of nitrogen application level on rice nutrient uptake and ammonia volatilization. Rice Sci 20(2):139–147CrossRef
  Yunusa IAM, Eamus D, Silva DL, Murray BR, Burchett MD, Skilbeck GC, Heidrich C (2006) Fly ash: an exploitable resource for management of Australian agricultural soils. Fuel 85:2337–2344CrossRef
  Yunusa IAM, Loganathan P, Nissanka SP, Manoharan V, Burchett MD, Skilbeck CG, Eamus D (2012) Application of coal fly ash in agriculture: a strategic perspective. Crit Rev Environ Sci Technol 42:559–600CrossRef
  Zhao FJ, McGrath SP, Meharg AA (2010) Arsenic as a food chain contaminant: mechanisms of plant uptake and metabolism and mitigation strategies. Annu Rev Plant Biol 61:535–559CrossRef PubMed
  
• 作者单位：Pradyumna Kumar Singh (1)
  Preeti Tripathi (1)
  Sanjay Dwivedi (1)
  Surabhi Awasthi (1)
  Manju Shri (2)
  Debasis Chakrabarty (2)
  Rudra Deo Tripathi (1)
  
  1. Plant Ecology and Environmental Science Division, CSIR-National Botanical Research Institute, Council of Scientific and Industrial Research, Rana Pratap Marg, Lucknow, 226 001, India
  2. Genetics and Molecular Biology Division, CSIR-National Botanical Research Institute, Council of Scientific and Industrial Research, Lucknow, 226 001, India
  
• 刊物类别：Biomedical and Life Sciences
• 刊物主题：Life Sciences
  Plant Physiology
  
• 出版者：Springer Netherlands
• ISSN：1573-5087

文摘

Fly-ash (FA) utilization in the agriculture sector is very common practice due to presence of beneficial elements required for plant growth. However, presence of excessive amount of toxic metals in FA may be serious concern for agriculture. In the present study, the effects of FA on soil health, plant growth, toxic metal accumulation and antioxidant responses were investigated in rice (Oryza sativa L.), grown on soil amended with 50 % FA in natural condition. FA application resulted in reduction in soil enzymatic activities viz., dehydrogenase, acid phosphatase, β-glucosidase and urease than garden soil (GS). FA amendments significantly decreased the root, shoot and panicle length and augmented sterility in rice. Interestingly, ICPMS analysis for metal accumulation revealed that the total accumulation of toxic metals, particularly Cd, Cr, Pb and As were 14–15 fold higher in roots and shoots and 4–20 fold higher in grains for the plants grown on FA amended soil than GS. The levels of nutrient elements viz., Mn, Co, Cu and Se were lesser in grains of FA treated soil than GS. Lipid peroxidation was increased in root and shoot of FA treated plants indicating oxidative stress. Activities of various antioxidant enzymes viz., SOD, APX, GPX, GR and their isozymes were correlated to each other and also increased against heavy metal induced toxicity. Human associated risk analysis revealed that the calculated maximum tolerable daily intake values for toxic metals (µg d−1) viz., Cr, As, Cd, Hg and Pb was beyond the safe limit in the rice grown in FA implicated soil. In conclusion, 50 % FA implication deteriorates the soil quality, rice production and elevates the toxic metals in grains, which may be a concern for safer rice consumption. Keywords Antioxidant Fly-ash Heavy metals Isozymes Rice