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Environmental Science and Pollution Research

, Volume 26, Issue 11, pp 11288–11299 | Cite as

Combined use of biochar and zinc oxide nanoparticle foliar spray improved the plant growth and decreased the cadmium accumulation in rice (Oryza sativa L.) plant

  • Shafaqat Ali
  • Muhammad RizwanEmail author
  • Shamaila Noureen
  • Sarwat Anwar
  • Basharat AliEmail author
  • Muhammad Naveed
  • Elsayed Fathi Abd_Allah
  • Abdulaziz A. Alqarawi
  • Parvaiz Ahmad
Research Article

Abstract

The contamination of large areas of arable land with cadmium (Cd) is a serious concern worldwide and environmentally feasible amendments are necessary to minimize Cd accumulation in cereals such as rice (Oryza sativa L.). A pot study was, therefore, conducted to evaluate the efficiency of foliar spray of different levels (0, 50, 75, 100 mg/L) of zinc oxide nanoparticles (ZnO NPs) alone or combined with biochar (1.0% w/w) on Cd content in rice plants grown on an aged Cd-polluted soil. The results showed that ZnO NPs alone or combined with biochar improved the biomass and photosynthesis of rice plant. The ZnO NPs significantly diminished the Cd concentration and enhanced the Zn concentrations in shoots and roots either alone or in combination with biochar. Foliar spray of 100 mg/L ZnO NPs significantly diminished the Cd content in rice shoot and rice roots by 30% and 31%, respectively. The Cd concentrations in rice shoot and root diminished by 39% and 38% after 100 mg/L ZnO NPs combined with biochar, respectively. The ZnO NPs in combination with biochar increased the soil pH from 8.03 to 8.23 units. Soil AB-DTPA-extractable Cd significantly reduced with the amendments applied over the control. Foliar spray of ZnO NPs combined with biochar could be used to grow rice plants especially in areas where Cd concentration is high and Zn deficiency is high.

Keywords

Cadmium Nanoparticles Biochar Rice Photosynthesis 

Notes

Funding information

Financial support was received from the Government College University, Faisalabad and Higher Education Commission (HEC) of Pakistan under NRPU Project No. 5634/Punjab/NRPU/R&D/HEC/2016. Funding was received from Deanship of Scientific Research at King Saud University to the Research Group number (RG-199).

References

  1. Abbas T, Rizwan M, Ali S, Adrees M, Mahmood A, Rehman MZ, Ibrahim M, Arshad M, Qayyum MF (2018) Biochar application increased the growth and yield and reduced cadmium in drought stressed wheat grown in an aged contaminated soil. Ecotoxicol Environ Saf 148:825–833CrossRefGoogle Scholar
  2. Abbas T, Rizwan M, Ali S, Rehman MZ, Qayyum MF, Abbas F, Hannan F, Rinklebe J, Ok YS (2017) Effect of biochar on cadmium bioavailability and uptake in wheat (Triticum aestivum L.) grown in a soil with aged contamination. Ecotoxicol Environ Saf 140:37–47CrossRefGoogle Scholar
  3. Ali B, Gill RA, Yang S, Gill MB, Farooq MA, Liu D, Daud MK, Ali S, Zhou W (2015) Regulation of cadmium-induced proteomic and metabolic changes by 5-aminolevulinic acid in leaves of Brassica napus L. PLoS One 10:1–23Google Scholar
  4. Ali B, Tao Q, Zhou Y, Gill RA, Ali S, Rafiq MT, Xu L, Zhou W (2013) 5-Aminolevolinic acid mitigates the cadmium-induced changes in Brassica napus as revealed by the biochemical and ultra-structural evaluation of roots. Ecotoxicol Environ Saf 92:271–280CrossRefGoogle Scholar
  5. Ali S, Rizwan M, Qayyum MF, Ok YS, Ibrahim M, Riaz M, Arif MS, Hafeez F, Al-Wabel MI, Shahzad AN (2017) Biochar soil amendment on alleviation of drought and salt stress in plants: a critical review. Environ Sci Pollut Res 24:12700–12712CrossRefGoogle Scholar
  6. Amacher MC (1996) Nickel, cadmium and lead. p. 739–768. In: Sparks DL (ed) Methods of soil analysis. Part 3. Chemical methods, 3rd edn. SSSA/ASA, MadisonGoogle Scholar
  7. Bashir A, Rizwan M, Ali S, Rehman MZ, Ishaque W, Riaz MA, Maqbool A (2018) Effect of foliar-applied iron complexed with lysine on growth and cadmium (cd) uptake in rice under cd stress. Environ Sci Pollut Res 25:20691–20699CrossRefGoogle Scholar
  8. Baycu G, Gevrek-Kürüm N, Moustaka J, Csatári I, Rognes SE, Moustakas M (2017) Cadmium-zinc accumulation and photosystem II responses of Noccaea caerulescens to cd and Zn exposure. Environ Sci Pollut Res 24:2840–2850CrossRefGoogle Scholar
  9. Beesley L, Marmiroli M (2011) The immobilisation and retention of soluble arsenic, cadmium and zinc by biochar. Environ Pollut 159:474–480CrossRefGoogle Scholar
  10. Bouyoucos GJ (1962) Hydrometer method improved for making particle- size analyses of soils. Agron J 54:464–465CrossRefGoogle Scholar
  11. Cakmak I, Kutman UB (2018) Agronomic biofortification of cereals with zinc: a review. Eur J Soil Sci 69:172–180CrossRefGoogle Scholar
  12. Dapkekar A, Deshpande P, Oak MD, Paknikar KM, Rajwade JM (2018) Zinc use efficiency is enhanced in wheat through nanofertilization. Sci Rep 8:1–10CrossRefGoogle Scholar
  13. Dimkpa CO, White JC, Elmer WH, Gardea-Torresdey J (2017) Nanoparticle and ionic Zn promote nutrient loading of sorghum grain under low NPK fertilization. J Agric Food Chem 65:8552–8559CrossRefGoogle Scholar
  14. Gallego SM, Pena LB, Barcia RA, Azpilicueta CE, Iannone MF, Rosales EP, Zawoznik MS, Groppa MD, Benavides MP (2012) Unravelling cadmium toxicity and tolerance in plants: insight into regulatory mechanisms. Environ Exp Bot 83:33–46CrossRefGoogle Scholar
  15. Gao X, Mohr RM, McLaren DL, Grant CA (2011) Grain cadmium and zinc concentrations in wheat as affected by genotypic variation and potassium chloride fertilization. Field Crop Res 122:95–103CrossRefGoogle Scholar
  16. García-Gómez C, Obrador A, González D, Babín M, Fernández MD (2018) Comparative study of the phytotoxicity of ZnO nanoparticles and Zn accumulation in nine crops grown in a calcareous soil and an acidic soil. Sci Total Environ 644:770–780CrossRefGoogle Scholar
  17. Gil-Diaz M, Pinilla P, Alonso J, Lobo MC (2017) Viability of a nanoremediation process in single or multi-metal (loid) contaminated soils. J Hazard Mater 321:812–819CrossRefGoogle Scholar
  18. Huang G, Ding C, Zhou Z, Zhang T, Wang X (2019) A tillering application of zinc fertilizer based on basal stabilization reduces cd accumulation in rice (Oryza sativa L.). Ecotoxicol Environ Saf 167:338–344CrossRefGoogle Scholar
  19. Hussain A, Ali S, Rizwan M, Rehman MZ, Javed MR, Imran M, Chatha SA, Nazir R (2018) Zinc oxide nanoparticles alter the wheat physiological response and reduce the cadmium uptake by plants. Environ Pollut 242:1518–1526CrossRefGoogle Scholar
  20. Keller C, Rizwan M, Davidian JC, Pokrovsky OS, Bovet N, Chaurand P, Meunier JD (2015) Effect of silicon on wheat seedlings (Triticum turgidum L.) grown in hydroponics and exposed to 0 to 30 μM cu. Planta 241:847–860CrossRefGoogle Scholar
  21. Lichtenthaler HK (1987) Chlorophylls and carotenoids: pigments of photosynthetic biomembranes. Methods Enzymol 148:350–382Google Scholar
  22. Li C, Wang P, Lombi E, Cheng M, Tang C, Howard DL, Menzies NW, Kopittke PM (2018a) Absorption of foliar-applied Zn fertilizers by trichomes in soybean and tomato. J Exp Bot 69:2717–2729CrossRefGoogle Scholar
  23. Li C, Wang P, Lombi E, Wu J, Blamey FP, Fernández V, Howard DL, Menzies NW, Kopittke PM (2018b) Absorption of foliar applied Zn is decreased in Zn deficient sunflower (Helianthus annuus) due to changes in leaf properties. Plant Soil 433:309–322CrossRefGoogle Scholar
  24. Li S, Wang M, Zhao Z, Li X, Han Y, Chen S (2018c) Alleviation of cadmium phytotoxicity to wheat is associated with cd re-distribution in soil aggregates as affected by amendments. RSC Adv 8:17426–17434CrossRefGoogle Scholar
  25. Liu J, Cai H, Mei C, Wang M (2015) Effects of nano-silicon and common silicon on lead uptake and translocation in two rice cultivars. Front Environ Sci Eng 9:905–911CrossRefGoogle Scholar
  26. Moodie CD, Smith HW, McCreery RA (1959) Laboratory manual for soil fertility. Washington State College Mimeograph, WashingtonGoogle Scholar
  27. Nagajyoti PC, Lee KD, Sreekanth TVM (2010) Heavy metals, occurrence and toxicity for plants: a review. Environ Chem Lett 8:199–216CrossRefGoogle Scholar
  28. O'Connor D, Peng T, Zhang J, Tsang DC, Alessi DS, Shen Z, Bolan NS, Hou D (2018) Biochar application for the remediation of heavy metal polluted land: a review of in situ field trials. Sci Total Environ 619:815–826CrossRefGoogle Scholar
  29. Pandey VC (2012) Phytoremediation of heavy metals from fly ash pond by Azolla caroliniana. Ecotoxicol Environ Saf 82:8–12CrossRefGoogle Scholar
  30. Pullagurala VL, Adisa IO, Rawat S, Kim B, Barrios AC, Medina-Velo IA, Hernandez-Viezcas JA, Peralta-Videa JR, Gardea-Torresdey JL (2018) Finding the conditions for the beneficial use of ZnO nanoparticles towards plants-a review. Environ Pollut 241:1175–1181CrossRefGoogle Scholar
  31. Qayyum MF, Rehman MZ, Ali S, Rizwan M, Naeem A, Maqsood MA, Khalid H, Rinklebe J, Ok YS (2017) Residual effects of monoammonium phosphate, gypsum and elemental sulfur on cadmium phytoavailability and translocation from soil to wheat in an effluent irrigated field. Chemosphere 174:515–523CrossRefGoogle Scholar
  32. Rehman MZ, Rizwan M, Ghafoor A, Naeem A, Ali S, Sabir M, Qayyum MF (2015) Effect of inorganic amendments for in situ stabilization of cadmium in contaminated soils and its phyto-availability to wheat and rice under rotation. Environ Sci Pollut Res 22:16897–16906CrossRefGoogle Scholar
  33. Rehman MZ, Rizwan M, Ali S, Naeem A, Yousaf B, Lui G, Azhar M (2018) A field study investigating the potential use of phosphorus combined with organic amendments on cadmium accumulation by wheat and subsequent rice. Arab J Geosci 11:1–10CrossRefGoogle Scholar
  34. Rizwan M, Ali S, Adrees M, Rizvi H, Rehman MZ, Hannan F, Qayyum MF, Hafeez F, Ok YS (2016a) Cadmium stress in rice: toxic effects, tolerance mechanisms, and management: a critical review. Environ Sci Pollut Res 23:17859–17879CrossRefGoogle Scholar
  35. Rizwan M, Ali S, Ali B, Adrees M, Arshad M, Hussain A, Rehman MZ, Waris AA (2019a) Zinc and iron oxide nanoparticles improved the plant growth and reduced the oxidative stress and cadmium concentration in wheat. Chemosphere 214:269–277CrossRefGoogle Scholar
  36. Rizwan M, Ali S, Hussain A, Ali Q, Shakoor MB, Rehman MZ, Farid M, Asma M (2017a) Effect of zinc-lysine on growth, yield and cadmium uptake in wheat (Triticum aestivum L.) and health risk assessment. Chemosphere 187:35–42CrossRefGoogle Scholar
  37. Rizwan M, Ali S, Qayyum MF, Ibrahim M, Rehman MZ, Abbas T, Ok YS (2016b) Mechanisms of biochar-mediated alleviation of toxicity of trace elements in plants: a critical review. Environ Sci Pollut Res 23:2230–2248CrossRefGoogle Scholar
  38. Rizwan M, Ali S, Qayyum MF, Ok YS, Adrees M, Ibrahim M, Rehman MZ, Farid M, Abbas F (2017b) Effect of metal and metal oxide nanoparticles on growth and physiology of globally important food crops: a critical review. J Hazard Mater 322:2–16CrossRefGoogle Scholar
  39. Rizwan M, Ali S, Rehman MZ, Maqbool A (2019b) A critical review on the effects of zinc at toxic levels of cadmium in plants. Environ Sci Pollut Res  https://doi.org/10.1007/s11356-019-04174-6
  40. Saifulah JH, Naeem A, Rengel Z, Dahlawi S (2016) Timing of foliar Zn application plays a vital role in minimizing cd accumulation in wheat. Environ Sci Pollut Res 223:16432–16439CrossRefGoogle Scholar
  41. Soltanpour PN (1985) Use of AB-DTPA soil test to evaluate elemental availability and toxicity. Commun Soil Sci Plant Anal 16:323–338CrossRefGoogle Scholar
  42. Sturikova H, Krystofova O, Huska D, Adam V (2018) Zinc, zinc nanoparticles and plants. J Hazard Mater 349:101–110CrossRefGoogle Scholar
  43. Tripathi DK, Singh VP, Prasad SM, Chauhan DK, Dubey NK (2015) Silicon nanoparticles (SiNp) alleviate chromium (VI) phytotoxicity in Pisum sativum (L.) seedlings. Plant Physiol Biochem 96:189–198CrossRefGoogle Scholar
  44. Venkatachalam P, Jayaraj M, Manikandan R, Geetha N, Rene ER, Sharma NC, Sahi SV (2017) Zinc oxide nanoparticles (ZnONPs) alleviate heavy metal-induced toxicity in Leucaena leucocephala seedlings: a physiochemical analysis. Plant Physiol Biochem 110:59–69CrossRefGoogle Scholar
  45. Walkley A, Black IA (1934) An examination of the Degtjareff method for determining in soil organic matter, and a proposed modification of the chromic soil titration method. Soil Sci 37:29–38CrossRefGoogle Scholar
  46. Wang H, Xu C, Luo ZC, Zhu HH, Wang S, Zhu QH, Huang DY, Zhang YZ, Xiong J, He YB (2018) Foliar application of Zn can reduce cd concentrations in rice (Oryza sativa L.) under field conditions. Environ Sci Pollut Res 25:29287–29294CrossRefGoogle Scholar
  47. Wang S, Wang F, Gao S (2015) Foliar application with nano-silicon alleviates cd toxicity in rice seedlings. Environ Sci Pollut Res 22:2837–2845CrossRefGoogle Scholar

Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2019

Authors and Affiliations

  • Shafaqat Ali
    • 1
  • Muhammad Rizwan
    • 1
    Email author
  • Shamaila Noureen
    • 1
  • Sarwat Anwar
    • 1
  • Basharat Ali
    • 2
    Email author
  • Muhammad Naveed
    • 3
  • Elsayed Fathi Abd_Allah
    • 4
  • Abdulaziz A. Alqarawi
    • 4
  • Parvaiz Ahmad
    • 5
    • 6
  1. 1.Department of Environmental Sciences and EngineeringGovernment College UniversityFaisalabadPakistan
  2. 2.Department of AgronomyUniversity of AgricultureFaisalabadPakistan
  3. 3.Institute of Soil and Environmental SciencesUniversity of AgricultureFaisalabadPakistan
  4. 4.Plant Production Department, College of Food and Agricultural SciencesKing Saud UniversityRiyadhSaudi Arabia
  5. 5.Botany and Microbiology Department, College of ScienceKing Saud UniversityRiyadhSaudi Arabia
  6. 6.Department of BotanyS.P. CollegeJammu and KashmirIndia

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