Effect of Zinc Sulfate and Salicylic Acid on Biological Degradation of Phenanthrene in the Cd Polluted Soil under Sorghum Cultivation Inoculated with Pseudomonas Putida
Subject Areas : Journal of Chemical Health RisksAmir Hossein Baghaie 1 , Aminollah Aghilizefreei 2
1 - Department of Soil Science, Arak Branch, Islamic Azad University, Arak, Iran
2 - Department of Chemical Engineering, Isfahan University of Technology, Isfahan, Iran
Keywords: Degradation, Salicylic acid, Phenanthrene, Pseudomonas putida,
Abstract :
Co-contamination of soils with heavy metals or petroleum hydrocarbons is one of the important environmental problems. This study was done to evaluate the effect of ZnSO4 and salicylic acid (SA) on biological degradation of phenanthrene in the Cd polluted soil under sorghum cultivation inoculated with Pseudomonas putida (P.putida). Treatments were consisted of applying ZnSO4 (0 and 40 kg/ha), SA foliar application (0 and 1.5 mmol/lit), Cd polluted soil (0, 5 and 10 mg Cd/kg soil) and soil pollution with phenanthrene at the rates of 0, 3 and 6% (W/W) in three replicate in the presence of P. putida. Plant in this experiment was sorghum. At the end of this experiment, plant was harvested and the plant Cd concentration was measured using atomic absorption spectroscopy. On the other hand, the degradation of phenanthrene (%) in the soil and soil microbial respiration via evaluated CO2 were measured. Based on the results of this study, applying 40 kg/ha ZnSO4 significantly decreased the plant Cd concentration by 14.3 %. In addition, a significant increasing by 15.4 % in degradation of phenanthrene in soil was also observed when the soil received 40 kg/ha. The similar results were also observed for SA foliar application.Soil application of ZnSO4, the presence of P. putida and foliar application of salicylic acid can increase plant resistance to abiotic stresses and thereby have significant effect on biological degradation of phenanthrene. However, the role of plant type on degradation of phenanthrene cannot be ignored.
1. Li Y.T., Li D., Lai L.J., Li Y. H., 2020. Remediation of petroleum hydrocarbon contaminated soil by using activated persulfate with ultrasound and ultrasound/Fe. Chemosphere. 238, 124657.
2. Khan M.A.I., Biswas B., Smith E., Naidu R., Megharaj M., 2018. Toxicity assessment of fresh and weathered petroleum hydrocarbons in contaminated soil- a review. Chemosphere. 212, 755-767.
3. Olasanmi I.O., Thring R.W., 2019. Evaluating Rhamnolipid-Enhanced Washing as a First Step in Remediation of Petroleum-Contaminated Soils and Drill Cuttings. J Advance Res. [In press].
4. Oyibo J.N., Wegwu M.O., Uwakwe A.A., Osuoha J.O., 2018. Analysis of total petroleum hydrocarbons, polycyclic aromatic hydrocarbons and risk assessment of heavy metals in some selected finfishes at Forcados Terminal, Delta State, Nigeria. Environmental Nanotechnol Monitor Manage. 9, 128-135.
5. Yazdani Foshtomi M., Oryan S., Taheri M., Darvish Bastami K., Zahed M.A., 2019. Composition and abundance of microplastics in surface sediments and their interaction with sedimentary heavy metals, PAHs and TPH (total petroleum hydrocarbons). Marine Pollut Bullet. 149, 110655.
6. Makombe N., Gwisai R.D., 2018. Soil Remediation Practices for Hydrocarbon and Heavy Metal Reclamation in Mining Polluted Soils.Sci World J. 1-7.
7. Khan A., Kathi S., 2014. Evaluation of heavy metal and total petroleum hydrocarbon contamination of roadside surface soil. Int J Environ Sci Technol. 11(8), 2259-2270.
8. Pinedo J., Ibáñez R., Lijzen J. P.A., Irabien Á., 2013. Assessment of soil pollution based on total petroleum hydrocarbons and individual oil substances. J Environ Manage. 130, 72-79.
9. Ja’afaru S.W., Cheng Y., 2018. Generic Assessment Criteria for Human Health Risk Assessment of Petroleum Hydrocarbons in Niger Delta Region of Nigeria. Journal of Environ Pollut Human Health. 6(3), 110-120.
10. Wilton N., Lyon-Marion B.A., Kamath R., McVey K., Pennell K. D., Robbat Jr A., 2018. Remediation of heavy hydrocarbon impacted soil using biopolymer and polystyrene foam beads. J Hazard Mater. 349, 153-159.
11. Thapa B., Kc A.K., Ghimire A., 2012. A review on bioremediation of petroleum hydrocarbon contaminants in soil. Kathmandu Univer J Sci Eng Technol. 8(1), 164-170.
12. Guo B., Liu C., Liang Y., Li N., Fu Q., 2019. Salicylic Acid Signals Plant Defence against Cadmium Toxicity. Int J Molecular Sci. 20(12), 2960.
13. Varjani S.J., 2017. Microbial degradation of petroleum hydrocarbons. Bioresour Technol. 223, 277-286.
14. Chen L., Lei Z., Luo X., Wang D., Li L., Li A., 2019. Biological Degradation and Transformation Characteristics of Total Petroleum Hydrocarbons by Oil Degradation Bacteria Adsorbed on Modified Straw. ACS Omega. 4(6), 10921-10928.
15. Shahsavari E., Schwarz A., Aburto-Medina A., Ball A. S., 2019. Biological Degradation of Polycyclic Aromatic Compounds (PAHs) in Soil: a Current Perspective. Current Pollut Report. 5(3), 84-92.
16. Ite A.E., Harry T.A., Obadimu C.O., Asuaiko E.R., Inim I.J., 2018. Petroleum hydrocarbons contamination of surface water and groundwater in the Niger Delta region of Nigeria. J Environ Polluti Human Health. 6(2), 51-61.
17. Pantsyrnaya T., Delaunay S., Goergen J.L., Guédon E., Paris C., Poupin P., Guseva E., Boudrant J., 2012. Biodegradation of phenanthrene by Pseudomonas putida and a bacterial consortium in the presence and in the absence of a surfactant. Indian J Microbiol. 52(3), 420-426.
18. Han Z.X., Meng Z., Lv C. X., 2012. Effect factors of biodegradation on phenanthrene by Pseudomonas putida. Advance Mater Res. 396, 2107-2110.
19. Adieze I.E., Orji J.C., Nwabueze R.N., Onyeze G., 2012. Hydrocarbon stress response of four tropical plants in weathered crude oil contaminated soil in microcosms. International J Environ Stud. 69(3), 490-500.
20. Disante K.B., Fuentes D., Cortina J., 2011. Response to drought of Zn-stressed Quercus suber L. seedlings. Environ Exp Botany. 70(2-3), 96-103.
21. Kapur D., Singh K.J., 2019. Zinc alleviates cadmium induced heavy metal stress by stimulating antioxidative defense in soybean [Glycine max (L.) Merr.] crop. Journal of Appl Natural Sci. 11(2), 338-345.
22. Planchamp C., Glauser G., Mauch-Mani B., 2015. Root inoculation with Pseudomonas putida KT2440 induces transcriptional and metabolic changes and systemic resistance in maize plants. Frontier Plant Sci. 5, 1-10.
23. Besalatpour A., Khoshgoftarmanesh A., Hajabbasi M., Afyuni M., 2008. Germination and growth of selected plants in a petroleum contaminated calcareous soil. Soil Sediment Contam. 17(6), 665-676.
24. Besalatpour A., Hajabbasi M., Khoshgoftarmanesh A., Dorostkar V., 2011. Landfarming process effects on biochemical properties of petroleum-contaminated soils. Soil Sed Contam. 20(2), 234-248.
25. Ueno D., Zhao F.l., Ma J.F., 2004. Interactions between Cd and Zn in relation to their hyperaccumulation in Thlaspi caerulescens. Soil Sci Plant Nutr. 50(4), 591-597.
26. Luo Q., Sun L., Hu X., Zhou R., 2014. The variation of root exudates from the hyperaccumulator Sedum alfredii under cadmium stress: metabonomics analysis. PloS one. 9(12), e115581.
27. Pinto A., Sim es I., Mota A., 2008. Cadmium impact on root exudates of sorghum and maize plants: a speciation study. J Plant Nutr. 31(10), 1746-1755.
28. Israr D., Mustafa G., Khan K. S., Shahzad M., Ahmad N., Masood S., 2016. Interactive effects of phosphorus and Pseudomonas putida on chickpea (Cicer arietinum L.) growth, nutrient uptake, antioxidant enzymes and organic acids exudation. Plant Physiol Biochem. 108, 304-312.
29. Zheng H., Wang M., Chen S., Li S., Lei X., 2019. Sulfur application modifies cadmium availability and transfer in the soil-rice system under unstable pe+pH conditions. Ecotox Environ Safe. 184, 109641.
30. Wang J., Li D., Lu Q., Zhang Y., Xu H., Wang X., Li Y., 2020. Effect of water-driven changes in rice rhizosphere on Cd lability in three soils with different pH. J Environ Sci. 87, 82-92.
31. Kohli S. K., Handa N., Kaur R., Kumar V., Khanna K., Bakshi P., Singh R., Arora S., Kaur R., Bhardwaj R. 2017. Role of salicylic acid in heavy metal stress tolerance: insight into underlying mechanism. Salicylic Acid: A Multifaceted Hormone. 123-144.
32. Raiesi F., Aghababae F., The decomposability of some plant residues and their susbsequent influence on soil microbial respiration and biomass, and enzyme activity. J Water Soil. 25(4), 863-873.
33. Karimian-Shamsabadi N., Ghorbani Dashtaki S., Raiesi F., 2017. The effect of urban sewage sludge on chemical properties, soil basal respiration and microbial biomass carbon in a calcareous silty clay loam soil. J Water Soil Sci. 21, 255-264.