The Sulfur Dioxide Absorption Capacity of Plants Tecoma Stans and its Effect on Antioxidants

Al-Jaba, Sura Razzaq Manhee; Al-Janabi, Ameera O. Hussain

doi:10.12912/27197050/190450

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Tytuł artykułu

The Sulfur Dioxide Absorption Capacity of Plants Tecoma Stans and its Effect on Antioxidants

Autorzy

Al-Jaba Sura Razzaq Manhee , Al-Janabi Ameera O. Hussain

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DOI

10.12912/27197050/190450

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Języki publikacji

Abstrakty

The current study used to prove the efficiency of Tecoma stans to sulfur dioxide gas (SO₂ )was at a concentration of 10 mg·m^-3 which is equal to 3.82 ppm for the period from summer exposure (May – June 2023) to reduce SO₂ thus reduce some gaseous pollutants that cause global warming and some air pollutants and know the effect of seasonal conditions to mitigate these pollutants. The physiological changes of the three replicates of study plant were observed through equal time periods daily for a period of seven days covered with polyethylene under controlled conditions represented by a greenhouse. The process was repeated three times between the three exposures provide rest periods for the plant for a week. During summer exposure, it was found that the concentration of flavonoids was significantly increased as compare to control (5.222 ± 0.27 mg/100 ml of extract) from 6.58 ± 0.43 to 6.24 ± 0.31 mg/100 ml of extract, but this concentration was increased after the third exposure into to 6.99 ± 0.29 mg/100 ml of extract. There was decrease in Tannins concentration after the second exposure (with concentration 1.5 ± 0.05 to 0.72 ± 0.01 µl/ml)), but this concentration was returned increased significantly to 1.36 ± 0.01 µl/ml) after the third exposure to SO₂ . Also in The enzyme activities for peroxidase (POD), superoxide dismutase (SOD) and catalase (CAT) demonstrated varied responses to SO₂ exposure, and T. stans showing distinct patterns of enzyme activation. The effect of POD and CAT increased in plants which exposure into SO₂ , whereas CAT play important role in inhibition of ROS.

Słowa kluczowe

phytoremediation pollution antioxidants flavonoids tannins catalase superoxide dismutase peroxidase

Wydawca

Lubelski Oddział Polskiego Towarzystwo Inżynierii Ekologicznej
Lublin University of Technology
WNGB Wydawnictwo Naukowe

Czasopismo

Ecological Engineering & Environmental Technology

Rocznik

2024

Tom

Vol. 25, iss. 9

Strony

268--276

Opis fizyczny

Bibliogr. 38 poz., rys., tab.

Twórcy

autor

Al-Jaba Sura Razzaq Manhee

Environmental Pollution Department-Environmental Sciences, College-Al-Qasim Green University, Babylon 51013, Iraq

autor

Al-Janabi Ameera O. Hussain

ameeraenvironment77@yahoo.com

Environmental Pollution Department-Environmental Sciences, College-Al-Qasim Green University, Babylon 51013, Iraq

Bibliografia

1. Adnan L.A., Mohd Yusoff A.R., Hadibarata, T., Khudhair, A.B. 2014. Biodegradation of Bis-Azo dye reactive black 5 by white-rot fungus Trametes gibbosa sp. WRF 3 and its metabolite characterization. Water, Air, & Soil Pollution, 225, 2119.
2. Agarwal, P., Sarkar, M., Chakraborty, B., Banerjee, T. 2018. Phytoremediation of air pollutants: prospects and challenges. InTech Open. Phytomanagement of Polluted Sites.
3. Bhave, P.P., Yeleswarapu, D. 2020. Removal of indoor air pollutants using activated carbon—a review. Global Challenges in Energy and Environment: Select Proceedings of ICEE 2018, 65–75.
4. Broadhurst R.B., Jones W.T. 1978. Analysis of condensed tannins using acidified vanillin. Journal of the Science of Food and Agriculture, 29(9), 788–94.
5. Burns, J., Boogaard, H., Polus, S., Pfadenhauer, L.M., Rohwer, A.C., Van Erp, A.M., Turley, R., Rehfuess, E.A. 2020. Interventions to reduce ambient air pollution and their effects on health: An abridged Cochrane systematic review. Environment International, 135, 105400.
6. Cao, D., Zhang, B., Yang, M., Luo, F., Yang, X., Zhu, S. 2019. Use of single atom catalysis for improvement of lignocellulosic conversion. BioResources, 14(3), 5018–5021.
7. Castro, R.J.S., Cason, V.G., Sato, H.H. 2017. Binary mixture of proteases increases the antioxidant properties of white bean (Phaseolus vulgaris L.) protein-derived peptides obtained by enzymatic hydrolysis. Biocatalysis and agricultural biotechnology, 10, 291–297.
‏ 8. Dhanabalan, S.S., Avaninathan, S.R., Rajendran, S., Carrasco, M.F. 2020. Photocatalysts for indoor air pollution: A brief review. Green Photocatalysts for Energy and Environmental Process, 247–274. 9. Espeland, E.K., Kettenring, K.M. 2018. Strategic plant choices can alleviate climate change impacts: A review. Journal of environmental management, 222, 316–324.‏
10. Fahad, M.J., Abdullah, A.K. 2022. The relationship between sulphur dioxide and trehalose and their effect on some biochemical characteristics of tomato plants. Asian Journal of Water, Environment and Pollution, 19(4), 81-90.
11. Fernandes, A., Mankad, A. 2022. An appraise on Tecoma stans L Ex. Juss, kunth.-phytochemical potentials. International Association of Biologicals and Computational Digest, 1(2), 259–274.
12. Gulcin, İ. 2020. Antioxidants and antioxidant methods: An updated overview. Archives of toxicology, 94(3), 651–715.
13. Hadibarata, T., Kristanti, R.A. 2012. Effect of environmental factors in the decolorization of Remazol Brilliant Blue R by Polyporus sp. S133. Journal of the Chilean Chemical Society, 57, 1095–1098.
14. Hadwan M.H, kadhum Ali S. 2018. New spectrophotometric assay for assessments of catalase activity in biological samples. Analytical biochemistry; 542, 29–33.
15. Hasanuzzaman, M., Fujita, M. 2022. Plant oxidative stress: Biology, physiology and mitigation. Plants, 11(9), 1185.‏
16. He, J., Gong, S., Yu, Y., Yu, L., Wu, L., Mao, H., Song, C., Zhao, S., Liu, H., Li, X., Li, R. 2017. Air pollution characteristics and their relation to meteorological conditions during 2014–2015 in major Chinese cities. Environmental pollution, 223, 484–496.‏
17. Zeng, Y., Cao, Y., Qiao, X., Seyler, B. C., Tang, Y. 2019. Air pollution reduction in China: Recent success but great challenge for the future. Science of the Total Environment, 663, 329–337.
18. Kanthasamy, S., Hadibarata, T., Hidayat, T., Alamri, S.A., AlGhamdi, A.A. 2020. Adsorption of azo and anthraquinone dye by using watermelon peel powder and corn peel powder: Equilibrium and kinetic studies. Biointerface Research in Applied Chemistry, 10, 4706–4713.
19. Karnosky, D.F., Zak, D.R., Pregitzer, K.S., Awmack, C.S., Bockheim, J.G., Dickson, R.E., Isebrands, J.G. 2003. Tropospheric O3 moderates responses of temperate hardwood forests to elevated CO2 : A synthesis of molecular to ecosystem results from the Aspen FACE project. Functional Ecology, 17(3), 289–304.‏
20. Khadabadi S.S., Deore S.L., Baviskar B.A. 2011. Experimental phytopharmacognosy. Nirali prakashan, page, 47.
21. Khattab, A., Awad, N.E., Fadeel, D.A., Fadel, M. 2022. Reviewing the reported pharmacognostic and pharmacological investigations on Tecoma stans Juss. ex Kunth. Journal of Herbmed Pharmacology, 12(1), 25–40.
22. Lahiri, M., Krishna, K. 2024. Effect of air pollution on plant secondary metabolites in selected trees of Delhi. Environmental Quality Management, 33(3), 399–409. Lasat, M. 2001. Phytoextraction of toxic metals: a review of biological mechanisms. Journal of Environmental Quality, 31, 109–120.
23. Lau, K.B.K., Hadibarata, T., Eliwina, E., Dewi, R., Al Sahil, A.A., Al-Ghamdi, A.A. 2020. Reactive dyes adsorption via Citrus hystrix peel powder and Zea mays cob powder: characterization, isotherm and kinetic studies. Biointerface Research in Applied Chemistry, 10, 4803–4810.
24. Lee, B.X.Y., Hadibarata, T., Yuniarto, A. 2020. Phytoremediation mechanisms in air pollution control: a review. Water, Air, & Soil Pollution, 231(8), 437.‏
25. Lee, G.Y., Lee, J., Vo, H.T., Kim, S., Lee, H., Park, T. 2017. Amine-functionalized covalent organic framework for efficient SO2 capture with high reversibility. Scientific reports, 7(1), 557.‏
26. Lelieveld, J., Klingmüller, K., Pozzer, A., Burnett, R.T., Haines, A., Ramanathan, V. 2019. Effects of fossil fuel and total anthropogenic emission removal on public health and climate. Proceedings of the National Academy of Sciences, 116(15), 7192–7197.
27. Li L., Yi H. 2020. Photosynthetic responses of Arabidopsis to SO2 were related to photosynthetic pigments, photosynthesis gene expression and redox regulation. Ecotoxicology and Environmental Safety, 203, 111019.
28. Lu X., Zhang L., Wang X., Gao M., Li K., Zhang Y., Xu Y., Zhang, Y. 2020. Rapid increases in warmseason surface ozone and resulting health impact over China since 2013. Environmental Science & Technology Letters, 7(6), 401–407.
29. Malik, C.P and Singh, M.B. 1980. In: Plant Enzymology and Histoenzymology. Kalyani Publishers New Delhi p.53.
30. Pitotti, A., Elizalde, B.E., Anese, M. 1994. Effect of caramelization and Maillard reaction products on peroxidase activity. Journal of Food Biochemistry, 18(6), 445-457.
31. Putter, J. 1974. In: Methods of Enzymatic Analysis 2 (Ed Bergmeyer) Academic Press New York p 685.
32. Ribarova, F., Atanassova, M., Marinova, D., Ribarova, F., Atanassova, M. 2005. Total phenolics and flavonoids in Bulgarian fruits and vegetables. JU Chem. Metal, 40(3), 255–260.‏
33. Salim, S.D., Hadibarata, T., Elwina, E., Dewi, R., Alaraidh, I.A., Al-Ghamdi, A.A., Alsahli, A.A. 2019. Development of activated carbon from Eichhornia Crassipes via chemical activation and its application to remove a synthetic dye. Biointerface Research in Applied Chemistry, 9, 4394–4400.
34. Sedjo, R., and Sohngen, B. 2012. Carbon sequestration in forests and soils. Annual Review of Resource Economics, 4, 127– 144.
35. Seinfeld, J.H., Pandis, S.N. 2016. Atmospheric chemistry and physics: from air pollution to climate change. John Wiley & Sons.
36. Singh, S.N., Verma, A. 2007. Phytoremediation of air pollutants: a review. In S. N. Singh and R. D. Tripathi (Eds.), Environmental Bioremediation Technologies (pp. 293– 314). Berlin: Springer Berlin Heidelberg.
37. Weyens, N., Thijs, S., Popek, R., Witters, N., Przybysz, A., Espenshade, J., Gawronska, H., Vangronsveld, J., Gawronski, S.W. 2015. The role of plant–microbe interactions and their exploitation for phytoremediation of air pollutants. International Journal of Molecular Sciences, 16, 25576–25604.
38. Zhang, B., Cao, D., Zhu, S. 2020. Use of plants to clean polluted air: a potentially effective and lowcost phytoremediation technology. BioResources, 15(3), 4650–4654.

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Bibliografia

Identyfikator YADDA

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