Abstract
This research work aimed to study the effects of phosphogypsum (PG) amendment on the physicochemical proprieties of saline soil as well as the biochemical and physiological traits of Capsicum annuum grown under controlled conditions. C. annuum plants were grown on soil amended with different rates of PG varying from 0% to 5%, 10%, and 20%. The effects of PG on C. annuum growth, productivity, nutritional status, antioxidant enzyme activities, heavy metal accumulation, and its potential to use in phytoremediation were also investigated. The results revealed that pH and electrical conductivity of the soil decreased whereas organic matter contents increased in proportion to PG concentration. Both of biomass accumulation and leaf chlorophyll contents were affected by 20% PG amendment in comparison with the 5% and 10% PG and control samples. Beyond 20% of PG, C. annuum plants developed an enzymatic antioxidant defense system in response to salinity and heavy metal stress. In other words, the application of phosphogypsum led to a decrease of potassium (K) concentrations in shoots and sodium (Na) and K in fruits. However, the calcium (Ca), zinc (Zn), cadmium (Cd) and chromium (Cr) accumulation were enhanced both in shoots and fruits. Eventually, Cd and Cr in pepper fruits were found to be above the recommended maximum allowable concentrations. The bioconcentration factor values of Cd in the root of Capsicum annuum were greater than 1, which indicated the Cd accumulation potential by this species. The translocation factor values of Cd and Zn were less than 1, proving that Cd and Zn were stabilized in the root part of the plant.
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Abril JM, García-Tenorio R, Enamorado SM, Hurtado MD, Andreu L, Delgado A (2008) The cumulative effect of three decades of phosphogypsum amendments in reclaimed marsh soils from SW Spain: 226Ra, 238U and Cd contents in soils and tomato fruit. Sci Tot Environ 403:80–88
Abril JM, García-Tenorio R, Manjón G (2009a) Extensive radioactive characterization of a phosphogypsum stack in SW Spain: 226Ra, 238U, 210Po concentrations and 222Rn exhalation rate. J Hazard Mater 164:790–797
Abril JM, García-Tenorio R, Enamorado SM, Hurtado MD, Andreu L, Delgado A (2009b) Occupational dosimetric assessment (inhalation pathway) from the application of phosphogypsum in agriculture in South West Spain. J Environ Radioact 100:29–34
Aebi H (1984) Catalase in vitro. Methods Enzymol 105:121–126
Alcordo IS, Rechcigl JE (1993) Phosphogypsum in agriculture: a review. Adv Agronom 49:55–118
Alcordo IS, Rechcigl JE, Roessler CE, Littell RC (1999) Radiological impact of phosphogypsum applied to soils under bahiagrass pasture. J Environ Qual 28:1555–1567
ASTM D112523 (2023) Standard test methods for electrical conductivity and resistivity of water
Bates R (1973) Détermination du pH. Wiley, New York
Bjaoui I, Kolsi-benzina N (2016) Cadmium and phosphorus lixiviation in polluted acidic forest soil amended with Tunisian phosphogypsum. J New Sci 29(3):1664–1671
Blum J, Herpinb U, Melfia AJ, Montes CR (2012) Soil properties in a sugar cane plantation after the application of treated sewage effluent and phosphogypsum in Brazil. Agric Water Manag 115:203–216
Bradford M (1976) A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dyebinding. Anal Biochem 72:248–254
Bush DS (1995) Calcium regulation in plant cells and its role in signaling. Annu Rev Pantl Physiol Plant Mol Biol 56:95–122
Caires EF, Churka S, Garbuio FJ, Ferrari RA, Morgano MA (2006) Soybean yield and quality as a function of lime and gypsum applications. Sci Agricol 63:370–379
Caires EF, Garbuio FJ, Churka S, Joris HAW (2011) Use of gypsum for crop grain production under a subtropical no-till cropping system. Agron J 103:1804–1814
Chi CM, Zhao CW, Sun XJ, Wang ZC (2012) Reclamation of saline-sodic soil properties and improvement of rice (Oriza sativa L.) growth and yield using desulfurized gypsum in the west of Songnen Plain, north China. Geoderma 187(188):24–30. https://doi.org/10.1016/j.geoderma.2012.04.005
Churka Blum S, Caires EF, Alleoni LRF (2013) Lime and phosphogypsum application and sulfate retention in subtropical soils under notill system. J Soil Sci Plant Nutr 13:279–300
Cramer GR, Lauchli A, Epstein E (1986) Effects of NaCl and CaCl2 on ion activities in complex nutrient solutions and root growth in cotton. Plant Physiol 81:792–797
Cui S, Zhou Q, Chao L (2007) Potential hyperaccumulation of Pb, Zn, Cu and Cd in endurant plants distributed in an old smeltery northeast China. Environ Geol 51:1043–1048
Delgado A, Uceda I, Andreu L, Kassem S, Del Campillo M (2002) Fertilizer phosphorus recovery from gypsumamended, reclaimed calcareous marsh soils. Arid Land Res Manag 16:319–334
Delgado A, Hurtado MD, Andreu L (2006) Phosphorus loss in tile drains from a reclaimed marsh soil amended with manure and phosphogypsum. Nutr Cycl Agroecosyst 74:191–202
Domínguez R, Del Campillo MC, Peña F, Delgado A (2001) Effect of soil properties and reclamation practices on phosphorus dynamics in reclaimed calcareous marsh soils from the Guadalquivir Valley, SW Spain. Arid Land Res Manag 15:203–221
Duan XW, Liu T, Zhang DD, Su XG, Lin HT, Jiang YM (2011) Effect of pure oxygen atmosphere on antioxidant enzyme and antioxidant activity of harvested litchi fruit during storage. Food Res Int 44:1905–1911
Elloumi N, Belhaj D, Mseddi S, Zouari M, Ben Abdallah F, Woodward S, Kallel M (2015) Effect of phosphogypsum on growth, physiology, and the antioxidativedefense system in sunflower seedlings. Environ Sci Pollut Res 22:14829–14840
Elloumi N, Belhaj D, Mseddi S, Zouari M, Ben Abdallah F, Woodward S, Kallel M (2017) Response of Nerium oleander to phosphogypsum amendment and its potential use for phytoremediation. Ecol Eng 99:164–171
El-Mrabet R, Abril JM, Periáñez R, Manjón G, García-Tenorio R, Delgado A, Andreu L (2003) Phosphogypsum amendment effect on radionuclide content in drainage wáter and marsh soil from south-western Spain. J Environ Qual 32:1262–1268
Enamorado S, Abril JM, Mas JL, Periáñez R, Polvillo O, Delgado A, Quintero, JM (2009) Transfer of Cd, Pb, Ra and U from phosphogypsum amended soils tomato plants. Water Air Soil Pollut 203:65–77
Esawy M, Abd El-Kader N (2015) Heavy metal immobilization in contaminated soils using phosphogypsum and rice straw compost. Land Degrad Dev 26:819–824
European Union (2006) Commission Regulation (EC) No.1881/2006 of 19 December 2006. Setting maximum levels for certain contaminants in foodstuffs. Off J Eur Union 364:5–24
Filipović-Trajković R, Ilić SZ, Šunić L (2012) The potential of different plant species for heavy metals accumulation and distribution. J Food Agric Environ 10:959–964
Garcia M, Daverede C, Gallego P, Toumi M (1999) Effect of various potassium-calcium ratios on cation nutrition of grape grown hydroponically. J Plant Nutr 22(3):417–425
Gharaibeh MA, Rusan MJ, Eltaif NI, Shunnar OF (2014) Reclamation of highly calcareous saline-sodic soil using low quality water and phosphogypsum. Appl Water Sci 4:223–230
Hafez EM, Abou El Hassan WH, Gaafar IA, Seleiman MF (2015) Effect of gypsum application and irrigation intervals on clay saline-sodic soil characterization, rice water use efficiency. J Agric Sci 7:208–219
Hurtado MD, Enamorado SM, Andreu L, Delgado A, Abril JM (2011) Drainflow and related salt losses as affected by phosphogypsum amendment inreclaimed marsh soils from SW Spain. Geoderma 161:43–49
Jain M, Mathur G, Koul S, Sarin NB (2001) Ameliorative effects of proline on salt stress-induced lipid peroxidation in cell lines of groundnut (Arachis hypogea L.). Plant Cell Rep 20:463–468
Khalil NF, Alnuaimi NM, Jamal MA (1990) Agricultural uses of phosphogypsum on calcareous soils. In: Proceedings of the third international symposium on Phosphogypsum, Orlando, FL. FIPR Pub. No. 01-060-083-1, pp 333-347
Krichen M, Jraba A, Ksibi H, Elaloui E (2023) Effects of inorganic constituents on thermal and mechanical properties in several types of phosphogypsum: a case study of Gafsa-site (TN). Euro-Med J Environ Integr 8:29–39
Lichtenthaler HK (1987) Chlorophylls and carotenoids: pigments of photosynthetic biomembranes. Methods Enzymol 148:350–382
Lin CC, Kao CH (2000) Effect of NaCl stress on H2O2 metabolism in rice leaves. Plant Growth Regul 30:151–155
Malik RN, Husain SZ, Nazir I (2010) Heavy metal contamination and accumulation in soil and wild plant species from industrial area of Islamabad, Pakistan. Pak J Bot 42:291–301
McGrath SP, Cunliffe CH (1985) A simplified method for the extraction of the metals Fe, Zn, Cu, Ni, Pb, Cr, Co and Mn from soils and sewage sludges. J Sci Food Agric 36:794–798
Mirecki N, Agič R, Šunić L, Milenković L, Ilić ZS (2015) Transfer factor as indicator of heavy metals content in plants. Fresenius Environ Bull 24:4212–4219
Najami N, Tibor J, Barriah W, Kayam G, Moshe T, Guy M, Volokita M (2008) Ascorbate peroxidase gene family in tomato: its identification and characterization. Mol Genet Genom 279:171–182
Nakano Y, Asada K (1981) Hydrogen peroxide is scavenged by ascorbate specific peroxidase in spinach chloroplasts. Plant Cell Physiol 22:867–880
Olsen SR, Sommers LE (1982) Phosphorus. In: Page AL et al (eds) Methods of soil analysis, part 2, agronomy monograph 9, 2nd edn. ASA and ASSA, Madison, pp 403–430
Ostos JC, Lopez-Garrido R, Murillo JM, Lopez R (2008) Substitution of peat formunicipal solid waste and sewage sludge-based composts in nursery growingmedia: effects on growth and nutrition of the native shrub Pistacia lentiscus L. Bioresour Technol 99:1793–1800
Papa S, Bartoli G, Nacca F, D’Abrosca B, Cembrola E, Pellegrino A, Fiorentino A, Fuggi A, Fioretto A (2012) Trace metals, peroxidase activity, PAHs contents and ecophysiological changes in Quercus ilex leaves in the urban area of Caserta (Italy). J Environ Manag 113:501–509
Papastefanou C, Stoulos S, Ioannidou A, Manolopoulou M (2006) The application of phosphogypsum in agriculture and the radiological impact. J Envion Radioact 89:188–198
Rafati M, Khorasani N, Moattar F, Shirvany A, Moraghebi F, Hosseinzadeh S (2011) Phytoremediation potential of Populus alba and Morus alba for cadmium, chromium and nickel absorption from polluted soil. Int J Environ Res 5:961–970
Rutherford PM, Dudas MJ, Samek RA (1994) Environmental impacts of phosphogypsum. Sci Total Environ 149:1–38
Sagisaka S (1979) The occurrence of peroxide in perennial plant Populus glerica. Plant Physiol 57:308–309
Smaoui-Jardak M, Kriaa W, Maalej M, Zouari M, Kammoun L, Trabelsi W, Ben Abdallah F, Elloumi N (2017) Effect of the phosphogypsum amendment of saline and agricultural soils on growth, productivity and antioxidant enzyme activities of tomato (Solanum lycopersicum L.). Ecotoxi 26(3):1089–1104. https://doi.org/10.1007/s10646-017-1836-x
State Environmental Protection Administration (SEPA) (1995) Environmental quality standard for soils. State Environ Geochem Health Environmental Protection Administration, China, Beijing (GB15618-1995)
Tuna AL, Kaya C, Ashraf M, Altunlu H, Yokas I, Yagmur B (2007) The effects of calcium sulphate on growth, membrane stability and nutrient uptake of tomato plants grown under salt stress. Environ Exp Bot 59:173–178
Vyshpolsky F, Mukhamedjanov K, Bekbaev U, Ibatullin S, Yuldashev T, Noble AD (2010) Optimizing the rate and timing of phosphogypsum application to magnesium affected soils for crop yield and water productivity enhancement. Agric Water Manag 97:1277–1286
Walkley A, Black IA (1934) An examination of Degtjareff method for determining soil organic matter and a proposed modification of the chromic acid titration method. Soil Sci 37:29–37
Wang Y, Feng H, Qu Y, Cheng J, Zhao Z, Zhang M, Wang X, An L (2006) The relationship between reactive oxygen species and nitric oxide in ultraviolet-B-induced ethylene production in leaves of maize seedlings. Environ Exp Bot 57:51–61
Xin J, Huang B, Dai H, Liu A, Zhou W, Liao K (2014) Characterization of cadmium uptake, translocation, and distribution in young seedlings of two hot pepper cultivars that differ in fruit cadmium concentration. Environ Sci Pollut Res 21:7449–7456
Xin J, Huang B, Dai H (2015) Difference in root-to-shoot Cd translocation and characterization of Cd accumulation during fruit development in two Capsicum annuum cultivars. Plant Soil 394:287–300
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This work was performed within the framework of a MOBIDOC PhD thesis supported by the European Union and run by the Tunisian National Agency for Scientific Research (ANPR) through the PASRI program.
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Smaoui-Jardak, M., Turki, M., Zouari, M. et al. Effect of phosphogypsum amendment on saline soil and on growth, productivity, and antioxidant enzyme activities of pepper (Capsicum annuum L.). Euro-Mediterr J Environ Integr 9, 393–403 (2024). https://doi.org/10.1007/s41207-023-00428-5
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DOI: https://doi.org/10.1007/s41207-023-00428-5