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1 1 Qasim, S.R. (2017). Wastewater Treatment Plants: Planning, Design, and Operation. London: Routledge.

2 2 Carr, S.A., Liu, J., and Tesoro, A.G. (2016). Transport and fate of microplastic particles in wastewater treatment plants. Water Research 91: 174–182.

3 3 Zhang, Q., Yang, W.N., Ngo, H.H. et al. (2016). Current status of urban wastewater treatment plants in China. Environment International 92: 11–22.

4 4 McIntyre, T. (2003). Phytoremediation of heavy metals from soils. In: Phytoremediation (ed. D.T. Tsao), 97–123. Berlin, Heidelberg: Springer.

5 5 Pascal‐Lorber, S. and Laurent, F. (2011). Phytoremediation techniques for pesticide contaminations. In: Alternative Farming Systems, Biotechnology, Drought Stress and Ecological Fertilisation (ed. E. Lichtfouse), 77–105. Dordrecht: Springer.

6 6 He, C., Li, L., and Gu, C. (2003). Phytoremediation techniques of heavy metal in sewage sludge. Chinese Journal of Ecology 22 (5): 78–81.

7 7 Jadia, C.D. and Fulekar, M. (2009). Phytoremediation of heavy metals: recent techniques. African Journal of Biotechnology 8 (6): 921–928.

8 8 Singh, O.V., Labana, S., Pandey, G. et al. (2003). Phytoremediation: an overview of metallic ion decontamination from soil. Applied Microbiology and Biotechnology 61 (5): 405–412.

9 9 Liu, P., Qiu, G., and Shang, L. (2007). Phytoremediation of mercury contaminated soil: a review. Chinese Journal of Ecology 6: 27.

10 10 Alloway, B.J. (2013). Sources of heavy metals and metalloids in soils. In: Heavy Metals in Soils (ed. B.J. Alloway), 11–50. Dordrecht: Springer.

11 11 Adamo, P., Denaix, L., Terribile, F. et al. (2003). Characterization of heavy metals in contaminated volcanic soils of the Solofrana river valley (southern Italy). Geoderma 117 (3–4): 347–366.

12 12 Callender, E. (2003). Heavy metals in the environment‐historical trends. Treatise on Geochemistry 9: 612.

13 13 Rylander, P.N. (1967). Platinum metals in catalytic hydrogenation. Annals of the New York; Academy of Sciences 145 (1): 46–51.

14 14 Jayasumana, C., Gajanayake, R., and Siribaddana, S. (2014). Importance of arsenic and pesticides in epidemic chronic kidney disease in Sri Lanka. BMC Nephrology 15 (1): 124.

15 15 Roberts, T.L. (2014). Cadmium and phosphorous fertilizers: the issues and the science. Procedia Engineering 83: 52–59.

16 16 Tchounwou, P.B., Yedjou, C.G., Patlolla, A.K. et al. (2012). Heavy metal toxicity and the environment. In: Molecular, Clinical and Environmental Toxicology: Volume 3: Environmental Toxicology (ed. A. Luch), 133–164. Basel: Springer.

17 17 Wei, B. and Yang, L. (2010). A review of heavy metal contaminations in urban soils, urban road dusts and agricultural soils from China. Microchemical Journal 94 (2): 99–107.

18 18 Tang, W., Shan, B., Zhang, H. et al. (2010). Heavy metal sources and associated risk in response to agricultural intensification in the estuarine sediments of Chaohu Lake Valley, East China. Journal of Hazardous Materials 176 (1): 945–951.

19 19 Arora, M., Kiran, B., Rani, S. et al. (2008). Heavy metal accumulation in vegetables irrigated with water from different sources. Food Chemistry 111 (4): 811–815.

20 20 Bradl, H.B. (2005). Sources and origins of heavy metals. In: Interface Science and Technology (ed. H.B. Bradl), 1–27. Amsterdam: Elsevier.

21 21 Buccolieri, A., Buccolieri, G., Dell’Atti, A. et al. (2006). Natural sources and heavy metals. Annali di Chimica 96 (3–4): 167–181.

22 22 Garrett, R.G. (2000). Natural sources of metals to the environment. Human and Ecological Risk Assessment: An International Journal 6 (6): 945–963.

23 23 Dias, G.M. and Edwards, G.C. (2003). Differentiating natural and anthropogenic sources of metals to the environment. Human and Ecological Risk Assessment: An International Journal 9 (4): 699–721.

24 24 Ochieng, E.Z., Lalah, J.O., and Wandiga, S.O. (2009). Anthropogenic sources of heavy metals in the Indian Ocean Coast of Kenya. Bulletin of Environmental Contamination and Toxicology 83 (4): 600–607.

25 25 Zhang, C., Qiao, Q., Appel, E. et al. (2012). Discriminating sources of anthropogenic heavy metals in urban street dusts using magnetic and chemical methods. Journal of Geochemical Exploration 119–120: 60–75.

26 26 Xu, Y., Sun, Q., Yi, L. et al. (2014). The source of natural and anthropogenic heavy metals in the sediments of the Minjiang River Estuary (SE China): implications for historical pollution. Science of the Total Environment 493: 729–736.

27 27 Davis, H.T., Aelion, C., McDermott, S. et al. (2009). Identifying natural and anthropogenic sources of metals in urban and rural soils using GIS‐based data, PCA, and spatial interpolation. Environmental Pollution (Barking, Essex: 1987) 157 (8–9): 2378–2385.

28 28 Pacyna, E.G., Pacyna, J.M., Fudala, J. et al. (2007). Current and future emissions of selected heavy metals to the atmosphere from anthropogenic sources in Europe. Atmospheric Environment 41 (38): 8557–8566.

29 29 Alloway, B.J. (2013). Sources of heavy metals and metalloids in soils. In: Heavy Metals in Soils: Trace Metals and Metalloids in Soils and Their Bioavailability (ed. B.J. Alloway), 11–50. Dordrecht: Springer.

30 30 Bååth, E. (1989). Effects of heavy metals in soil on microbial processes and populations (a review). Water, Air, and Soil Pollution 47 (3): 335–379.

31 31 Jansen, E., Michels, M., van Til, M. et al. (1994). Effects of heavy metals in soil on microbial diversity and activity as shown by the sensitivity‐resistance index, an ecologically relevant parameter. Biology and Fertility of Soils 17 (3): 177–184.

32 32 Leita, L., De Nobili, M., Muhbachova, G. et al. (1995). Bioavailability and effects of heavy metals on soil microbial biomass survival during laboratory incubation. Biology and Fertility of Soils 19 (2): 103–108.

33 33 Kandeler, F., Kampichler, C., and Horak, O. (1996). Influence of heavy metals on the functional diversity of soil microbial communities. Biology and Fertility of Soils 23 (3): 299–306.

34 34 Wang, Y., Shi, J., Wang, H. et al. (2007). The influence of soil heavy metals pollution on soil microbial biomass, enzyme activity, and community composition near a copper smelter. Ecotoxicology and Environmental Safety 67 (1): 75–81.

35 35 Fließbach, A., Martens, R., and Reber, H.H. (1994). Soil microbial biomass and microbial activity in soils treated with heavy metal contaminated sewage sludge. Soil Biology and Biochemistry 26 (9): 1201–1205.

36 36 Chander, K. and Brookes, P.C. (1991). Effects of heavy metals from past applications of sewage sludge on microbial biomass and organic matter accumulation in a sandy loam and silty loam U.K. soil. Soil Biology and Biochemistry 23 (10): 927–932.

37 37 Weng, L., Temminghoff, E., Lofts, S. et al. (2002). Complexation with dissolved organic matter and solubility control of heavy metals in a Sandy soil. Environmental Science & Technology 36 (22): 4804–4810.

38 38 Valsecchi, G., Gigliotti, C., and Farini, A. (1995). Microbial biomass, activity, and organic matter accumulation in soils contaminated with heavy metals. Biology and Fertility of Soils 20 (4): 253–259.

39 39 Reuter, J.H. and Perdue, E.M. (1977). Importance of heavy metal‐organic matter interactions in natural waters. Geochimica et Cosmochimica Acta 41 (2): 325–334.

40 40 Brookes, P.C. (1995). The use of microbial parameters in monitoring soil pollution by heavy metals. Biology and Fertility of Soils 19 (4): 269–279.

41 41 Clemente, R., Escolar, Á., and Bernal, M.P. (2006). Heavy metals fractionation and organic matter mineralisation in contaminated calcareous soil amended with organic materials. Bioresource Technology 97 (15): 1894–1901.

42 42 Barceló, J. and Poschenrieder, C. (1990). Plant water relations as affected by heavy metal stress: a review. Journal of Plant Nutrition 13 (1): 1–37.

43 43 Nagajyoti, P.C., Lee, K.D., and Sreekanth, T.V.M. (2010). Heavy metals, occurrence and toxicity for plants: a review. Environmental Chemistry Letters 8 (3): 199–216.

44 44 Påhlsson, A.‐M.B. (1989). Toxicity of heavy metals (Zn, Cu, Cd, Pb) to vascular plants. Water, Air, and Soil Pollution 47 (3): 287–319.

45 45 Schützendübel, A. and Polle, A. (2002). Plant responses to abiotic stresses: heavy metal‐induced oxidative stress and protection by mycorrhization. Journal of Experimental Botany 53 (372): 1351–1365.

46 46 Ernst, W.H.O. (1996). Bioavailability of heavy metals and decontamination of soils by plants. Applied Geochemistry 11 (1): 163–167.

47 47 Vinodhini, R. and Narayanan, M. (2008). Bioaccumulation of heavy metals in organs of fresh water fish Cyprinus carpio (common carp). International Journal of Environmental Science and Technology 5 (2): 179–182.

48 48 Khan, S., Cao, Q., Zheng, Y.M. et al. (2008). Health risks of heavy metals in contaminated soils and food crops irrigated with wastewater in Beijing, China. Environmental Pollution 152 (3): 686–692.

49 49 Ma, J., Ding, Z., Wei, G. et al. (2009). Sources of water pollution and evolution of water quality in the Wuwei basin of Shiyang river, Northwest China. Journal of Environmental Management 90 (2): 1168–1177.

50 50 Castro‐González, M.I. and Méndez‐Armenta, M. (2008). Heavy metals: implications associated to fish consumption. Environmental Toxicology and Pharmacology 26 (3): 263–271.

51 51 Wang, Q. and Yang, Z. (2016). Industrial water pollution, water environment treatment, and health risks in China. Environmental Pollution 218: 358–365.

52 52 Cheng, S. (2003). Heavy metal pollution in China: origin, pattern and control. Environmental Science and Pollution Research 10 (3): 192–198.

53 53 Uversky, V.N., Li, J., and Fink, A.L. (2001). Metal‐triggered structural transformations, aggregation, and fibrillation of human α‐Synuclein: a possible molecular link between Parkinson's disease and heavy metal exposure. Journal of Biological Chemistry 276 (47): 44284–44296.

54 54 Muchuweti, M., Birkett, J.W., Chinyanga, E. et al. (2006). Heavy metal content of vegetables irrigated with mixtures of wastewater and sewage sludge in Zimbabwe: implications for human health. Agriculture, Ecosystems & Environment 112 (1): 41–48.

55 55 Zhuang, P., McBride, M.B., Xia, H. et al. (2009). Health risk from heavy metals via consumption of food crops in the vicinity of Dabaoshan mine, South China. Science of the Total Environment 407 (5): 1551–1561.

56 56 Singh, A., Sharma, R.K., Agrawal, M. et al. (2010). Health risk assessment of heavy metals via dietary intake of foodstuffs from the wastewater irrigated site of a dry tropical area of India. Food and Chemical Toxicology 48 (2): 611–619.

57 57 Mahmood, A. and Malik, R.N. (2014). Human health risk assessment of heavy metals via consumption of contaminated vegetables collected from different irrigation sources in Lahore, Pakistan. Arabian Journal of Chemistry 7 (1): 91–99.

58 58 Fowler, B.A. (2013). Biological and Environmental Effects of Arsenic, vol. 6. Amsterdam: Elsevier.

59 59 Marin, A., Pezeshki, S.R., Masschelen, P.H. et al. (1993). Effect of dimethylarsenic acid (DMAA) on growth, tissue arsenic, and photosynthesis of rice plants. Journal of Plant Nutrition 16 (5): 865–880.

60 60 Burlo, F., Guyarro, I., Carbonell‐Barrachina, A.A. et al. (1999). Arsenic species: effects on and accumulation by tomato plants. Journal of Agricultural and Food Chemistry 47 (3): 1247–1253.

61 61 Stoeva, N., Berova, M., and Zlatev, Z. (2005). Effect of arsenic on some physiological parameters in bean plants. Biologia Plantarum 49 (2): 293–296.

62 62 Sun, H.‐J., Rathinasabapathi, B., Wu, B. et al. (2014). Arsenic and selenium toxicity and their interactive effects in humans. Environment International 69: 148–158.

63 63 Banerjee, M., Banerjee, N., Bhattacharjee, P. et al. (2013). High arsenic in rice is associated with elevated genotoxic effects in humans. Scientific Reports 3: 2195.

64 64 Abernathy, C.O., Liu, Y.P., Longfellow, D. et al. (1999). Arsenic: health effects, mechanisms of actions, and research issues. Environmental Health Perspectives 107 (7): 593.

65 65 Mergler, D., Anderson, H.A., Chan, L.H. et al. (2007). Methylmercury exposure and health effects in humans: a worldwide concern. Ambio: A Journal of the Human Environment 36 (1): 3–11.

66 66 Sun, H.J., Xiang, P., Luo, J. et al. (2016). Mechanisms of arsenic disruption on gonadal, adrenal and thyroid endocrine systems in humans: a review. Environment International 95: 61–68.

67 67 Guo, P., Qi, Y.‐P., Cai, Y.,.‐T. et al. (2018). Aluminum effects on photosynthesis, reactive oxygen species and methylglyoxal detoxification in two Citrus species differing in aluminum tolerance. Tree Physiology 38 (10): 1548–1565.

68 68 Khan, A., Khan, S., Khan, M.A. et al. (2015). The uptake and bioaccumulation of heavy metals by food plants, their effects on plants nutrients, and associated health risk: a review. Environmental Science and Pollution Research 22 (18): 13772–13799.

69 69 Mišík, M., Burke, I.T., Reismüller, M. et al. (2014). Red mud a byproduct of aluminum production contains soluble vanadium that causes genotoxic and cytotoxic effects in higher plants. Science of the Total Environment 493: 883–890.

70 70 Sade, H., Meriga, B., Surapu, V. et al. (2016). Toxicity and tolerance of aluminum in plants: tailoring plants to suit to acid soils. Biometals 29 (2): 187–210.

71 71 Dórea, J. (2015). Exposure to mercury and aluminum in early life: developmental vulnerability as a modifying factor in neurologic and immunologic effects. International Journal of Environmental Research and Public Health 12 (2): 1295.

72 72 Rajiv, S., Jerobin, J., Saranya, V. et al. (2016). Comparative cytotoxicity and genotoxicity of cobalt (II, III) oxide, iron (III) oxide, silicon dioxide, and aluminum oxide nanoparticles on human lymphocytes in vitro;. Human & Experimental Toxicology 35 (2): 170–183.

73 73 Annangi, B., Bonassi, S., Marcos, R. et al. (2016). Biomonitoring of humans exposed to arsenic, chromium, nickel, vanadium, and complex mixtures of metals by using the micronucleus test in lymphocytes. Mutation Research/Reviews in Mutation Research 770: 140–161.

74 74 Stambulska, U.Y., Bayliak, M.M., and Lushchak, V.I. (2018). Chromium (VI) toxicity in legume plants: modulation effects of rhizobial symbiosis. BioMed Research International 3: 1–18.

75 75 Heer, M. and Egert, S. (2015). Nutrients other than carbohydrates: their effects on glucose homeostasis in humans. Diabetes/Metabolism Research and Reviews 31 (1): 14–35.

76 76 Mishra, S. and Bharagava, R.N. (2016). Toxic and genotoxic effects of hexavalent chromium in environment and its bioremediation strategies. Journal of Environmental Science and Health, Part C 34 (1): 1–32.

77 77 Kolahian, S., Sadri, H., Larijani, A. et al. (2016). Supplementation of diabetic rats with leucine, zinc, and chromium: effects on function and histological structure of testes. International Journal for Vitamin and Nutrition Research 85 (5–6): 311–321.

78 78 Shabani, L. and Sabzalian, M.R. (2016). Arbuscular mycorrhiza affects nickel translocation and expression of ABC transporter and metallothionein genes in Festuca arundinacea. Mycorrhiza 26 (1): 67–76.

79 79 Shanying, H., Yang, X., He, Z. et al. (2017). Morphological and physiological responses of plants to cadmium toxicity: a review. Pedosphere 27 (3): 421–438.

80 80 Amari, T., Ghnaya, T., and Abdelly, C. (2017). Nickel, cadmium and lead phytotoxicity and potential of halophytic plants in heavy metal extraction. South African Journal of Botany 111: 99–110.

81 81 Das, K., Das, S., and Dhundasi, S. (2008). Nickel, its adverse health effects & oxidative stress. Indian Journal of Medical Research 128 (4): 412.

82 82 Lippmann, M., Ito, K., Hwang, J.S. et al. (2006). Cardiovascular effects of nickel in ambient air. Environmental Health Perspectives 114 (11): 1662.

83 83 Vinit‐Dunand, F., Epron, D., Alaoui‐Sossé, B. et al. (2002). Effects of copper on growth and on photosynthesis of mature and expanding leaves in cucumber plants. Plant Science 163 (1): 53–58.

84 84 Yruela, I. (2005). Copper in plants. Brazilian Journal of Plant Physiology 17 (1): 145–156.

85 85 Araya, M., Epron, D., and Alaoui‐Sossé, B. (2006). Understanding copper homeostasis in humans and copper effects on health. Biological Research 39 (1): 183–187.

86 86 Valberg, L., Flanagan, P.R., and Chamberlain, M.J. (1984). Effects of iron, tin, and copper on zinc absorption in humans. The American Journal of Clinical Nutrition 40 (3): 536–541.

87 87 Vuori, E., Makinen, S.M., Kara, R. et al. (1980). The effects of the dietary intakes of copper, iron, manganese, and zinc on the trace element content of human milk. The American Journal of Clinical Nutrition 33 (2): 227–231.

88 88 Scuderi, P. (1990). Differential effects of copper and zinc on human peripheral blood monocyte cytokine secretion. Cellular Immunology 126 (2): 391–405.

89 89 Sharma, P. and Dubey, R.S. (2005). Lead toxicity in plants. Brazilian Journal of Plant Physiology 17 (1): 35–52.

90 90 Seregin, I. and Ivanov, V. (2001). Physiological aspects of cadmium and lead toxic effects on higher plants. Russian Journal of Plant Physiology 48 (4): 523–544.

91 91 de Vries, W., Römkens, P.F.A.M., and Schütze, G. (2007). Critical soil concentrations of cadmium, lead, and mercury in view of health effects on humans and animals. In: Reviews of Environmental Contamination and Toxicology (ed. P. de Voogt), 91–130. New York;, NY: Springer New York;.

92 92 James, H.M., Hilburn, M.E., and Blair, J.A. (1985). Effects of meals and meal times on uptake of lead from the gastrointestinal tract in humans. Human Toxicology 4 (4): 401–407.

93 93 Das, P., Samantaray, S., and Rout, G. (1997). Studies on cadmium toxicity in plants: a review. Environmental Pollution 98 (1): 29–36.

94 94 Di Toppi, L.S. and Gabbrielli, R. (1999). Response to cadmium in higher plants. Environmental and Experimental Botany 41 (2): 105–130.

95 95 Benavides, M.P., Gallego, S.M., and Tomaro, M.L. (2005). Cadmium toxicity in plants. Brazilian Journal of Plant Physiology 17 (1): 21–34.

96 96 Fowler, B.A. (2009). Monitoring of human populations for early markers of cadmium toxicity: a review. Toxicology and Applied Pharmacology 238 (3): 294–300.

97 97 Klaassen, C.D., Liu, J., and Diwan, B.A. (2009). Metallothionein protection of cadmium toxicity. Toxicology and Applied Pharmacology 238 (3): 215–220.

98 98 Godt, J., Scheidig, F., Grosse‐Siestrup, C. et al. (2006). The toxicity of cadmium and resulting hazards for human health. Journal of Occupational Medicine and Toxicology 1 (1): 22.

99 99 Assche, F.V. and Clijsters, H. (1990). Effects of metals on enzyme activity in plants. Plant, Cell & Environment 13 (3): 195–206.

100 100 Banks, M., Schwab, A.P., Fleming, G.R. et al. (1994). Effects of plants and soil microflora on leaching of zinc from mine tailings. Chemosphere 29 (8): 1691–1699.

101 101 Solomons, N.W. and Jacob, R. (1981). Studies on the bioavailability of zinc in humans: effects of heme and nonheme iron on the absorption of zinc. The American Journal of Clinical Nutrition 34 (4): 475–482.

102 102 Sandström, B. and Sandberg, A.‐S. (1992). Inhibitory effects of isolated inositol phosphates on zinc absorption in humans. Journal of Trace Elements and Electrolytes in Health and Disease 6 (2): 99–103.

103 103 Boening, D.W. (2000). Ecological effects, transport, and fate of mercury: a general review. Chemosphere 40 (12): 1335–1351.

104 104 Mishra, A. and Choudhuri, M. (1998). Amelioration of lead and mercury effects on germination and rice seedling growth by antioxidants. Biologia Plantarum 41 (3): 469–473.

105 105 Munzuroglu, O. and Geckil, H. (2002). Effects of metals on seed germination, root elongation, and coleoptile and hypocotyl growth in Triticum aestivum and Cucumis sativus. Archives of Environmental Contamination and Toxicology 43 (2): 203–213.

106 106 Burbacher, T.M., Rodier, P.M., and Weiss, B. (1990). Methylmercury developmental neurotoxicity: a comparison of effects in humans and animals. Neurotoxicology and Teratology 12 (3): 191–202.

107 107 Singh, H. (2006). Mycoremediation: Fungal Bioremediation. Chichester: Wiley.

108 108 Kulkarni, M. and Chaudhari, A. (2007). Microbial remediation of nitro‐aromatic compounds: an overview. Journal of Environmental Management 85 (2): 496–512.

109 109 Cunningham, S.D. and Berti, W.R. (1993). Remediation of contaminated soils with green plants: an overview. in vitro; Cellular & Developmental Biology: Plant 29 (4): 207–212.

110 110 Cataldo, D. and Wildung, R. (1978). Soil and plant factors influencing the accumulation of heavy metals by plants. Environmental Health Perspectives 27: 149.

111 111 Reeves, R.D. (2003). Tropical hyperaccumulators of metals and their potential for phytoextraction. Plant and Soil 249 (1): 57–65.

112 112 Wu, H., Zhang, J., Ngo, H.H. et al. (2015). A review on the sustainability of constructed wetlands for wastewater treatment: design and operation. Bioresource Technology 175: 594–601.

113 113 Bratby, J. (2016). Coagulation and Flocculation in Water and Wastewater Treatment. London: IWA Publishing.

114 114 Giuliano, A., Sabia, G., Cabez, J.F. et al. (2017). Assessment of performance and advantages related to the use of a natural coagulant in the industrial wastewater treatment. Environmental Engineering & Management Journal (EEMJ) 16 (8): 1709–1719.

115 115 Goncalves, A.L., Pires, J.C., and Simões, M. (2017). A review on the use of microalgal consortia for wastewater treatment. Algal Research 24: 403–415.

116 116 Wang, Q., Wei, W., Gong, Y. et al. (2017). Technologies for reducing sludge production in wastewater treatment plants: state of the art. Science of the Total Environment 587: 510–521.

117 117 Limmer, M. and Burken, J. (2016). Phytovolatilization of organic contaminants. Environmental Science & Technology 50 (13): 6632–6643.

118 118 Ijaz, A., Imran, A., ul Haq, M.A. et al. (2016). Phytoremediation: recent advances in plant‐endophytic synergistic interactions. Plant and Soil 405 (1–2): 179–195.

119 119 He, Y., Langenhoff, A.M., Sutton, N.B. et al. (2017). Metabolism of ibuprofen by Phragmites australis: uptake and phytodegradation. Environmental Science & Technology 51 (8): 4576–4584.

120 120 Al‐Baldawi, I.A., Sheikh Abdullah, S.R., Anuar, N. et al. (2015). Phytodegradation of total petroleum hydrocarbon (TPH) in diesel‐contaminated water using Scirpus grossus. Ecological Engineering 74: 463–473.

121 121 Vera‐Estrella, R., Gómez‐Méndez, M.F., Amezcua‐Romero, J.C. et al. (2017). Cadmium and zinc activate adaptive mechanisms in Nicotiana tabacum similar to those observed in metal tolerant plants. Planta 246 (3): 433–451.

122 122 Hasan, M., Cheng, Y., Kanwar, M.K. et al. (2017). Responses of plant proteins to heavy metal stress – a review. Frontiers in Plant Science 8: 1492.

123 123 Van Oosten, M.J. and Maggio, A. (2015). Functional biology of halophytes in the phytoremediation of heavy metal contaminated soils. Environmental and Experimental Botany 111: 135–146.

124 124 Malar, S., Vikram, S.S., Favas, P.J.C. et al. (2016). Lead heavy metal toxicity induced changes on growth and antioxidative enzymes level in water hyacinths [Eichhornia crassipes (Mart.)]. Botanical Studies 55 (1): 54.

125 125 Banerjee, G., Pandy, S., Ray, A.K. et al. (2015). Bioremediation of heavy metals by a novel bacterial strain Enterobacter cloacae and its antioxidant enzyme activity, flocculant production, and protein expression in presence of lead, cadmium, and nickel. Water, Air, & Soil Pollution 226 (4): 91.

126 126 Kumar, S., Kaushik, G., Dar, M.A. et al. (2018). Microbial degradation of organophosphate pesticides: a review. Pedosphere 28 (2): 190–208.

127 127 Goyal, N., Jain, S., and Banerjee, U. (2003). Comparative studies on the microbial adsorption of heavy metals. Advances in Environmental Research 7 (2): 311–319.

128 128 Day, T.A., Bliss, M.S., Tomes, A.R. et al. (2018). Desert leaf litter decay: coupling of microbial respiration, water‐soluble fractions and photodegradation. Global Change Biology 24 (11): 5454–5470.

129 129 John, E.M. and Shaike, J.M. (2015). Chlorpyrifos: pollution and remediation. Environmental Chemistry Letters 13 (3): 269–291.

130 130 Alneyadi, A.H. and Ashraf, S.S. (2016). Differential enzymatic degradation of thiazole pollutants by two different peroxidases – a comparative study. Chemical Engineering Journal 303: 529–538.

131 131 Silverman, A.I., Sedlak, D.L., and Nelson, K.L. (2018). Simplified process to determine rate constants for sunlight‐mediated removal of trace organic and microbial contaminants in unit process open‐water treatment wetlands. Environmental Engineering Science 36 (1): 43–59.

132 132 Dar, M.I., Naikoo, M.I., Green, I.D. et al. (2018). Heavy metal hyperaccumulation and hypertolerance in Brassicaceae. In: Plants under Metal and Metalloid Stress (eds. M. Hasanuzzaman, K. Nahar and M. Fujita), 263–276. Springer.

133 133 Clemens, S. and Ma, J.F. (2016). Toxic heavy metal and metalloid accumulation in crop plants and foods. Annual Review of Plant Biology 67: 489–512.

134 134 Epelde, L., Lanzén, A., Blanco, F. et al. (2015). Adaptation of soil microbial community structure and function to chronic metal contamination at an abandoned Pb‐Zn mine. FEMS Microbiology Ecology 91 (1): 1–11.

135 135 Yin, H., Niu, J., Ren, Y. et al. (2015). An integrated insight into the response of sedimentary microbial communities to heavy metal contamination. Scientific Reports 5: 14266.

136 136 Pishchik, V., Oliveira, R.S., Ren, Y. et al. (2016). Mechanisms of plant and microbial adaptation to heavy metals in plant–microbial systems. Microbiology 85 (3): 257–271.

137 137 Richter, J., Ploderer, M., Mongelard, G. et al. (2017). Role of CrRLK1L Cell Wall sensors HERCULES1 and 2, THESEUS1, and FERONIA in growth adaptation triggered by heavy metals and trace elements. Frontiers in Plant Science 8: 1554.

138 138 Mesa, J., Mateos‐Naranjo, E., Caviedes, M.A. et al. (2015). Scouting contaminated estuaries: heavy metal resistant and plant growth promoting rhizobacteria in the native metal rhizoaccumulator Spartina maritima. Marine Pollution Bulletin 90 (1–2): 150–159.

139 139 Krämer, U. (2018). The plants that suck up metal. German Research 40 (3): 18–23.

140 140 de la Torre, V.S.G., Majorel‐Loulergue, C., Gonzalez, D.A. et al., Wide cross‐species RNA‐seq comparison reveals convergent molecular mechanisms involved in nickel hyperaccumulation across angiosperms. CellPress. Available at: https://papers.ssrn.com/sol3/papers.cfm?abstract_id=3272237 (2018).

141 141 Deng, T.‐H.‐B., Van Der Ent, A., Tang, Y.‐T. et al. (2018). Nickel hyperaccumulation mechanisms: a review on the current state of knowledge. Plant and Soil 423 (1–2): 1–11.

142 142 Pilon‐Smits, E.A. (2017). Mechanisms of plant selenium hyperaccumulation. In: Selenium in Plants (eds. E.A.H. Pilon‐Smits, L.H.E. Winkel and Z.‐Q. Lin), 53–66. Springer.

143 143 Im, J., Yang, K., Jho, E.H. et al. (2015). Effect of different soil washing solutions on bioavailability of residual arsenic in soils and soil properties. Chemosphere 138: 253–258.

144 144 Xian, Y., Wang, M., and Chen, W. (2015). Quantitative assessment on soil enzyme activities of heavy metal contaminated soils with various soil properties. Chemosphere 139: 604–608.

145 145 Dias, D., de Castro Moreira, M.E., Contin Gomes, M.J. et al. (2015). Rice and bean targets for biofortification combined with high carotenoid content crops regulate transcriptional mechanisms increasing iron bioavailability. Nutrients 7 (11): 9683–9696.

146 146 Ullah, A., Fahad, S., Munis, H.F. et al. (2015). Phytoremediation of heavy metals assisted by plant growth promoting (PGP) bacteria: a review. Environmental and Experimental Botany 117: 28–40.

Soil Bioremediation

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