Abstract
Decorative ornamental plants have been applied as hyperaccumulators/phytoremediators to a wide spectrum of heavy metal contaminants. In this study, pot culture experiments were conducted to investigate the Sn tolerance and accumulation in Impatiens balsamina L., Mirabilis jalapa L. and Tagetes erecta L., in order to assess the possibility of these three ornamental plants to be used as phytoremediators of Sn-contaminated soil. Results show that all three plants exhibited strong tolerance to Sn contamination, and no significant visual toxicity was observed for all three plants grown under most of the Sn treatments. The amount of Sn accumulated in the three plants was positively correlated with the Sn concentration in the soil. The order of the Sn accumulative capacity was Impatiens balsamina > Mirabilis jalapa > Tagetes erecta. Impatiens balsamina and Tagetes erecta showed a low translocation ability (TF) (<1), and the roots accumulated the highest Sn concentration, but Impatiens balsamina showed a relatively high bioconcentration factor (BCF, Sn concentration in each part > 100 mg/kg after Sn treatment of 500 mg/kg). Meanwhile, the TF of Mirabilis jalapa was >1, and the fluorescence accumulated the most Sn. In combination with the adaptation to high concentrations of various heavy metals, these three ornamental plants are potential candidates for Sn mining tailings or contaminated soil.
Highlights
Published: 3 March 2021Tin (Sn) generally exists as +IV and +II oxidation states [1]
The plant height of Impatiens balsamina and Mirabilis jalapa grown in Sn-loaded soils did not show visible differences
It seemed that the plant heights of Impatiens balsamina, Mirabilis Jalapa and Tagetes erecta were not sensitive to Sn contamination, the growth of Tagetes erecta was restrained under the highest Sn treatment (T4) to some extent
Summary
Published: 3 March 2021Tin (Sn) generally exists as +IV and +II oxidation states [1]. Sn compounds have been widely applied for industrial purposes. SnO2 was used as a catalyst in certain industrial processes and a polishing powder for steel, SnCl2 was used as a reducing agent in the manufacture of polymers and dyes, SnF2 and Sn pyrophosphate were used in dentifrices and organic Sn compounds were used as stabilizers in plastics and preservatives, as well as biocides for bacteria, fungi and insecticides [1,2,3]. Excess SnCl4 in human lymphocytes induced chromosome aberrations, micronuclei and sister chromatid exchanges (SCEs). Previous studies found SnF2 caused DNA damage in cultures of human lymphocytes [1,3]
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