Plant Responses and Tolerance to Metal/Metalloid Toxicity

© 2020 by the authors; CC BY-NC-ND license

metal stress; toxicity; silicon; Si-fertilization; genomics; transporter genes; cadmium toxicity; oxidative stress; antioxidative defense system; photosynthetic pigments; environmental pollution; phytoextraction; cadmium; biostimulation; oxidative damage; metal toxicity; sulphur nutrition; stress mitigation; cation exchange capacity; glutathione; agriculture; Cd stress; environmental; gene expression; PGPB; switchgrass; P. fasciculatum; heavy metals; tolerant plant; protein carbonylation; photosynthesis proteins; mining soils; heavy metals; thiols; phenolic metabolites; organic acids; lead; castor beans; citric acid; phytoextraction; antioxidant enzyme; antioxidant system; ethylene; glyoxalase system; photosynthesis; proline metabolism; zinc; jute varieties; copper stress; phytoremediation; bioaccumulation factor; translocation factor; oxidative stress; growth; copper toxicity; micronutrient deficiency; silicon; iron; nicotianamine; histidine; Cu-chelation; lead pollution; antioxidants; bentonite; translocation factor; grain biochemistry; biochar; oxidative stress; maize hybrids; nickel; nutrients; translocation; oxidative stress; heavy metal; reactive oxygen species; oxidative burst; antioxidants; Rhododendron arboreum; Vigna radiata; enzymes activity; chromium (Cr); polyphenols; abiotic stress; antioxidant defense; metal toxicity; methylglyoxal; oxidative stress; organic acid; oxidative stress; ripening physiology; silver; chemical elicitors; chili; fibrous crop; phytoextraction; environmental pollutants; morphological traits; soil remediation; chelating agents; chromium; wastewater; sunflower; biomass; chlorophyll contents