Toxicities of DDE on Wheat and Bioremediation of DDE by Fungus Pleurotus pulmonarius

An in vitro study was performed to determine the acute phytotoxicities and genotoxicity of DDE either spiked to soil or added to hydrophonic cultures on wheat Triticum aestivum. A 24-well plate was first used to determine toxicity on individual grains using conventional seed germination/seedling growth toxicity tests whereas a single cell electrophoresis system was applied to measure genotoxicity at single cell level for wheat. Hydrophonic cultures provide a simplified environment to screen for toxicities with high sensitivity. Inverse dose-response relationships were detected between exogenous DDE levels and one of the following parameters: seed germination, seedling growth, and genotoxicity. In contrast, soil reduced the stress on T. aestivum by lowering bioavailability leading to less DDE distributed in radicle and coleoptile, modulated growth, and enhanced tolerance. At all DDE doses spiked to soil including the reference safety level of 0.5 mg/kg, DNA breakage was detected in both radicle and coleoptile but their magnitudes did not correlate with the organ nor the soil DDE contents. Thus, although wheat is highly sensitive to the genotoxic effect of DDE, first demonstrated here, the seed germination test offers a simple quantitative measure of DDE's phytotoxicity in soil and hydrophonic cultures. This study also found that fungus Pleurotus pulmonarius, which secretes extracellular ligninolytic enzymes causing non-specific cleavage of lignin and organopollutants, remediated DDE spiked to soil. In 5 weeks, 78% of 10 mg/kg DDE was biodegraded, and the fungal-treated soil reduced acute toxicity on T. aestivum using the seed germination test.