2,4,6-Trichlorophenol mediated increases in extracellular peroxidase activity in three species of Lemnaceae

Stress responses to trichlorophenol in Arabidopsis and integrative analysis of alteration in transcriptional profiling from microarray

Trichlorophenols, also known as TCPs, are one of the most persistent environmental pollutants. It is a matter of concern as they are toxic and cumulative in soil and water bodies which could lead to serious consequences to the biosphere. How plants respond to this compound has rarely been examined previously. In our study, detailed morphological and physiological responses of Arabidopsis to 2,4,6-trichlorophenol, a representative TCP, were investigated. Seed germination and seedling growth were markedly inhibited by 2,4,6-TCP. Furthermore, we performed gene expression profiling analysis upon 2,4,6-TCP treatment in Arabidopsis and identified 34 transcripts induced and 212 repressed more than four folds. Gene Ontology (GO) analysis showed that these TCP-responsive genes are involved in various biological processes, such as secondary metabolism, biological regulation, response to stimulus and other processes related to growth and development. The activities of two reactive oxygen species-related enzymes (peroxidase and superoxide dismutase) and the content of malondialdehyde were increased significantly after 2,4,6-TCP treatment. Our findings have the potential to provide valuable gene resources and theoretical information for more in-depth analyses of TCPs' response in Arabidopsis thaliana and even other organic pollutants.

Concentration responses to organochlorines in Phragmites australis

Phragmites australis shows potential for the phytoremediation of chlorinated chemicals. Also there has been some attempt to determine the phytotoxic effects of organochlorines (OC). This study reports for lindane (HCH), monochlorobenzene (MCB), 1,4-dichlorobenzene (DCB) and 1,2,4-trichlorobenzene (TCB), a no-observed-effect-concentration (NOEC(7d)) that was 1000-300,000 times higher than environmental concentrations. Nevertheless, the combined OC mixture (NOEC(7d) level of each congener) induced a synergistic toxic effect, causing a severe drop (70%) in chlorophyll concentration. The mixture 0.2 mg L(-1) MCB+0.2 mg L(-1) DCB+2.5 mg L(-1) TCB+0.175 mg L(-1) HCH, that was 15 times more concentrated than environmental OC mixture, did not cause phytotoxicity during 21 days. Antioxidant enzymes were affected immediately after the start of exposure (3 days), but the plants showed no signs of stress thereafter. These data suggest that environmental OC mixtures do not pose a significant risk to P. australis.

Alumina nanoparticles enhance growth of Lemna minor

The industrial use of nanoparticles is rapidly increasing, and this has given rise to concerns about potential biological impacts of engineered particles released into the environment. So far, relatively little is known about uptake, accumulation and responses to engineered nanoparticles by plants. In this study, the effects of alumina nanoparticles on growth, morphology and photosynthesis of Lemna minor were quantified. It was found that alumina nanoparticles substantially increase biomass accumulation of L. minor. Such a stimulatory effect of alumina nanoparticles on growth has not been reported previously. Enhanced biomass accumulation was paralleled by morphological adjustments such as increased root length and number of fronds per colony, and by increased photosynthetic efficiency. Metal nanoparticles have previously been shown to enhance the energy transfer efficiency of isolated reaction centres; therefore it is proposed that the mechanism underlying the alumina mediated enhancement of biomass accumulation in L. minor is associated with increased efficiencies in the light reactions of photosynthesis.