Potential use of Lemna minor for the phytoremediation of isoproturon and glyphosate.

International audienc

Enzymatic basis for fungicide removal by <em>Elodea canadensis</em>.

Purpose Plants can absorb a diversity of natural and man-made toxic compounds for which they have developed diverse detoxification mechanisms. Plants are able to metabolize and detoxify a wide array of xenobiotics by oxidation, sugar conjugation, glutathione conjugation, and more complex reactions. In this study, detoxification mechanisms of dimethomorph, a fungicide currently found in aquatic media were investigated in Elodea canadensis. Methods Cytochrome P450 (P450) activity was measured by an oxygen biosensor system, glucosyltransferases (GTs) by HPLC, glutathione S-transferases (GSTs), and ascorbate peroxidase (APOX) were assayed spectrophotometrically.Results Incubation of Elodea with dimethomorph induced an increase of the P450 activity. GST activity was not stimulated by dimethomorph suggesting that GST does not participate in dimethomorph detoxification. In plants exposed to dimethomorph, comparable responses were observed for GST and APOX activities showing that the GST was more likely to play a role in response to oxidative stress. Preincubation with dimethomorph induced a high activity of O- and N-GT, it is therefore likely that both enzymes participate in the phase II (conjugation) of dimethomorph detoxification process. Conclusions For the first time in aquatic plants, P450 activity was shown to be induced by a fungicide suggesting a role in the metabolization of dimethomorph. Moreover, our finding is the first evidence of dimethomorph and isoproturon activation of cytochrome P450 multienzyme family in an aquatic plant, i.e., Elodea (isoproturon was taken here as a reference molecule). The detoxification of dimetomorph seems to proceed via hydroxylation, and subsequent glucosylation, and might yield soluble as well as cell wall bound residues

Mechanisms of partner recognition by intrinsically disordered proteins

10th European-Biophysical-Societies-Association (EBSA) European Biophysics Congress, Dresden, GERMANY, JUL 18-22, 2015International audienceno abstrac

Mechanisms of partner recognition by intrinsically disordered proteins

10th European-Biophysical-Societies-Association (EBSA) European Biophysics Congress, Dresden, GERMANY, JUL 18-22, 2015International audienceno abstrac

A Unifying Mechanism for Cancer Cell Death through Ion Channel Activation by HAMLET

10.1371/journal.pone.0058578PLoS ONE83e5857

Exploration of nucleoprotein α-MoRE and XD interactions of Nipah and Hendra viruses

International audienceHenipavirus, including Hendra virus (HeV) and Nipah virus (NiV), is a newly discovered human pathogen genus. The nucleoprotein of Henipavirus contains an α-helical molecular recognition element (α-MoRE) that folds upon binding to the X domain (XD) of the phosphoprotein (P). In order to explore the conformational dynamics of free α-MoREs and the underlying binding-folding mechanism with XD, atomic force field-based and hybrid structure-based MD simulations were carried out. In our empirical force field-based simulations, characteristic structures and helicities of α-MoREs reveal the co-existence of partially structured and disordered conformations, as in the case of the well characterized cognate measles virus (MeV) α-MoRE. In spite of their overall similarity, the two α-MoREs display subtle helicity differences in their C-terminal region, but much different from that of MeV. For the α-MoRE/XD complexes, the results of our hybrid structure-based simulations provide the coupled binding-folding landscapes, and unveil a wide conformational selection mechanism at early binding stages, followed by a final induce-fit mechanism selection process. However, the HeV and NiV complexes have a lower binding barrier compared to that of MeV. Moreover, the HeV α-MoRE/XD complex shows much less coupling effects between binding and folding compared to that from both NiV and MeV. Our analysis revealed that contrary to NiV and MeV, the N- and C-terminal regions of the HeV α-MoRE maintains a low helicity also in the bound form