Abstract EN:

The 3,5-dinitrotrifluoromethylbenzene (3,5-DNBTF) is currently evaluated by the (Commissariat a l'Energie Atomique). The challenge was the conception of a specific biosensor, based on enzymatic or microbial interactions. This will help monitoring of the compound for either environmental protection and security. Our first investigations were focused on the analytical methods for the detection of 3,5-DNBTF metabolites and derivatives in solution. Taken into account thee weak solubility of these molecules in water, we used a sensitive chromatographic HPLC technique coupled to mass spectrometry on APCI ionization, to assign the structure of newly observed compounds. We first investigate the chemical reactivity of 3,5-DNBTF. Only nitro substituants can be transformed to their respective diamino derivatives through catalytic hydrogenation. This molecule give rise to original photochemical reactivity. Indeed, the photo-irradiation at 310nm of the 3,5-DABTF in water lead to 3,5-diaminobenzoi͏̈c acid, as well as various polymers diriving from the interaction between 3,5-DABTF and some defluorination intermediates. A screnning was conducted on the biodegradation of 3,5-DNBTF, that allows the selection of a bacterial strain of Bacillus (Bacillus LMA), that was the solely strain to reduce both nitro groups of the 3,5-DNBTF with high efficiency. The purification of the nitroréductase involved in this reaction was investigated by classical chromatographic method, as well as an affinity chromatography process. This latter was based on a specific matrice coupled with a substrate analog, 3,5-dinitrobenzoic acid (3,5-DNBA). Mass spectrometry of the protein spots lead to the identification of a putative nitroreductase from Bacillus subtilis168. The corresponding gene was cloned and has been over-expressed in E. Coli successfully. The presence of a His-tag on the protein lead to a large quantities of purified active protein. The total nitro-reduction of 3,5-DNBTF, catalyzed by a whole microorganism or by the purified nitroreductase, has been coupled to the photochemical transformation of the corresponding diamine. This is the basis of our biosensor. The detection was oriented against Several parameters: the formation of the 3,5-DABA, that could be fluorescent under particular conditions, the decrease in pH during the reaction, the production of fluoride ions and the dark colour associated to particular, polymers formed during irradiation. Last phases in biosensor construction are under study.