Zablotowicz, Robert M.; Locke, Martin A.; Hoagland, Robert E. published the artcile< Aromatic nitroreduction of acifluorfen in soils, rhizospheres, and pure cultures of rhizobacteria>, Synthetic Route of 35852-58-5, the main research area is acifluorfen soil phytoremediation rhizobacteria.
Reduction of nitroarom. compounds to their corresponding amino derivatives is one of several pathways in the degradation of nitroxenobiotics. The nitrodiphenyl ether herbicide acifluorfen showed rapid metabolism to aminoacifluorfen followed by incorporation into unextractable soil components in both soil and rhizosphere suspensions. Aminoacifluorfen was formed more rapidly in rhizospheres compared to soil, which can be attributed to higher microbial populations, especially of Gram-neg. bacteria. Several strains of Pseudomonas fluorescens that possess nitroreductase activity capable of converting acifluorfen to aminoacifluorfen were identified. Factors affecting acifluorfen nitroreductase activity in pure cultures and cell-free extracts, and other catabolic transformations of acifluorfen, ether bond cleavage, are discussed. Plant rhizospheres should be conducive for aromatic nitroredn. Nitroredn. by rhizobacteria is an important catabolic pathway for the initial degradation of various nitroherbicides and other nitroarom. compounds in soils under phytoremediation management.
ACS Symposium Series published new progress about Pseudomonas fluorescens. 35852-58-5 belongs to class chlorides-buliding-blocks, and the molecular formula is C7H4ClF3O, Synthetic Route of 35852-58-5.
Referemce:
Chloride – Wikipedia,
Chlorides – an overview | ScienceDirect Topics