[Microbial degradation of glyphosate herbicides (review)].

This review analyzes the issues associated with biodegradation of glyphosate (N-(phosphonomethyl)glycine), one of the most widespread herbicides. Glyphosate can accumulate in natural environments and can be toxic not only for plants but also for animals and bacteria. Microbial transformation and mineralization ofglyphosate, as the only means of its rapid degradation, are discussed in detail.

[Xylanase and cellulase of fungus Cerrena unicolor VKM F-3196: production, properties, and applications for the saccharification of plant material].

Under the conditions of submerged cultivation in a medium containing microcrystalline cellulose, the Cerrena unicolor VKM F-3196 basidiomycete is capable of producing xylanase and cellulase. Electrophoretically homogeneous cellulase and xylanase were obtained using ion exchange and hydrophobic chromatography. The molecular weight of both cellulase and xylanase was -44 kDa.

[Sorption and microbial degradation of glyphosphate in soil suspensions].

Sorption and microbial destruction of glyphosphate, the active agent of the herbicide Groundbio, in suspensions of sod-podzolic and gray forest soils has been studied. According to the values of the adsorptive capacity (3560 and 8200 mg/kg, respectively) and the Freundlich constants (Kf, 15.6 and 18.

[Microbial degradation of organophosphonates by soil bacteria].

Bacteria that can utilize glyphosate (GP) or methylphosphonic acid (MPA) as a sole phosphorus source have been isolated from soil samples polluted with organophosphonates (OP). No matter which of these compounds was predominant in the native habitat of the strains, all of them utilized methylphosphonate. Some of the strains isolated from GP-polluted soil could utilize both phosphorus sources.