posted on 2022-12-05, 17:11authored byMonica
E. McFadden, Keith P. Reber, John D. Sivey, David M. Cwiertny, Gregory H. LeFevre
Dichloroacetamide safeners are common ingredients in
commercial
herbicide formulations. We previously investigated the environmental
fate of dichloroacetamides via photolysis and hydrolysis, but other
potentially important, environmentally relevant fate processes remain
uncharacterized and may yield products of concern. Here, we examined
microbial biotransformation of two dichloroacetamide safeners, benoxacor
and dichlormid, to identify products and elucidate pathways. Using
aerobic microcosms inoculated with river sediment, we demonstrated
that microbial biotransformations of benoxacor and dichlormid proceed
primarily, if not exclusively, via cometabolism. Benoxacor was transformed
by both hydrolysis and microbial biotransformation processes; in most
cases, biotransformation rates were faster than hydrolysis rates.
We identified multiple novel products of benoxacor and dichlormid
not previously observed for microbial processes, with several products
similar to those reported for structurally related chloroacetamide
herbicides, thus indicating potential for conserved biotransformation
mechanisms across both chemical classes. Observed products include
monochlorinated species such as the banned herbicide CDAA (from dichlormid),
glutathione conjugates, and sulfur-containing species. We propose
a transformation pathway wherein benoxacor and dichlormid are first
dechlorinated, likely via microbial hydrolysis, and subsequently conjugated
with glutathione. This is the first study reporting biological dechlorination
of dichloroacetamides to yield monochlorinated products in aerobic
environments.