Affiliation:
1. Research School of Chemistry, Australian National University, Canberra, Australian Capital Territory 0200, Australia
Abstract
ABSTRACT
Phosphotriesterases catalyze the hydrolytic detoxification of phosphotriester pesticides and chemical warfare nerve agents with various efficiencies. The directed evolution of phosphotriesterases to enhance the breakdown of poor substrates is desirable for the purposes of bioremediation. A limiting factor in the identification of phosphotriesterase mutants with increased activity is the ability to effectively screen large mutant libraries. To this end, we have investigated the possibility of coupling phosphotriesterase activity to cell growth by using methyl paraoxon as the sole phosphorus source. The catabolism of paraoxon to phosphate would occur via the stepwise enzymatic hydrolysis of paraoxon to dimethyl phosphate, methyl phosphate, and then phosphate. The
Escherichia coli
strain DH10B expressing the phosphotriesterase from
Agrobacterium radiobacter
P230 (OpdA) is unable to grow when paraoxon is used as the sole phosphorus source.
Enterobacter aerogenes
is an organism capable of growing when dimethyl phosphate is the sole phosphorus source. The enzyme responsible for hydrolyzing dimethyl phosphate has been previously characterized as a nonspecific phosphohydrolase. We isolated and characterized the genes encoding the phosphohydrolase operon. The operon was identified from a shotgun clone that enabled
E. coli
to grow when dimethyl phosphate is the sole phosphorus source.
E. coli
coexpressing the phosphohydrolase and OpdA grew when paraoxon was the sole phosphorus source. By constructing a short degradative pathway, we have enabled
E. coli
to use phosphotriesters as a sole source of phosphorus.
Publisher
American Society for Microbiology
Subject
Ecology,Applied Microbiology and Biotechnology,Food Science,Biotechnology
Cited by
66 articles.
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