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Evolution of an organophosphate-degrading enzyme: a comparison of natural and directed evolution

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Date

2003

Authors

Yang, Hong
Carr, Paul D
Yu McLoughlin, Sean
Liu, Jian-Wei
Horne, Irene
Qiu, Xinghui
Jeffries, Cy
Russell, Robyn
Oakeshott, John Graham
Ollis, David

Journal Title

Journal ISSN

Volume Title

Publisher

Oxford University Press

Abstract

Organophosphate-degrading enzyme from Agrobacterium radiobacter P230 (OPDA) is a recently discovered enzyme that degrades a broad range of organophosphates. It is very similar to OPH first isolated from Pseudomonas diminuta MG. Despite a high level of sequence identity, OPH and OPDA exhibit different substrate specificities. We report here the structure of OPDA and identify regions of the protein that are likely to give it a preference for substrates that have shorter alkyl substituents. Directed evolution was used to evolve a series of OPH mutants that had activities similar to those of OPDA. Mutants were selected for on the basis of their ability to degrade a number of substrates. The mutations tended to cluster in particular regions of the protein and in most cases, these regions were where OPH and OPDA had significant differences in their sequences.

Description

Keywords

Keywords: enzyme; hydrolase; mutant protein; organophosphate; phosphotriesterase; amino acid sequence; article; Brevundimonas diminuta; comparative study; enzymatic degradation; enzyme isolation; enzyme specificity; enzyme structure; molecular evolution; mutation; Agrobacterium; Bioremediation; Carboxylated lysine; Directed evolution; Organophosphates; Phosphotriesterase

Citation

URI

http://hdl.handle.net/1885/88369

Collections

ANU Research Publications

Source

Protein Engineering

Type

Journal article

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