Subcellular Targeting of Methylmercury Lyase Enhances Its Specific Activity for Organic Mercury Detoxification in Plants

Scott P. Bizily , Tehryung Kim , Muthugapatti K. Kandasamy , and Richard B. Meagher ^*

Genetics Department, University of Georgia, Athens, Georgia 30602

^* Corresponding author; email: meagher{at}arches.uga.edu.

Methylmercury is an environmental pollutant that biomagnifiesin the aquatic food chain with severe consequences for humansand other animals. In an effort to remove this toxin in situ,we have been engineering plants that express the bacterial mercuryresistance enzymes organomercurial lyase MerB and mercuric ionreductase MerA. In vivo kinetics experiments suggest that thediffusion of hydrophobic organic mercury to MerB limits therate of the coupled reaction with MerA (Bizily et al., 2000).To optimize reaction kinetics for organic mercury compounds,the merB gene was engineered to target MerB for accumulationin the endoplasmic reticulum and for secretion to the cell wall.Plants expressing the targeted MerB proteins and cytoplasmicMerA are highly resistant to organic mercury and degrade organicmercury at 10 to 70 times higher specific activity than plantswith the cytoplasmically distributed wild-type MerB enzyme.MerB protein in endoplasmic reticulum-targeted plants appearsto accumulate in large vesicular structures that can be visualizedin immunolabeled plant cells. These results suggest that thetoxic effects of organic mercury are focused in microenvironmentsof the secretory pathway, that these hydrophobic compartmentsprovide more favorable reaction conditions for MerB activity,and that moderate increases in targeted MerB expression willlead to significant gains in detoxification. In summary, tomaximize phytoremediation efficiency of hydrophobic pollutantsin plants, it may be beneficial to target enzymes to specificsubcellular environments.

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