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'Designer plants' to clean up heavy metals
Researchers have demonstrated that a chemical that permits plants to detoxify heavy metals can be transported from the roots to stems and leaves.
This finding raises the possibility of using plants to clean up soil contaminated with toxic metals such as lead, arsenic and cadmium.
A paper detailing the discovery by scientists at the University of California, San Diego appears in an advance online publication of the Proceedings of the National Academy of Sciences and will appear in the journal's 19 August issue.
"There are about four important steps in developing plants for bioremediation [the process of using organisms to restore toxic or damaged areas]," says Julian Schroeder, a professor of biology at UCSD who headed the study. "The roots of the plant need to secrete a substance that makes the metals in the soil soluble, making it possible for the plant to take them up. The plant needs to detoxify the metals once it takes them up, and the metals need to be transported to the stems and leaves of the plant, and stored there. We have found that phytochelatins, chemicals produced by an enzyme for which our lab co-discovered the gene four years ago, unexpectedly function in the root to leaf transfer of metals."
Prior to his team's recent discovery, plant biologists presumed that phytochelatins only acted within individual plant cells, surrounding and binding to, or "chelating" heavy metal ions, forming a complex, which is then sequestered in vacuoles-large storage compartments within plant cells. Phytochelatins, in other words, were not known to travel significant distances within a plant.
If the phytochelatins remain in the roots and concentrate the heavy metals there, using plants for bioremediation is much less feasible. That's because pulling the plants out of the ground with the roots attached is much more difficult than harvesting the parts above ground, and because the leaves and stems produce a lot of new biomass for metal accumulation.
For bioremediation to be practical, heavy metals would need to be transported from roots to shoots. Initially, the UCSD biologists thought it unlikely that phytochelatins could perform this function. "We thought maybe the phytochelatins would be trapped in roots," says Ji-Ming Gong, a postdoctoral fellow in Schroeder's lab and the first author on the paper.
To find out, Schroeder's group used mutant plants that do not make their own phytochelatins. Although phytochelatins are found in most plants, they used Arabidopsis, a relative of the mustard plant, commonly used by plant biologists because of its well characterized genetics and readily available mutant varieties. The researchers took a mutant variety of Arabidopsis, which lacks the genes to synthesize phytochelatins, and genetically modified the mutant plants, targeting the gene for the enzyme that synthesizes phytochelatins to the roots of the plant.
To their surprise, the phytochelatins, while only synthesized in the roots, were found in the leaves and stems as well. In addition, when the researchers exposed the roots of the genetically modified plants to cadmium, arsenate and mercury, the plants had restored resistance to these heavy metals. Furthermore, expression of the gene only in roots increased the accumulation of cadmium in leaves. This suggests that engineering plants with the gene to synthesize phytochelatins in roots could make plants contribute to bioremediation.
"We demonstrated that phytochelatins can be transported from roots to shoots and that phytochelatins have a key role in preventing cadmium over-accumulation in roots and enhancing long-distance cadmium transport to leaves," says Schroeder.
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