Lessons from herbicide tolerance

August 24th, 2012 in Biology / Biotechnology
Fluorescent labeling reveals expression of the RMV1 gene, localized to cell membranes of Arabidopsis root cells. The left panel shows the GFP-labeling, the right panel is under a red filter showing plasma membrane stained with ‘FM 4-64’. © 2012 Miki Fujita, RIKEN Plant Science Center


Fluorescent labeling reveals expression of the RMV1 gene, localized to cell membranes of Arabidopsis root cells. The left panel shows the GFP-labeling, the right panel is under a red filter showing plasma membrane stained with ‘FM 4-64’. © 2012 Miki Fujita, RIKEN Plant Science Center

(Phys.org)—Polyamines are widespread and important organic compounds involved in multiple cellular processes in living organisms. Their levels are highly regulated through a combination of processes including synthesis, breakdown and transport. However, the mechanisms of polyamine transport are still largely unknown.

Since the widely used (methyl viologen) follows the same transport pathways as polyamines, Miki Fujita and colleagues at the RIKEN Plant Science Center in Tsukuba, Japan, analyzed natural variability in paraquat susceptibility in the thaliana. They found that the gene resistance to methyl viologen 1 (RMV1) is involved in the transport of both paraquat and polyamines in Arabidopsis.

Paraquat's herbicidal activity results from causing oxidative stress in . However, Fujita and her team found that most paraquat-tolerant varieties of Arabidopsis remained susceptible to other oxidative stress inducers, implying tolerance was due to reduced uptake rather than limitation of paraquat's oxidative effects. By crossing different paraquat-resistant varieties, they showed that paraquat-tolerance was linked to a single locus, while cloning and complementation techniques revealed its genomic location. Using in which they had placed the fluorescent jellyfish protein, (GFP), under the same genetic control as RMV1, the researchers revealed that its expression is localized to the cell membrane, indicating a likely role in uptake or transport of molecules into cells.

Fujita and colleagues then verified that RMV1 mediates paraquat uptake by studying Arabidopsis plants in which RMV1 is inactivated by mutation: these plants showed higher paraquat tolerance, indicating reduced paraquat uptake or transport. Many of these mutants also showed increased tolerance to certain polyamines, indicating that the same locus is involved in polyamine transport. However this effect was relatively slight, suggesting to Fujita and her team that other polyamine transporter genes might exist in the Arabidopsis genome.

Fujita is now aiming to identify other polyamine transporters and investigate their biological significance in terms of plant growth and stress responses. The identification of such transporters may facilitate developments in fields as diverse as cancer treatments—reduced polyamine uptake is linked to the efficacy of certain anticancer drugs—and GM crops. "It is really urgent to create the next generation of herbicide-resistant crops," Fujita says. Some hurdles remain, however: paraquat is banned in many countries due to its toxicity, but these findings are a step towards creating more environmentally friendly herbicide-resistant crops.

More information: Fujita, M., Fujita, Y., Iuchi, S., Yamada, K., Kobayashi, Y., Urano, K., Kobayashi, M., Yamaguchi-Shinozaki, K. & Shinozaki, K. Natural variation in a polyamine transporter determines paraquat tolerance in Arabidopsis. Proceedings of the National Academy of Sciences 109, 6343–6347 (2012). www.pnas.org/content/early/201… /03/1121406109.short

Provided by RIKEN

"Lessons from herbicide tolerance." August 24th, 2012. http://phys.org/news/2012-08-lessons-herbicide-tolerance.html