Researchers discover key link in understanding billion-dollar pests in agriculture
Studies show that parasitic nematodes mimic plant hormones in order to attack their hosts
- Date:
- September 29, 2015
- Source:
- University of Missouri-Columbia
- Summary:
- Invisible to the naked eye, plant-parasitic nematodes are a huge threat to agriculture, causing billions in crop losses every year. Researchers have now found the first genetic evidence linking one method these animals use to attack plants; they proved that nematodes use a specialized hormone to help them feed. This research could allow plant scientists to develop plants with enhanced resistance to these devastating agricultural pests.
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Invisible to the naked eye, plant-parasitic nematodes are a huge threat to agriculture, causing billions in crop losses every year. Plant scientists at the University of Missouri and the University of Bonn in Germany have found the first genetic evidence linking one method these animals use to attack plants; they proved that these tiny worms use a specialized hormone to help them feed from the plant. This research could allow plant scientists to develop crop plants with enhanced resistance to these devastating agricultural pests.
"Cell cycle regulation is a key aspect of plant development and one of the first events altered during the formation of the feeding sites nematodes use to acquire nutrients from host plants," said Melissa Goellner Mitchum, a researcher in the Bond Life Sciences Center and an associate professor in the Division of Plant Sciences at MU. "These discoveries led scientists to suspect that cytokinin, a hormone that promotes cell division in plants, might play a key role in feeding site formation for nematode parasites."
Carola De La Torre, a doctoral student in the Bond Life Sciences Center, and Demosthenis Chronis, a postdoctoral fellow at MU, worked with Mitchum to determine if nematode infection alters the cytokinin signaling pathways plants use to regulate growth and development and how the process changes due to nematode infection.
"As part of our research, we examined the activation of different components of the cytokinin pathway in response to nematode infection," De La Torre said. "Also, we evaluated numerous plants that lacked the presence of these components and found that most of these plants were less susceptible to nematode infection. These results suggested to us that these little worms are not only utilizing parts of a plant hormonal pathway that is important for plant growth and development, but they also are doing it in a way that allows them to cause disease."
Mitchum's team partnered with Florian Grundler's group at Rheinische Friedrich-Wilhelms-University of Bonn, Germany, who further analyzed the connection between cytokinin and nematodes. Using advanced genetic tools, they discovered that nematodes create their own form of plant cytokinin and that, by secreting the hormone into the plant, they actively control the cell cycle leading to the production of ideal feeding sites to support their development. These findings show the ability of an animal to synthesize and secrete a functional plant hormone to establish long-term parasitism.
"Understanding how plant-parasitic nematodes modulate host plants to their own benefit is an essential first step in finding new technologies needed to develop crop plants with enhanced resistance to these devastating agricultural pests," Mitchum said.
Story Source:
Materials provided by University of Missouri-Columbia. Original written by Sheena Rice. Note: Content may be edited for style and length.
Journal Reference:
- Shahid Siddique, Zoran S. Radakovic, Carola M. De La Torre, Demosthenis Chronis, Ondřej Novák, Eswarayya Ramireddy, Julia Holbein, Christiane Matera, Marion Hütten, Philipp Gutbrod, Muhammad Shahzad Anjam, Elzbieta Rozanska, Samer Habash, Abdelnaser Elashry, Miroslaw Sobczak, Tatsuo Kakimoto, Miroslav Strnad, Thomas Schmülling, Melissa G. Mitchum, Florian M. W. Grundler. A parasitic nematode releases cytokinin that controls cell division and orchestrates feeding site formation in host plants. Proceedings of the National Academy of Sciences, 2015; 201503657 DOI: 10.1073/pnas.1503657112
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