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Rewiring plant defense genes to reduce crop waste

Defensive feedback control system developed -- enables plants to strengthen their defenses

June 20, 2018
University of Warwick
Plants could be genetically rewired to better resist disease, helping safeguard crop yields worldwide according to new research. Defensive feedback control system developed enables plants to strengthen their defenses to withstand attack by re-wiring existing gene connections. The system uses same approach as aircraft autopilots use to counteract turbulence.

Plants can be genetically rewired to resist the devastating effects of disease -- significantly reducing crop waste worldwide -- according to new research into synthetic biology by the University of Warwick.

Led by Professor Declan Bates from the Warwick Integrative Synthetic Biology Centre (WISB) and Professor Katherine Denby from the University of York, who is also an Associate member of WISB, researchers have developed a genetic control system that would enable plants to strengthen their defence response against deadly pathogens -- so they could remain healthy and productive.

When pathogens attack crop plants, they obtain energy and nutrients from the plant but also target the plant's immune response, weakening defence, and making the plants more vulnerable.

Building on experimental data generated by Prof. Denby, Professor Bates' group simulated a pathogen attack in Arabidopsis plants, and modelled a way to rewire the plants' gene network, creating a defensive feedback control system to combat disease -- which works in much the same way as an aircraft autopilot.

Just as an aircraft's autopilot control system detects disturbances like wind gusts or turbulence and acts to reject them, this new plant control system detects a pathogen attack, and prevents the pathogen weakening the plants' defence response.

This method could render crops more resilient against disease, helping mitigate crop wastage throughout the world. Since the system can be implemented by re-wiring plants' natural defence mechanisms, no external genetic circuitry needs to be added.

Declan Bates, Professor of Bioengineering at the University of Warwick's School of Engineering, commented:

"Disease, drought and extreme temperatures cause significant yield losses in crop plants all over the globe, threatening world food security. It is therefore crucial to explore new ways to develop crops that are resilient to pathogen attacks and can maintain yields in challenging environments. This study shows the enormous potential of using feedback control to strengthen plants' natural defence mechanisms."

Katherine Denby, Professor of Sustainable Crop Production and Director of the N8 AgriFood Resilience Programme at the University of York commented:

"Minimising crop waste is obviously an essential part of creating a more sustainable food system. What is exciting here is applying engineering principles to plant biology to predict how to re-design plant gene regulation to enhance disease resistance. We use re-wiring of existing genes in the plant to prevent pathogen manipulation."

The next steps of the research will be to take the theory into the lab, and experimentally implement the defensive feedback control system in plants.

Story Source:

Materials provided by University of Warwick. Note: Content may be edited for style and length.

Journal Reference:

  1. Mathias Foo, Iulia Gherman, Peijun Zhang, Declan G. Bates, Katherine J. Denby. A Framework for Engineering Stress Resilient Plants Using Genetic Feedback Control and Regulatory Network Rewiring. ACS Synthetic Biology, 2018; 7 (6): 1553 DOI: 10.1021/acssynbio.8b00037

Cite This Page:

University of Warwick. "Rewiring plant defense genes to reduce crop waste." ScienceDaily. ScienceDaily, 20 June 2018. <>.
University of Warwick. (2018, June 20). Rewiring plant defense genes to reduce crop waste. ScienceDaily. Retrieved April 17, 2024 from
University of Warwick. "Rewiring plant defense genes to reduce crop waste." ScienceDaily. (accessed April 17, 2024).

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