New research has identified the mechanism used by plants in stress conditions to sense low oxygen levels - and scientists then used that knowledge and advanced breeding techniques to reduce yield loss in barley under water-logged conditions.

In 2011, University of Nottingham Professor of Crop Science Michael Holdsworth and colleagues identified the mechanism used by plants in stress conditions to sense low oxygen levels and now they have discovered how this works in barley.

“We now know how to breed barley cultivars more tolerant to waterlogging and flooding,” says Holdsworth.

Across the world farmers are falling victim to the increasing frequency of catastrophic flooding events. Plants starved of oxygen cannot survive flooding for long periods of time. Persistent flooding and saturated arable land can wipe out crops and reduce harvests so the search for flood tolerant crops is a key target for global food security.

Living on low oxygen 

Barley is comparatively more susceptible to waterlogging than other cereals. Average yields can be reduced by up to 50 per cent as a result of waterlogging. Resistance to this stress is an important objective of breeding efforts in high-rainfall areas of the world.

Professor Holdsworth said, “Barley cultivars with the capability to withstand waterlogging have excellent growth, superior yields, retain their green appearance due to chlorophyll retention and have a more efficient metabolism even in low oxygen conditions. We now have the strategy developed for plant breeding to select for enhanced tolerance to waterlogging in barley and other crops.”  

This research was funded by UK Biotechnology and Biological Sciences Research Council (BBSRC) and by SABMiller plc, the Pierre et Marie Curie University, Paris, the University of Silesia, Katowice, Poland and the International Atomic Energy Agency.

Citation: Guillermina M. Mendiondo, Daniel J. Gibbs, Miriam Szurman-Zubrzycka, Arnd Korn1,3, Julietta Marquez, Iwona Szarejko, Miroslaw Maluszynski, John King, Barry Axcell, Katherine Smart, Francoise Corbineau, Michael J. Holdsworth, 6 FEB 2015 DOI: 10.1111/pbi.12334