video: This timelapse shows the effects of drought on plant growth. The plant on the right continues to be watered while growth is stunted in the plant on the left in response to drought. The dry plant produces leaves more slowly, makes smaller leaves and loses chlorophyll. view more
Credit: Professor Kathy Barton, Carnegie Institution for Science
A feature thought to make plants sensitive to drought could actually hold the key to them coping with it better, according to new findings published in eLife.
Plants that are resistant to the hormone abscisic acid (ABA) have until now been understood to be bad at coping with drought. However, scientists from the Carnegie Institution for Science have discovered ABA-resistant varieties that grow better than their normal neighbours when water is scarce. The new research suggests breeders should explore them for "stay green" traits.
"When breeders are looking for plants able to withstand drought, they discount those resistant to ABA, but our findings show that a subset of ABA-resistant plants may be a great source of drought-tolerant germplasm," says Professor Kathryn Barton from the Carnegie Institution for Science in California.
Drought and ABA trigger several water conserving strategies in the plant: pores on the leaf close to prevent evaporation, growth is slowed and some leaves yellow and fall from the plant. The new research identifies a protein as the agent that retards growth and causes leaves to yellow. The team have renamed the protein ABA INSENSITIVE GROWTH 1 (ABIG1) to reflect its previously undiscovered role in preventing plant growth.
Plants with and without the protein were grown and watered for 34 days but, from day 35, water was withheld for 17 days. Un-watered plants without the crucial ABIG1 protein retain double the number of green leaves, are able to remain upright and retain a healthier root system. Plants with the ABIG1 protein yellow, lose their leaves and fall over.
Barton and colleagues hypothesize that reducing the amount of ABIG1 in the plant increases the threshold at which the plant triggers drastic water conserving measures. Raising this threshold may be one way to breed plants that remain green and growing during short-term drought episodes.
California is over five years into one of its worst droughts on record and recent research raises the prospect of it lasting hundreds of years. Global warming is increasing the frequency and severity of droughts elsewhere too. Plant scientists and breeders will play a crucial role in helping farmers adapt. This is essential to retain our supply of food, fuel, clothing and medicine.
"Stay green" traits have already been bred into crop plants such as sorghum and rice to maintain a harvest under drought conditions. Plants that retain their leaves are able to continue to provide nutrition from the environment to the parts of the plants that we harvest, for example to the seeds we use for food. For now, it is not known what molecules underlie this 'stay green' germplasm. Barton and colleagues' work suggests that ABIG1 may be part of the answer.
"The ability of the plants we studied to remain green longer and to maintain an upright shoot even when we deprived them of water for over two weeks is an exciting discovery that could lead to more drought-tolerant crop varieties," says Barton.
She and her team are already carrying out experiments to see if reducing the amount of the ABIG1 homolog in maize, the world's third most important cereal crop, will generate similar "stay green" plants.
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Reference
The paper 'The Arabidopsis transcription factor ABIG1 relays ABA signaled growth inhibition and drought induced senescence' can be freely accessed online at http://dx.doi.org/10.7554/eLife.13768. Contents, including text, figures, and data, are free to reuse under a CC BY 4.0 license.
About eLife
eLife is a unique collaboration between the funders and practitioners of research to improve the way important research is selected, presented, and shared. eLife publishes outstanding works across the life sciences and biomedicine -- from basic biological research to applied, translational, and clinical studies. All papers are selected by active scientists in the research community. Decisions and responses are agreed by the reviewers and consolidated by the Reviewing Editor into a single, clear set of instructions for authors, removing the need for laborious cycles of revision and allowing authors to publish their findings quickly. eLife is supported by the Howard Hughes Medical Institute, the Max Planck Society, and the Wellcome Trust. Learn more at elifesciences.org.