新澳门六合彩内幕信息

How Tomato Plants Use Their Roots to Ration Water During Drought

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At left a bald man with a short beard and glasses, to right a woman with shoulder length red hair. Both are wearing dark blue lab coats. They are surrounded by tomato plants.
New work by Alex Cant贸-Pastor (left) and Professor Siobhan Brady, Department of Plant Biology, shows how tomato plants protect themselves from drought by waterproofing their roots. The findings could lead to new ways to breed drought-tolerant tomato and other crops. (Photo by TJ Ushing for the College of Biological Sciences)

Plants have to be flexible to survive environmental changes, and the adaptive methods they deploy must often be as changeable as the shifts in climate and condition to which they adapt. To cope with drought, plant roots produce a water-repellent polymer called suberin that blocks water from flowing up towards the leaves, where it would quickly evaporate. Without suberin, the resulting water loss would be like leaving the tap running.

In some plants, suberin is produced by endodermal cells that line the vessels inside the roots. But in others, like tomatoes, suberin is produced in exodermal cells that sit just below the skin of the root.

The role of exodermal suberin has long been unknown, but a new study by researchers at the University of California, Davis, published Jan. 2 in  shows that it serves the same function as endodermal suberin, and that without it, tomato plants are less able to cope with water stress. This information could help scientists design drought-resistant crops.

鈥淭his adds exodermal suberin to our toolbox of ways to help plants survive for longer and cope with drought,鈥 said , professor in the 新澳门六合彩内幕信息 Davis Department of Plant Biology and Genome Center, and senior author on the paper. 鈥淚t鈥檚 almost like a jigsaw puzzle鈥攊f you can figure out which cells have modifications that protect the plant during difficult environmental conditions, you can start to ask questions like, if you build those defenses up one upon the other, does it make the plant stronger?鈥

In the new study, postdoctoral scholar Alex Cant贸-Pastor worked with Brady and an international team of collaborators to uncover the role of exodermal suberin and map the genetic pathways that regulate its production.

Combining new and classical methods

鈥淚t's really the merging of classical and cutting-edge methodology that lets us look at both the process that's happening in an individual cell and what you see in the whole plant,鈥 said Brady. 鈥淪o going from super small to really, really big.鈥

Brady, Cant贸-Pastor and colleagues started by identifying all of the genes that are actively used by root exodermal cells. Then they performed gene editing to create mutant strains of tomato plant that lacked functional versions of several genes they suspected might be involved in suberin production. They discovered seven genes that were necessary for suberin deposition.  

Next, the researchers tested exodermal suberin's role in drought tolerance by exposing some of the mutant tomato plants to a ten-day drought. For these experiments, the researchers focused on two genes: SIASFT, an enzyme involved in suberin production and SlMYB92, a transcription factor that controls the expression of other genes involved in suberin production.

The experiments confirmed that both genes are necessary for suberin production and that without them, tomato plants are less able to cope with water stress. The mutant plants grew as well as normal plants when they were well-watered but became significantly more wilted after ten days with no water.

鈥淚n both of those cases where you have mutations in those genes, the plants are more stressed and they're not able to respond to drought conditions,鈥 Brady said.

Having shown suberin鈥檚 worth in a greenhouse setting, the researchers now plan to test suberin鈥檚 drought-proofing potential in the field.

鈥淲e鈥檝e been working on taking this finding and putting it into the field to try and make tomatoes more drought tolerant,鈥 Brady said.

Additional authors on the paper are: at 新澳门六合彩内幕信息 Davis, Lidor Shaar-Moshe, Concepci贸n Manzano, Sharon Gray, He Yang, Sana Mohammad, Niba Nirmal, G. Alex Mason, Mona Gouran, Kaisa Kajala, Kenneth A. Shackel, Donnelly A. West and Neelima Sinha; Prakash Timilsena and Song Li, Virginia Tech; Damien De Bellis, Robertas Ursache and Niko Geldner, University of Lausanne, Switzerland; Julia Holbein, Kiran Suresh and Rochus Benni Franke, Rheinische Friedrich-Wilhelms-University of Bonn, Germany; Alexander T. Borowsky and Julia Bailey-Serres, 新澳门六合彩内幕信息 Riverside.,

The work was supported by the National Science Foundation and the Howard Hughes Medical Institute.

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(Nature Plants)

Liana Wait is a freelance science writer based in Philadelphia. She has a Ph.D. in ecology and evolutionary biology and specializes in writing about the life sciences.

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