The research, published in Nature Communications, is part of the international research project Realizing Increased Photosynthetic Efficiency (RIPE) supported by the Bill & Melinda Gates Foundation, the Foundation for Food and Agriculture Research, and the UK Department for International Development.
Agriculture already monopolises 90 per cent of global freshwater; yet dramatic increases in production are still needed to feed and fuel this century’s growing population.
“This is a major breakthrough,” said RIPE Director Stephen Long, professor of crop sciences at Lancaster.
“Crop yields have steadily improved over the past 60 years, but the amount of water required to produce one ton of grain remains unchanged; which led most to assume that this factor could not change. Proving that our theory works in practice should open the door to much more research and development to achieve this all-important goal for the future.”
The international team increased the levels of a photosynthetic protein (PsbS) to conserve water by tricking plants into partially closing their stomata, the microscopic pores in the leaf that allow water to escape. Stomata are the gatekeepers to plants: when open, carbon dioxide enters the plant to fuel photosynthesis, but water is allowed to escape through the process of transpiration.
“These plants had more water than they needed, but that won’t always be the case,” said co-first author Katarzyna Glowacka, a postdoctoral researcher who led this research at the Carl R. Woese Institute for Genomic Biology (IGB). “When water is limited, these modified plants will grow faster and yield more; they will pay less of a penalty than their non-modified counterparts.”
The team improved the plant’s water-use-efficiency — the ratio of carbon dioxide entering the plant to water escaping — by 25 per cent without significantly sacrificing photosynthesis or yield in real-world field trials. The carbon dioxide concentration in our atmosphere has increased by 25 per cent in just the past 70 years, allowing the plant to amass enough carbon dioxide without fully opening its stomata.
“Evolution has not kept pace with this rapid change, so scientists have given it a helping hand,” said Professor Long, who is also Ikenberry Endowed Chair of Plant Biology and Crop Sciences.
Four factors can trigger stomata to open and close: humidity, carbon dioxide levels in the plant, the quality of light, and the quantity of light. This study is the first report of hacking stomatal responses to the quantity of light.
PsbS is a key part of a signaling pathway in the plant that relays information about the quantity of light. By increasing PsbS, the signal says there is not enough light energy for the plant to photosynthesize, which triggers the stomata to close since carbon dioxide is not needed to fuel photosynthesis.
This research complements previous work, published in Science, which showed that increasing PsbS and two other proteins can improve photosynthesis and increase productivity by as much as 20 percent. Now the team plans to combine the gains from these two studies to improve production and water-use by balancing the expression of these three proteins.
For this study, the team tested their hypothesis using tobacco, a model crop that is easier to modify and faster to test than other crops. Now they will apply their discoveries to improve the water-use-efficiency of food crops and test their efficacy in water-limited conditions.
“Making crop plants more water-use efficient is arguably the greatest challenge for current and future plant scientists,” said co-first author Johannes Kromdijk, a postdoctoral researcher at the IGB. “Our results show that increased PsbS expression allows crop plants to be more conservative with water use, which we think will help to better distribute available water resources over the duration of the growing season and keep the crop more productive during dry spells.”
Watch a video about the research here.
The paper “Photosystem II subunit S Overexpression Increases the Efficiency of Water Use in a Field-Grown Crop” is available by request. Co-authors also include Illinois researchers Katherine Kucera, lab technician; Jiayang Xie, student; Amanda Cavanagh, postdoctoral researcher; Andrew Leakey, associate professor; Donald Ort, Robert Emerson Professor of Plant Biology and Crop Sciences; and from the University of California, Berkeley: Lauriebeth Leonelli, postdoctoral associate, and Professor Krishna Niyogi.
Realizing Increased Photosynthetic Efficiency (RIPE) is engineering crops to more efficiently turn the sun’s energy into food to sustainably increase worldwide food productivity. RIPE is led by the University of Illinois in partnership with the University of Essex, Lancaster University, Australian National University, Chinese Academy of Sciences, Commonwealth Scientific and Industrial Research Organisation, University of California, Berkeley, and Louisiana State University, and USDA/ARS.