U. ILLINOIS (US)—Global grain production must double by 2050 to address rising population and demand and unless new approaches to adapt crop plants to climate change are adopted, yields will suffer, according to a new study.
Improved agronomic traits responsible for the increases in yield accomplished during the past 50 years have reached their ceiling for some of the world’s most important crops.
“Global change is happening so quickly that its impact on agriculture is taking the world by surprise,” says Don Ort, professor of crop sciences at the University of Illinois.
“Until recently, we haven’t understood the urgency of addressing global change in agriculture.”
The need for new technologies to conduct global change research on crops in an open-field environment is holding the commercial sector back from studying issues such as maximizing the elevated carbon dioxide advantage or studying the effects of ozone pollution on crops.
The Free Air Concentration Enrichment (FACE) research facility, SoyFACE, allows researchers to conduct novel studies using the technology capable of creating environments of the future in an open-field setting.
“If you want to study how global change affects crop production, you need to get out of the greenhouse,” Ort says. “At SoyFACE, we can grow and study crops in an open-field environment where carbon dioxide and ozone levels can be raised to mimic future atmospheric conditions without disturbing other interactions.”
From an agricultural standpoint, one of the few positive aspects of global change has been the notion that elevated carbon dioxide in the atmosphere will stimulate photosynthesis and result in increased crop yields.
But recent studies show that crops grown in open fields under elevated carbon dioxide levels resulted in only half the yield increase expected and half of what the United Nation’s Intergovernmental Panel on Climate Change used in their model predictions regarding the world’s food supply in 2050.
There’s no doubt that carbon dioxide levels are rising. At the beginning of the Industrial Revolution, atmospheric carbon dioxide levels were 260 parts per million (ppm). Today, those numbers have increased to 385 ppm. By 2050, carbon dioxide levels are expected to be 600 ppm.
“Elevated carbon dioxide is creating a global warming effect that in turn is driving other climate change factors such as precipitation patterns,” Ort says. “By 2050, rainfall during the Midwest growing season is projected to drop 30 percent.”
How elevated ozone levels will affect crop yields is also part of the current research.
Soybean plants are being evaluated in elevated ozone at SoyFACE. New studies show that yields in the tri-state area of Indiana, Illinois, and Iowa have been suppressed by 15 percent due to ozone pollution.
Ort says if the same cultivars of soybean are used in 2050 that are being planted now, producers can expect to see an additional 20 percent drop in yield due to expected increases in ozone levels by the middle of the century.
“Ozone is a secondary pollutant caused by the interaction of sunlight with pollution clouds produced in industrialized areas and carried over rural areas by wind,” Ort explains. “For example, if pollution from Chicago blows out of the city into agricultural areas, it can interact with sunlight to produce ozone and cause plant yields to suffer.”
Because ozone is an unstable gas, its concentration levels vary greatly, Ort says. Agricultural areas located near industrial areas will face the greatest challenges. Unfortunately, of the world’s two top-growing areas for soybean—the United States faces a much greater ozone challenge than Brazil.
“The SoyFACE experiment and historical data recorded over the past 10 years both indicate that for every additional one part per billion of ozone, soybean yields will decrease 1.5 bushels per acre,” Ort predicts.
In addition to generating results about the response of crops to global change, SoyFACE has provided proof of concept that adaptation of crop plants to global change can be achieved in the field. Ort says this approach should be scaled to much larger sizes necessary for conventional selective breeding.
“FACE technology, coupled with revolutionary genomic tools, can markedly accelerate the breeding cycle,” Ort says.
“Once we discover the suites of genes that control the optimal response of plants growing in global change conditions, we can screen germplasm collections to narrow down hundreds of thousands of cultivars before testing the best ones in the field.”
Ort said top priorities of focus include tropical areas that are already food insecure and areas such as the U.S. Corn Belt that produce a large percentage of the world food supply.
“More research in these areas is critical,” he said. “How top-producing areas fare with climate change will be very important in determining global food security for the future.”
Scientists from Shanghai Institute of Biological Sciences in China contributed to the research, which was funded by the U.S. Department of Agriculture, the Department of Energy, and the Illinois Council on Food and Agricultural Research.
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