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Computer
models soybean crop with 8.5 percent more productivity, using 13 percent less
water
Computer
models soybean crop with 8.5 percent more productivity, using 13 percent less
water
Date:
April 3,
2014
Source:
University of Illinois at
Urbana-Champaign
Summary:
Crops that produce more while using less water seem
like a dream for a world with a burgeoning population and already strained
resources. This dream is closer to reality for researchers who developed a new
computer model to help plant scientists breed better soybean crops. The model
predicts a soybean crop with 8.5 percent more productivity, but using 13
percent less water, by breeding for slightly different leaf distribution,
angles and reflectivity.
........................
Crops that
produce more while using less water seem like a dream for a world with a
burgeoning population and already strained food and water resources. This dream
is coming closer to reality for University of Illinois at Urbana-Champaign
researchers who have developed a new computer model that can help plant
scientists breed better soybean crops.
Under
current climate conditions, the model predicts a design for a soybean crop with
8.5 percent more productivity, but using 13 percent less water, and reflecting
34 percent more radiation back into space, by breeding for slightly different
leaf distribution, angles and reflectivity. This work appears in the journal Global
Change Biology.
"The
model lets you look at one of those goals individually or all of them
simultaneously," said Praveen Kumar, a co-author of the study who is the
Lovell Professor of Civil and Environmental Engineering at Illinois.
"There might be some areas where you look at only one aspect -- if you're
in an arid zone, you can structure things to maximize the water efficiency. In
other areas you may want to concentrate on food productivity."
Plants have evolved
to outcompete other plants -- for example, shading out other plants or using
water and nutrients liberally to the detriment of neighboring plants. However,
in an agricultural setting, the plants don't need such competitive measures.
"Our
crop plants reflect many millions of years of evolution in the wild under these
competitive conditions," said U. of I. plant biology professor Stephen P.
Long, also a co-author on the study. "In a crop field we want plants to
share resources and conserve water and nutrients, so we have been looking at
what leaf arrangements would best do this."
The
researchers aimed for three specific areas of improvement. First, productivity.
Second, water usage. Third, combating climate change by reflecting more
sunlight off the leaves. To address all three, they used the unique tactic of
computationally modeling the whole soybean plant.
"Our
approach used a technique called 'numerical optimization' to try out a very
large number of combinations of structural traits to see which combination
produced the best results with respect to each of our three goals," said
lead author Darren Drewry, a former postdoctoral researcher who is now at the
Jet Propulsion Laboratory at the California Institute of Technology. "And
surprisingly, there are combinations of these traits that can improve each of
these goals at the same time."
The model
looks at biological functions, such as photosynthesis and water use, as well as
the physical environment. The researchers looked at how the plant's biology changed
with varying structural traits such as leaf area distributions, how the leaves
are arranged vertically on the stalk, and the angles of the leaves.
For example,
by changing the structure so that leaves are more evenly distributed, more
light can penetrate through the canopy. This lets photosynthesis happen on
multiple levels, instead of being limited to the top, thus increasing the
plant's bean-producing power. A less dense canopy uses less water without
affecting productivity. And changing the angle of the leaves can let the plant
reflect back more solar radiation to offset climate change.
"Most
of the genetic approaches have looked at very specific traits," Kumar
said. "They haven't looked at restructuring the whole canopy. We have a
very unique modeling capability where we can model the entire plant canopy in a
lot of detail. We can also model what these plant canopies can do in a future
climate, so that it will still be valid 40 or 50 years down the line."
Once the
computer predicts an optimal plant structure, then the crop can be selected or
bred from the diverse forms of soybeans that are already available -- without
the regulation and costs associated with genetic engineering.
"This
kind of numerical approach -- using realistic models of plant canopies -- can
provide a method for trying many more trait combinations than are possible
through field breeding," Drewry said. "This approach then can help
guide field programs by pointing to plants with particular combinations of
traits, already tested in the computer, which may have the biggest payoff in
the field."
The
researchers hope their modeling approach will not only improve soybean yields,
but also benefit agriculture worldwide as the population continues to rise.
According to
Long, "The Food and Agriculture Organization of the United Nations predict
that by 2050 we will need 70 percent more primary foodstuffs to feed the world
than we are producing today -- and yet will have to do that with probably no
more water while at the same time dealing with climate change."
"We
need new innovations to achieve the yield jump," Long said. "We've
shown that by altering leaf arrangement we could have a yield increase, without
using more water and also providing an offset to global warming."
Next, the
researchers plan to use their model to analyze other crops for their structural
traits. As part of a project supported by the Bill and Melinda Gates
Foundation, Long is leading an international effort to improve rice, soybean
and cassava guided by similar computational approaches, with the end goal of
making more productive and sustainable crops.
"By
examining plants using detailed computer models and optimization, we have the
potential to greatly expedite the development of new types of agricultural
plants that can tackle some of the greatest challenges facing society today,
related to the need to produce more food in a more variable and uncertain
climate system," Drewry said.
Kumar also
is affiliated with the department of atmospheric sciences. Long also is a
professor of crop sciences and a faculty member in the Institute for Genomic
Biology. The National Science Foundation and the Gates foundation supported
this work.
Story
Source:
The above
story is based on materials provided by University
of Illinois at Urbana-Champaign. Note: Materials may be
edited for content and length.
Journal
Reference:
- Darren T. Drewry, Praveen Kumar, Stephen P. Long. Simultaneous improvement in productivity, water use, and albedo through crop structural modification. Global Change Biology, 2014; DOI: 10.1111/gcb.12567
Cite This
Page:
University of Illinois at
Urbana-Champaign. "Computer models soybean crop with 8.5 percent more
productivity, using 13 percent less water." ScienceDaily. ScienceDaily, 3
April 2014. <www.sciencedaily.com/releases/2014/04/140403132355.htm>.
