Light green plants save nitrogen without sacrificing photosynthetic efficiency

Scientists have designed plants with light green leaves to allow more light to penetrate the crop canopy to increase photosynthesis and yield; however, models show these plants likely require less nitrogen and photosynthesis is hardly affected. Credit: Claire Benjamin/University of Illinois

“Leaves up at the top of the canopy are really greedy–they absorb a lot of light and don't let much down to their brothers and sisters below them,” said Berkley Walker, an Alexander von Humboldt Postdoctoral Fellow at the University of Düsseldorf, who led this work supported by Realizing Increased Photosynthetic Efficiency (RIPE).

“Leaves up at the top aren't very efficient with that light energy, but the leaves at the bottom are very efficient. So, if you could just take some of that light that's being hogged up at the top, and move it down deeper into the canopy, theoretically, you'd have a more efficient canopy.”

Published in Plant Physiology, researchers tested this idea using a computer simulation incorporating data from nearly 70 varieties of soybeans with varying levels of chlorophyll from the U.S. Department of Agriculture germplasm bank. They found that plants with 20 percent less chlorophyll theoretically require 9 percent less nitrogen with no penalty to carbon gain (biomass) and yield.

“The simulation reveals that the complex interior structure of leaves causes the light to bounce around so much that the light has the same probability of going up as it does going down,” said RIPE Deputy Director Don Ort, a physiologist with the USDA/ARS Photosynthesis Research Unit and the Robert Emerson Professor of Plant Biology and Crop Sciences at the Carl R. Woese Institute for Genomic Biology at the University of Illinois. “When we decrease chlorophyll, more light is lost to reflection, and we don't get the full benefits of getting light deeper into the canopy where it can be absorbed.”

Next, they are exploring if these nitrogen savings could be used to fix other photosynthetic bottlenecks as well as other ways to increase light penetration into the canopy.

“It's not case closed on light green plants, but the strategy is going to be a little more nuanced than just putting plants out there with lower chlorophyll content,” Walker said. “We need to explore if light green can be combined with changes in leaf architecture or if we can re-engineer leaves to be thinner to reduce light reflectance and improve transmittance.”

Other RIPE-funded work that modeled a decrease in chlorophyll content in rice found that reallocating these nitrogen savings could improve canopy photosynthesis and nitrogen use efficiency by 30 percent. According to collaborator Xinguang Zhu of the Chinese Academy of Sciences, “Manipulation of leaf chlorophyll content is one exciting option to explore both increased energy and light use efficiencies. This study shows that gaining the desired benefit requires a more thorough understanding of the leaf optical properties and nitrogen distribution patterns among photosynthetic proteins in a leaf.”

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Realizing Increased Photosynthetic Efficiency (RIPE) is engineering staple food crops to more efficiently turn the sun's energy into food to sustainably increase worldwide food productivity, with support from the Bill & Melinda Gates Foundation, the Foundation for Food and Agriculture Research, and the U.K. Department for International Development.

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, Louisiana State University, University of California, Berkeley, and the USDA Agricultural Research Service.

The paper “Chlorophyll can be reduced in crop canopies with little penalty to photosynthesis” was published in Plant Physiology (doi: doi.org/10.1104/pp.17.01401). Co-authors include Darren T Drewry, Jet Propulsion Laboratory; Rebecca A Slattery, USDA-ARS; Andy VanLoocke, Iowa State University; and Young B. Cho, University of Illinois.

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Claire Benjamin
claire@illinois.edu
217-244-0941

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