Skip to main content

Scientists further cowpea research—boosting canopy CO2 assimilation, water-use efficiency


CHAMPAIGN, Ill. — Crops grow dense canopies that consist of several layers of leaves—the upper layers with younger sun leaves and the lower layers with older shaded leaves that may have difficulty intercepting sunlight trickling down from the top layers.

In a recent study published in Food and Energy Security, scientists from Realizing Increased Photosynthetic Efficiency (RIPE) aimed to understand how much variation exists within diverse cowpea lines in light absorption and carbon dioxide (CO2) assimilation throughout the canopy. This information can ultimately be used to design more efficient canopies—with greater CO2 assimilation and water-use efficiency—to increase yields.

RIPE, which is led by the University of Illinois, is engineering crops to be more productive by improving photosynthesis, the natural process all plants use to convert light energy to produce biomass and yields. RIPE is supported by the Bill & Melinda Gates Foundation, the U.S. Foundation for Food and Agriculture Research (FFAR), and the U.K. Government’s Department for International Development (DFID). One of the target crops of the RIPE project is cowpea.

Cowpeas, commonly known as black-eyed peas in the U.S., are one of the oldest domesticated crops in the world, responsible for feeding more than 200 million people per day.

“They are a staple crop in Africa, providing a source of protein for humans and livestock, and restoration of soil nutrition through nitrogen fixation,” said Lisa Ainsworth, a research plant physiologist with the U.S. Department of Agriculture, Agricultural Research Service (USDA-ARS).

The RIPE team screened 50 cowpea genotypes from a multi-parent advanced generation inter-cross (MAGIC) population for canopy architecture traits, canopy photosynthesis, and water-use efficiency by using a canopy gas exchange chamber. This chamber was used to measure the rate by which plants would convert CO2 in the atmosphere into carbohydrates as energy for growth.

Canopy gas exchange chamber
A canopy enclosure is used to measure gas exchange and identify which plant traits most strongly affect canopy photosynthesis.

“Since sub-Saharan Africa is the region where important yield gaps persist, it is crucial that we develop a high yielding crop that can be easily grown there,” said first author Anthony Digrado, a USDA-ARS postdoctoral researcher in Ainsworth’s lab based at Illinois. “That is to say that water-use efficiency should be taken into serious account when developing new varieties for sub-Saharan African countries that are challenged by access to water in several regions.”

The team used Principal Component Analysis (PCA) models to first group the 50 MAGIC genotypes into five general canopy architectural types to study plant traits, including leaf area index, leaf greenness, and canopy height and width. This analysis gave researchers the ability to gather an overview of the traits, or combinations of traits, that could be modified to have the strongest impact on canopy photosynthesis to maximize growth.

Cowpea research team
Team led by Anthony Digrado collecting data from the cowpea population.

Canopy architecture contributed to 38.6 percent of the variance observed in canopy photosynthesis. Results showed that in canopies with lower biomass, the major limitation to canopy photosynthesis was leaf area; however, in higher biomass canopies, the major limiting factor was, instead, the light environment. Canopies with high biomass have greater canopy photosynthesis when leaves at the top of the canopy have lower chlorophyll content.

Overall, canopy architecture significantly affected canopy photosynthetic efficiency and water-use efficiency, suggesting that optimizing canopy structures can contribute to yield enhancement in crops.

“Water-use efficiency refers to the amount of CO2 assimilated by a crop canopy relative to the amount of water that is lost by the canopy,” said Digrado, who led this work at the Carl R. Woese Institute for Genomic Biology (IGB). “The ideal for a crop is to be able to have a lot of carbon intake without losing too much water.”

The MAGIC cowpea population that the team used matches this criteria for an ideal crop, especially one to be grown in the drought conditions of Africa. However, research on how canopy architecture affects canopy CO2 assimilation and water-use efficiency in cowpea continues to be scarce.

“There is still a lot to do to improve cowpea yields and much more research is needed,” Digrado said. “But this work has established that variation exists that can be used to improve productivity and efficiency of an important food security crop.”


The RIPE project and its sponsors are committed to ensuring Global Access and making the project’s technologies available to the farmers who need them the most.

Realizing Increased Photosynthetic Efficiency (RIPE) aims to improve photosynthesis to equip farmers worldwide with higher-yielding crops to ensure everyone has enough food to lead a healthy, productive life. This international research project is sponsored by the Bill & Melinda Gates Foundation, the U.S. Foundation for Food and Agriculture Research, and the U.K. Government’s Department for International Development.

RIPE is led by the University of Illinois in partnership with The Australian National University, Chinese Academy of Sciences, Commonwealth Scientific and Industrial Research Organisation, Lancaster University, Louisiana State University, University of California, Berkeley, University of Cambridge, University of Essex, and U.S. Department of Agriculture, Agricultural Research Service.


By: Amanda Nguyen || RIPE Communications Specialist 

Go to newswire story

RIPE OBJECTIVES

Optimizing Canopies