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Flip the on-off switch on pollen production

Controlling pollen production can be critical to improving crop yield.

August 5, 2020

3 Min Read
A metal on and off switch on a white background
POLLEN POWER: It is not nearly as simple as toggling a metal button, but researchers at the Donald Danforth Plant Science Center in St. Louis found a way to switch pollen production on or off through genetic pathways. Michael Burrell/Getty Images

An unexpected result happened when a team of researchers looked at the genetic pathways of flowering plants. They realized they could turn on or off pollen production.

The research team was led by Blake Meyers, member of the Donald Danforth Plant Science Center and professor in the Division of Plant Sciences at the University of Missouri, and Virginia Walbot, professor of biology at Stanford University.

Their findings, “Dicer-like 5 deficiency confers temperature-sensitive male sterility in maize,” were published in the journal Nature Communications.

Small RNAs are key regulators involved in plant growth and development. Two groups of small RNAs are abundant during development of pollen in the anthers — a critical process for reproductive success. A research collaboration has demonstrated the function of a genetic pathway for anther development, with this pathway proven in 2019 work to be present widely in the flowering plants.

Their research uncovered an environmentally sensitive male sterile phenotype. By using mutants and knocking out one of the pathways, the research team produced plants that failed to make pollen, but when they lowered the temperature, they found they could recover full male fertility.

Importance for agriculture

This ability to turn on or turn off pollen production in different conditions could be beneficial for seed production. The team also could attribute the function of this pathway in anther development, an observation previously missing but important. These results are important companions to a previously published discovery, which described the evolutionary distribution of the pathway across flowering plants.

“Putting these two discoveries together, we can understand the role these molecules play is important for full male fertility in maize, plus, the pathway first evolved with flowering plants,” Meyers said. “Understanding the genetic mechanisms by which flowers develop is important for improving crop yields and breeding better varieties, particularly for making the high-yielding hybrid crops that support modern agriculture.”

More research on the way

The research team will continue to work to understand why there is an environmentally sensitive response to changes in this pathway, and what exactly is the molecular mechanism that leads to this male sterility in the absence of this small RNA pathway.

Work in a separately funded project is examining if modulation of this pathway could be used to regulate pollen development in other crops, for the improvement of seed production and crop yield. The work is funded by the National Science Foundation.

Founded in 1998, the Donald Danforth Plant Science Center is a nonprofit research institute with a mission to improve the human condition through plant science. Research, education and outreach aim to have impact at the nexus of food security and the environment, and position the St. Louis region as a world center for plant science.

The center’s work is funded through competitive grants from many sources, including the National Institutes of Health, U.S. Department of Energy, National Science Foundation, and the Bill & Melinda Gates Foundation.

Source: Donald Danforth Plant Science Center, which is solely responsible for the information provided and is wholly owned by the source. Informa Business Media and all its subsidiaries are not responsible for any of the content contained in this information asset.

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