Breakthrough research offers new source of nitrogen for farmers

A scientist at Pivot Bio scraping corn roots to measure the colonization of Pivot Bio's nitrogen producing microbe.

Peer-reviewed research published in Scientific Reports describes a new technology that could revolutionize a century-old approach to providing nitrogen to crops.

The study, by a collaboration of researchers from the University of Wisconsin-Madison, Purdue University, and Pivot Bio, a sustainable agriculture company, presented first-of-its-kind evidence showing how gene-editing enhances microbes’ ability to fix atmospheric nitrogen and transfer it to cereal crops.

Using isotopically labelled nitrogen, researchers traced nitrogen in the air to chlorophyll in corn leaves, providing evidence that it was fixed from the air by the gene-edited microbes. Field studies also showed that these microbes could fix and supply nitrogen comparable to up to 40 pounds of synthetic nitrogen fertilizer with similar yields.

Improving the effectiveness of nitrogen fertilizers has been a long-standing challenge. “The core issue,” said Bruno Basso, a professor of environmental science at Michigan State University, who was not involved in the study, “is that the soil-plant-atmosphere system is extremely complex.”

Unpredictable weather makes it difficult to match nutrient supply to plants’ demand, and to determine precisely how much nitrogen a crop will require and whether the nutrient will remain in the soil.

“My research lab has spent years helping farmers, using advanced sensing technology and computer models to help them better understand their fields and use nitrogen fertilizer more efficiently to increase profit and reduce environmental impact, such as nutrient losses to groundwater and greenhouse gas emissions to the atmosphere,” Basso said.

Diazotrophs, special types of bacteria that occur in nature, have a unique ability to turn atmospheric nitrogen gas into ammonium, the building block of amino acids and proteins. This process, commonly known as biological nitrogen fixation (BNF), was the main form of nitrogen nutrition for crops for thousands of years before synthetic nitrogen fertilizer was invented.

“Native soil diazotrophs lose their ability to perform BNF when exposed to high concentrations of nitrogen in the soil for extended periods of time. This is an evolutionary response to conserve energy because BNF is a very energy-intensive process,” said Jean-Michel Ané, professor of bacteriology and plant and agroecosystem sciences at the University of Wisconsin-Madison, a co-author of the study.

“We need to convince these bacteria to maintain high levels of BNF in environments with lots of nitrogen, such as synthetically fertilized soils.”

Researchers at Pivot Bio developed gene-edited microbes using non-transgenic methods to enable diazotrophs to continue providing nitrogen to the crop even under high nitrogen conditions.

“With the gene edits, we blind microbes to the presence of nitrogen in their surroundings, so they continue to fix ammonium, delivering it directly on the root system,” said Karsten Temme, chief innovation officer and co-founder at Pivot Bio and a co-author of the paper.

“We also introduced other edits to ensure the bacteria can transfer the fixed nitrogen to the crop instead of keeping it for itself.”

The paper presents evidence of this process happening in the lab and field test plots. It is also the first peer-reviewed paper covering PROVEN® 40, Pivot Bio’s second-generation commercial product for corn containing gene-edited nitrogen-fixing microbes.

“Nitrogen fertilizer is arguably the most significant invention of the past century and will be essential to the world’s development and food security for the foreseeable future. However, we believe it can be used better,” Temme said.

“Pivot Bio’s focus is on improving the productivity of farming by increasing the efficiency of nitrogen with our gene-edited microbes and reducing losses of synthetic fertilizer to the environment.”

In the field, the researchers used a variety of isotopic experiments to again demonstrate nitrogen fixation, this time under real-world conditions, and quantify the nitrogen levels in the plant. They also collected hundreds of samples from farmers who reduced nitrogen fertilizer rate by 35 to 40 pounds of nitrogen per acre, replacing it with Pivot Bio’s PROVEN 40. On average, researchers found plants treated with PROVEN 40 had higher nitrogen levels early in the season and no negative impacts on yield, even though they had received less synthetic fertilizer.

“It is very hard to keep track of nitrogen as it moves from the air to the microbe and then to the plant. We rely on the isotopic signatures of nitrogen atoms coming from the air versus those in the soil,” Ané said.

With these measurements, researchers detected isotopically labeled nitrogen in the chlorophyll of corn leaves in the lab, a sign that microbes supplied that nitrogen to the plant.

“This extensive research is promising because it means that farmers can start reducing nitrogen fertilizer without compromising productivity: a win-win for the farmer and the environment,” Temme said.

“This is very exciting because the technology is highly scalable. Our products have already been used on over 13m acres in the US since their commercial launch five years ago, which translates into real impact.”

Basso concluded: “If this technology continues to improve and deliver more nitrogen to crops, and they show this translates to reductions of environmental pollution and the overall agricultural carbon footprint, it could be a game changer for nitrogen management. The more we replace synthetic fertilizer for more efficient and sustainable sources of nitrogen to support crop yield, the better is for farmers, communities and the environment.”

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Jim Cornall is editor of Future Food Today and publisher at Ayr Coastal Media. He is an award-winning writer, editor, photographer, broadcaster, designer and author. Contact Jim here.