Researchers at the University of California, Riverside, USA, are engineering plants to consume acetate instead of sunlight, enabling food production without photosynthesis.

From Cell Press 24/10/24 (first released 23/10/24)

Prototype. Credit Feng Jiao

Photosynthesis, the chemical reaction that enables almost all life on Earth, is extremely inefficient at capturing energy—only around 1% of light energy that a plant absorbs is converted into chemical energy within the plant.

In a perspective paper publishing October 23 in the Cell Press journal Joule, bioengineers propose a radical new method of food production that they call “electro-agriculture.”

The method essentially replaces photosynthesis with a solar-powered chemical reaction that more efficiently converts CO2 into an organic molecule that plants would be genetically engineered to “eat.”

The researchers estimate that if all food in the US were produced using electro-agriculture, it would reduce the amount of land needed for agriculture by 94%.

The method could also be used to grow food in space.

“If we don’t need to grow plants with sunlight anymore, then we can decouple agriculture from the environment and grow food in indoor, controlled environments,” says corresponding author and biological engineer Robert Jinkerson (@JinkersonLab) of University of California, Riverside.

“I think that we need to move agriculture into the next phase of technology, and producing it in a controlled way that is decoupled from nature has to be the next step.”

Electro-agriculture would mean replacing agricultural fields with multi-story buildings.

Solar panels on or near the buildings would absorb the sun’s radiation, and this energy would power a chemical reaction between CO2 and water to produce acetate—a molecule similar to acetic acid, the main component in vinegar.

The acetate would then be used to feed plants that are grown hydroponically.

The method could also be used to grow other food-producing organisms, since acetate is naturally used by mushrooms, yeast, and algae.

“The whole point of this new process to try to boost the efficiency of photosynthesis,” says senior author Feng Jiao (@Jiao_Lab), an electrochemist at Washington University in St. Louis.

“Right now, we are at about 4% efficiency, which is already four times higher than for photosynthesis, and because everything is more efficient with this method, the CO2 footprint associated with the production of the food becomes much smaller.”

To genetically engineer acetate-eating plants, the researchers are taking advantage of a metabolic pathway that germinating plants use to break down food stored in their seeds.

This pathway is switched off once plants become capable of photosynthesis, but switching it back on would enable them to use acetate as a source of energy and carbon.

“We’re trying to turn this pathway back on in adult plants and reawaken their native ability to utilize acetate,” says Jinkerson.

“It’s analogous to lactose intolerance in humans—as babies we can digest lactose in milk, but for many people that pathway is turned off when they grow up. It’s kind of the same idea, only for plants.”

The team is focusing their initial research on tomatoes and lettuce but plan to move on to high-calorie staple crops such as cassava, sweet potatoes, and grain crops in future.

Currently, they’ve managed to engineer plants that can use acetate in addition to photosynthesis, but they ultimately aim to engineer plants that can obtain all of their necessary energy from acetate, meaning that they would not need any light themselves.

“For plants, we’re still in the research-and-development phase of trying to get them to utilize acetate as their carbon source, because plants have not evolved to grow this way, but we’re making progress,” says Jinkerson.

“Mushrooms and yeast and algae, however, can be grown like this today, so I think that those applications could be commercialized first, and plants will come later down the line.”

The researchers also plan to continue refining their method of acetate production to make the carbon-fixation system even more efficient.

“This is just the first step for this research, and I think there’s a hope that its efficiency and cost will be significantly improved in the near future,” says Jiao.

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