Scientists are experimenting with new genetic modification technology that “supercharges” plants to enhance what they already excel at– sequestering carbon. As the world scrambles to find innovative mitigation solutions, plants have been doing what they quietly perfected over millions and millions of years ago– taking carbon from the atmosphere and converting it into carbohydrates, energy and oxygen.
A recent study shows one research institute’s promising progress on the quest to create a patented plant that grows deeper, cork-like roots that store 20 times more carbon than the average plant. The researchers believe these findings can eventually be applied to cash crops at a scale that can truly impact climate change.
Related: Scientists confirm tree planting is our best bet against climate change
The California-based Salk Institute is leading the way in what they call the Harnessing Plants Initiative. Their goal is to create an enhanced plant that not only stores more carbon but also yields an agricultural product that profits farmers and feeds people. Historically, genetic plant modification has been used to target and enhance specific traits within a plant, such as the size or taste of the fruit or its resistance to pests and disease. Now, Salk’s plant biologists are targeting specific hormones and genes that indicate and increase root biomass.
Deep dive: why deep roots matter
For centuries, farmers have recognized that deeper roots stabilize the soil and make trees and crops more resilient to heavy winds, floods, hurricanes and erosion. Deep roots also encourage drought resistance because they allow the plant to search for hard to reach water reserves that haven’t been dried out by the sun. But recently, deep roots have become coveted for their ability to sequester, store and stabilize carbon dioxide.
The carbon in roots is stored as a complex carbohydrate that is not easily broken down by soil microbes and therefore it is more stable storage than above ground plants, especially for plants that are frequently harvested.
The idea behind deep roots is actually very logical– deeper roots store the carbon further from the place we are trying to keep it away from– the atmosphere.
Although plants have always sequestered carbon, they can no longer keep up with the rate that humans are pumping it into the atmosphere– at least not naturally. Globally, people emit 37 billion tons of carbon dioxide every year and plants can only capture about half.
The idea, according the Salk’s plant biologist, Wolfgang Busch, is to “store carbon in parts of the soil where the carbon is more stable. Change the biochemistry, increase the stability. We’re not trying to get plants to do something they don’t normally do,” says Busch. “We’re just trying to increase the efficiency. Then we can use that to mitigate climate change.”
Joanne Chory, also a plant biologist at the Salk Institute echoed Busch’s explanation in an interview with Foreign Policy News. “All we have to do is make them about 2 percent more efficient at redistributing carbon than they are right now, and we can effect a global change,” said Chory.
The Salk Ideal Plant
Wolfgang Busch, Chory and their team of plant biologists at the Salk Institute recently published their preliminary findings in Cell. Their research focused on a test plant – the thale cress – where they experimented with root hormones and a specific gene found to control the shape of roots.
The science behind it: hormones and genes
The hormone auxin is the most important hormone that dictates root growth. The biologists at Salk, however, also identified a gene – EXOCYST70A3 – that controls the shape and extent of roots by monitoring how much of the auxin hormone is released. By identifying and isolating these findings, the researchers can now control the size and direction of the roots in their test plants. The EXOCYST70A3 gene is present in all plants, so their research is profoundly scalable if applied to the world’s top grown crops. Indeed, Salk intends to apply their findings to corn, soy, rice, wheat, cotton and rapeseed (canola).
Salk’s secret sauce: suberin
But the researchers didn’t stop at isolating the hormone and gene, they also identified a specific substance to modify and replicate based on its benefits. According to their website, their ‘secret sauce’ is a substance called suberin. Suberin is a cork material that is carbon-rich, found naturally in plants and resistant to decomposition. It enhances soil, but is also one of the best (meaning most stable) storage vessels for carbon dioxide. Salk’s patented plant, The Ideal Plant, will maximize suberin within its roots. Ultimately, their plants will increase root biomass that is both deeper and higher in suberin.
But aren’t GMOs bad for the environment?
There is a lot of controversy surrounding genetically modified organisms, including their potentially harmful impacts on human health, ecosystems and farmers’ livelihoods. However, GMO proponents believe they are the answer to feeding the world’s growing population and increasing resilience against a rapidly changing environment. For the Salk Institute, GMO nay-sayers, like the European Union and India, aren’t their biggest concern. Their research continues (and receives millions of dollars of investment) for expected implementation in places where GMOs are not banned.
In order to reach their goal of using the Salk Ideal Plant to store half of the carbon that humans emit every year, the researchers claim they would need their patented product in six percent of the world’s agriculturally productive land. While there are natural ways of cross breeding to reach similar results, it would take considerably longer and there simply isn’t enough time.
The climate clock is ticking
The Salk Institute’s recently published study holds promising breakthroughs, but they are still not ready with a usable product and time is running out. Environmental experts agree that drastic action needs to be taken to mitigate greenhouse gases, so the best time to start planting the yet-to-be-designed Ideal Plant was years ago.
Via Vice
Images via Salk Institute
