One “extreme” plant that has evolved to handle, or even thrive, in harsh conditions could help researchers engineer climate-resistant crops.
When faced with conditions that are too dry, salty, or cold, most plants try to conserve resources. They send out fewer leaves and roots and close up their pores to hold in water. If circumstances don’t improve, they eventually die.
But some plants, known as extremophytes, have evolved to handle harsh environments.
Schrenkiella parvula, a scraggly, branching member of the mustard family, doesn’t just survive in conditions that would kill most plants—it thrives in them. It grows along the shores of Lake Tuz in Turkey, where salt concentrations in the water can be six times higher than in the ocean.
As reported in Nature Plants, researchers found that Schrenkiella parvula actually grows faster under these stressful conditions.
“Most plants produce a stress hormone that acts like a stop signal for growth,” says senior author José Dinneny, an associate professor of biology at Stanford University. “But in this extremophyte, it’s a green light. The plant accelerates its growth in response to this stress hormone.”
Dinneny and his colleagues are studying Schrenkiella parvula to better understand how some plants cope with challenging conditions. Their findings could help scientists engineer crops that are able to grow in lower-quality soil and adapt to the stresses of climate change.
“With climate change, we can’t expect the environment to stay the same,” says lead author Ying Sun, a postdoctoral researcher at the Salk Institute who earned her doctorate at Stanford. “Our crops are going to have to adapt to these rapidly changing conditions. If we can understand the mechanisms that plants use to tolerate stress, we can help them do it better and faster.”
Extreme plants speed growing
Schrenkiella parvula is a member of the Brassicaceae family, which contains cabbage, broccoli, turnips, and other important food crops. In areas where climate change is expected to increase the duration and intensity of droughts, it would be valuable if these crops were able to weather or even thrive in those dry spells.
When plants encounter dry, salty, or cold conditions—all of which create water-related stress—they produce a hormone called abscisic acid, or ABA. This hormone activates specific genes, essentially telling the plant how to respond. The researchers examined how several plants in the Brassicaceae family, including Schrenkiella parvula, responded to ABA. While the other plants’ growth slowed or stopped, the roots of Schrenkiella parvula grew significantly faster.
Schrenkiella parvula is closely related to the other plants in the study and has a very similar-sized genome, but ABA is activating different sections of its genetic code to create a completely different behavior.
“That rewiring of that network explains, at least partially, why we’re getting these different growth responses in stress-tolerant species,” Dinneny says.
Extreme plants ‘secret sauce’
Understanding this stress response—and how to engineer it in other species—could help more than just food crops, Dinneny says. Schrenkiella parvula is also related to several oilseed species that have the potential to be engineered and used as sustainable sources of jet fuel or other biofuels. If these plants can be adapted to grow in harsher environmental conditions, there would be more land available for cultivating them.
“You want to be growing bioenergy crops on land that is not suitable for growing food—say, an agricultural field that has degraded soil or has accumulated salinity because of improper irrigation,” Dinneny says. “These areas are not prime agricultural real estate, but land that would be abandoned otherwise.”
Dinneny and his colleagues are continuing to investigate the network of responses that could help plants survive in extreme conditions. Now that they have an idea of how Schrenkiella parvula sustains its growth in the face of limited water and high salinity, they will try to engineer related plants to be able to do the same by tweaking which genes are activated by ABA.
“We’re trying to understand what the secret sauce is for these plant species—what allows them to grow in these unique environments, and how we can use this knowledge to engineer specific traits in our crops,” Dinneny says.
Additional coauthors are from Louisiana State University, the Salk Institute for Biological Studies, and Stanford.
The US Department of Energy, the Carnegie Institution for Science, the National Science Foundation, the Rural Development Association of South Korea, and the HHMI-Simons Faculty Scholars program funded the work.
Source: Stanford University
