Not long after Calyxt moved into its shiny new steel and glass headquarters on the outskirts of Minneapolis last summer, someone pulled her car into its freshly poured parking lot and headed for the biotech firm’s front door. She caught the company’s chief science officer, Dan Voytas, as he was leaving. “Um, is this a medical marijuana facility?” she asked, her eyes drifting to the rows of greenhouses at the back of the property and the high fences surrounding them. No, they weren’t growing pot. They were growing something at once even more revolutionary and perhaps more controversial: gene-edited food crops.

Farmers and breeders have been manipulating the DNA of the plants humans eat for millennia. But with powerful new gene-editing technologies developed over the last five years, scientists can now add or subtract plant genes with unprecedented precision and speed—leaving first-generation GMOs, along with their stigma and burdensome regulations, in the dust. Companies big and small have adopted the technology to make products as disparate as climate change-resistant cacao and extra-starchy corn for adhesives. But last month Calyxt became the first to commercially debut a gene-edited food, a soybean oil it claims to have made healthier.

Shoppers can’t yet buy the oil, a product of soybean plants that have been edited to produce fewer saturated fats and zero trans fats, but Calyxt’s CEO Jim Blome says people are already eating it. The company’s first client—a restaurant with multiple locations in the Midwest—has begun using the oil to fry, make sauces, and dress salads, as the Associated Press reported last week. Calyxt describes its oil as having the heart-healthy fat profile of olive oil without its strong, sometimes grassy flavor. Whether that’s something customers want remains to be seen. But Calyno, as the oil is known, marks an important moment in the long human history of messing with plant DNA. It signals the official arrival of foods that have been genetically altered not solely to make farmers' lives easier, but to make consumers’ tummies (and hearts and other organs) happier.

“Right now the food industry solves all its problems through processing or chemistry,” says Voytas. “We’d like to do it through genetics and gene-editing.” In addition to its soybean oil, Calyxt is working on wheats with more fiber and less gluten and potatoes that can safely be put in cold storage without accumulating sugars that catalyze into cancer-causing chemicals when cooked at high temperatures. (That’s a thing that actually happens.)

The company is also working on developing traits useful to farmers too. When I visited Calyxt last August, rows of alfalfa plants had just been moved from the greenhouses to test plots outside to make way for herbicide-resistant soy and canola. But those are in much earlier stages of development. What Calyxt is really trying to do, according to Voytas, is make it easier for people to have a healthy diet without giving up the foods they like. “We’d like a piece of Wonder Bread to meet all your daily requirements of fiber,” he adds.

Engineering these novel nutritional attributes starts on the top floor of the Calyxt lab, where its scientists design gene-editing molecules on computer screens and then have pipetting robots build them. The most well-known gene editor is Crispr, but Calyxt uses a different set of DNA-cutting enzymes called TALENs. In 2010, Voytas co-invented the method in his plant genetics lab at the University of Minnesota, where he still spends some of his time. For a few years, he and his grad students were busy making TALENs for other researchers who wanted to supercharge their plant gene-tinkering toolbox. “Then Crispr came along and you didn’t really need the Voytas lab anymore,” he says.

LEARN MORE The WIRED Guide to Crispr

By then, though, he had taken his tech to the French biotechnology firm Cellectis and been installed as chief scientist of its new plant engineering division. Calyxt, as that company is known today, has about 50 employees. Many of them are scientists who work down in the sterile plant-tissue culture labs. There they sort seeds, transfer embryonic plant cells to agar-filled petri dishes, and deliver the custom-designed TALENs. Then they douse the cells in root- and leaf-stimulating hormones and let them grow until they become big enough to punch out a bit of leaf material to sequence and see if the right edit was made.