Page 1 Page 2 Page 3 Page 4 Page 5 Page 6 Page 7 Page 8 Page 9 Page 10 Page 11 Page 12 Page 13 Page 14 Page 15 Page 16 Page 17 Page 18 Page 19 Page 20 Page 21 Page 22 Page 23 Page 24 Page 25 Page 26 Page 27 Page 28 Page 29 Page 30 Page 31 Page 32 Page 33 Page 34 Page 35 Page 36 Page 37 Page 38 Page 39 Page 40 Page 41 Page 42 Page 43 Page 44 Page 45 Page 46 Page 47 Page 48 Page 49 Page 50 Page 51 Page 5248 Plant breeders have an exciting new tool at their disposal called gene editing. It’s not new anymore, having been around at least five years. It’s really just a suite of technologies that allows us to modify a gene in a desired fashion. We hear about it now on morning shows, as the public becomes more aware of it and tools like CRISPR/Cas9 become more mainstream. The public seems relatively comfortable with new gene editing tools being used on plants. It doesn’t carry the stigma that the acronym “GM” carries with it. Although CRISPR/Cas9 is a natural system for bacteria to fend off viruses, which can sound scary, on a plant side it simply takes advantage of DNA repair mechanisms. The difference between gene editing and GM is gene editing is a very targeted modification. We’re tweaking a specific gene, not inserting a new one. In people’s minds, it’s not as scary a technology as GM, as nature modifies genes all the time. What we get from gene editing is the same result you would get from classical plant breeding. We can improve traits in a highly efficient manner now. This is crucial in plant breeding, where you don’t have the genetic variation found in nature. Canadian scientists have painstakingly created wheat germplasm to try and find disease-resistant genes for stem and leaf rusts, endemic in Western Canada. We may now be able to use gene editing to create broad genetic resistance in wheat to protect against a range of diseases. After proof of concept in lettuce for downy mildew, this is exactly what a team of research- ers at the University of California, Davis, is working on. Gene editing technology is a game changer, and one of the most important technologies for breeders. A public scientist in general will not release a standard GM product due to the cost of regulation, liability and trade barriers. CRISPR is a huge opportunity for everyone. Still, activist groups have a loud voice, especially on social media, and it’s easy to scare people without data. Scientists New Breeding Tools, New Opportunities are limited to data, but so many of these advocacy groups are not. They can say whatever they like. Reports from the National Academy of Sciences have again proven that DNA technology is perfectly safe. Plant breeding itself is a filter that ensures safety. Anything that goes through the plant breeding process — whether it’s GM, gene editing, crosses from wild species, you name it — goes through many trials across locations and years before being released. This ensures it grows well and has the adaptability, disease resistances, yield and quality farmers want, and the quali- ties prized by processors and consumers. People choose with their wallets. Seed companies and public scientists and breeders know if you put a variety out that won’t grow well, you won’t be in business too long. Focus on Values Still, this message is not getting out to the public. I grew up on a small farm in Manitoba. I’ve been in agriculture since I was born. I used to think the key to solving this problem was about education. That’s part of it, but it’s really a matter of making it personal — just like activist groups do so well. Scientists need to ask people what matters to them. Is it fewer pesticides? More nutritious food? Affordable food? Find out what they care about, and explain how plant breeding con- tributes to that, as it has for generations. Showing them stud- ies and trying to explain the technology alone is not enough. Influencing the public will, of course, influence regulators. Canada has a huge advantage over other nations in that it truly doesn’t regulate the breeding process, but rather the product itself. We have a truly logical process, but there are many forces at work trying to change this. For trade to work best, we need a harmonious regulatory system. If everyone would adopt and objectively implement the Canadian system, there would be a lot more great things happening in plant breeding as far as products coming out, and everyone could use the tools to help create them. Allen Van Deynze, director of research at the Seed Biotechnology Center and associate director of the Plant Breeding Center at the University of California, Davis.