Agriculture Committee on Feb. 7th, 2011

The types of studies you are referring to have been done historically. This is where I go back to square one: understand biology. If the plants are self-pollinated, you're going to have a different buffer zone than if they were cross-pollinated by bees. The zone for alfalfa will not be the same as the one for flax.

We've just interviewed people who seem to have a done a lot of work on this in the flax industry, and it's stimulated by the whole transgenic issue. It looks as if 40 metres would be a barrier for flax. It may be a little bit bigger for alfalfa, because you have to understand the biology of the bees and how far pollen is going to transfer. It may depend on whether you use honey bees or leafcutter bees. It's basically a science question; once that question is understood, you can come up with reasonable guidelines that will create isolations that are a compromise position for everyone.

Those are very good comments. Again, it's the tolerance issue.

To give another analogy, I'm growing a Genuity Roundup Ready canola. Let's say I have a grower beside me who's using some new form of whatever, and that species ends up being a plant on my side of the fence that current herbicides can't control. I can name you a few that are minor crops. Should we also tell him that the dill or the new camomile cannot be grown in my rural municipality because he can contaminate me as much as he will be? It all goes back to tolerance, and zero is not an option.

I can address it.

When we are doing public sector research, we start with a bright idea. We write a proposal describing that idea. It's evaluated by a public body. Typically it is also evaluated by other scientists to see whether it's a sensible idea. Then we get the funding, or we don't.

A private corporation, a private company, may know our expertise and ask us to answer a question for them, or they may ask us to work with them to develop an answer for a problem they have. In those cases, you work with them to decide the budget and how much work you can do. You tell them what you want to do and what it would cost, and they tell you whether they can afford to fund the research.

Let me give you an example from my own research. I deal with a firm for artificial insemination. I started looking at molecules in the sperm membrane to see how they would affect the sperm's recognition of the egg. That's basic, fundamental, discovery-level research. There are companies that sell semen for dairy bulls or for pigs or chickens. They thought they would like to be able to protect their sperm so that they could freeze that semen and use it for inseminating their females. I worked with the companies to look at ways to adapt the information I had from my basic research to better protect the sperm for freezing and thawing and to develop freezing and thawing methods for them.

That's the difference. If I hadn't done the basic research, I couldn't have developed the application, and the corporations wouldn't have been interested, and sometimes companies aren't interested anyhow. Sometimes they want to pay you just to answer a specific question for them, such as whether a machine works or not.

You can go to corporations, and the best operations we have in Canada are those partnerships through which we work with a company in partnership with a federal agency and get extra money into the private sector that will enable them to develop new products, make them more profitable, and benefit the overall Canadian industry. In these federal-public partnerships Canada does exceptionally well--much better than the U.S., according to my U.S. colleagues.

In my case, we've never been able to attract much money from companies. Because it was a small crop--peas and lentils--nobody was prepared to invest. However, we had some forward-thinking farmers who set up an organization. They taxed themselves and put the checkoff dollars into genetics. To date they've probably spent 50% of their research money on genetics. In exchange, we gave them the commercialization rights to all the genetics. That has created a different scenario, which is maybe unique. Maybe asparagus has the same thing, but in the grain industry, this is unique on a global scale.

When the issue of herbicide tolerance came in, transgenics was a difficult thing for our traders. We started on transgenics, but we stopped because of this difficulty. We did it for about three years. We were able to do it, but instead we went in favour of something that was basically mutation-based. We knew that a variation existed for herbicide tolerance in the natural population, so we were able to develop herbicide-tolerant lentils. In that case, we came to an arrangement with the corporation, so now we, together with the farmers and the corporation, are partners in this. In fact, we receive royalties, but not on seed. We receive them on herbicide use.

There are many creative ways to do things if you understand biology and have willing partners.

Yes. If we understand where the gene is, we can then go through the natural process of hybridizing. Without hybridizing, none of us would be here. In that case, what it allows us to do genomically is just to track the fate of the genes. For a very low cost, we can find out which progeny of the genetic strains we want to select. We can find out which ones are carrying the genes we want.

Well, the best example is canola, if I may go back again to the canola industry.

There are three different types of herbicide tolerance, we'll call it, within the systems. The one, as Mr. Vandenberg said, is using a mutagenesis-type system, and the other two are using the traditional insertion of the gene into that plant. The two genes that are inserted into the plant are based on a cell's ability to metabolize ammonia. That's how it was discovered: in rinsing out the vats of a winery, they saw the mould wouldn't die, so they took it to the lab to find out why ammonia wouldn't kill it and they put it into the plant.

The other one was in a water purifier. They found out that it didn't do a very good job of purifying water, but in fact killed anything that photosynthesized. I grow those three types of canola on my farm. If you crush them into oil and put the oil in a canola oil jar and take it from the Loblaws or whatever to a lab, you would not be able to tell one bit of difference as to which one came from which one. Both are bringing in a new event, but it's within the plant. You would not tell any—

As well, if you had an organic oil or a totally conventional oil from Europe in that same bottle and took it to the lab, you would not be able to tell which one is which. They are all canola oil.

Go ahead. There are vaccines.

Most pharmaceutical compounds today are examples of genetically engineered products that they will not only ingest, but inject.

Any vaccine given to either an animal or a human today is a biotech product.

You'll see more of that.

I might have the number wrong, but I think that GM soy, in North America anyway, is found in about 40% of processed foods that you buy. Soy is prevalent in any kind of processed food that you buy, and there are no problems.