Login

GPC Members Login
If you have any problems or have forgotten your login please contact [email protected]


Superweed resists another class of herbicides

We’ve all heard about bacteria that are becoming resistant to multiple types of antibiotics. These are the so-called superbugs perplexing and panicking medical science. The plant analogue may just be waterhemp, a broadleaf weed common to corn and soybean fields across the Midwest. With resistance to multiple common herbicides, waterhemp is getting much harder to kill.

In a new study from the University of Illinois, scientists document waterhemp’s resistance to yet another class of herbicides, known as Group 15s. The study provides the first documentation of a non-grass plant to be resistant to Group 15 herbicides.

There are many herbicides on the market, but they all fall into one of 16 classes describing their mode of action (MOA), or specific target in the plant that the chemical attacks. Because of various regulations and biological realities, a smaller number of herbicide MOAs can be used on any given crop and the suite of weeds that goes along with it. Historically, about nine have been useful for waterhemp – and now the weed appears to be resistant to at least seven.

“In some areas, we’re one or two MOAs away from completely losing chemical control of waterhemp and other multiple-herbicide-resistant weeds,” says Adam Davis, head of the Department of Crop Sciences at Illinois and co-author on the study. “And there are no new herbicide MOAs coming out. There haven’t been for 30 years.”

Illinois weed scientist and co-author Aaron Hager adds, “We don’t want to panic people, but farmers need to be aware this is real. It continues on with the challenges we’ve warned people about for years.”

The research team tested the effectiveness of soil-applied Group 15 herbicides in a Champaign County population already resistant to five MOAs. They applied eight Group 15 formulations in the field at their label rates, and chose three – non-encapsulated acetochlor (Harness), S-metolachlor (Dual Magnum), and pyroxasulfone (Zidua) – for a rate-titration experiment in which the herbicides were applied at one-half, one, two, and four times the label rate.

The eight Group 15 products varied in their effectiveness, with encapsulated acetochlor (Warrant), S-metolachlor, metolachlor (Stalwart), and dimethenamid-P (Outlook) performing the worst. These products provided less than 25% control 28 days after application and less than 6% control 14 days later.

Of the rate-titration experiment, Hager says, “We found we could apply significantly higher than the labeled dose and still see resistance.” For example, S-metolachlor provided only 10% control at the standard label rate, 20% at 2x the label rate, and 45% at 4x the label rate.

Hager says farmers might not notice the poor performance of these soil-applied pre-emergence herbicides because waterhemp germinates continuously throughout the season. When a weed pops up mid-season, it’s hard to tell exactly when it emerged and whether it was exposed to residual soil-applied herbicides.

“If you think about how you use these products, rarely do they last the entire year. They’re very dependent on environmental conditions to work effectively. It could be too wet or too dry. Generally speaking, you have some weed escape. But many farmers would chalk it up to these weather issues. If you’re not thinking about it, you could very easily overlook resistance,” Hager says.

To confirm results from the field, the team performed a dose response test in the greenhouse. In that test, four waterhemp populations – three with resistance to multiple herbicides and one that is sensitive to all herbicides – were dosed with increasing levels of S-metolachlor, acetochlor, dimethenamid-P, and pyroxasulfone. Populations from Champaign County and McLean County survived higher levels of the Group 15 herbicides than the other populations.

Hager suspects the plants are breaking the chemicals down before they cause damage, a trick known as metabolic resistance. All organisms can turn on cellular defenses against toxins, but it is rather worrisome when weeds and other undesirable pests use their biology against human interventions.

“As we get into the era of metabolic resistance, our predictability is virtually zero. We have no idea what these populations are resistant to until we get them under controlled conditions,” Hager says. “It’s just another example of how we need a more integrated system, rather than relying on chemistry only. We can still use the chemistry, but have to do something in addition.

“We want farmers to understand that we have to rethink how we manage waterhemp long term.”

Read the paper: Weed Science

Article source: University of Illinois

Image: Aaron Hager with waterhemp. Photo by L. Brian Stauffer

News

Scientists transform tobacco info factory for high-value proteins

For thousands of years, plants have produced food for humans, but with genetic tweaks, they can also manufacture proteins like Ebola vaccines, antibodies to combat a range of conditions, and now, cellulase that is used in food processing and to break down crop waste to create biofuel. In Nature Plants, a team from Cornell University and the University of Illinois announced that crops can cheaply manufacture proteins inside their cellular power plants called chloroplasts—allowing the crops to be grown widely in fields rather than restrictive greenhouses—with no cost to yield.


Climate change could affect symbiotic relationships between microorganisms and trees

Some fungi and bacteria live in close association, or symbiosis, with tree roots in forest soil to obtain mutual benefits. The microorganisms help trees access water and nutrients from the atmosphere or soil, sequester carbon, and withstand the effects of climate change. In exchange, they receive carbohydrates, which are essential to their development and are produced by the trees during photosynthesis.


Aggressive, non-native wetland plants squelch species richness more than dominant natives do

Dominant, non-native plants reduce wetland biodiversity and abundance more than native plants do, researchers report in the journal Ecology Letters. Even native plants that dominate wetland landscapes play better with others, the team found.