UNIVERSITY PARK, Pa. — Grubs are, well, gross.
Lack of "cute factor" aside, what athletic field managers, golf course superintendents and homeowners find most repulsive about these tiny beetle larvae is their voracious appetite for grass roots, and the insidious way they go about satisfying their craving, feeding below the surface, undetected for months.
The most detested of these is the offspring of the Japanese beetle, which can damage root systems so severely that turf can be rolled back like a carpet. The U.S. Department of Agriculture reports that losses attributable to this type of white grub come to $234 million per year, an amount that represents $156 million to replace damaged turf and $78 million for control costs.
Those control costs likely include the use of a neonicotinoid insecticide — imidacloprid — one of the most widely used insecticides in the world. While it has been a popular choice for curtailing the number of gluttonous grubs, in recent years it seems to be losing its effectiveness, and researchers in Penn State's College of Agricultural Sciences want to know why.
"We are hearing from the golf industry that it's becoming harder to control grubs, especially at sites that have used imidacloprid for years," said Andrew Huling, master's degree candidate in turfgrass entomology in the Department of Plant Science. "Since grubs spend about 10 months of their pre-adult life in the soil, they can cause a lot of damage if not controlled. We need to find a solution."
For this reason, Huling and his adviser, Ben McGraw, associate professor of turfgrass science, are halfway through a two-year field study on the residual activity of imidacloprid in turfgrass. Their research is taking place at the Joseph Valentine Turfgrass Research Center on the University Park campus, a facility Huling describes as "world class" when it comes to turfgrass research.
McGraw explained that neonicotinoids revolutionized white grub management because their lengthy residual activity meant they could be applied preventively — in advance of egg laying — which reduced the need to scout for, and potentially underestimate, pest presence.
"Andrew and I have both been really surprised to find that imidacloprid concentrations dramatically declined in soils collected from sites that used the active ingredient year after year," he said.
The duo have thoughts on why this might be happening. They speculate that cultural practices — such as thatch management — and microorganisms in the soil may reduce uptake and prematurely degrade the insecticide. To test these theories, Huling is currently conducting experiments under field conditions, which requires trapping thousands of beetles a day.
Using sections of 8-inch plastic pipe positioned in the ground, the researchers have created "mating arenas," each housing between 40 and 50 adult Japanese beetles. After the insects mate and the females lay their eggs in the soil, Huling sprays different concentrations of imidacloprid at different times. As soon as the grubs hatch, they begin feasting on the treated roots.
"After about a month, we remove soil cores and physically break them up and look for larvae while also measuring imidacloprid concentration within the root tissue," Huling said. "We are documenting the conditions that are the most effective — and least effective — in controlling grub populations."