Texas A&M Entomology Research Network

Extension News

Corn Rootworm Control Project Showing Success in New York and Texas Corn Fields

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Extension Entomologist Dr. Pat porter notes that persistent entomopathogenic nematodes have remained effective for many years in New York after just one application, and our data from Texas suggest that will be the case here. While initially deployed for corn rootworm control, this technology shows promise for some of our other serious soil-dwelling pests like grubs in wheat and wireworms in several crops.

Our research on these pests is in the planning stages. Also, the whitefringed beetle is a major pest of alfalfa in New Mexico and we are working with New Mexico State University to investigate control with nematodes. This will likely be successful since whitefringed beetle is a relative of the beetle in New York alfalfa that has been brought under control with this same nematode technology.

The corn rootworm control project has opened the door to potential low cost, successful biological control in other crops. In corn it has given us a third line of defense against corn rootworm after Bt transgenic crops and soil applied insecticides.

John Thobe Named IPM Agent for Bailey, Castro, Parmer Counties

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Excerpted from an AgriLife Today story by Susan Himes

John Thobe headshotThe Department of Entomology and Texas A&M AgriLife Extension Service welcomes Dr. John Thobe as the new integrated pest management agent for Bailey, Castro and Parmer counties.

Thobe earned his bachelor’s degree in plant soil and environmental sciences from West Texas A&M University, Canyon.

“We are excited to welcome John to AgriLife Extension,” said Clawson. “Between his education and past professional experience, he will be a great addition to the integrated pest management team.”

Thobe most recently worked as a location manager for Sooner Co-op in Enid, Oklahoma. Prior to that he was a seed technician. While a student at West Texas A&M University, Thobe worked for AgriLife Extension in Bushland.

“I wanted to be a part of Texas A&M AgriLife Extension to provide an unbiased opinion that producers can turn to when they need an up-to-date source of information,” said Thobe. “I will strive to be the first phone call producers make when a new pest, disease pressure or variety change comes their way.”

A Prickly Situation

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Cactus moth now in Texas, eating prickly pear cactus, a vital weed needed by livestock during drought  

by Dr. Mike Merchant, Professor and Extension Entomologist, Texas A&M AgriLife Extension Service

Initial point of entry by Cactoblastis, and hollowed-out pad, is evident in this backlighted photo of an Opuntia cactus. Photo courtesy Larry Gilbert.
Initial point of entry by Cactoblastis, and hollowed-out pad, is evident in this backlighted photo of an Opuntia cactus. Photo courtesy Larry Gilbert.

Prickly pear cactus has its detractors.  Long hated for its clusters of barbed spines, or glochids, that are difficult to remove, it has been cursed, hacked, burned and sprayed.

But prickly pear is also used by a variety of wildlife and cattle and is prized as a part of the Mexican-American diet. There is even a small industry devoted to rearing insects, called cochineal scale, that feed exclusively on prickly pear. These scales produce a vivid red dye, called cochineal or carmine, sometimes used as a natural coloring agent in cosmetics and beverages.

Prickly pear invaders

Unfortunately, a small moth called Cactoblastis cactorum, or cactus moth, poses a new threat to the ecological stability of prickly pear in Texas. The cactus moth is a predator of prickly pear in its native home of Argentina. It was distributed by humans into the Caribbean in 1959. Since then, it has expanded its territory slowly through Cuba and Florida, and most recently Louisiana and Texas.

The reliable weed

There are over 100 species of prickly pear native to the Americas, and most are not considered pests. Though ranchers may curse prickly pears as “weeds,” they also rely on them to provide emergency food for cattle during times of drought. In addition, many insect and vertebrate species rely on different kinds of prickly pears for food and shelter. Despite our sometimes love-hate relationship, many Texans view the various prickly pear species as valuable native plants.

Cactus moth now found in Texas

The bad news is that cactus moth has now become established and is spreading in Texas. According to reports, the moth appears to have leapfrogged over the Houston area into Brazoria County and is now established as far south as Mad Island, east of Victoria.  According to Robert Vines’ book, Trees, Shrubs and Woody Vines of the Southwest, over 50 native species of prickly pear can be found in Texas and surrounding states. It is not certain how many of these species might ultimately be affected by the new insect invader.

The problem with invasive species is that natural control agents are often left behind in their country of origin.  When this occurs, the invading species is free of ecological restraints to reproduction.  This seems to be the case with the cactus moth. Its impact on prickly pear is much worse here than in its native home.

Entomologists hope that a tiny Argentine wasp, Apanteles opuntiarum, might be enlisted in the struggle to preserve native prickly pear. The wasp parasitizes its host by inserting eggs into the body of the caterpillar with its long ovipositor. The wasp eggs then hatch and begin devouring the caterpillar from the inside. Research is being conducted to learn how to rear this tiny parasitic wasp and learn whether it might be safe to release into Texas.

Ultimately, if the cactus moth continues to spread, it could have an effect on ornamental cacti grown by Texas gardeners. Of course, for gardeners there are a variety of insecticides that can be sprayed on cacti, but who wants to have to do that? Let’s hope that the Argentine wasp can come to the rescue and tip the scales in the favor of the cactus.

For the original article, visit Insects in the City.

Kaufman named head of Department of Entomology, effective July 1

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Phillip Kaufman joins Texas A&M as the head of the Department of Entomology in the College of Agriculture and Life Sciences.
Phillip Kaufman joins Texas A&M as the head of the Department of Entomology in the College of Agriculture and Life Sciences.

Phillip Kaufman, Ph.D., will begin his appointment as head of the Department of Entomology at Texas A&M University, starting July 1.

Kaufman joins Texas A&M from the University of Florida where he served as a professor in the Entomology and Nematology Department in the Institute of Food and Agricultural Sciences. During his 15 years at the university, he helped develop and implement research programs to support Florida livestock producers, taught courses on medical and veterinary entomology and forensic entomology, as well as provided support to Florida Extension faculty and livestock and companion animal stakeholders.

Kaufman’s appointment will include responsibilities in both administration and research. He aims to foster success in both basic and applied research with a plan to continue his own research in addressing current threats and evaluating potential threats to livestock.

“I am very excited to be joining the department’s world-class faculty,” he said. “I believe that it is a department head’s charge to foster faculty and staff professional development, and I look forward to working with everyone in our department to ensure that they feel they are appreciated and have every opportunity to be successful.”

With facilitating an environment where faculty may explore new, cutting-edge research avenues that improve the lives of Texans, Kaufman will also be seeking opportunities for global reach, he explained.

“I want faculty to feel confident in looking in new directions, experimenting with new techniques and areas of interest, so that they can offer the students that we are teaching at Texas A&M the opportunity to be at the forefront of scientific discovery,” he said.

“Dr. Kaufman’s background and experience in research, teaching and Extension will benefit the Department of Entomology and the College of Agriculture and Life Sciences,” said Patrick J. Stover, Ph.D., vice chancellor of Texas A&M AgriLife, dean of the College of Agriculture and Life Sciences and director of Texas A&M AgriLife Research. “I look forward to his leadership of the department and the contributions he will make in this new role. I would also like to thank Dr. Pete Teel for his service as interim department head during the last year.”

Kaufman was awarded the Lifetime Achievement Award in Veterinary Entomology in 2014 at the 58th Annual Livestock Insect Workers’ Conference, and the Illinois 4-H Alumni of the Year award in 2013 by the Illinois 4-H Foundation. He earned his bachelor’s degree in animal sciences from the University of Illinois, his master’s degree in entomology from the University of Wisconsin and his doctorate in plant, soil and insect sciences at the University of Wyoming.

Research looks to beneficial insects for pest control

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by Adam Russell, Texas A&M AgriLife Communications

Predator insects could reduce pesticide use in commercial production

Erfan Vafaie, Texas A&M AgriLife Extension Service entomologist, Overton, holds a vile filled with whiteflies captured during a trial focused on the use of beneficial insects to control whitefly populations. (Texas A&M AgriLife Extension Service photo by Adam Russell)
Erfan Vafaie, Texas A&M AgriLife Extension Service entomologist, Overton, holds a vial filled with whiteflies captured during a trial focused on the use of beneficial insects to control whitefly populations. (Texas A&M AgriLife Extension Service photo by Adam Russell)

A Texas A&M AgriLife Extension Service entomologist is studying how a combination of beneficial insects can help control the pests in greenhouses.

Erfan Vafaie, AgriLife Extension program specialist in Integrated Pest Management, Overton, just wrapped up the second year of a three-year study looking at the use of predatory beneficial insects – mites and wasps – to control sweet potato whiteflies in commercial settings.

Vafaie’s study is for his doctorate dissertation under the supervision of Kevin Heinz, Ph.D., a senior professor in Texas A&M University’s Department of Entomology at College Station.

Whiteflies are sucking insect pests, similar to aphids, and can feed on hundreds of different ornamental, field and vegetable crops. Adults are winged while young whiteflies lie flat against leaves and can be difficult to see with the naked eye.

They reduce plant growth by consuming plant nutrients, he said. Whiteflies also excrete honeydew, which can lead to sooty mold. Sooty mold will not directly hurt the plant but can reduce plant aesthetics; the most important characteristic for retailing ornamental plants. Left unchecked, whitefly populations can overwhelm and cause mortality to many plants, including poinsettias.

Vafaie said ornamental crops, like poinsettias, are especially vulnerable to decreased marketability and ultimately loss in value from appearance of whiteflies and their feeding. Growers are often aggressively proactive with chemical spray treatments to ensure their poinsettias will meet market demands.

“They’re protective of their crop,” he said. “But the potential for using a combination of biological controls to address a suite of harmful insects instead of conventional chemical controls is something growers are interested in and want to learn more about. I think there are a number of potential benefits to using beneficial insects in commercial settings.”

Fighting pests with predators

An adult sweet potato whitefly on the underside of a poinsettia leaf with her recently produced group of eggs. (Texas A&M AgriLife Extension photo by Erfan Vafaie)
An adult sweet potato whitefly on the underside of a poinsettia leaf with her recently produced group of eggs. (Texas A&M AgriLife Extension photo by Erfan Vafaie)

Vafaie said there are many questions about pesticide efficacy, pest resistance to certain chemicals, increased pesticide applicator regulations and the overall cost of using pesticides. Consumer trends also show they want ornamentals to have limited-to-no exposure to pesticides.

Using beneficial insects to control pests and minimize damage to crops could be an important aspect of sustainable production, he said. There are numerous studies showing the effectiveness of using beneficial insects in commercial settings in more temperate climates, especially in fruit and vegetable production, but very little information about how they manage pests of ornamentals in hot, humid areas like East Texas.

Previous studies have tended to focus on the use of a single beneficial insect, such as a parasitic wasp, he said.

“The goal is to determine whether the combination of two beneficial insect species to manage whiteflies can work better than just one for poinsettias in a greenhouse environment,” he said. “I want to know how the wasp and mite work together to suppress whiteflies.”

Parasitic wasps are distributed by hanging cards containing more than 60 wasp pupae per card, and slowly emerge and disperse within the greenhouse. The predatory mites are dispersed using a custom-made blower that distributes the mites on carrier material (wood chip-like material seen on the leaves). (Texas A&M AgriLife Extension photo by Erfan Vafaie)
Parasitic wasps are distributed by hanging cards containing more than 60 wasp pupae per card, and slowly emerge and disperse within the greenhouse. The predatory mites are dispersed using a custom-made blower that distributes the mites on carrier material (wood chip-like material seen on the leaves). (Texas A&M AgriLife Extension photo by Erfan Vafaie)

Vafaie is looking to determine how introducing beneficial predatory mites and parasitic wasps affect the need for pesticide spray treatments. His study started with determining initial whitefly populations on poinsettia cuttings at the grower facilities over two years, whitefly retailer thresholds for two years, and small-scale studies to determine if the combination of the two beneficial insects works better than either one alone.

In the most recent year, Vafaie has focused on commercial trials to manage whitefly populations using beneficial insects in three locations where poinsettias are being grown – two local commercial growers’ greenhouses and Texas A&M AgriLife Research  greenhouses holding poinsettia trials in Overton.

The mites, which are tiny spiders, and wasps, which are smaller than fruit flies and do not sting humans, are natural whitefly predators. The mites feed on small soft-bodied insect nymphs and eggs, including eggs and young nymphs of whiteflies and thrips. The wasps lay eggs under middle-aged nymphs, and the young wasps ultimately feed on the whitefly nymphs.

Wasps have a better ability to move around and often encounter dense populations of whiteflies, whereas mites’ dispersal is much more limited, Vafaie said.

Vafaie and his assistant scouted for whiteflies in both greenhouses managed under conventional insecticide rotations and greenhouses that relied mainly on the wasps and mites for whitefly control.

So far, so good

A predatory mite feeding on a whitefly nymph on the underside of a poinsettia leaf. (Texas A&M AgriLife Extension photo by Erfan Vafaie)
A predatory mite feeding on a whitefly nymph on the underside of a poinsettia leaf. (Texas A&M AgriLife Extension photo by Erfan Vafaie)

At Location 1, Vafaie said spot sprays were required in addition to the beneficial insects in sections of the greenhouses after whitefly populations moved in. At Location 2, no pesticide applications for whiteflies were necessary in the beneficial insect-managed greenhouse, but fire ant bait was needed to manage the fire ants, which were consuming the beneficial insects.

In Overton, two broadcast applications were needed to bring whitefly populations back down to manageable levels for the beneficial insects.

In small-scale trials, Vafaie said the combination of wasps and mites worked as well as either predator alone. Scouting for whiteflies and spot-spraying alone helped decrease the use of pesticides during the study.

Pesticides that do not kill the wasps and mites are typically used, or a spray that will not leave residuals that will harm the beneficial insects following a treatment, he said.

“Throughout the small-scale study, the combination of mites and wasps were more reliable in handling simulated whitefly migrations into the greenhouses,” he said. “Mites are thought to wait and intercept incoming whiteflies, while wasps actively move around and encounter new populations of whiteflies.”

Wasps were released every week while mites were released every four weeks, Vafaie said.

Vafaie said applications of beneficial insects took less time and labor than spray applications. Although the cost of beneficial insects was roughly equivalent to the typical cost of pesticide inputs, a full cost comparison between conventional insecticide rotations and the beneficial insect strategy is still pending.

“The key to this strategy is to use the beneficial insects to maintain whiteflies below the retailer threshold,” he said. “Unlike pesticide applications, biological control is a numbers game; each beneficial insect can only eat or lay eggs under so many whiteflies for a given period of time. If whiteflies are reproducing at a faster rate than the beneficial insects can consume, then it’s time to knock down whitefly population with some selective pesticides to levels manageable by the beneficial insects again.”

Vafaie hopes to extend the study further and incorporate an economist to analyze the cost benefits of using beneficial insects compared to conventional preventative insecticide rotations for commercial poinsettia production.