Faculty

AgriLife Research Entomologist Creates Toolbox for Vegetable Producers

August 18, 2016 by Rob Williams

Dr. Ismael E. Badillo-Vargas, a Texas A&M AgriLife Research insect vector entomologist in Weslaco, is helping create strategies to revive vegetable production in the Rio Grande Valley (AgriLife Communications photo by Rod Santa Ana)

by Rod Santa Ana, Texas A&M AgriLife Communications

WESLACO – It’s an imaginary toolbox, but Dr. Ismael E. Badillo-Vargas wants to create one for South Texas growers to help them revive what was once a thriving vegetable industry in the Rio Grande Valley.

It would contain both short- and long-term strategies to once again harvest vast fields of produce in Texas for local, national and international markets.

Badillo-Vargas, a Texas A&M AgriLife Research insect vector entomologist in Weslaco, said insects and the plant diseases they carry represent a formidable barrier to farming lucrative vegetable crops.

After decades of being a top producer of vegetables in the country, Texas is now a net importer, according to U.S. Department of Agriculture statistics.

“Insects, especially those that are vectors of plant pathogens, pose a new challenge for vegetable production in Texas,” he said. “Those insects were not here in the 1950s, ‘60s and ‘70s. Insects presently in the Rio Grande Valley are constantly changing, and they are carried here not only by changing weather patterns that can disseminate them long distances but also by human and commercial traffic to and from the area that didn’t exist back then.”

Badillo-Vargas said Trojan horse-type insects, those that arrive carrying pathogens, pose a double whammy to an area.

“Suddenly, an area like the Valley doesn’t have just a new insect pest to deal with, it also has a new plant disease never seen here before,” he said. “It takes a great deal of research to learn the biology of that new insect as well as how the disease works. And sometimes, the pathogen can change the insect or vice-versa. It can get very complicated.”

Unlike areas that routinely have hard winter freezes, the subtropical climate of South Texas allows insects and pathogens to survive year round, moving among host plants as the seasons change.

“In the absence of crops, after a harvest, for example, an insect population can move to weeds in ditches to survive,” he said. “Once crops are planted again, they simply move from the weeds back onto the crops. The pathogens they carry also survive.”

Those pathogens can be bacteria, fungi or viruses, which require different approaches to control, Badillo-Vargas said.

“And different insect vectors carrying any of these pathogens will also require multiple strategies to control their damaging effects.”

Insecticides can be effective, but because insects have an innate ability to adapt, they can quickly develop resistance to those insecticides.

“Suddenly, an insecticide that was highly effective against an insect is no longer effective, so it’s important to develop insecticide rotation programs,” he said. “That helps.”

An insecticide rotation program would occupy the short-term strategy segment of the tool box, along with cultural and biological control practices.

“Cultural practices would include recommendations on farming methods,” he said. “This could include recommended planting dates or using different types of mulches. Biological control would involve the use of ‘good’ insects controlling the populations of ‘bad’ insects. That’s our goal, to develop new strategies that could be combined into an integrated pest management program to make it more difficult for pests and pathogens to succeed.”

Long-term strategies in the toolbox will first require gaining an in-depth understanding of the interactions of vectors and the pathogens they transmit to develop resistant varieties and transgenic plants genetically modified to resist pests and diseases, Badillo-Vargas said.

“One example of this is what’s called RNAi, or RNA interference,” he said. “These studies take much longer to develop, but basically involve targeting a gene in the insect’s genetic makeup that plays a key role in reproduction and/or the ability to transmit a pathogen.

“If we can switch off that particular gene, the insect would not be able to reproduce, or it wouldn’t have the ability to infect plants with the bacteria or virus it’s carrying.”

A combination of short- and long-term weapons in the toolbox could allow vegetable growers to produce healthy, profitable crops once again, Badillo-Vargas said.

“But it takes time, even after you’ve developed a new strategy, to determine scientifically that the strategy is effective,” he said. “It takes several seasons of testing to make sure that success in the first, second or third season wasn’t just a fluke.”

And during all this time, weather patterns and insects keep changing, and commerce and travelers continue introducing new challenges to an area.

“All of these studies take time and a tremendous amount of resources, but Texas A&M AgriLife is determined to make the investment required to revive the state’s vegetable industry,” he said.

A native of Puerto Rico, Badillo-Vargas assumed his duties in February at the Texas A&M AgriLife Research and Extension Center at Weslaco. Among his first steps to help growers was to set up a large research field plot of tomatoes and potatoes to monitor the insects currently in play.

“We haven’t found anything we weren’t expecting,” Badillo-Vargas said. “In tomatoes we’ve encountered whiteflies, red mites and thrips. In potatoes, of course, we have the potato psyllid that transmits zebra chip disease. And there are major and minor aphids affecting both crops, and some insects that can move to other crops, like whiteflies in cotton.”

Badillo-Vargas’ colleagues and collaborators at the Weslaco center include Dr. Carlos Avila, an AgriLife Research vegetable breeder, and Dr. Juan Anciso, the Texas A&M AgriLife Extension Service fruit and vegetable specialist, among others.

Badillo-Vargas also administers a statewide program that tracks migration and population patterns of the potato psyllid.

“Stakeholders throughout the state of Texas, the nation and even other countries subscribe to our findings because it’s such an insidious vector of zebra chip disease in potatoes,” he said. “Many growers and other stakeholders want to know what they’re up to and where. They use this information to best combat this insect vector and bacterial pathogen in potato growing areas.”

Badillo-Vargas said it is difficult to predict but short-term strategies to help Texas growers begin producing profitable vegetable crops could be possible in five years. The long-term strategies that involve in-depth understanding and genetic work would likely take longer.

Sword’s research plays key role in new technology poised to make major cotton industry contribution

August 3, 2016 by Rob Williams

by Steve Byrns, Texas A&M AgriLife Communications

COLLEGE STATION—The dream of many Texas cotton farmers plagued by dwindling irrigation water and drought might be to someday produce more fiber using the same amount of water.

That dream is fast becoming reality now thanks to a commercially available seed treatment from Indigo Ag called Indigo™ Cotton. The science behind the treatment stems directly from research started by Dr. Greg Sword, a Texas A&M entomologist.

But the dream gets better.

Sword and Indigo-his industry partner-say that under some conditions the production or yield can be as much as 10 percent higher than untreated crops and needs no special crop management inputs beyond a simple endophyte microbial coating of the planting seed.

Endophytes are microbes that can live inside plants, analogous to the microbes that live inside humans and play important roles in human health.

Students working in the field — Sword Lab students working in the field. Photo by Cesar Valencia.

That means no specialized farming equipment is required, no genetically modified organism technology is associated with the process, no more acreage is taken into account, there’s no need for increased planting rates, and no additional pesticides or fertilizer applications need be applied over what’s normally used, Sword said.

In fact, Sword’s lab has shown that some endophytes can reduce pest pressure on cotton as well. In short, the process means more profit for the producer with no added stress on the environment.

“As an entomologist, my first research initially focused on the important effects microbes could have in conferring resistance in cotton to insects and nematodes and potentially affect cotton yields in that way,” Sword said. “But I also started to suspect that water stress was involved, and we conducted field trials showing increased yields were possible. This is what started getting the early attention from industry in 2012-2013.”

Now, there are 50,000 acres planted with the Indigo™ Cotton treated with a microbe from Sword’s lab – most of it in the High Plains of Texas. This part of Texas, often called “The World’s Largest Cotton Patch,” is the most intense area of cotton production in the U.S. and sits over the huge, but slowly dwindling Ogallala Aquifer.

In 2013, Texas A&M AgriLife Research, with assistance from Texas A&M Technology Commercialization, inked an exclusive licensing deal with Indigo to have the rights to commercialize the fungal endophytes that Sword’s lab collected from cotton.

“Through joint research with Indigo, we began to find that many of the microbes I collected were also having effects in conferring water stress resistance,” Sword said.

Sword said that it was his early work that clearly showed the microbes could be applied to seeds that could then be planted under normal field conditions with observable effects on plant performance and yields.

Indigo has raised close to $156 million in private investment funding so far, with $100 million of that from the most recent round of fundraising, as noted by reports in the media, Sword said.

“That made a big splash because it was the largest private equity fundraising effort ever in the agricultural technology sector to date,” Sword said. “So not only are the ag people paying attention now, but so are the finance/Wall Street types.

“Although Indigo’s first product is in cotton and based on a microbe from my lab, they have lots of other developments going on with other microbes in other crops,” Sword said. “But the cotton data was promising enough that it led to their first commercial offering being for cotton, and the strength of the cotton data surely helped them convince investors to invest. So it’s not exclusively due to the cotton data, but it definitely helped.”

So why should non-farmers care?

“Because producing more food and fiber with less water, or even producing the same amount with less water, is a critical global need as water becomes scarce and droughts become more common and widespread,” Sword said. “It is my hope that our partnership with Indigo is a strong start to a new kind of green revolution, where considerably more food and fiber can be produced without further taxing the water supply or environment.”

Teel Wins Distinguished Achievement Award In Teaching from ESA

July 28, 2016 by Rob Williams

Dr. Pete Teel close up — Dr. Pete Teel. Photo by Rob Williams

Congratulations to Professor and Associate Department Head for Academic Programs Dr. Pete Teel for winning the Entomological Society of America’s (ESA) Distinguished Award In Teaching for 2016. This is the highest level of achievement from the ESA bestowed on its members.

The award is presented annually to members of the ESA that have achieved success throughout their career in teaching. Teel has been honored for his 38 years of teaching undergraduate and graduate entomology courses.

Teel currently teaches the Occupation and Professional Development course (ENTO 482), where students learn how to prepare themselves for entry into either graduate school or employment. He also teaches a graduate course in acaralogy (ENTO 617) where students learn about the systematics, morphology and

Dr. Pete Teel teaching — Dr. Pete Teel demonstrating the Tick App during a session of the Tick Identification and Foreign Animal Disease Awareness workshops.

physiology and management of ticks and mites.

He also has directed the development and implementation of a 12-credit-hour undergraduate certificate in public health Entomology. This certificate program has 129 students enrolled from various colleges.

In addition to his role as classroom instructor at at Texas A&M, Teel has developed and taught various tick identification workshops for inspectors with the Texas Animal Health Commission and USDA working with statewide tick surveillance programs, as well as a forensic acarology workshop for the North American Forensic Entomology Association.

Teel has contributed to several programs on tick biology, ecology, and management for Texas A&M AgriLife Extension Service and has at the annual Texas A&M Beef Cattle Short Course held every summer. Every spring, he directs a 4-H and FFA Entomology clinic that helps youths with identifying insects, preparing them for the upcoming area and statewide contests during the summer.

Teel serves as the Associate Department Head for Academic Programs and Associate Director of the Forensic and Investigative Sciences program.

“I am deeply honored to be selected as the recipient of the Distinguished Achievement Award in Teaching for the Entomological Society of America,” he said. “I am very proud to be able to bring this home to our department as recognition of our outstanding teaching program.”

The award will be presented in September during the International Congress of Entomology meeting in Orlando.

New discovery may improve future mosquito control

June 13, 2016 by Rob Williams

AgriLife Research scientist’s paper outlines a new mechanism of sugar feeding aversion

By: Steve Byrns, Texas A&M AgriLife Communications

Aedes aegypti females reject the sucrose solution containing the synthetic peptide. The sugary solution contained a blue dye to trace the meal in their gut. (Photo courtesy Dr. Patricia Pietrantonio, Texas A&M AgriLife Research Fellow) — *Aedes aegypti* females reject the sucrose solution containing the synthetic peptide. The sugary solution contained a blue dye to trace the meal in their gut. (Photo courtesy Dr. Patricia Pietrantonio, Texas A&M AgriLife Research Fellow)

COLLEGE STATION – Major rainfall across most of Texas triggering hordes of mosquitoes coupled with seemingly constant mosquito-related Zika virus media reports from around the globe may have set the stage perfectly for what one researcher deems as a very significant discovery in man’s war against earth’s leading human disease carrier.

Dr. David Ragsdale, head of the entomology department at Texas A&M University, College Station, credits Dr. Patricia Pietrantonio, a Texas A&M AgriLife Research Fellow in the entomology department at College Station, along with her students and colleagues from other institutions, with discovering a receptor on the legs of mosquitoes that when activated, keeps female mosquitoes from taking a sugar meal and makes them fly away.

“This finding could lead to novel mosquito repellents,” Ragsdale said. “This is really a big deal, a major achievement.”

Ragsdale said Pietrantonio has just had the article, “Leucokinin mimetic elicits aversive behavior in mosquito Aedes aegypti (L.) and inhibits the sugar taste neuron,” on the work published in the Proceedings of the National Academy of Sciences. To view the work and its authors go to http://www.pnas.org/content/early/2016/06/01/1520404113.abstract.

“What makes this even more compelling is the work was with Aedes aegypti, the mosquito species responsible for spreading Zika, dengue, yellow fever and Chikungunya viruses,” Ragsdale said. “This work is the culmination of over five years of study by Dr. Pietrantonio, her students and collaborators. With Zika a looming threat, this is a timely discovery.”

Pietrantonio said after mating, Aedes aegypti females immediately search for a blood meal from a human host.

“They are highly anthropophilic, meaning they are attracted to humans,” Pietrantonio said. “They may even follow people indoors. If female mosquitoes are infected with viruses they may transmit them to humans when they acquire a blood meal.”

The blood meal supplies the protein source female mosquitoes require to produce eggs, she said.

“However, in the field, if human hosts are not present, females will feed on sucrose solutions such as nectar from flowers, though they prefer a blood meal to a sugar meal but male mosquitoes feed only on nectar. Certainly sugar feeding is one of the two feeding modalities for adults of this species.”

“We found that a synthetic peptide that was designed to mimic a peptide naturally present in mosquitoes triggers an aversive fly away, walk away or jump away behavior in female mosquitoes.”

If the same aversion could be tied to a blood meal, she said a totally new and effective mosquito feeding deterrent may be in the offing, one that perhaps would cause the mosquito to pass up the required blood meal needed to lay eggs. Doing so would either disrupt the life cycle and/or reduce disease transmission.

However, this is far from being accomplished, she said.

“One of our team designed a peptide mimetic of the kinin peptides, which are diuretic hormones in mosquitoes, to be resistant to enzymatic degradation,” Pietrantonio said. “These mimetics are more potent than those found naturally, because they take longer to be degraded by the insect. These diuretic hormones make mosquitoes lose water after a blood meal, but we also found the peptidomimetic blocked sugar perception. This is a completely new and unexpected discovery.”

The research team localized these receptors in the feet and mouthparts of mosquitoes. What is really new, they said, is that this type of receptor proteins known as GPCRs, were not previously considered to be important for “taste” in insects and further, contact with the peptidomimetic made the mosquitoes fly away.

“In sum, we unequivocally verified this kinin receptor is present in the taste organs of the legs and labella, the pair of lobes at the tip of the proboscis.”

Pietrantonio said their observation that the peptide blocks sugar perception is interesting because the peptide is insect-specific, therefore, the receptor represents a target for further applied research to find ways to diminish the ability of female mosquitoes to feed. Doing so would likely reduce their lifespan or reproductive capacity.

“We had a lot of fun doing this research within the frame of an international, multi-institutional and multidisciplinary collaboration,” she said.

Institutions involved along with Texas A&M were the U.S. Department of Agriculture-Agriculture Research Service, Iowa State University and Université Paris-Saclay, France.

Pietrantonio said the team will continue to study the system in the hope of developing an effective mosquito feeding deterrent in order to stop what is arguably the greatest foe to mankind on earth.