Faculty

Texas A&M Entomology Sweeps Awards at ESA National Meeting

November 26, 2019 by Rob Williams

Dr. Jim Woolley, right receiving a plaque recognizing his work as an editor in chief of Thomas Say Publications from 2003-2019. Photo by Entomological Society of America. — Dr. Jim Woolley, right receiving a plaque recognizing his work as an editor in chief of Thomas Say Publications from 2003-2019

Fifteen students, the Sugarcane Aphid Team, and two retired faculty members in the Department were recognized at the 2019 annual meeting of the Entomological Society of America meeting in St. Louis.

The four-day-long event featured speakers from universities across the nation, symposia, and student poster and paper contests, as well as mixers and networking events held at the America’s Center and the Marriott Grand St. Louis Hotel.

Professor Emeritus Dr. Jim Woolley received recognition for being editor in chief of the Thomas Say Publications from 2003-2019 during the Professional Awards breakfast on Tuesday, November 12.

Professor Emeritus Dr. Frank Gilstrap was named 2019 Honorary Member of the ESA for his extraordinary contributions to the ESA through his career while he was with the Department of Entomology, Texas A&M AgriLife Research.

Ph.D student Jocelyn Holt also was recognized as being named the Southwestern Branch recipient of the John Comstock Award for her outstanding research and other contributions in entomology and the ESA.

Thirteen students also received awards for their posters and presentations during the Student Competition for the President’s Prize, including:

Graduate 10 Minute Papers

Mackenzie Tietjen speaking during the paper presentation sessions. Photo by Lauren Beebe

Mackenzie Tietjen: First Place – Medical, Urban, and Veterinary Entomology section, Diversity for her paper titled “Assessing host associated differentiation in Dermacentor variabilis (Acari: Ixodidae)”

Constance Lin – First Place in the Medical, Urban, and Veterinary Entomology – Ecology and Behavior 1 for “Raising the “anty” in decomposition ecology: Effects of vertebrate carrion on fire ant colony performance

Mark Janowiecki – First Place in Medical Urban and Veterinary Entomology – Life History for “Seasonality and spatial distribution of Reticulitermes spp. (Blattodea: Rhinotermitidae)

Blake Elkins – Second place Plant – Insect Ecosystems – Biocontrol of Insects 2 for “Species complex and population variation of natural enemies of sugarcane aphid across gradients of landscape composition and structure”

Jose Santiago – First Place in Physiology, Biology and Toxicology, Insecticide Resistance for “Monitoring the susceptibility of Helicoverpa zea (Lepidoptera: Noctuidae) populations collected in Texas to Cry1Ac, Cry2Ab2 and Vip3Aa using F2 screens”

Ruth Henderson with her poster. Photo by Pierre Lau. — Ruth Harrison with her poster. Photo by Pierre Lau.

Crys Wright – First Place in the Plant – Insect Ecosystems – Biocontrol of Insects 2 “Testing for fecundity compensation in parasitized sugarcane aphids”

Undergraduate 10 Minute Papers

Drew Little – Second Place in the Systematics, Evolution, and Biodiversity 2 for “Analysis of Stimulus in the phase-related behavior of Schistocerca piceifrons”

Carolina Wilson – Second Place in Plant – Insect Ecosystems for “Effects of fungal endophyte treatment and herbivory on extra floral nectar carbohydrate composition”

Undergraduate Posters

Alex Payne, right, speaking about her poster during the poster session. Submitted photo.

Ruth Harrison – Plant – Insect Ecosystems 1 for “Pollinator assemblages across different levels of landscape development in the Post Oak Savannah ecoregion”

Sabrina Quintanilla – Physiology, Biochemistry and Toxicology for “Lipid preferences in laboratory-maintained colonies of the red imported fire ant (Solenopsis invicta)

Xiaotian Tang with his poster. Submitted photo.

Graduate Posters

Xiaotian Tang – First Place in Plant – Insect Ecosystems, Plant Disease Vectors for “‘Candidatus Liberibacter solanacearum’ inhibits apoptosis in Bactericera cockerelli gut to facilitate its acquisition and transmission”

Alexandria Payne – First Place in Physiology, Biochemistry, and Toxicology for “Interspecies virus transmission between ants and honey bees (Apis mellifera)

John Grunseich in Plant – Insect Ecosystems, Biology Control for “A specialist herbivore uses chemical cues from host-plant roots to avoid induced defenses and elevated predation risk”

Pierre Lau, right, receives the La Fage Award from Li-Byerly Hongmei. Photo by Photo by Dr. James Nieh.

Ph.D. student Pierre Lau also received the International Union for the Study of Social Insects, North American Section’s 2019 Jeffery P. LaFage Student Award for Applied Research on Social Insects during a special recognition event.

The Jeffery P. La Fage Student Award for Applied Research on Social Insects recognizes a graduate student for distinguished research and scholarly activity on social insects, with an emphasis on applied projects.

Members of the Sugarcane Aphid Team received the 2019 Plant-Insect Ecosystem Integrated Pest Management Team Award, sponsored by Corteva Agriscience. The team established thresholds and sampling protocols for sugarcane aphids and incorporated aphid resistant sorghum hybrids into management, and identified and evaluated natural enemies for regulating the aphids.

The team includes Brent Bean (United Sorghum Checkoff Program), Robert Bowling (Bayer Crop Science and former AgriLife Extension faculty), Michael Brewer (Texas A&M AgriLife Research – Corpus Christi), David Buntin (University of Georgia), Norman Elliott (USDA-ARS, Southern Plains), Amanda Jacobson (Corteva Agriscience), John Gordy (Syngenta Crop Protection and former Ph.D. student), Ronald Navarrete-Ganchozo (Bayer Crop Science), Nick Seiter (University of Illinois), Jason Thomas (University of Idaho and former M.S student), and Dr. Jim Woolley (Professor Emeritus – Texas A&M University).

Since its creation, the team has published 20 journal articles, 12 Extension publications and developed nine web resources as a result of their work.

Tawny crazy ants’ weird genetics may help them thrive in new environments

November 22, 2019 by Rob Williams

Ed Vargo, professor and endowed chair in Urban and Structural Entomology (right), shows ant specimens with postdoctoral research associate Pierre-André Eyer (center), and doctoral student Alex Blumenfeld (left). (Photo by Rob Williams)

by Olga Kuchment, Texas A&M AgriLife Communications

Tawny crazy ants’ pattern of genetic inheritance may have helped the South American species spread in the U.S., Texas A&M AgriLife researchers have discovered. The results could lead to a new way to control this invasive species.

“We might be able to use the mechanism to drive a lethal gene into the population,” said Dr. Ed Vargo, senior investigator of the study and professor of urban and structural entomology in the College of Agriculture and Life Sciences at Texas A&M University.

Also known as Rasberry crazy ants, the species has been spreading in Texas since at least 2002. Crazy ants can kill grass, displace other insects and destroy electrical equipment, causing a lot of damage in urban and rural areas. What’s more, their colonies can evade typical pest control tactics. They can thrive both indoors and outdoors. They ignore baits and create numerous escape routes from their supersized colonies.

Tawny crazy ants were named for their random-looking walk, but the way they pass down genes to the next generation may also be described as crazy.

A nest of genetic diversity

The team investigated crazy ant colonies in Texas and Florida cities.

Vargo and lab members Pierre-André Eyer and Alexander Blumenfeld found that in this species, the females were much more genetically diverse than one would expect from pure chance. Females tend to inherit their mother’s genes, and males tend to inherit their grandfather’s. And, males and females are quite different genetically. The pattern of inheritance seems to be unique among 15,000 ant species.

The study was published in Proceedings of the National Academy of Sciences in November.

The invasion paradox

Tawny crazy ants’ success as an invasive species represents one solution to the so-called invasion paradox: How can a small number of animals move to a new area and reproduce without suffering from genetic disorders due to inbreeding?

One way that species can fight inbreeding, scientists have hypothesized, is by making use of the differences between males and females.

Battle of the sexes

Scientists have known for a long time that males and females can develop dissimilar genetic traits. Some of these traits cause problems for one sex and help the other. Such traits are normally found in sex chromosomes, such as X and Y in mammals. But ants, and their relatives, bees and wasps, have no sex chromosomes. Instead, a female has two copies of the genome while a male has one.

Scientists have hypothesized that in species where females have two copies of the genome and males have only one, the whole genome can act like a sex chromosome. A gene’s effect might be canceled or masked by another version of the same gene. In this way, a gene can be harmful and recessive in females but favorable and dominant in males, where it can’t be masked by a second copy.

Genetic Diversity, at a steep cost

The researchers analyzed several spots in crazy ants’ genome and discovered that ant colonies have three distinct versions of a certain genetic region. The team called the three versions A, B and C. If ants inherited the genes at random, a male ant could carry version A, B or C. A female could carry any combination of two versions. Instead, the team found something completely different. The vast majority of adult crazy ant females carried A/B or A/C. Adult males possessed only A.

This strategy ensures that each generation is genetically diverse. But it comes at a cost, said Vargo and Eyer. The team found that many female eggs have genetics that don’t fit the A/B or A/C pattern. These eggs seem to disappear from the nest before they can develop. The team hypothesizes that these eggs — almost 40% — either die or are destroyed by ants in the nest.

“There’s something about the genes and their expression that’s harmful to females,” said Vargo.

Back in Brazil

The study “fills a gap in our understanding of the inheritance of traits by males and females and shows how conflicts between the sexes can occur at the genomic level,” Vargo said. “This is a very positive finding.”

Next, the team plans to study whether the same crazy pattern of inheritance appears in the ants’ native Brazil or is just a consequence of being in a new place. Either way, the results would shed light on the weird and powerful adaptability of the tawny crazy ant.

What is Forensic Entomology? Professor shares insight on how insects assist in legal investigations

October 22, 2019 by Rob Williams

by Paul Schattenberg, Texas A&M AgriLife Communications

Students investigating at a mock crime scene on the Texas A&M University campus in College Station. Photo by Rob Williams

Insects can help fight crime by providing important scientific insights that can be applied to legal investigations – plus provide interested individuals with a truly unique profession in forensic entomology. While most may view forensic entomology as the “creepy-crawly” part of CSI-type television shows, that perspective only scratches the surface of this field.

Forensic entomology is the understanding of how the biology of insects and arthropods that inhabit decomposing remains can be used for the purpose of assisting in a variety of legal investigations. Forensic entomologists often work with medical examiners, coroners, local and state police agencies and federal agencies, using their knowledge and skills to ascertain valuable information to be used in their investigations.

AgriLife Today asked Dr. Jeffery Tomberlin, professor and director of the Forensic and Investigative Sciences Program about his interest in forensic entomology as well as his involvement in investigations to assist law enforcement.

In what ways are insects used to provide insights or information for forensic investigations?

Tomberlin: Insects tend to find vertebrates — humans or other animals — soon after death. By understanding how insects develop we can estimate time of colonization, which can translate into a minimum time-of-death estimate based on certain assumptions. Of course, because some of these insects colonize living individuals, understanding their biology can also be quite useful for determining instances of neglect or abuse. And, they can help in determining if there have been health code violations.

Insects, as related to forensics, can also be useful for determining if a deceased individual had consumed narcotics prior to death — or if the remains were moved from one location to another.

Has the popularity of crime scene investigation TV shows helped bring greater attention to forensic entomology?

Tomberlin: Most definitely. I believe the interest in forensics at Texas A&M, in general, is partially driven by such shows and the overall interest the public has shown in them.

What bugs you about crime scene TV? Do they get certain things wrong — or oversimplify them?

Tomberlin: Ha! Nothing really “bugs” me about it. As I see it, they do the best they can with representing the science. And if they can encourage the youth of this country to have an interest in STEM subjects, I’m all for it. Of course, our job at the university is to help address any misunderstandings that may arise regarding the sciences implemented in forensics.

How did you become interested in forensic entomology? Was there something in particular that drew you to this field?

Tomberlin: The exact moment when I realized I wanted to pursue a career in this field occurred during my undergraduate studies in biology at the University of Georgia. I was taking an elective in entomology that was much like the Insects and Society course at Texas A&M. I had an interest in attending medical school and pursuing a career in forensic pathology, but when my professor discussed forensic entomology, I knew at that moment I wanted to be a forensic entomologist. Medical school was no longer a consideration.

What coursework does Texas A&M offer related to forensic entomology?

Tomberlin: We have a number of courses that relate to forensic entomology, but the key course is titled Forensic Entomology. This is a three-hour course that also has a lab component. This course has been at Texas A&M for over 20 years and is the seed from which the forensic science program germinated.

We also have other courses that address the science aspect of forensic science. There are courses in crime scene investigation, applied forensic entomology and the science of forensic entomology. There are also several courses related to other aspects of forensics, such as biotechnology and forensics and forensic soil science.

FACTOID: Texas A&M University’s Forensic and Investigative Sciences major in the Department of Entomology was ranked No. 1 out of the top 25 forensic science programs in the U.S. by Bachelor’s Degree Center.

Who do you collaborate with in your forensic investigations?

Tomberlin: We work closely with multiple local, state and federal institutions from across the U.S.. Over the course of my career, I have assisted with more than 130 investigations.

Can you tell us about the forensic investigations you helped with?

Tomberlin: For most cases, I am asked to review entomological evidence associated with decomposing remains to determine time of colonization, which can be used to infer a minimum time of death. However, I have also worked on cases dealing with abuse and neglect. And, I have had civil cases involving insects on human remains in funeral homes, hospitals, nursing homes, as well as in food at restaurants.

What is the Forensic Laboratory for Investigative Entomological Science, or FLIES, facility at Texas A&M, and what sort of research is being done there to expand or improve the science related to forensic entomology?

Tomberlin: The FLIES facility is where the “rubber meets the road” as far as decomposition ecology research at Texas A&M. Basically, we focus on everything related to decomposition, but our primary interests are exploring how nature recycles organic matter, and how such information can be used to better society. While many people recognize us for our forensic efforts, we also explore the use of such processes to recycle organic waste to produce protein for use as livestock feed. We also try to apply such information in sustainable agriculture with confined animal facilities. We look at “cultural” methods for reducing nuisance flies associated with such operations to reduce or eliminate the need for insecticides. But as far as forensic entomology, we want to determine what factors regulate insect attraction to and colonization of remains.

What is something about the practice of forensic entomology that people may not realize?

Tomberlin: I think it’s interesting that out of the 130-plus cases I have been a part of, I have only been to one actual crime scene. A person can have an interest in entomology — but not want to deal with decomposing human remains — and still be quite successful in the discipline. I’ve never had a problem with the macabre aspects of my discipline, so this has never been an issue for me. I’m just stating this as fact for those who may feel unsure if they can “handle” forensic entomology.

Where do graduates with degrees in forensic entomology work?

Tomberlin: I have found that most students who take forensic entomology at Texas A&M are curious about the topic, but forensic students take it because it is a required course. In terms of practicing in the field, most students pursue a graduate degree in entomology, which allows them to be active as I am — as a professor and forensic entomologist. Others may seek employment with crime labs as crime scene investigators.

Symposium Showcases Top Evolutionary Genetics and Genomics Research in SE Texas Area

August 22, 2019 by Rob Williams

Keynote speaker Dr. Mark Kirkpatrick speaking during the first session. Photo by Rob Williams

Scientists from across the Southeastern Texas area gathered inside the Interdisciplinary Life Sciences Building for the fourth meeting of the Southeast Texas Evolutionary Genetics and Genomics Symposium on July 18.

The day-long symposium featured various presentations by researchers from the Southeastern Texas area, including Texas A&M, Texas A&M Galveston, the University of Houston, the University of Texas Health Science Center, and the University of Texas Rio Grande Valley.

The event was hosted by the Department of Entomology and the Ecology and Evolutionary Biology program faculty. The purpose of the symposium was to bring together scientists from various backgrounds interested in evolutionary genetics to share their research, develop collaborations, and network.

Dr. Aaron Tarone opening the symposium. Photo by Rob Williams

Keynote speaker Dr. Mark Kirkpatrick from the University of Texas opened the symposium with “Sex differences in the recombination landscape” Presenters from the Department of Entomology included Ph.D. student Ashley Tessnow who spoke on “Genomic insights into the migration and host strain hybridization patterns of a major agricultural pest, Spodoptera frugiperda”, Pierre-Andre Ayer with his talk “Sexually antagonistic selection: Genetic divergence between males and females maintains diversity in an invasive ant”.

There also was a presentation before lunch made by Dr. Charlie Johnson on a seed grant that the College of Agriculture and Life Sciences genomics core faculty is supporting to promote collaboration among evolutionary geneticists in Texas.

Carlos Aguero with his poster during the poster session. Photo by Rob Williams

Several Entomology graduate students and postdoctoral research associates presented posters, including “Characterization of microbial communities outside and within subterranean termite communities” by Carlos Aguero, “Characterization of the Sugarcane Aphid Microbiota” by Jocelyn Holt, “Cycle knockout alters circadian gene expression and

behavior in Aedes aegypti mosquito” by Jacob Meyers, “Evaluation of Illumina Sequenced Bacterial Genomes from Environmental Samples” and “Potential Host Range of Bacterial Infections in Drosophila” by Igor Vilchez.

Dr. Spencer Johnston then closed the symposium with a talk on the history of genomic research and evolutionary genetics.

Dr. Aaron Tarone said the Organizing Committee was impressed by the attendance and the outstanding quality of work in this year’s presentations and posters.

“The turnout was the best for the four STEGG meetings so far,” Tarone said. “There were a lot of high quality and interesting presentations.”

The program was financially supported by the Department of Entomology, Department of Biology, Department of Veterinary Pathobiology, Department of Integrative Biomedical Sciences, VWR, Thermo Fisher Scientific, and the TAMU Office of Graduate and Professional Studies. TAMU Galveston provided management of the website and communications. Many thanks to these sponsors and contributors.

Zero waste: Maggots as recyclers and protein sources

August 9, 2019 by Rob Williams

Texas A&M professor invents technology to harness black soldier flies for waste removal, protein for animals

by Laura Muntean, Texas A&M AgriLife Communications

Adult black soldier flies look similar to wasps, but without the stinger. (Photo courtesy of Dr. Jeff Tomberlin.)

COLLEGE STATION — Black soldier fly maggots provide a zero waste option for organic recycling, according to Jeff Tomberlin, Ph.D., professor in the department of entomology at Texas A&M University and director of EVO Conversion Systems, LLC.

Despite the “ick-factor,” maggots can be helpful for the environment by reducing waste and serving as an animal feed source, he said.

The larval form of the black soldier fly eats profusely during this stage of development. The maggots essentially climb on top of each other, wriggling and writhing in an effort to get to the food source or waste material. The larvae eat until they are full, and as they take a breather from their snack, other larvae push in to snag a bite to eat, shifting the others up and out of the way, creating a tower of maggots.

It may sound gross, but it reduces decomposition time for compost by months, Tomberlin explained.

At the end of the 14-day cycle, the tower of larvae is dried. These dried larvae become feed for animals that humans then consume. The most common example is as a protein source for chickens.

The larvae can also be processed to isolate the protein, which can then become part of a feed for livestock, poultry and fish. The maggot waste can also be used as compost for landscaping. Essentially, it’s the natural life-cycle power of the black soldier fly but harnessed by humans.

It’s been very successful in China, Europe and other parts of the world, and the process is now being utilized for profit here in Texas.

BULLET TECHNOLOGY

Tomberlin and his team have come up with a more efficient way to harness the process of waste reduction with a new technology he calls the Black Soldier Fly Bullet. The Bullet provides storage of the larvae for an extended period of time, giving the human users the ability to “wake them up” whenever the need arises by opening the container and placing them on the waste material.

“Drs. Tomberlin, Cammack and Mr. Yang, all from Texas A&M AgriLife Research, invented a new technology to greatly increase the efficiency of black soldier fly, or BSF, conversion of waste material,” said Robert Brummett, AgriLife Research licensing manager, College Station. “This technology, called the Black Soldier Fly Bullet, also facilitates storage and shipment of BSF, thus creating more stability and assurances in processes utilizing BSF larvae.”

Texas A&M AgriLife Intellectual Property and Commercialization worked with Dr. Tomberlin to exclusively license this AgriLife technology created by Tomberlin to his company, EVO Conversion Systems, LLC.

“Through EVO, he and his co-inventors can take the results of their research from the lab to real-world application and use,” Brummett said.

Tomberlin said this gave the company, which manages organic waste with black soldier fly larvae then uses the insect biomass as a sustainable animal feed ingredient and crop fertilizer, an opportunity to create zero waste on a larger scale.

“We were able to develop a system to put them in a state of stasis,” said Dr. Jonathan Cammack, chief operating officer of EVO Conversion Systems and former AgriLife Research postdoctoral research associate. “We are taking newly hatched larvae and putting them in an optimal environment to develop to a certain point, then sit and hang out until ready to be used.”

Tomberlin explained data supports that they can hold the larvae at an optimal temperature, potentially up to five months.

“The larval development time is 14 days, and we can do it in 6-7 days,” he said.

The larvae can then be placed on to the material, regardless of what the waste is, and in six to seven days, they have matured, Cammack explained. The larvae can then be harvested and dried, and the biomass has been converted from waste to insect protein in half the time.

“Basically, this technology puts them into hibernation for long-term storage, and when ready to use them, you wake them up and put them to work,” Tomberlin said.

RESPECT FOR SUSTAINABILITY

Growing up in Georgia, Tomberlin was taught the importance of family, agriculture and sustainability at a very young age. His grandmother, the matriarch of the family, shared with him the importance of taking care of the things you own and the resources available. This life lesson has stayed with Tomberlin and is reflected in his work with the black soldier fly and his dedication to finding ways to most effectively utilize food waste.

During his undergraduate career at the University of Georgia, Tomberlin was introduced to the black soldier fly through his Ph.D. advisor. The insect was not being widely studied at the time, but through Tomberlin’s research, has been widely adopted and is now being used around the world.

FROM MAGGOTS TO PROTEIN SOURCE

Black soldier flies typically lay one batch of eggs. (Photo courtesy of Dr. Jeff Tomberlin.)

Tomberlin explained the adult black soldier fly, which looks similar to a wasp but without the stinger, will live for about two weeks. In general, the female will mate once and lay one batch of eggs. Those eggs hatch in about four days, and the larvae will feed for two weeks. This leaves about 18 days in the development aspect and about another two weeks in the pupal stage before the adult emerges.

“The lab at Texas A&M is a leading lab in the world on this topic,” Tomberlin said. “The first thing we did was develop a method to mass produce this insect in a colony. That method is now being employed in every major black soldier fly production facility in the world.”

As other countries employ these systems, they often first come to Tomberlin’s lab at Texas A&M to learn about the research, then go to the factory to learn about the industrial side of things.

“Most groups around the world are focused on that 14-day development that they can feed waste to it, recycle it and produce protein,” he said. “Through our research at Texas A&M, we have been able to enhance that system.

Cammack explained that they wanted to put some stability into the system, so the team looked at how much waste material a colony needed in order to flourish without having too much material for the colony, or too little. This balance would help to maximize the number of eggs that the colony would produce.

“If they lay a whole bunch of eggs and you don’t have enough material for them to digest or process, then you are losing eggs, and if you don’t have enough eggs and you have a whole bunch of waste available, then you have waste that rots,” Cammack said. “One is driving the other.”

PARTNERING UP FOR ZERO WASTE

With zero waste being the ultimate goal, the team has implemented a circular economy by working with Blackwater Draw Brewing Company, Rio Brazos Distillery and Cosmic Landscapes of Texas.

“We get the byproducts from the distillery and brewery and convert them to protein, and the compost that we then produce, or digestate, goes to the landscape company, and they use it for landscaping,” Tomberlin said. “So it is zero waste. That is what we are developing here in College Station and Bryan. There should be no food waste going into the landfill. It should be recycled to products of value.”

ZERO WASTE FACILITIES

“Our goal is to build a facility here and make College Station and Bryan a zero waste area,” he said. “If we can build a facility like that, it is not just a facility for recycling waste, it is a teaching facility. If we can build it in conjunction with A&M, we are talking about a facility where research can take place and students can be trained, and at the same time we are taking care of the community. We are creating jobs. That’s what we would like to see happen.”

Tomberlin sees success in this industry through the building of small to mid-sized industry sites, producing a facility with as little as $250,000. Creating these smaller facilities and placing them throughout rural America is the goal and will create jobs, protect the environment and produce a valued resource.

“We are looking to expand who we get our material from here in Bryan-College Station, but at the same time we want to talk with our local waste management companies,” Tomberlin said. “We don’t want to encroach on them, we want to help them. If there are things that we can divert from that waste that can go into our compost facility, we will work with them. We don’t see that as competition; we see it as collaboration.”