Texas A&M Entomology Research Network

Faculty

$3.9M project on self-deleting genes takes aim at mosquito-borne diseases

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Texas A&M AgriLife researchers’ work to aid mosquito control efforts

by Olga Kuchment, Texas A&M AgriLife Marketing and Communications

mosquito close-upTo control mosquito populations and prevent them from transmitting diseases such as malaria, many researchers are pursuing strategies in mosquito genetic engineering. A new Texas A&M AgriLife Research project aims to enable temporary “test runs” of proposed genetic changes in mosquitoes, after which the changes remove themselves from the mosquitoes’ genetic code.

The project’s first results were published on Dec. 28 in Philosophical Transactions of the Royal Society B, titled “Making gene drive biodegradable.”

Zach Adelman, Ph.D, and Kevin Myles, Ph.D., both professors in the Texas A&M College of Agriculture and Life Sciences Department of Entomology are the principal investigators. Over five years, the team will receive $3.9 million in funding from the National Institute of Allergy and Infectious Diseases to test and fine-tune the self-deleting gene technology.

“People are wary of transgenes spreading in the environment in an uncontrolled manner. We feel that ours is a strategy to potentially prevent that from happening,” Adelman said. “The idea is, can we program a transgene to remove itself? Then, the gene won’t persist in the environment.

“What it really comes down to is, how do you test a gene drive in a real-world scenario?” he added. “What if a problem emerges? We think ours is one possible way to be able to do risk assessment and field testing.”

A crucial target for mosquito control

Many genetic engineering proposals revolve around inserting into mosquitoes a select set of new genes along with a “gene drive.” A gene drive is a genetic component that forces the new genes to spread in the population.

“A number of high-profile publications have talked about using a gene drive to control mosquitoes, either to change them so they can’t transmit malaria parasites anymore, or to kill off all the females so the population dies out,” Adelman said.

An often-voiced worry is that such genetic changes could carry unintended or harmful consequences.

One plan makes the cut

In the project’s first publication, the colleagues describe three ways for an introduced genetic change to remove itself after a designated period of time. The time period could, for instance, be 20 generations of mosquitoes, or about a year. The team modeled how the genes would spread among mosquitoes based on generation times and parameters of an average mosquito’s life. Of the three methods, the team has chosen one to pursue further.

This method takes advantage of a process all animals use to repair damaged DNA, Adelman said. Inside cell nuclei, repair enzymes search for repeated genetic sequences around broken DNA strands. The repair enzymes then delete what’s between the repeats, he said.

So, Adelman and Myles’ team plans to test in fruit flies and mosquitoes a gene drive, a DNA-cutting enzyme and a small repeat of the insect’s own DNA.

Once the introduced enzyme cuts the DNA, the insect’s own repair tools should jump into action. The repair tools will cut out the genes for the gene drive and the other added sequences. At least, that’s what should happen in theory.

Failure is not just an option, it’s part of the plan

The team has already started lab work to test different gene drives and determine how long they last in flies and mosquitoes. The goal is to see a gene drive spread rapidly through a lab insect population. After a few generations, the added genes should disappear and the population should again consist of wild-type individuals.

“We assigned various rates of failure for how often the mechanism does not work as expected,” Adelman said. “The models predict that even with a very high rate of failure, if it succeeds just 5% of the time, that’s still enough to get rid of the transgene.”

 

Juliana Rangel Receives Award for Outstanding Research, Outreach in Beekeeping Industry

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Juliana Rangel, left, with John Talbot, center, and Ashley Ralph. Photo by Rob Williams.
Juliana Rangel (left) with John Talbot (center), and Ashley Ralph, Texas Beekeepers Association president (right). Photo by Rob Williams.

The Department of Entomology at Texas A&M congratulates Dr. Juliana Rangel as she received the Dr. John G. Thomas Meritorious Service Award from the Texas Beekeepers Association during a special visit on Tuesday, November 3.

Rangel received the award for her outstanding research and her dedication to the beekeeping industry. Her research involves investigating various aspects of the reproductive biology of honey bee queens and drones, honey bee nutritional biology, and the behavioral ecology and genetics of managed and wild honey bees.

The award is given to a non-commercial beekeeper, researcher, regulator, industry or individual who has had a major impact on the Texas beekeeping industry.

Since joining the Department in 2013, Rangel has acquired over $1 million in extramural support and funding for her research program, focusing on providing solutions to improve colony health, such as a study on the effects of agricultural pesticides on honey bee fertility, a grant to identify floral sources foraged by honey bees in four locations in the U.S., and a grant to create and lead the Texas A&M University’s Tech Transfer Team.

In collaboration with the Texas Beekeeepers Association, Rangel also wrote a successful grant to raise awareness of the benefits of “Real Texas Honey.” Along with the above major grants, she has forged several significant collaborations with faculty and scientists at the national and international levels to research honey bee reproduction, ecological genetics of feral Africanized honey bees, and integrated pest management techniques for control of Varroa destructor mites in Texas apiaries.

Rangel appreciated the association and the Department for supporting her research programs.

“I am so grateful to the Texas Beekeeper Association and to the Department of Entomology for taking the time to do this and for allowing me to travel to other cities to talk about our research program,” Rangel said. “It is truly an honor and I am humbled and grateful for them to give me this award.”

TBA president Ashley Ralph said that Rangel’s research has provided a positive impact on the beekeeping industry and Texas agriculture as a whole.

“We are so proud to award Juliana the John G. Thomas Meritorious Service Award for her continued work in research and education,” Ralph said. “Through her research and the research of the graduate students she leads in the Honey Bee Research Program, we are given a better understanding of what we consider to be the most fascinating insect on the planet. Honey bees are the backbone of our diverse Texas agriculture and this research allows us all to be better stewards for bees.”

Blue light assists a night hunt for bugs

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Hojun Song holds one of the insects studied with blue light fluorescence, in Costa Rica. Photo courtesy of Song
Hojun Song holds one of the insects studied with blue light fluorescence, in Costa Rica. Photo courtesy of Song

by Olga Kuchment, Texas A&M AgriLife Marketing and Communications

A blue flashlight that makes corals shine in the sea can help spot insects in nighttime forests, according to a recent Texas A&M AgriLife study. The peer-reviewed study suggests that blue light could help with pest control, natural history research and night insect collecting.

A lightbulb goes on at a conference

The study grew out of a chance meeting at a conference between a vendor and a former student of Hojun Song, Ph.D., associate professor in the Department of Entomology at Texas A&M College of Agriculture and Life Sciences.

The conference vendor was marine biologist Charles Mazel, Ph.D., co-founder of NIGHTSEA in Massachusetts. Mazel showed Song’s former graduate student Derek Woller, Ph.D., some blue-light fluorescence photographs he had taken for fun of various caterpillars and grasshoppers.

Fast-forward about a year, and Woller convinced Song to purchase one of Mazel’s leading-edge blue lights to test in various lab projects. With the light, they embarked on a quest that led to the published study.

A little about fluorescence

Under blue light fluorescence, a camouflaged grasshopper stands out in green on red tree bark. Photo by Charles Mazel / NIGHTSEA
Under blue light fluorescence, a camouflaged grasshopper stands out in green on red tree bark. Photo by Charles Mazel / NIGHTSEA

The reason the light piqued Woller’s curiosity is that some objects and animals can glow like beacons under intense blue light, a phenomenon called fluorescence. When the right wavelength of light hits certain materials, they emit light of a lower energy, or longer wavelength. The color and intensity of fluorescence depends on the material and the wavelength of light.

According to Mazel, most marine life, for example, tends to fluoresce less brightly under ultraviolet light than under blue light. When using blue light, though, yellow goggles must be worn to filter out reflected blue light and see the fluorescence.

But which insects would fluoresce intensely under blue light was relatively unknown at the time, so Woller and Song decided to check, because of the types of insects they studied.

“Those of us who work on grasshoppers, mantids, katydids and walking sticks, we actually have to go and catch them by hand,” Song said. “We also do a lot of night collecting because a lot of these animals are nocturnal. We have a regular headlamp, and we just walk about and spot things or listen to their songs and try to find where they are.”

Scavenger hunts in parks, fields, museum collections

A camouflaged grasshopper on tree bark. Photo by Charles Mazel / NIGHTSEA
A camouflaged grasshopper on tree bark. Photo by Charles Mazel / NIGHTSEA

Woller, now an entomologist with the U.S. Department of Agriculture in Phoenix, designed an experiment with other students to test what types of insects fluoresce under blue light. They also decided to study whether blue light could be more effective than white light for finding insects in the dark.

Woller kept in touch with Mazel, who eventually became a coauthor of the study.

Using either a blue light and yellow glasses or a white light, 12 students undertook nighttime scavenger hunts. Their task: to find freeze-dried grasshoppers Woller and other student coauthors had glued to trees in a park. Overall, the participants were able to locate more grasshoppers by looking at fluorescence.

Next, Woller’s team studied the preserved specimens of several large insect collections. The students tested every order of Hexapoda, which are animals with an exoskeleton, a segmented body and six legs. Most specimens fluoresced under blue light, regardless of how they were preserved.

Finally, the team reprised the experiment in the field. Under blue light, fresh green plants tend to fluoresce red, making a strong contrast with bugs that tend to shine in green or yellow.

A useful new tool

In the end, blue-light fluorescence has become a useful tool in Song’s lab. Some of the bugs Song studies, such as katydids, are masters of camouflage.

“They look like leaves, and they don’t move,” Song said. “Even with a headlight, they’re very easy to miss. With this fluorescence, the background looks red and the insect looks green. I was like, you can just see it!”

Though the tool can’t spot insects hiding behind leaves, Song said the blue light can definitely be helpful.

“We actually bought one more unit,” Song said. “Now, everywhere we go, we travel with it.”

For more information

The study appeared in American Entomologist in March. A grant to Song from the USDA provided funding for the study.

Rangel Receives COALS Dean’s Outstanding Achievement Award for Diversity

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Dr. Juliana Rangel, left, with Dr. Patrick Stover, Vice Chancellor and Dean, Agriculture and Life Sciences
Dr. Juliana Rangel, left, with Dr. Patrick Stover, Vice Chancellor and Dean, Agriculture and Life Sciences. Photo by Rob Williams

Congratulations to Dr. Juliana Rangel as she received the College of Agriculture and Life Sciences Dean’s Outstanding Achievement Award for Diversity on Friday, January 10.

The award was given at a special awards breakfast before the College of Agriculture and Life Sciences’ session at the AgriLife Conference held at the Texas A&M Hotel and Conference Center.

Rangel is an assistant professor in the Department where she conducts honey bee biology research. Since joining the department in 2013, she has mentored a total of 19 undergraduate students in which 10 are women and six are in a highly underrepresented minority group. She also has successfully recruited 3 students from the Texas A&M University’s Scholar Program and 3 from the National Science Foundation’s Research Experience for Undergraduates program, which are very highly competitive programs.

Rangel is a very strong advocate for students in the department and is a member of the Graduate Admissions Committee and the chair of the Travel Grant Subcommittee. Rangel also served as the Faculty Advisory Committee and was Chair and Co-Chair of the Graduate Research Forum and member of the Graduate Diversity Fellowship Selection Committee.

Rangel currently coaches the Department’s undergraduate and graduate Linnaean Teams. These teams compete with other universities at both the Southwestern Branch and national Entomological Society of America meetings in a quiz bowl style competition testing entomological knowledge. Since she has been coach, the undergraduate team has won first place at the national Linnaean Games in Denver in 2017 and second place in 2018 at Vancouver.

Rangel also has been very involved in service where she has participated in numerous activities related to extending honey bee biology knowledge to the community. Some of these activities included having at the Brazos Valley Museum of Natural Science’s Boonville Days and annual “Wish on a Butterfly” butterfly release events. She also has participated in the Brazos Valley Beekeepers’ annual Bee School, and the College of Agriculture and Life Sciences’ annual tailgate. Rangel has served internationally as the faculty advisor for Café y Miel Program for Beekeepers in Latin America.

“I am humbled and honored to be receiving this award, which I hope will help bring about an increase in diversity and inclusion in our department, our college and our institution,” she said.  “As the field of entomology grows, it is becoming more diverse and inclusive. But we can all do more to break barriers and invite all members of our society to hear about our research and the importance of entomology-related fields in everyone’s daily lives. I look forward to using this award as an opportunity to start conversations that lead us to a more colorful and vibrant community!”

Professor Participates in Post-Graduate Program Planning Workshop in Brazil

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Dr. Cecilia Tamborindeguy speaking
Dr. Cecilia Tamborindeguy speaking to participants of a special workshop held at the State University of Maringa in Maringa, Brazil. Photo by Dr. William de Carvalho Nunes.

Texas A&M Entomology professor Dr. Cecilia Tamborindeguy spent the second week in December helping members of the State University of Maringá plan the future for its post-graduate Agronomy program during a special workshop meeting at the university from December 9-12.

During her visit, Tamborindeguy gave a two-day course on Tools to Study Vector-Borne Plant Diseases in Maringá, she also gave a seminar on the study of plant-psyllids-Liberibacter interactions in the Umuarama Campus.

Finally, Tamborindeguy spoke about her research and what she does at the Department of Entomology at Texas A&M and shared some insights about her research and her experiences being a faculty member. She also talked about the challenges she faces working in an academic setting.

The workshop was held to help come up with written degree plans that masters and doctorate level students in the program can follow, with the finished product to be submitted to the State Superintendent of Science, Technology, and Higher Education in the Brazilian State of Paraná at a later date.

Some of the other speakers at the workshop included CEO of Paranaense Institute of Technical Assistance and Rural Extension, Natalino Avance de Souza, and PGA coordinator Marcos Rafael Nanni and PGA adjunct coordinator William de Carvalho Nunes.

“I have been working with Dr. Nunes for 5 years. As part of this collaboration Angelica Frias spent 6 month in my lab and we plan to continue our collaboration,” Tamborindeguy said. “Both universities are keen in increasing the international impact of our programs. These efforts enrich our students and allow them to have a global perspective of the importance of their research.”

Tamborindeguy said that all the participants enjoyed the workshop.

“I was very well-received and the students were invested in the class and came in great numbers to the seminar,” she said.