- Author: Kathy Keatley Garvey
UC Davis received three awards:
- Medical entomologist-geneticist Geoffrey Attardo received the Medical, Urban, and Veterinary Entomology Award. (See news story)
- Doctoral student Erin Taylor Kelly of the Attardo lab won the Student Leadership Award (See news story)
- Undergraduate entomology student Gwen Erdosh of the Louie Yang lab and a member of the Research Scholars Program in Insect Biology, won the inaugural Dr. Stephen Garczynski Undergraduate Research Scholarship (See news story)
The branch encompasses 11 Western states, parts of Canada and Mexico and several U.S. territories.
In the United States: Alaska, Arizona, California, Hawai'i, Idaho, Montana, Nevada, Oregon, Utah, Washington, Wyoming
U.S. Territories: American Samoa, the Federated States of Micronesia, Guam, Johnston Atoll, Commonwealth of the Northern Mariana Islands, Midway Islands, Wake Island
In Canada: Alberta, British Columbia, Northwest Territories, Saskatchewan, Yukon
In Mexico: Baja California, Baja California Sur, Sinaloa, Sonora
Congratulations to all the winners!
- Author: Kathy Keatley Garvey
Kelly will be honored at an awards luncheon during the annual PBESA meeting, set April 10-13 in Santa Rosa. The branch encompasses 11 Western states, parts of Canada and Mexico and several U.S. territories.
Kelly, who joined the Attardo lab in 2018, is the two-term president of the UC Davis Equity in STEM and Entrepreneurship (ESTEME) and serves as the vice president of the Entomology Graduate Student Association (EGSA).
"She excels in leadership, as well as in research, academics and public service," wrote Steve Nadler, professor and chair, UC Davis Department of Entomology and Nematology, in his letter of nomination. Known as Taylor, she "is an important role model, sharing her enthusiasm for entomology and other sciences with the public, and eagerly supporting undergraduate students and others on their paths to scientific careers."
Taylor drew strong support from doctoral candidate Jill Oberski, president of EGSA and an active member of ESTEME; ESTEME past president Alexus Roberts, and ESTEME colleague Sophie Zhu. The organization supports greater equity and inclusion in science, helping help low-income, underrepresented, non-traditional students face and overcome the overwhelming barriers in reaching their goals. They also organize and coordinate activities for K-12 students and undergraduates, while also providing professional development events for fellow members.
Helping Fellow Graduate Students. Taylor's leadership activities in EGSA include collaborating with her peers to provide resources to support incoming students. Each year she collects information about awards they can apply for, and the courses that need teaching assistants. "She surveys students on their cost-of-living needs, and works with our administration to secure the assistance they need," wrote Nadler. "She continually shares information related to living in Davis and thriving in graduate school." Since 2019, Kelly has helped the EGSA coordinate the department's UC Davis Picnic Day activities, leading the EGSA committee in 2020-21. She also serves on the UC Davis Graduate Admissions Committee.
Taylor's leadership activities in EGSA include collaborating with her EGSA peers to provide resources to support incoming students. Each year she collects information about awards they can apply for, and the courses that need teaching assistants. "She surveys students on their cost-of-living needs, and works with our administration to secure the assistance they need," wrote Nadler. "She continually shares information related to living in Davis and thriving in graduate school." In addition, she is the EGSA coordinator of the department's UC Davis Picnic Day activities and serves on the UC Davis Graduate Admissions Committee.
Kelly won a coveted first-place award at the Entomological Society of America (ESA) meeting last November with her poster, “Metabolic Snapshot: Using Metabolomics to Compare Near-Wild and Colonized Aedes aegypti.” She has been instrumental in teaching the graduate student offering of ENT 010 (Natural History of Insects).
Her major professor, medical entomologist and geneticist Geoffrey Attardo, praises her strong leadership, her excellence as a doctoral student and her strong leadership role in his lab. "She is dedicated, self-motivated, compassionate, enthusiastic, confident, and demonstrates deep-rooted integrity in how she goes about her work and her interactions with colleagues and students," Attardo wrote in his letter of recommendation. "Within the lab, Taylor plays a strong leadership role, critical to the mentorship of undergraduate researchers who join the lab. Taylor greatly helps assist students with training in experimental design and execution; reading and interpretation of the scientific literature; training in data analysis; and scientific writing. Her mentorship manifested in the publication of a first- author manuscript (van Schoor et al.) by a talented undergraduate researcher in my group. The work explores the relationship between larval dietary composition and adult outcomes in Aedes aegypti mosquitoes. Taylor is always willing to help lab members with their projects and plays a key role in maintaining the lab's welcoming atmosphere and research successes."
People-Motivated. Forensic entomologist Robert Kimsey, the faculty chair of the department's Picnic Day activities, says that "Taylor ranks among the most people-motivated graduate students I have had the pleasure to work with.”
“Setting aside for the moment Taylor's top flight academic background and qualifications, I have found her to be the ideal collaborator, very cooperative, consistently cheerful, perfectly dependable, and delightful to work with,” Kimsey related. “Competition may or may not select for exceptional researchers, but often selects for difficult characters. Taylor almost uniquely combines high productivity and intense curiosity with a delightful personality, an ideal combination to have in a program in which people must survive with each other. She has been an excellent graduate student, very gregarious, conscientious, with an exceptional ability to work with persons of any sort. She ranks among the most people-motivated graduate students I have had the pleasure to work with.”
UC Davis medical entomologist Anthony Cornel, who leads the Mosquito Control Research Laboratory in Parlier, works with Taylor on insecticide resistance in mosquitoes. “Taylor's PhD project is challenging as she endeavors to tease apart the biochemical and genetic factors that cause resistance to some commonly used insecticides to control Aedes aegypti," Cornel wrote. "Ae. aegypti is considered the second most dangerous insect worldwide because of its role in transmission of dengue, yellow fever, Zika and Chikungunya viruses which cause considerable morbidity and mortality. Hence, it is an important organism to study especially to eventually improve measures to control this mosquito."
Critical Thinker. "Taylor has done very well as a PhD student, so far, having 4 publications related to Ae. aegypti, 3 publications on webspinners (Embioptera) and 2 publications related to astrobiology," Cornel related. “My interactions with her convince me that she is a critical thinker and questions everything before undertaking tasks and experiments. These are attributes of a young scientist that will stand her in good stead to become excellent in academia. Almost all successful academics think out of the box and can work independently and collegially. She works with several other graduate and research assistants, and everyone likes her kindness, honesty, and helpfulness. Taylor's interests so far have mostly related to entomology systematics, genetics, and metabolomics. She has expressed her desire to remain as an entomologist beyond her graduate studies. She will always be a wonderful ambassador for entomology and her diverse knowledge of disciplines from systematics to behavior to protein and DNA studies makes her an excellent entomologist indeed.”
Taylor holds a bachelor of science degree in biology, with a minor in chemistry, from Santa Clara University, where she served as president of the campuswide Biology Club and led STEM projects, encouraging and guiding underrepresented students to seek careers in science, technology, engineering and mathematics (STEM).
/span>- Author: Kathy Keatley Garvey
Attardo, who joined the UC Davis Department of Entomology and Nematology in 2017 from the Yale School of Public Health's Department of Epidemiology of Microbial Diseases, “excels not only as a researcher, but as a teacher, mentor, scientific illustrator, macro photographer, videographer and science communicator,” said UC Davis distinguished professor Bruce Hammock in his letter of nomination.
The Attardo lab monitors the dynamics of vector insects at the levels of physiology, population genetics and environmental interactions.
“I have known Geoff personally since July 2017 and I have always admired his scientific expertise, his unbridled enthusiasm, his many talents, and his scores of accomplishments,” wrote Hammock, who holds a joint appointment with the entomology department and the UC Davis Comprehensive Cancer Center. “He leads a highly successful research group that focuses on the molecular biology, biochemistry and physiology of medically important insects. His work, encompassing his research, teaching/mentorship, public service and outreach, brings international recognition to our department, college, university, the UC system and the entomological world.”
Eleven Western States. PBESA will recognize Attardo at an April 12 awards luncheon during its annual meeting, set April 10-13 in the Hyatt Regency Sonoma Wine Country. (link to https://www.entsoc.org/membership/branches/pacific/meeting.) PBESA is comprised of 11 Western states (Alaska, Arizona, California, Hawaii, Idaho, Montana, Nevada, Oregon, Utah, Washington, Wyoming), parts of Canada and Mexico, and seven U. S. territories. (Link to https://www.entsoc.org/membership/branches/pacific)
Attardo received a Ruth Kirshstein National Research Service Award from the National Institutes of Health (NIH) to study the molecular and biochemical physiology of tsetse fly lactation. His results “broadened our understanding of the physiology of live birth and lactation,” said Hammock, adding that his work “was the first to bring to bear state-of-the-art/high-throughput genetic, molecular and biochemical techniques.”
The co-principal investigator of a five-year NIH R01 grant, Attardo led a multinational collaboration resulting in the production, annotation and functional analysis of the first tsetse fly genome sequence.
Attardo is also a talented macro photographer and scientific illustrator, Hammock noted. Science editors featured his tsetse photo on their cover and used his illustrations throughout the article to show the tsetse's unique physiology. Attardo's work also drew high-profile coverage twice in the New York Times.
Attardo's current work focuses on defining the mating physiology of tsetse flies. He uses X-ray based MicroCT scanning to generate high resolution 3-dimensional images of tsetse reproductive tissues to understand the morphological specializations that enable live birth and lactation in tsetse flies. (See Attardo lab)
Attardo collaborated with the KQED (Public Broadcasting Service) “Deep Look” team to produce a YouTube video featuring macro footage and illustrations of tsetse live birth, blood feeding, and mating. The video, winner of a 2020 Northern California Emmy Award, has scored 6.2 million views, as of Jan. 4, 2022.
In a letter of support, molecular geneticist and physiologist Joanna Chiu, vice chair of the UC Davis Department of Entomology and Nematology, wrote in part:
“Dr. Attardo's internationally recognized research program on the physiology and genomics of insect vectors is creative, significant, and always of the highest quality and rigor. His research program seamlessly integrates fundamental mechanistic work and applied research to study physiology and behavior of insects that vector devastating human diseases. His teaching and mentoring program is innovative, inclusive, and he is fiercely supportive of his trainees and junior colleagues. Finally, he is passionate about outreach and extension because he understands the importance and value of transferring technologies from his lab to the field and extending information to benefit stakeholders locally and internationally.”
Very Effective Teaching Style. For the past two years, Chiu and Attardo have been co-teaching an undergraduate animal biology course on “Applications, Social and Ethical Issues in Animal Biology.” Chiu praised his ability to “engage the students” and his “very effective teaching style in helping students build critical thinking skills and confidence.”
Professor Immo Hansen of the Department of Biology, Institute of Applied Biosciences at New Mexico State University, echoed the praise. “Geoff is a prolific scholar with more than 55 publications and an h-index of 30 a value that one might expect for a full professor in the entomology field (my own h-index is 29). His early work on mosquito regulation of gene expression and nutritional signaling pathways as well as his later works on Tsetse genomics, nutrition, milk production, and symbiont interactions are highly original and represent significant increases in our knowledge in insect reproductive physiology.”
“He led the effort to sequence and annotate the genome of the Tsetse fly which resulted in a Science paper,” Hansen pointed out. “Geoff is a leading expert in the field of the molecular basis of insect reproduction (of tsetse flies) which is reflected by the large number of invited presentations he has given over the years. His truly innovative research in the field puts him at the forefront of researchers in his discipline.”
- Author: Kathy Keatley Garvey
"We are working with scientists and public health authorities in STP to establish the conditions that would facilitate an informed societal and government decision about a proposed release of Anopheles mosquitoes engineered to prevent transmission of the malaria parasite Plasmodium falciparum on the islands,” said principal investigator Gregory Lanzaro, director of the Vector Genetics Laboratory and a PMI professor.
This award will be used to extend their ongoing entomological, engagement and capacity building work through 2025.
“We are working in collaboration with the UC Irvine Malaria Initiative (UCIMI), a research consortium including scientists from UC Irvine, San Diego and Berkeley as well as Johns Hopkins University,” Lanzaro said. “We are working toward the application of advanced genetic tools aimed at the mosquito vector. It is our belief that this approach, used in conjunction with early malaria treatment and detection, can provide a cost effective, sustainable, and environmentally responsible program to ultimately eliminate malaria from Africa.”
Said Ana Kormos, engagement program manager and lead author of the proposal: “These funds provide the UCIMI program with support to strengthen our existing relationship-based approach to the co-development of this technology and ensures that our partners in STP lead the decision-making processes involved in all aspects of the research. This is a huge step forward in advancing a truly collaborative approach to translational research.”
The Vector Genetics Laboratory is engaged in research and training in the areas of population and molecular genetics, genomics and bioinformatics of insect vectors of human and animal disease. The website: “We have developed a program aimed at expanding knowledge that may be applied to improving control of disease vectors and that also addresses problems of interest in the field of evolutionary genetics. We are currently engaged in a range of projects, but our major research focus is on vectors of malaria in Africa."
Directors of the Vector Genetics Laboratory research programs are Lanzaro and Anthony "Anton" Cornel, a research entomologist with the UC Davis Department of Entomology and Nematology and director of the Mosquito Control Research Laboratory, Parlier.
New Tools. "The fight to reduce and possibly eliminate malaria continues and becomes especially challenging as efforts to reduce malaria morbidity have plateaued since 2015,” said Cornel. “Therefore, we must seriously consider new tools. One such tool is genetically modifying the major mosquito vector in the Afrotropics so that it cannot transmit malaria."
"The project aims to use genetically modified (GM) mosquito strategy to reduce and eliminate malaria from the Islands of São Tomé and Príncipe, as proof of concept, before using this technology on larger scales on mainland Africa,” Cornel said, adding that his role, as a field team co-investigator for UCIMI and VGL, is to work with Lanzaro and Pinto “to understand as much as we can about the behavior, population structure and population sizes of Anopheles coluzzi (the malaria vector) on these islands to design the most efficient strategy of releasing the genetically modified mosquitoes to have maximum effect.”
Malaria is an acute illness caused by Plasmodium parasites, which spread to humans through the bites of infected female Anopheles mosquitoes, according to the World Health Organization (WHO). In 2020, nearly half of the world's population was at risk of malaria. An estimated 241 million cases of malaria occurred worldwide in 2020, with 627,000 dying.
Tremendous Burden. Medical entomologist and geneticist Geoffrey Attardo of the UC Davis Department of Entomology and Nematology (who is not involved in this project), noted that “Malaria is a disease which creates a tremendous burden on people living in affected areas. In particular its impacts on the mortality in young children and pregnant women are devastating. Attempts to control this disease using traditional methods have been effective in recent years.”
The island nation of São Tomé and Príncipe, population of 178,700 in 2016, is located about 200 miles west of Gabon on Africa's mainland. It shares maritime borders with Equatorial Guinea, Gabon, and Nigeria. The combined area of the archipelago is about five times the size of Washington, DC. The United States established diplomatic relations with São Tomé and Príncipe in 1976, following its independence from Portugal.
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Resource:
São Tomé and Príncipe (nationsonline.org)
- Author: Kathy Keatley Garvey
The work, published in the current edition of Parasites & Vectors, a BioMed Central open-access medical journal, focuses on “determining how informative well-established genetic markers of resistance to pyrethroids are in predicting the resistance phenotype of individual mosquitoes of Aedes aegypti within a population,” said lead author Geoffrey Attardo, medical entomologist-geneticist in the UC Davis Department of Entomology and Nematology.
“Specifically, we generated mosquito colonies from invasive A. aegypti populations from four locations in the Central Valley (Dinuba, Clovis, Sanger and Kingsburg) and from collections in the Greater Los Angeles Area,” he said. “Mosquitoes from these populations have all demonstrated resistance to pyrethroid-type insecticides and we think this may be part of the reason why these mosquitoes have been so successful in spreading throughout California.”
A. aegypti transmits such viruses as dengue, Zika, chikungunya, and yellow fever. Despite California's aggressive surveillance and treatment efforts, this species presents a “significant challenge to local control agencies,” the nine-member team wrote in their research paper, “Frequency of Sodium Channel Genotypes and Association with Pyrethrum Knockdown Time in Populations of Californian Aedes aegypti.“
The paper is online and publicly accessible at https://bit.ly/3vmUxXR.
“What was interesting was that while all the mosquitoes from California show resistance to pyrethroids, there is a lot of variability from one individual to the next in terms of the level of resistance, even when they are carrying genetically identical resistance mutations,” Attardo said. “In particular, there seem to be two levels of resistance in these populations. The two levels seem to represent a resistant group and a super resistant group. However, the proportions of resistant/super-resistant differ in the sampled mosquitoes from population to population.”
Of particular interest was that mosquitoes carrying the resistance mutations at all five genetic locations were very resistant, he said. “However, there was also a large amount of unexplained variability in terms of the knockdown phenotypes demonstrated by mosquitoes of the same age and rearing conditions. We compared the knockdown times of mosquitoes positive for all five resistance mutations from different populations and found that these mutations account for only a proportion of the observed level of resistance. We believe that the unexplained variability is likely being mediated by the presence or absence of an undefined resistance mechanism.”
In launching the project, the researchers designed an assay “to test for the presence of mutations in the gene coding for the pyrethroid target protein, the voltage gated sodium channel (the para gene),” Attardo explained. “Detection of these mutations is used to monitor the level or resistance in populations. However, the actual link between the effect the genotype has on the phenotype of individual mosquitoes has not been looked at in detail. “
The scientists identified mutations from genetic sequences of Californian mosquitoes provided by co-author Yoosook Lee, a former UC Davis mosquito researcher now at the University of Florida-Florida Medical Entomology Laboratory, Vero Beach.
The authors also include research entomologist Anthony Cornel and staff research associate Katherine Brisco of the Mosquito Control Research Laboratory, Kearney Agriculture and Extension Center and UC Davis Department of Entomology and Nematology; and Lindsey Mack, Erin Taylor Kelly, Katherine Brisco, Kaiyuan Victoria Shen, Aamina Zahid, and Tess van Schoor, all with the UC Davis Department of Entomology and Nematology.
First, they tested the individual resistance phenotype of mosquitoes by placing them into bottles coated with the pyrethroid insecticide permethrin, and observed them to determine how long it takes for them to respond to the insecticide. Said Attardo: “This is a modified version of the assay used by the Center for Disease Control and Prevention to evaluate phenotypic resistance in groups of mosquitoes.”
Then they isolated the DNA from and performed a high-throughput genetic analysis on each individual to determine the composition of the five mutations in each individual. Next they looked at the resulting data to see how well knockdown time correlates with individual genotypes of mosquitoes.
Although A. aegypti was first detected in California in 2013, researchers believe that its arrival involved multiple introductions. Populations in Southern California are thought to have crossed the border from Mexico, while Central Valley populations may have been introduced, in part, from the southeastern United States.
“Upon detection in 2013, the Consolidated Mosquito Abatement District implemented an integrated vector control management strategy which involved extensive public education, thorough property inspections, sanitation, insecticide treatment at larval sources and residual barrier spraying with pyrethroids,” the authors wrote. Despite their efforts, the species successfully overwintered and continued to spread, implicating that it arrived in California with genetic mutations “conferring resistance to the type I pyrethroid insecticides applied for vector control in California.”
The project drew financial support from the Pacific Southwest Regional Center of Excellence for Vector-Borne Diseases, funded by the U.S. Centers for Disease Control and Prevention.