- Author: Kathy Keatley Garvey
The seminar, set for 4:10 p.m., Pacific Time, will be virtual only, announced seminar series coordinator Emily Meineke, an urban landscape entomologist and assistant professor.
The Zoom link: https://ucdavis.zoom.us/j/95882849672.
His abstract: "Because they vector pathogens to humans, mosquitoes impact millions of people every year. The global strategy for the management of mosquito-borne diseases involves controlling vector populations, to a large extent, through insecticide application. However, vector-borne diseases are now resurgent, largely because of rising insecticide resistance in vector populations and the drug resistance of pathogens. In this context, the Vinauger Lab studies the molecular, physiological, and neural basis of mosquito behavior. We rely on a collaborative, integrative, and
multidisciplinary approach, at the intersection between data science, neuro-ethology, molecular biology, and chemical ecology. Our long-term goal is to identify targets to disrupt mosquito-host interactions and reduce mosquito-borne disease transmission."
On his website, Vinauger elaborates: "The ability of mosquitoes to detect, process, and respond to olfactory information emitted by their hosts can affect disease transmission. The magnitude of their responses to host and plant odors varies drastically throughout the day, but, despite their clear epidemiological relevance, the neural and molecular mechanisms acting at the circuit levels to control mosquito behavior remain to be determined. In the lab, we employ an interdisciplinary approach combining behavioral assays, electrophysiological recordings, transcriptomic analysis, and CRISPR/Cas9 gene editing, to characterize rhythms in odorant detection, perception, and olfactory behavior, thereby identifying the genetic basis of the temporal plasticity in mosquito-host interactions."
Molecular geneticist and physiologist Joanna Chiu, professor and vice chair of the Department of Entomology and Nematology and a Chancellor's Fellow, will serve as the host. "I have very high regard for Dr. Vinauger's integrative and multidisciplinary research into the biochemical and neurophysiological basis of insect behavior," Professor Chiu said. "His research program is innovative and rigorous, leveraging techniques in quantitative behavioral analysis, bioengineering, neurobiology, and computational methods to address exciting and important questions in mosquito biology and behavior."
The Vinauger lab "studies the molecular, physiological, and neural basis of mosquito behavior," according to its website. "We are a group of experimental biologists, relying on a collaborative, integrative, and multidisciplinary approach, at the intersection between data science, neuro-ethology, molecular biology, and chemical ecology. Our long-term goal is to identify targets to disrupt mosquito-host interactions and reduce mosquito-borne disease transmission."
The Vinauger lab's latest publication, "Visual Threats Reduce Blood-Feeding and Trigger Escape Responses in Aedes aegypti Mosquitoes," appears in the Dec. 9, 2022 edition of Scientific Reports.
The abstract:
"The diurnal mosquitoes Aedes aegypti are vectors of several arboviruses, including dengue, yellow fever, and Zika viruses. To find a host to feed on, they rely on the sophisticated integration of olfactory, visual, thermal, and gustatory cues emitted by the hosts. If detected by their target, this latter may display defensive behaviors that mosquitoes need to be able to detect and escape in order to survive. In humans, a typical response is a swat of the hand, which generates both mechanical and visual perturbations aimed at a mosquito. Here, we used programmable visual displays to generate expanding objects sharing characteristics with the visual component of an approaching hand and quantified the behavioral response of female mosquitoes. Results show that Ae. aegypti is capable of using visual information to decide whether to feed on an artificial host mimic. Stimulations delivered in a LED flight arena further reveal that landed Ae. aegypti females display a stereotypical escape strategy by taking off at an angle that is a function of the direction of stimulus introduction. Altogether, this study demonstrates that mosquitoes landed on a host mimic can use isolated visual cues to detect and avoid a potential threat."
Vinauger joined the Virginia Tech faculty in October 2017, after serving as a postdoctoral research associate at the University of Washington, Seattle. Educated in France, he received his bachelor of science degree in biology/biological sciences in 2006 from the University of Orléans; his master's degree in 2008 from the University of Tours, France; and his doctorate in 2011 from the University of Tours, Research Institute on Insect Biology.
The UC Davis Department of Entomology seminars are held on Wednesdays through March 15. (See schedule.) Eight of the 10 will be in-person in 122 Briggs Hall, and all will be virtual.
- Author: Kathy Keatley Garvey
Winokur will discuss "Temperature Drives Transmission of Mosquito-borne Pathogens: Improving Entomological Estimates for Aedes aegypti-borne Virus Transmission Risk." Her seminar will be both in-person and virtual. The Zoom link:
https://ucdavis.zoom.us/j/95882849672.
"The mosquito Aedes aegypti is the primary vector of a range of viruses that cause a major burden on human health worldwide, including dengue, Zika, chikungunya, and yellow fever viruses," Winokur writes in her abstract. "As the Zika epidemic emerged in 2016, estimates for Zika risk were based on proxy evidence from closely related dengue virus. To improve risk estimates, we studied how temperature affects Zika virus extrinsic incubation period. We sought to further improve risk estimates by studying thermal preferences of Ae. aegypti mosquitoes in the laboratory and in the field. Current mosquito-borne pathogen risk models primarily use temperatures from weather stations or thermal imagery as a proxy for the temperatures mosquitoes experience, however such approaches do not account for local environments or microclimates available to adult mosquitoes. Taken together, the results of these studies can be used to improve prediction of mosquito-borne pathogen risk and inform mosquito control decisions."
A doctoral student at UC Davis since 2016, Winokur is studying for her PhD in entomology with a designated emphasis in the biology of vector-borne diseases. She will submit her dissertation in October and officially graduate then, "although I participated in the doctoral ceremony in June," she related. "I will be a postdoc in the Barker lab working with VectorSurv (https://vectorsurv.org/), and also have a PacVec postdoctoral fellowship (https://pacvec.us/) to dedicate 25 percent of my time to "Enriching Practical Learning Resources for Entomological, Medical, and One-Health Curricula.'
Olivia received her bachelor's degree in May of 2015 from Cornell University where she was an interdisciplinary studies major (environmental effects on human health).
At UC Davis, Winokur served as the 2019-2020 president of the Entomology Graduate Student Association and as a 2020-2022 committee member of the UC Davis Entomology Diversity, Equity, Inclusion, & Belonging. She co-founded the Girls' Outdoor Adventure in Leadership and Science (GOALS) in 2017 and continues to serve in leadership roles. GOALS is a free two-week summer science program for high school girls and gender expansive youth from backgrounds underrepresented in STEM fields. They learn science, outdoors skills, and leadership hands-on while backpacking in Sequoia National Park.
In academic leadership, Winokur co-developed a Stanford course in 2019 on "How Vector-Borne Diseases Have Shaped Human History" and co-developed a syllabus and mentored students. She also co-developed a UC Davis course (2019, 2019, 2020) with other entomology graduate students on "The Natural History of Insects." She has served as both a teaching assistant and lecturer, as well as a mentor.
Active in the vector-borne disease community, Winokur completed a 2019-2020 term as the Executive Council student representative for the American Committee on Medical Entomology (ACME) and as a 2017-2019 volunteer with the Vector-Borne Disease Section of the California Department of Public Health, where she assisted with hantavirus and plague surveillance. She peer-reviews manuscripts for the Journal of Medical Entomology.
Winokur is the recipient of numerous fellowships and grants, including a $140,00 National Science Foundation Graduate Research Fellowship; a $30,000 Pacific Southwest Center of Excellence in Vector-Borne Diseases Graduate Fellowship; a $25,000 Pacific Southwest Center of Excellence in Vector-Borne Diseases Postdoctoral Fellowship; a Professors for the Future Fellowship (UC Davis) of $3,000; and two-consecutive Hazeltine Student Research Awards (UC Davis), totaling $5,500. She also received an American Geophysical Union Centennial Grant of $9,720 and an American Association for University Women Community Action Grant of $5,000 (outreach grants).
Winokur's latest peer-reviewed publications include co-authoring "The Influence of Vector-borne Disease on Human History: Socio-Ecological Mechanisms" in the journal Ecology Letters; and serving as the lead author of "Impact of Temperature on the Extrinsic Incubation Period of Zika Virus in Aedes aegypti in the journal PLOS (Public Library of Science): Neglected Tropical Diseases.
Emily Meineke, assistant professor of urban landscape entomology, UC Davis Department of Entomology and Nematology, coordinates the department's seminars for the 2022-23 academic year. All 11 seminars will take place both person and virtually at 4:10 p.m. on Wednesdays in Room 122 of Briggs Hall except for the Nov. 9th and Dec. 7th seminars, which will be virtual only, she said. (See list of seminars)
For further information on the seminars or technical difficulties with Zoom, contact Meineke at ekmeineke@ucdavis.edu.
- Author: Kathy Keatley Garvey
The Zoom seminar, open to all interested persons, will take place from 4:10 to 5 p.m. Click here for the form to obtain the Zoom link to connect.
"In this talk, we are going to demonstrate the tripartite interactions between the microbiome, mosquitoes of the genus Aedes and Zika virus that they transmit," she says. Aedes albopictus is also known as the Asian tiger mosquito.
"My research focuses on the tripartite interactions between the microbiome, mosquitoes as vectors and the arboviruses they transmit," Onyango says. "In addition, I am interested in the role the vector-host- pathogen interface plays in enhancing disease severity in the vertebrate host. The goal of my research is to develop innovative control mechanisms both for the vector and pathogens they transmit."
Host is medical entomologist-geneticist Geoffrey Attardo, assistant professor, UC Davis Department of Entomology and Nematology. Cooperative Extension specialist and assistant professor Ian Grettenberger coordinates the fall seminars.
"Dr. Maria Onyango works on the biology underlying interactions between arboviruses (Zika virus), vector mosquitoes and the associated microbiome," Attardo said.
Along with seven other scientists, Attardo and Onyango co-authored a research article in the Oct. 2nd edition of Frontiers in Microbiology on"Zika Virus Infection Results in Biochemical Changes Associated With RNA Editing, Inflammatory and Antiviral Responses in Aedes albopictus."
The abstract:
"Rapid and significant range expansion of both the Zika virus (ZIKV) and its Aedes vector species has resulted in the declaration of ZIKV as a global health threat. Successful transmission of ZIKV by its vector requires a complex series of interactions between these entities including the establishment, replication and dissemination of the virus within the mosquito. The metabolic conditions within the mosquito tissues play a critical role in mediating the crucial processes of viral infection and replication and represent targets for prevention of virus transmission. In this study, we carried out a comprehensive metabolomic phenotyping of ZIKV infected and uninfected Ae. albopictus by untargeted analysis of primary metabolites, lipids and biogenic amines. We performed a comparative metabolomic study of infection state with the aim of understanding the biochemical changes resulting from the interaction between the ZIKV and its vector. We have demonstrated that ZIKV infection results in changes to the cellular metabolic environment including a significant enrichment of inosine and pseudo-uridine levels which may be associated with RNA editing activity. In addition, infected mosquitoes demonstrate a hypoglycemic phenotype and show significant increases in the abundance of metabolites such as prostaglandin H2, leukotriene D4 and protoporphyrinogen IX which are associated with antiviral activity. These provide a basis for understanding the biochemical response to ZIKV infection and pathology in the vector. Future mechanistic studies targeting these ZIKV infection responsive metabolites and their associated biosynthetic pathways can provide inroads to identification of mosquito antiviral responses with infection blocking potential."
Onyango holds two degrees from the University of Nairobi, Kenya: a bachelor of science degree in biochemistry and zoology and a master's degree in applied parasitology. She received her doctorate in veterinary entomology from Deakin University and Australian Animal Health Laboratory, Commonwealth Scientific and Industrial Research Organisation (CSIRO), and then completed postdoctoral training at the Yale School of Public Health, Department of Epidemiology of Microbial Diseases.
For any technical issues regarding the seminar, contact Grettenberger at imgrettenberger@ucdavis.edu
- Author: Kathy Keatley Garvey
They're all heavily involved in mosquito research and each won a Bill Hazeltine Student Research Award, presented annually by the Hazeltine family.
And they all have stories to tell.
Stephanie Kurniawan
Stephanie Kurniawan is working on her master's degree, studying with major professors Ed Lewis and Shirley Luckhart. “Though I have lived in California my entire life, I often visited relatives in Indonesia,” she said. “During one trip when I was in middle school, I got dengue and had to be hospitalized for several days. No one in America knew about this disease, not even my pediatrician. This made me interested in vector-borne diseases and mosquitoes.”
Kurniawan went on to receive her degree in animal biology with a minor in medical and veterinary entomology at UC Davis.
“I am adapting methods for estimating age structure of Anopheles mosquito populations using the captive cohort method developed by Dr. James Carey. It is a potentially inexpensive and practical alternative for real-time surveillance of mosquito populations. I currently am testing this method on local populations of Anopheles freeborni from Sutter and Butte County rice fields.”
Sandy Olkowski
Sandy Olkowski is working on her doctorate in entomology, studying with medical entomologist Thomas Scott, emeritus professor of entomology.
“While working for a pediatrician when I was living in Thailand, I became aware of the significant disease burden that dengue places on populations in developing countries,” Olkowski said. “I returned to the United States with the goal of doing whatever I could to alleviate that burden, and subsequently applied to UC Davis because of the ground-breaking dengue research of Thomas Scott. I conducted research for my senior honors thesis in the Scott lab while completing a bachelor's degree in economics, with a focus on international development. I then continued on into a PhD in Entomology, with a designated emphasis in biology of vector-borne diseases. I am entering the 4th year of my PhD. I recently returned from 10 months of fieldwork in Iquitos, Peru.”
“My research is focused on dengue disease surveillance,” Olkowski said. “I am interested in identifying and quantifying ways that human behavior affects surveillance data. Rapid detection of increases in dengue cases is very important for public health officials, so they can implement vector control in a timely manner, but delays in treatment seeking by patients and clinical diagnosis by physicians may be impeding that process. I hope that the results of my research can be directly applied. Eventually, I would like to be able to sit down with public health officials and discuss evidence-based improvements to dengue surveillance.”
Maribel "Mimi" Portilla
Maribel "Mimi" Portilla has her master's degree in public health. “As many scientists, I am a very curious person, intrigued by multifaceted questions about the world around me,” Portilla said. “ As an undergraduate at Santa Clara University, I quickly found my calling to the sciences, and I double-majored in Biology, with an emphasis in ecology and evolution, and combined health sciences. However, I often found myself wondering how I could take my new knowledge and apply it in a way that would be beneficial to others. Completing a minor in sociology at SCU became pivotal in my search for a graduate program. I found that public health incorporated my love for biology and my growing interest in social issues. At UC Berkeley School of Public Health, I was able to study health and disease within a larger context, and how to consider the biology and the social determinants of disease."
"After completing my master's in public health with an emphasis in infectious diseases and vaccinology, I realized I really missed the research experiences I had as an undergraduate, and so I looked for a way to bridge my new-found passion for Public Health and basic science research. This led me to UC Davis, where I am now pursuing a Ph.D in medical entomology. At UC Davis I learned about One Health, which states that the health of people, the environment, and animals is closely intertwined, and a seamless interaction between disciplines is critical for the health of all. Medical entomology is inherently a prefect field in which to ask questions about how the interactions between humans and animals impact health."
"Within One Health theory, I am particularly interested in how people manipulate the environment in ways that change the risk of disease by arthropod vectors, such as mosquitoes," Portilla said. "Although environmental manipulation is a classic mosquito control technique, indirect effects of managing other concerns, such as invasive weeds, is not well understood. I am focusing on how the management practices of the invasive exotic weeds, Brazilian waterweed (Egeria densa) and water hyacinth (Eichhornia crassipes), in the Sacramento-San Joaquin Delta impact mosquitoes and their habitat. My goal is to better understand the ecology of these management practices in order to inform and create better techniques to reduce both mosquito and weed problems.”
“Due to my diverse interests and skill set, I am very open about my career choices. I have extensive teaching experience, and would love to be a professor with both teaching and research opportunities. However, there are many work opportunities beyond academia. My research is introducing me to many government organizations, such as Vector Control districts, who are doing important work and research to keep people safe and healthy. I hope to continue developing a strong research skill set while at UC Davis, and find a career path which takes advantage of my diverse abilities and love for One Health and Public Health. “
William Emery Hazeltine II
William Emery Hazeltine II (1926-1994), for whom the Bill Hazeltine Student Research Award is named, worked tirelessly in mosquito research. He managed the Butte County Mosquito Abatement District, Oroville, from 1966 to 1992. He was an ardent supporter of the judicious use of public health pesticides to protect public health.
Hazeltine studied entomology in the UC Berkeley graduate program, 1950-53, and received his doctorate in entomology from Purdue University in 1962.
He managed the Lake County Mosquito Abatement District from 1961-64 and the Butte County Mosquito Abatement District from 1966-1992. He continued work on related projects until his death in 1994.
Two of his sons actively support the memorial fund: Craig of Scottsdale and Lee of Woodland. A third son, Jeff of Los Angeles, supported the memorial award until his death in March 2013.
Dec. 8, 2010
He managed the Butte County Mosquito Abatement District, Oroville, from 1966 to 1992. He was an ardent supporter of the judicious use of public health pesticides to protect public health.
Hazeltine studied entomology in the UC Berkeley graduate program, 1950-53, and received his doctorate in entomology from Purdue University in 1962.
He managed the Lake County Mosquito Abatement District from 1961-64 and the Butte County Mosquito Abatement District from 1966-1992. He continued work on related projects until his death in 1994.
Bruce Eldridge, emeritus professor of entomology at UC Davis, eulogized him at the 2005 annual meeting of the American Mosquito Control Association (April 4) as "a man who made a difference." His talk, illustrated with photos, was published in the 2006 edition of the Journal of the American Mosquito Control Association. (See PDF)
"He was a medical entomologist who had a varied career in the field of mosquito biology and control, but he will forever be remembered as a man who fought in the trenches of the pesticide controversy from 1960 until the end of his life, and who made the safe and efficient use of pesticides in public health a personal crusade," Eldridge said.
Eldridge noted that Hazeltine "was an advocate for the use of mosquito control to protect people from mosquitoes and the disease agents they transmit, and he believed chemical control to be a necessary part of the means to accomplish this. He also considered himself an environmentalist, and billed himself as such on his business cards and on his signature block. He had a vast knowledge of pesticides and pesticide legislation, and a strong belief in the scientific basis for public policy issues related to the safe and effective use of pesticides. Because the federal Endangered Species Act influenced mosquito control, he became an authority on this as well."
Hazeltine's message about pesticides never strayed, Eldridge sad. His positions on pesticide use and regulation included:
1. Decisions on pesticide use should be made by competent people and based on good data
2. Biological contorls are good, and must be used, but chemicals are also necessary for an effective program.
3. When you discuss pesticides, do not stipulate to something just to get acceptance.
4. There is a real need for continuing educaiotn, which is a mark of professionalism.
In closing, Eldridge said that much of AMCA's current involvement with federal legislation affecting mosquito control stems from Hazeltine's work.
Hazeltine, born Sept. 4, 1926 in San Jose, was the youngest of six children born to Karl Snyder Hazeltine and Rachel Josephine Crawford Hazeltine. Karl, a graduate of the University of California, served on the faculty of San Jose State University, where he taught agricultural and natural science. Rachel, a graduate of San Jose State, was a teacher.
William Hazeltine's son, Craig, of Scottsdale, Ariz: commented: "Three recollections: Dad grew and changed over the years. The reports may cast him as a constant iconoclast, but he learned to love and be loved. When I became a Christian in college, I felt compelled to tell my Dad 'I love you' often and to back it up with a hug. He was like a stiff board at first, but later on was almost a menace with his wonder hugs.
"Dad was not so gruff as he was 'occupied.' I figured out early on that the best way to spend time with him was to help him with his projects--and there was always something in the works. He was always reading, studying, and trying new things.
"Dad was extremely well-documented. After a debate at Chico State in the late 60s, we talked about having references at the ready to refute bad arguments. This led to a couple of very full boxes that traveled in the trunk of his car with copies of published works that backed up his positions. And that in addition to the famous stacks of re-prints in his home office."
Today the work of William Emery Hazeltine II lives on through the William Hazeltine Memorial Student Research Fellowship Awards. UC Davis students studying mosquitoes are eligible to apply for the award.
Recipients:
2016: Sandy Olkowski, Maribel “Mimi” Portilla and Stephanie Kurniawan
2015: Sandy Olkowski, Maribel “Mimi” Portilla and Stephanie Kurniawan
2014: Martha Armijos, Elizabeth “Lizzy” Glennon and Rosanna Kwok
2013: Jenny Carlson, Elizabeth “Lizzy” Glennon and Sandy Olkowski
2012: Jenny Carlson, Kelly Liebman and Sandy Olkowski
2011: Brittany Nelms Mills, Kelly Liebman and Jenny Carlson
2010: Tara Thiemann and Jenny Carlson
2009: Kelly Liebman and Wei Xu
2008: Ashley Horton and Tara Thiemann
2007: Lisa Reimer and Jacklyn Wong
2006: Christopher Barker and Tania Morgan
2005: Nicole Mans
2004: Sharon Minnick
2003: Hannah Burrack
2002: Holly Ganz and Andradi Villalobos
2001: Laura Goddard and Linda Styer
2000: Laura Goddard
1999: Linda Boose Styer
1998: Larisa Vredevoe
1997: John Gimnig
--Kathy Keatley Garvey
Communications specialist
UC Davis Department of Entomology
(530) 754-6894