- Author: Kathy Keatley Garvey
Nayduch, based in Manhattan, Kansas, will speak at 4:10 p.m., Wednesday, March 1 in 122 Briggs Hall. Her lecture also will be virtual. The Zoom link:
https://ucdavis.zoom.us/j/95882849672
"Dana is doing very cool work with house flies and looking at how bacteria in the fly are trading antibiotic resistance genes amongst themselves," said the seminar host, medical entomologist-geneticist Geoffrey Attardo, assistant professor, UC Davis Department of Entomology and Nematology. "It's an interesting and scary system as antibiotic resistance is so high due to antibiotic usage in livestock rearing."
"House flies (Musca domestica L.) are ubiquitous, cosmopolitan pests inhabiting urban, rural and agricultural environments throughout the world. In these habitats acquire microbes from septic substrates that are used for feeding and reproduction. Flies subsequently harbor and disseminate these microorganisms which may pose a risk to human and animal health," Nayduch says in her abstract. "Our research characterizes and analyzes microbial communities of house flies using culture-based and molecular approaches in order to better understand their roles in the transmission of important bacterial disease agents and/or antimicrobial resistance. Because the microbial communities within house flies represent a snapshot of the microbes found in their local habitat, we also gain valuable insight into existing and emerging microbial threats to humanand animal health through our surveys which can help in predicting and preventing disease."
A pre-seminar will take place from 3:30 to 4:10 in 158 Briggs.
Nayduch, an authority on fly-microbe interactions, joined USDA in August of 2011. She is a member of the USDA-ARS Arthropod-Borne Animal Diseases Research Unit, researching molecular and microbiological studies of Culicoides midges and house flies. She works with several laboratories on comparative transcriptomic and microbiomic studies of Muscid flies.
Nayduch received her bachelor's degree in animal science from Rutgers University and her doctorate in zoology from Clemson University, where she studied house flies as vectors for pathogens. She served as a postdoctoral fellow at Yale University School of Public Health, working on molecular-genetic studies of tsetse flies. She then joined Georgia Southern University (GSU) as an assistant professor of biology in 2004, advancing to associate professor in 2009. At GSU she received NIH-R15 funding to study house fly-microbe molecular interactions.
Nayduch, active in the Entomological Society of America (ESA), is the vice president-elect of the Medical, Urban and Veterinary Entomology (MUVE) Section. A peer reviewer for the Journal of Medical Entomology and an editorial board member and subject editor for Annals for ESA, she organized and edited the first special collection for Annals: “Filth Fly-Microbe Interactions."
The UC Davis Department of Entomology and Nematology's winter seminars are held on Wednesdays at 4:10 p.m. in 122 Briggs Hall. All are virtual. A pre-seminar coffee is held from 3:30 to 4:10 p.m. in 158 Briggs. Urban landscape entomologist Emily Meineke, assistant professor, coordinates the seminars. (See schedule.) She may be reached at ekmeineke@ucdavis.edu for technical issues.
- Author: Kathy Keatley Garvey
The seminar is open to all interested persons. The Zoom link is https://ucdavis.zoom.us/j/99515291076.
Heck, who focuses her USDA-ARS research on the discovery and characterization of insect vector-plant-pathogen interactions, serves as a lead scientist and research molecular biologist with the Emerging Pests and Pathogens Research Unit, located in the Robert W. Holley Center for Agriculture and Health, Ithaca.
The invasive pest, Asian citrus psyllid, is a threat to America's citrus industry and causes serious damage to citrus plants and citrus plant relatives, according to a USDA Fact Sheet. "Burned tips and twisted leaves result from an infestation on new growth. Psyllids are also carriers of the bacterium that causes Huanglongbing (HLB) disease, also known as citrus greening disease, spreading the disease to healthy citrus plants. Citrus greening is one of the most serious citrus plant diseases in the world. Once a tree is infected, there is no cure."
"Vector-borne diseases are among the most challenging problems in agriculture," says Heck, who plans and conducts sophisticated experiments using a variety of molecular, genetic and functional genomics methods to gain a deeper understanding of vector-borne plant pathogens.
"Research planning involves novel, exceptionally difficult, team research that is subdivided into multiple phases with agency stakeholders," Heck says. Her research "integrates developed knowledge into applied agricultural practices to create novel management strategies for vector-borne plant diseases and the insect vectors." She conducts her studies in support of the USDA-ARS NP 304 Action Plan: Crop Protection and Quarantine, Problem Statement 3A2, a systems approach to environmentally sound pest management.
Heck, who holds a bachelor's degree in biology from Boston University, received her doctorate from.Cold Spring Harbor Laboratory, Cold Spring, N.Y. She completed her postdoctoral training in vector biology and mass spectrometry-based proteomics. Her research on protein interactions and protein transport in plants and insects spans more than 20 years, resulting in an international reputation as a vector biology authority skilled in the management of vector-borne plant diseases. Heck is a lead in the USDA-ARS Citrus Greening Grand Challenge, the agency's coordinated national response to combat citrus greening disease and the agency's scientific representative on the National Cotton Council's Cotton Leafroll Dwarf Virus Task Force.
Heck has published more than 50 peer-reviewed journal articles, book chapters, and several patents. Her peers have recognized her scientific excellence with a number of awards, including a 2017 Presidential Early Career Award for Scientists and Engineers from the Obama White House Office of Science and Technology Policy.
For technical issues involving the seminar, contact Siddique at siddique@ucdavis.edu.
- Author: Kathy Keatley Garvey
Research entomologist Daniel Hasegawa of the Crop Improvement and Protection Research Unit, Agricultural Research Service, U. S. Department of Agriculture, will speak on "Landscape and Molecular Approaches for Managing Thrips and Thrips-Transmitted Viruses in the Salinas Valley" at the UC Davis Department of Entomology and Nematology's first seminar of the winter quarter on Wednesday, Jan. 20.
His virtual seminar begins at 4:10 p.m., announced agricultural Extension specialist Ian Grettenberger, seminar coordinator. To access the seminar, fill out this Google form link.
"In 2019-2020, lettuce production in the Salinas Valley of California was devastated by thrips-transmitted impatiens necrotic spot virus (INSV)," Hasegawa says in his abstract. "Due to the inherent challenges in managing thrips using conventional chemical tactics, and no direct means for managing the virus, there is a strong need for new management strategies. This seminar will provide an overview of (1) the challenges in managing thrips and INSV in lettuce production, (2) what we've learned about the epidemiology of thrips and INSV, and (3) opportunities to improve cultural practices and develop biotechnology tools, such as RNAi for managing thrips and INSV in the Salinas Valley."
Hasegawa joined the Salinas USDA-ARS team in May 2019 after serving as a postdoctoral research associate (molecular biology) for three years with USDA-ARS in Charleston, S. C. He specializes in vector entomology, molecular biology and biotechnlogy. "My lab uses a variety of techniques to understand insect vector-virus relationships that impact plant health and agriculture," he says on Linked In. "We use molecular, genetic, and epidemiological concepts to understand drivers of vector-borne transmission of pathogens and utilize genetic technologies (e.g. RNAi and CRISPR), to improve agriculture productivity and sustainability."
Hasegawa received his bachelor of science degree in biochemistry in 2007 from UC Riverside and his doctorate in biology from Clemson University in 2013.
The mission of the Crop Improvement and Protection Research Unit is to improve germplasm of lettuce, spinach and melon, determine basic biology of viral, fungal and bacterial diseases affecting these crops, develop alternatives to methyl bromide as a soil fumigant for control of soilborne pests in strawberry and vegetables, reduce postharvest losses of lettuce, develop scientifically based organic crop production practices, and develop methods for control of weeds. See more on the Pacific West Area website.
/span>- Author: Kathy Keatley Garvey
The event is scheduled to begin at 1 p.m. The site is located next to the Harry H. Laidlaw Jr. Honey Bee Research Facility.
“The focus of this new USDA-ARS honey bee research program is to develop technology that improves colony survivorship through long-term studies of multiple stress factors,” a spokesman said. “These new facilities support two recently hired researchers: Drs. Arathi Seshadri and Julia Fine. These new scientists and associated technical staff are members of the Invasive Species and Pollinator Health Research Unit, whose mission is to develop and transfer integrated biologically based approaches for the management of invasive species and the improvement of pollinator health. The research team collaborates with federal, university, non-governmental and industry partners conducting research to improve honey bee survival and beekeeping sustainability in California and nationwide."
Research leader Paul Pratt of the Invasive Species and Pollinator Health Research Lab will give the welcoming address, followed by the presentation of colors by the Travis Air Force Base Honor Guard.
Among the speakers: Robert Matteri, director of the Pacific West Area, USDA-ARS; Anita Oberbauer, associate dean, UC Davis College of Agricultural and Environmental Sciences; and Kevin Hackett, national program leader, USDA-ARS.
The two new researchers will be introduced, followed by remarks by Darren Cox of Cox Honey of Utah, past president of the American Honey Producers' Association; Jackie Parks-Burris, past president of the California State Beekeepers' Association; and Extension apiculturist Elina Lastro Niño of the UC Davis Department of Entomology and Nematology and the Harry H. Laidlaw Jr. Honey Bee Research Facility. Niño also directs the California Master Beekeeper Program.
The event is open to invited guests. All guests are invited to tour the new facilities following the program. A stakeholder meeting is set from 2:30 to 3:30 p.m. in the Laidlaw bee facility classroom. For more information,contact Platt at paul.pratt@usda.gov.
- Author: Kathy Keatley Garvey
See full paper
DAVIS--Hear that honey bee buzzing toward a flower? It's not just the nectar that she's scented.
Nectar-living microbes release scents or volatile compounds, too, and can influence a pollinator's foraging preference, according to newly published research led by UC Davis community ecologist Rachel Vannette.
The groundbreaking research, published in the current edition of New Phytologist journal, shows that nectar-inhabiting species of bacteria and fungi “can influence pollinator preference through differential volatile production,” said Vannette, an assistant professor in the UC Davis Department of Entomology and Nematology.
“This extends our understanding of how microbial species can differentially influence plant phenotype and species interactions through a previously overlooked mechanism,” Vannette said. “It's a novel mechanism by which the presence and species composition of the microbiome can influence pollination.”
“Broadly, our results imply that the microbiome can contribute to plant volatile phenotype,” she said. “This has implications for many plant-insect interactions.”
Their paper, titled “Nectar-inhabiting Microorganisms Influence Nectar Volatile Composition and Attractiveness to a Generalist Pollinator,” may explain in part the previous documented extreme variation floral volatiles that Robert Junker of University of Salzburg, Austria, and his team found; New Phytologist published their work in March 2017.
Although microbes commonly inhabit floral nectar, microbial species differ in volatile profiles, they found. “Honey bees detected most of the microbial volatiles or scents that we tested,” Vannette said, “and they distinguished the solutions of yeasts or bacteria based on volatiles only.” This suggests that pollinators could choose among flowers based on the microbes that inhabit those flowers.
The yeast Metschnikowia reukaufii produced the most distinctive compounds (some shared with the fruity flavors in wine) and was the most attractive of all microbes compared. This yeast is commonly found in flower nectar and is thought to hitch a ride on pollinators to travel from one flower to the next. Its scent production may help it attract pollinators, which then help the yeast disperse among flowers.
The Harry H. Laidlaw Jr. Honey Bee Research Facility, UC Davis, provided the honey bees. More than 20 species of flowers--mostly natives--were used in the survey, including canyon delphinium or canyon larkspur (Delphinium nudicaule), sticky monkey flower (Mimulus aurantiacus), salvia (Lepechinia calycina) and purple Chinese houses (Collinsia heterophylla). The samplings were done in the spring and early summer, when the natives are at their peak.
Co-authors of the paper are Caitlin Rering, postdoctoral fellow at USDA-ARS, Gainesville, Fla.; John Beck researcher at USDA-ARS; Griffin Hall, junior specialist in the Vannette lab; and Mitch McCartney in UC Davis Department of Mechanical and Aerospace Engineering.
The USDA and USDA-ARS funded the research.