- Author: Kathy Keatley Garvey
His seminar begins at 4:10 p.m. Monday, Nov. 6 in Room 122, Briggs Hall, and also will be on Zoom. The Zoom link:
https://ucdavis.zoom.us/j/95882849672
"Growers consider soilborne disease management one of their main production issues," Hong writes in his abstract. "It is estimated that members of the soilborne pest complex (SPC), weeds, nematodes, fungi, oomycetes, bacteria, viruses, and protozoans, account for 10-20 percent crop loss annually worldwide. Methyl bromide was used to manage the SPC, however, it was discovered that it contributed to ozone depletion, thus was banned worldwide. Currently, no registered alternative chemical fumigant is as effective as methyl bromide for SPC management. Anaerobic soil disinfestation (ASD) is biologically based alternative to soil fumigation. ASD consists of amending the soil with a labile carbon source, tarping the soil with a plastic film, and watering the soil under the film to field capacity. During the ASD process the soil microbiome undergoes populations shifts and various anti-microbial compounds are produced. ASD has shown to be as effective as methyl bromide SPC management. This presentation will discuss the history of ASD and current research."
Hong holds a bachelor's degree in microbiology from The Ohio State University and received both his master's and doctorate in plant pathology from the University of Florida. He then served as a post doctoral fellow at West Virginia University, followed by a postdoctoral fellowship at USDA.
See his 2020 YouTube video in which he "discusses his path into the field of plant pathology, and the research that he currently conducts that is improving agricultural output in key food crops. Dr. Hong also highlights the key role that the USDA plays in modern society as the holder of more US patents than any other organization. Dr. Hong focuses his research presentation on techniques that he and his team are developing to increase food production by improving soil microbial health."
Seminar coordinator is Brian Johnson, associate professor, UC Davis Department of Entomology and Nematology. For Zoom technical issues, he may be reached at brnjohnson@ucdavis.edu. The list of seminars is posted here.
- Author: Kathy Keatley Garvey
The seminar is set for 4:10 p.m., Wednesday, May 17 and will only be virtual, announced host Shahid Siddique, nematologist. The Zoom link:
https://ucdavis.zoom.us/j/95882849672.
"The beech leaf disease nematode, Litylenchus crenatae mccannii, is recognized as a newly emergent nematode species that causes beech leaf disease (BLD) in beech trees (Fagus spp.) in North America," Vieira says in his abstract. "Since the first report of BLD on Fagus grandifolia in Ohio in 2012, the disease has rapidly spread to other states and Canada. This nematode has been so far reported in Pennsylvania, New York, Connecticut, Massachusetts, Maine, Michigan, Rhode Island, New Jersey, West Virginia, and Virginia, as well as Ontario. Leaf symptoms include swelling and darkening of interveinal tissues as well as chlorosis, while tissue necrosis and leaf curling occur at later stages of the disease. As a result, mortality of nematode infected understory beech trees has been reported after several years of infection in the United States. The fast dissemination of this nematode can impose a dramatic effect on beech forest ecosystems and natural diversity in North America."
Vieira says that "Little information on the molecular and cellular interaction between this nematode and its hosts is available. To advance our understanding into this unknown host- nematode system, we investigated the cytological aspects of this interaction using bright-field and scanning electron microscopy. Our data reveal that these nematodes can induce morphological changes in both bud and leaf tissues, which so far seem unique in the Nematoda phylum. These cellular changes ultimately provide the necessary nutrients for completion of the nematode life cycle, while dramatically affecting bud and leaf morphology. In addition, we used Illumina mRNA sequence analysis of a mixed stage population to obtain insight into the transcriptome of this nematode. Gene comparative analyses were combined to select a list of candidate effector/parasitism genes. Spatial expression of transcripts within the esophageal glands of L. crenatae mccannii by in situ hybridization validated a list of pioneer effectors novel to this species and across the Nematoda phylum. These analyses provide additional data for understanding the mode of parasitism of this newly emergent plant-parasitic nematode."
Vieira, who joined USDA-ARS in November 2021, holds a master's degree (2007) in plant pathology, phytopathoogy from the University of Évora, Portugal, and a doctorate (2012 in plant pathology, plant-nematode interaction from the University of Nice Sophia-Antipolis and Institute Sophia Agrobiotech, France. His resume includes postdoctoral researcher at the University of Évora (2012-2013) and USDA (2013-2015). Vieira served as a researcher in molecular biology at Virginia Tech for eight years before joining USDA-ARS in Beltsville.
Vieira's current research interests:
- Identification and functional analyses of effectors of plant-parasitic nematodes
- Genomics and transcriptomics of plant-parasitic nematodes, with a particular focus on migratory nematodes
- Plant-nematode interaction studies using cell and molecular biology approaches
Department seminar coordinator is urban landscape entomologist Emily Meineke, assistant professor. For technical issues regarding Zoom connections, she may be reached at ekmeineke@ucdavis.edu. (See complete list of spring seminars.)
Related Resources:
First report of the beech leaf disease nematode Litylenchus crenatae mccannii (Nematoda: Anguinidae) in Michigan (Plant Disease journal, Nov. 22, 2022)
Paulo Vieira: Google scholar, Twitter accounts
- Author: Kathy Keatley Garvey
His seminar is set for 4:10 p.m., Wednesday, April 12 in 122 Briggs Hall. It also will be virtual. The Zoom link:
https://ucdavis.zoom.us/j/95882849672
"Parasitic infections, pesticide exposures, and lack of nutrition are thought to interact to cause synergistic declines in honey bee health," Mayack says in his abstract. "First, I will demonstrate how disease can lead to altered behavior that is linked to the honey bee‚ a highly social nature that results in its inability to buffer against energetic stress. Then I will discuss how environmental chemical exposure biomarker profiles (fingerprints) can be used to predict presence of the most common honey bee diseases and how the two are likely interact along metabolic pathways, which is likely to be key in explaining the underlying mechanisms responsible for synergistic declines in honey bee health."
"Lastly, I will present how a systems biology approach coupled with long term monitoring of bee health will be a central powerful tool, moving forward, for unraveling the mystery that surrounds identifying the specific mechanistic causes of global bee health declines."
New Scientist featured him in its April 28, 2021 edition in an article headlined: "Honeybees Stress Each Other Out by Warning about Minor Parasites."
"A one-celled fungus called Nosema ceranae can infect the guts of individual bees, causing a disease called nosemosis," wrote science journalist Christa Lesté-Lasserre. "Similar to tapeworm infections in humans, nosemosis apparently makes bees hungrier and reduces their resistance to pesticides and probably viruses, but it isn't particularly fatal. Yet, nosemosis is one of the top reasons honeybee populations are declining."
She wrote that Mayack, then of Swarthmore College, Pennsylvania, "suspected this might have something to do with how the fungus affects the bees' social structures."
Mayack, who joined the USDA-ARS in August of 2022, holds a bachelor's degree in biology (2007) from the State University of New York, Geneseo, and a doctorate in zoology (2012) from Colorado State University. He wrote his dissertation on “Behavioral Alteration in the Honeybee Due to Parasite-induced Energetic Stress.” Mayack served as a 2012-2014 Alexander von Humboldt Postdoctoral Fellow at the Zoology Institute, Martin-Luther-University Halle-Wittenberg, Germany.
His research interests include systems biology, improving honey bee health, animal physiology, animal behavior, parasite-host interactions, neurobiology, effects of aging, evolution of social behavior, regulation of appetite and energetic homeostasis, and metabolomics/exposomics.
Seminar coordinator is Emily Meineke, urban landscape entomologist and assistant professor. See the list of spring seminars here. For technical issues (Zoom), contact Meineke at ekmeineke@ucdavis.edu.
- 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.