- Author: Kathy Keatley Garvey
For the beekeepers that's easy. They dislike the pests known as "wax moths" and their larvae.
The female wax moths hang around the hives at night and when the opportunity arises, slip in to lay their eggs. If the colony is weak, this pest can take over.
The honey bee bible, The Hive and the Honey Bee (Dadant Publication), says the wax moth female "produces less than 300 eggs during her life span of 3 to 30 days, but a few lay as many as 2000 eggs. Mated females fly to beehives one to three hours after dark, enter, and lay eggs until they leave shortly before daylight."
The Hive and the Honey Bee authors relate that "the presence of the wax moth larvae usually signals a major problem such as queenlessness, an infectious disease, poisoning and starvation."
In his book, Honey Bee Biology (2023 Princeton University), bee scientist Brian Johnson, associate professor, UC Davis Department of Entomology and Nematology, touches on colony pests in addition to his indepth coverage of everything from molecular genetics, development, and physiology to neurobiology, behavior, and pollination biology.
Johnson writes in part: "The greater wax moth (Galleria mellonella) and the lesser wax moth (Achroia grisella) are old and well-known pests of honey bees. The female moth lays her eggs on the comb and the larvae consume the wax, pollen and honey. In nature, these pests are mainly a threat to weak colonies, as strong colonies can kill their larvae." He goes on to mention that beekeepers who inadequately store large amounts of wax combs may be subject to wax moth infestations. He recommends air tight storage and the use of mothballs.
The larvae are not always unwanted. They've been introduced as an alternative model to study microbial infections.
So, in keeping with National Moth Week, the Bohart Museum of Entomology is hosting its annual Moth Night from 7 to 11 p.m. on Saturday, July 20 at its headquarters in Room 1124 of the Academic Surge Building, 455Crocker Lane, UC Davis. Inside, Jeff Smith, curator of the Bohart's Lepidoptera collection, and his colleagues will be displaying moth specimens and answering questions. Outside, Bohart research associate John "Moth Man" De Benedictus will set up a blacklighting display, complete with white sheet and a UV light to attract moths and other night-flying insects.
The open house is free and family friendly. Also free: hot chocolate and cookies, according to Tabatha Yang, education and outreach coordinator.
Founded in 1946, the Bohart Museum is the home of a global collection of eight million insect specimens. It also features a petting zoo (including Madagascar hissing cockroaches, walking sticks and tarantulas) and a gift shop stocked with insect-themed t-shirts, hoodies, books, posters, jewelry and more. The museum is directed by Professor Jason Bond, the Evert and Marion Schlinger Endowed Chair, UC Davis Department of Entomology and Nematology, and associate dean, Agricultural Sciences, UC Davis College of Agricultural and Environmental Sciences.
- Author: Kathy Keatley Garvey
"I took a gap decade. During that time I had a series of eclectic jobs and life experiences. Those experiences proved extremely useful during my PhD."
Lamas, a former commercial beekeeper in New Hampshire, will share his life and research experiences at a seminar hosted by the UC Davis Department of Entomology and Nematology, on Monday, April 15.
His seminar, titled "How Doing a PhD Is Like Building a House," begins at 4:10 p.m. in Room 122 of Briggs Hall. It also will be on Zoom. The Zoom link:
https://ucdavis.zoom.us/j/9 5882849672
"This presentation describes how the intersection of life experiences and my PhD led to creative and generative research that led to large discovery in disease transmission dynamics in collapsing honey bee colonies," Lamas says.
A first-generation college student, Lamas received his bachelor's degree in biology in 2008 from Colby-Sawyer College, a private college in New London, New Hampshire. He obtained his doctorate in entomology at the University of Maryland in 2022.
He credits his mentor, USDA-ARS research entomologist Jay Evans of the Bee Research Laboratory, Beltsville, MD., with encouraging him to apply to become an Oak Ridge Institute for Science and Education (ORISE) fellow with the USDA-ARS Research Participation Program.
Lamas, known as "Dr. Zac," has presented programs on his research and beekeeping management to state beekeeping associations in California, Texas, Florida, Colorado, Virginia, Missouri, West Virginia, and Washington State, among others, and has addressed the American Beekeeping Federation, American Honey Producers' Association and Apimondia. Globally, he has delivered presentations to Apimondia, Montreal, Canada, and to the Eurbee 8th Congress of Apidology, Ghent, Belgium.
Lamas rears open-mated carniolans. "These are docile, productive bees, that I produce for my own experiments," he writes on his website. "We can literally pet our bees during experiments. This level of docility allows us to work intimately with the bees, sitting in front of open colonies for long periods to collect samples."
Lamas is a noted researcher on varroa mites. "Who do Varroa really feed on? Check out this presentation where I share a new finding of Varroa destructor I carried out three years of research, and along with collaborators (including my family!) individually inspected over 30,000 bees to describe the distribution of Varroa inside a colony." (See YouTube presentation.)
Lamas' recent publications involve varroa mites, infectious diseases and pesticides:
- Zachary S. Lamas, Eugene V. Ryabov, David J. Hawthorne, Jay D. Evans, "Oversharing by honey bees and the spread of viruses," bioRxiv 2022.05.15.492017; DOI: https://doi.org/10.1101/2022.05.15.492017
- Ryabov EV, Posada-Florez F, Rogers C, Lamas ZS, Evans JD, Chen Y and Cook SC (2022) "The vectoring competence of the mite Varroa destructor for deformed wing virus of honey bees is dynamic and affects survival of the mite," Frontiers in Insect Science. 2:931352. DOI: 10.3389/finsc.2022.931352
- Posada-Florez, F., Lamas, Z.S., Hawthorne, D.J. et al. "Pupal cannibalism by worker honey bees contributes to the spread of deformed wing virus," Scientific Reports 11, 8989 (2021). https://doi.org/10.1038/s41598-021-88649-y
- Alger, S.A.1, Burnham, P.A., Lamas, Z.S2, Brody, A.K., Richardson, L.R., (2017). "Home sick: impacts of migratory beekeeping on honey bee (Apis mellifera) pests, pathogens, and colony size," PeerJ 6:e5812; DOI 10.7717/peerj.5812
- Kirsten S. Traynor, Dennis vanEngelsdorp, Zachary S. Lamas, "Social disruption: Sublethal pesticides in pollen lead to Apis mellifera queen events and brood loss," Ecotoxicology and Environmental Safety, Volume 214, 2021, 112105, ISSN 0147-6513, https://doi.org/10.1016/j.ecoenv.2021.112105
Honey bee scientist Brian Johnson, associate professor, UC Davis Department of Entomology and Nematology, is coordinating the department's seminars for the 2023-24 academic year. For any Zoom technical issues, he may be reached at brnjohnson@ucdavis.edu.
The complete list of spring quarter seminars is here.
- Author: Kathy Keatley Garvey
Bees comprise more than 20,000 described species in seven families and are found on all continents except Antarctica, but where did they originate? And when did they originate?
Cornell University alumnus Eduardo Almeida, an associate professor at the University of São Paulo, Brazil, will discuss “The Evolutionary History of Bees in Time and Space” at a seminar hosted by the UC Davis Department of Entomology and Nematology on Monday, April 8.
The seminar begins at 4:10 p.m. in 122 Briggs Hall, and also will be on Zoom. The Zoom link:
https://ucdavis.zoom.us/j/95882849672
"Bees likely originated in the Early Cretaceous (120 million years ago), shortly before the breakup of Western Gondwana (Africa and South America), and the early evolution of any major bee lineage is associated with either the South American or African land masses," Almeida says in his abstract.
"I will present the results of an investigation on bee biogeograpy using extensive new genomic and fossil data to demonstrate that bees originated in Western Gondwana. Bees later colonized northern continents via a complex history of vicariance and dispersal. The notable early absences of these insects from large landmasses, particularly in Australia and India, have important implications for understanding the assembly of local floras and diverse modes of pollination. The partnership between flowering plants and bees began in the Cretaceous, and the history of how bees spread around the world from their hypothesized southern hemisphere origin parallels the histories of numerous plant clades."
Almeida, who joined the University of São Paulo in 2011, conducts research on bee evolution, and is particularly interested in phylogenomics, comparative morphology, biogeography, and associations with host plants.
A native of Brazil, he received his doctorate in 2007 from Cornell University, where he studied with major professor Bryan Danforth. Almedia's focus: the biogeographic history of colletid bees. Prior to enrolling in the doctoral program at Cornell, he obtained his bachelor of science degree (biology) and his master's degree (ecology) from the Universidade Federal de Minas Gerais, Brazil. He speaks Portuguese, English, Spanish and French.
Almeida and his colleagues published a research paper in August 2023 in the journal, Current Biology, on "The Evolutionary History of Bees in Time and Space."
The summary: "Bees are the most significant pollinators of flowering plants. This partnership began ca. 120 million years ago, but the uncertainty of how and when bees spread across the planet has greatly obscured investigations of this key mutualism. We present a novel analysis of bee biogeography using extensive new genomic and fossil data to demonstrate that bees originated in Western Gondwana (Africa and South America). Bees likely originated in the Early Cretaceous, shortly before the breakup of Western Gondwana, and the early evolution of any major bee lineage is associated with either the South American or African land masses. Subsequently, bees colonized northern continents via a complex history of vicariance and dispersal. The notable early absences from large landmasses, particularly in Australia and India, have important implications for understanding the assembly of local floras and diverse modes of pollination. How bees spread around the world from their hypothesized Southern Hemisphere origin parallels the histories of numerous flowering plant clades, providing an essential step to studying the evolution of angiosperm pollination syndromes in space and time."
Coordinating the department's spring seminars is associate professor Brian Johnson. For any technical Zoom issues, he may be reached at brnjohnson@ucdavis.edu.
The complete list of spring quarter seminars is here.
- Author: Kathy Keatley Garvey
All seminars are on Mondays at 4:10 p.m. in Room 122 of Briggs Hall and also will be on Zoom. The Zoom link:
https://ucdavis.zoom.us/j/95882849672.
No seminar will take place on Monday, Jan. 15, which is Martin Luther King Jr. Day, a university holiday.
On tap for Monday, Jan. 22 is William Ja, associate professor, Herbert Wertheim Scripps UF Institute for Biomedical Innovation and Technology in Jupiter, Florida.
He will present "Eat, Excrete, & Die: Regulation of Homeostatic Behaviors and Aging in Drosophila."
"The Ja lab uses the fruit fly, Drosophila melanogaster, as a model organism for uncovering the genetic and neuronal mechanisms that drive aging, behavior, and disease, Ja says in his abstract. "Recently developed tools allow us to track fly feeding behavior with unparalleled resolution. These tools facilitate the identification of genes and circuits that regulate food intake at diverse time scales, including studies of: 1) meal intake; 2) daily (circadian) feeding rhythms; and 3) compensatory feeding in response to high or low quality food. Our studies of feeding behavior and nutrition also inform aging interventions, including a novel caloric restriction paradigm and an intermittent fasting regime that extends fly life through the stimulation of circadian-regulated autophagy. Overall, our fly studies shed light on basic neurobiological principles that drive animal behavior, providing insights that potentially inform the development of conserved therapeutic strategies."
Ja received his chemistry degree at UC Berkeley, working with Richard Mathies and Alex Glazer on DNA sequencing technologies. He pursued doctoral studies at the California Institute of Technology with Rich Roberts, utilizing mRNA display technology to identify modulators of G protein signaling. Ja remained at Cal Tech as a postdoctoral scholar to work with Seymour Benzer on developing longevity ‘drugs' in Drosophila. His laboratory focuses on aging and nutrition, animal behavior, and host-microbiome interactions.
Upcoming seminars:
Monday, Jan. 29
Todd Johnson
Assistant professor of forest entomology, Louisiana State University
Title: "Characterizing Ecological Interactions of Arthropods in Forests under Global Change"
Monday, Feb. 5
Orie Shafer
Professor of biology and cognitive neuroscience, City University of New York
Title: "Circadian and Homeostatic Regulation of Fly Sleep"
Monday, Feb. 12
Peter Piermarini
Professor and associate chair of entomology, The Ohio State University, Wooster
Title: "Discovery of Novel Chemical Tools for Controlling the Most Dangerous Animals on Earth"
Monday, Feb. 26
Dorith Rotenberg
Professor and director of graduate programs, Department of Entomology and Plant Pathology, North Carolina State University
Title: "Advances and Innovations in the Characterization of Molecular Interactions Between Frankliniella occidentalis and Tomato Spotted Wilt Virus."
Monday, March 4
Salil Bidaye
Research Group Leader, Max Planck Florida Institute for Neuroscience
Title: "How Flies Control How They Walk by Knowing When and How to Stop"
Adler Dillman, professor of parasitology and nematology and chair of the Department of Nematollgoy, UC Riverside, launched the series on Jan. 8. (See Bug Squad blog)
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. More information on the seminars is here.
/span>- Author: Kathy Keatley Garvey
All seminars will be in-person and will take place on Mondays at 4:10 p.m. in Room 122 Briggs Hall through Dec. 4, and also will be broadcast on Zoom. The exception: UC Davis doctoral alumnus' Charlotte Alberts' seminar on Nov. 13 will be Zoom only.
Pollination ecologist Neal Williams, professor, UC Davis Department of Entomology and Nematology, will introduce CaraDonna.
The Zoom link:
https://ucdavis.zoom.us/j/
The schedule:
Paul CaraDonna
Research scientist at the Chicago Botanic Garden and a professor of instruction at Northwestern University
Title: "Understanding the Dynamics of Plant-Animal Interactions in a Changing World"
Abstract: "Plant-pollinator interactions are ubiquitous and play an important role in ecosystem functioning across the globe. Critically, plants, pollinators, and their interactions face numerous threats in our changing world, including those related to climate change. However, our understanding of the consequences of these threats to plant-pollinator interactions has been hampered because we lack knowledge of the basic ecology of many of these organisms, and how their ecology responds to changing abiotic and biotic conditions. We will investigate these issues in this seminar."
Monday, Oct. 9
Geoffrey Attardo
Associate professor and medical entomologist/geneticist, UC Davis Department of Entomology and Nematology
Title: “The Mating Biology of Tsetse Flies – Insights into the Morphological, Biochemical, and Molecular Responses to Mating Stimuli in a Viviparous Disease Vector”
Abstract: "Research into the reproductive behavior of tsetse flies offers key insights into controlling diseases like African sleeping sickness. Unique among insects, these flies give birth to live offspring. During mating, males transfer a mix of sperm and other vital substances to the females. This study employs state-of-the-art techniques, including 3D scanning and genetic analysis, to monitor changes in the female fly's reproductive system over a 72-hour period post-mating. Findings indicate that mating sets off a chain of intricate changes in the female, affecting everything from biochemistry to gene activity. These changes prepare her for pregnancy and childbirth. The study opens up new avenues for understanding tsetse fly biology and offers potential strategies for disease control."
Anthony Domiano Vaudo
Research entomologist, U.S. Forest Service, Rocky Mountain Research Station
Title: "Pollen Nutritional ecology of Bee-Flower Interactions"
Abstract: "Pollen provides bees their primary source of protein and lipid macronutrients, essential for development, fitness, and resistance to stress. Yet, pollen macronutrient quality differs substantially among host-plant species. And thus, bees may be sensitive to their nutritional needs and differentially forage among host plants to obtain appropriate nutrition. In this presentation, I will highlight my research that has linked bumble bee host plant foraging preferences to pollen nutritional quality and individual and colony health. Using this as a theoretical framework, I will present recent research where I show that floral pollen nutritional quality can help explain the structure and patterns of bee-wildflower community interactions among diverse populations; and how this research can inform conservation practices. Finally, I will discuss how the quality of pollen that bees collect may differ between and remain consistent within species populations and help explain their history of floral preferences."
Monday, Oct. 23
Sascha Nicklisch
Assistant professor, UC Davis Department of Environmental Toxicology Department
Title: "Disarming the Defenses of Resistant Pests: Rational Design of Inhibitors for ABC Transporter Proteins in the Varroa Mite"
Abstract: "Varroa mites pose a significant global menace to honeybee colonies, causing colony losses, ecological imbalances, and food scarcity. Escalating pesticide resistance in these mites necessitates innovative strategies to bolster acaricide effectiveness. Small molecule synergists that heighten mite susceptibility to acaricides offer a promising solution by amplifying chemical treatment efficacy, thus reducing overall pesticide demand. Present synergist development strategies primarily target metabolic enzyme inhibition to restore insect sensitivity to pesticides. Our research focuses on ABC efflux transporters, pivotal in cellular xenobiotic handling, as a new approach. We aim to establish a toxicokinetic pipeline to uncover novel synergists and validate their ability to increase Varroa mite vulnerability to existing miticides. By capitalizing on synergistic interactions between sensitizing agents and acaricides, we aim to equip beekeepers and regulators with a sustainable toolbox to combat Varroa resistance, ultimately fostering long-term honey bee well-being."
Monday, Oct. 30
Rodrigo Monjaraz-Ruedas
Department of Biology, San Diego State University
Title: "Ring Species, Ring Speciation or a Ring of Species? An Example with California Mygalomorph Spiders."
Abstract: "Ring species can be defined as a chain of interbreeding populations which expands along two pathways around a geographic barrier, where terminal forms can coexist without interbreeding. A broken ring species model preserves the geographic setting and fundamental features of an idealized model but accommodates varying degrees of gene flow restriction through evolutionary time. Members of the genus Calisoga are distributed around the Central Valley of California, and previous genetic studies have shown that this is a lineage-rich complex of mygalomorph spiders, with evidence to suggest that Calisoga might be a case of ring speciation. Here we examine broken ring species dynamics in Calisoga spiders, using UCEs and mitogenomes we test key predictions of timing, ancestry, connectivity and terminal overlap. I will discuss why ring species should not be viewed as homogeneous entities, but rather as heterogeneous units with different predicted evolutionary dynamics in different geographic parts of the ring."
Monday, Nov. 6
Jason Hong
Research Microbiologist at the USDA-ARS United State Horticultural Lab in Fort Pierce, FL.
Title: "Managing Soilborne Pathogens and Pests with Anaerobic Soil Disinfestation (ASD)"
Abstract: "Growers consider soilborne disease management one of their main production issues. It is estimated that members of the soilborne pest complex (SPC), weeds, nematodes, fungi, oomycetes, bacteria, viruses, and protozoans, account for 10-20% 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."
Charlotte Alberts
Smithsonian National Museum of Natural History
Title: "Assassin Fly (Diptera: Asilidae) Systematics and Predator Ecology"
Abstract: "Assassin flies (Diptera: Asilidae) are a diverse family that plays an essential ecological role as top aerial and venomous predators. Little is known about the evolution of their predatory habits. This study provides a novel phylogenetic hypothesis of Asilidae along with prey preference and ancestral state reconstruction in a maximum likelihood framework. This study is based on 176 assassin fly species, 35 Asiloidea outgroup species, 3,400 prey preference records accumulated from literature and museum collections, and approximately 7,913 bp of nuclear DNA from five genes (18S and 28S rDNA, AATS, CAD, and EF-1a protein-encoding DNA) and mitochondrial DNA from one gene (COI). Of the 12 asilid subfamilies included in the analysis the monophyly of six was supported. We used ancestral state reconstruction and stochastic character mapping to test whether a polyphagous arthropod predator is the ancestral state for Asilidae. Assassin flies are polyphagous arthropod predators, with specialized arthropod prey preferences evolving 20 independently across the Asilidae phylogeny. I will also summarize my other dissertation chapter, a review of Nearctic Saropogon with a new species description."
Monday, Nov. 20
Etienne GJ Danchin
Evolutionary biologist working with genomes: INRAE (French National Research Institute for Agriculture, Food and Environment) senior scientist and scientific leader of the GAME team (Genomics and Adaptive Molecular Evolution) at ISA (Institut Sophia Agrobiotech), in Sophia-Antipolis, on the French Riviera.
Title: "Parasitic Success in the Absence of Sex: What Have We Learned from Nematode Genomes?"
Abstract: "Root-knot nematodes are devastating plant parasites of worldwide importance. Interestingly, species that cause most damages reproduce entirely asexually. These nematodes are extremely polyphagous and have a wide geographic range. Theoretically, in the absence of sexual recombination animal species have lower adaptive potential and are predicted to undergo genome decay. To investigate how these species can be successful parasites on many hosts and in many places around the world, we have sequenced and analyzed their genomes. Out analysis confirmed these species are polyploid hybrids and the combination of several genotypes from different species might provide them with a general-purpose genotype. However, this does not explain how with a theoretically fixed genotype these species are able to overcome resistance genes or adapt to a new host. Therefore, we analyzed genomic variability across different populations and the possible mechanisms underlying genomic variations. In this presentation, I will provide an overview of our findings."
Monday, Nov. 27
Arnon Dag
Senior Scientist in the Institute of Plant Sciences, The Volcani Center, Israel
Title: "Improving Cross-Pollination in Deciduous Fruit Trees"
Abstract: "Tree crops belonging to the Rosaceae, such as almond, pear, apple, and sweet cherry, depend on cross-pollination by insects to set fruit. The primary pollinator of the crops is the honey bee (Apis mellifera). However, due to harsh climatic conditions during flowering, limited movement of bees between cultivars, low preference of the bees for flowers of the target crop, and limited overlap in flowering between the cultivars, pollination is a primary factor limiting yield. Our group has tested multiple approaches to mitigate this problem: Using 'Pollen dispensers,' sequential introduction of beehives to the orchards, selection of honeybee strains with higher preference for the target crop, introduction of bumblebee (Bombus terrestris) colonies and phosphorous fertilization to increase nectar secretion and improve crop-flower attractiveness. I will summarize the effects of those methods on fruit set and yield in apples, almonds, and pears."
James Nieh
Professor in the Section of Ecology, Behavior, and Evolution, Division of Biological Sciences, University of California, San Diego, and associate dean in the Division of Biological Sciences
Title: "Danger, Dopamine, and Dance: New Insights from the Magic Well of Honey Bee Communication"
Abstract: "Karl von Frisch referred to the waggle dance as the 'magic well' for the insights that it provides not only on honey bees, but on the general cognitive complexity that social insects are capable of. New research demonstrates that the neurotransmitter, dopamine, the “pleasure molecule” plays a similar hedonic role in honey bees as it does in many vertebrates, regulating the perception of danger and the anticipation of food rewards as revealed in the excitatory waggle dance and the associated, inhibitory stop signal. I will also discuss new data showing that the honey bee waggle dance is partially learned and has elements that may be culturally transmitted. Together, these findings, demonstrate that the waggle dance can teach us a great deal about shared cognitive mechanisms and the importance of social learning across taxa."
For seminars technical issues, contact Johnson at brnjohnson@ucdavis.edu.
Johnson, a leading expert on the behavior, genomics and evolution of honey bees, is the author of a newly published book, “Honey Bee Biology,” released June 6 by Princeton University Press. Johnson joined the UC Davis faculty in 2011 after conducting postdoctoral research at UC San Diego and UC Berkeley. He focuses his research on the behavior, evolution, theoretical biology and genomics of the honey bee.
“Our lab studies the genetics, behavior, and evolution of honey bees,” Johnson writes on his website. “We use experimental and theoretical approaches to all the questions we explore. Current work in our lab focuses on the evolution and genetic basis of social behavior using comparative and functional genomics, task allocation using behavioral and theoretical approaches, and honey bee health using a combination of genetics, epidemiology, and physiological approaches.”