- Author: Kathy Keatley Garvey
Are you ready to celebrate Moth Night at the Bohart Museum of Entomology at the University of California, Davis?
Mark your calendar for 8 p.m. to 11 p.m. on Saturday, July 21.
That's when the Bohart Museum will join forces with National Moth Week, July 21-29, to celebrate the beauty, life cycles and habitats of moths. It's free, open to the public, and family friendly.
The Bohart, located in Room 1124 of the Academic Surge Building, Crocker Lane, is hosting the "Moth Night" both inside and outside the museum. You will see scores of moth and butterfly displays inside. Outside, moth light traps will be set up so you can see what moths are drawn to the blacklighting displays.
The UC Davis event is one of only two public events scheduled in California during the week; the other is in San Mateo County on July 28.
Bohart scientists will be on hand to discuss moths and answer questions. They include three Bohart associates: entomologist Jeff Smith of Rocklin, curator of the the moth and butterfly specimens; and "Moth Man" John DeBenedictis and naturalist and photographer Greg Kareofelas, both of Davis, who will staff the light traps/blacklighting displays. The best time to see the moths in the light traps is later in the evening, closer to 10, according to Lynn Kimsey, director of the museum, and Tabatha Yang, education and outreach coordinator.
"We will focus on colorful moths of the night--night rainbows if you will and the biodiversity of tropical moths," Yang said. A family craft activity is planned. Last year the family craft activity featured making moth-shaped window ornaments resembling stained glass.
Free refreshments--cookies and hot chocolate--will be served. Common Grounds, a Davis coffee shop. will be providing the large containers of hot water for the event.
One of the "oh, wow!" moths is Attacus atlas (Atlas moth), found in the rainsforests of Asia. One of the largest moths in the world, it has a wingspan that can measure 10 to 11 inches.
Last year more than 15 species landed on the blacklighting display. The first moth to arrive was the alfalfa looper moth, Trichopusia ni. The most striking: the grape leaffolder, Desmia funeralis.
Some facts about moths, from the National Moth Week website:
Why moths?
- Moths are among the most diverse and successful organisms on earth.
- Scientists estimate there are 150,000 to more than 500,000 moth species.
- Their colors and patterns are either dazzling or so cryptic that they define camouflage. Shapes and sizes span the gamut from as small as a pinhead to as large as an adult's hand.
- Most moths are nocturnal--others fly like butterflies during the day.
- Finding moths can be as simple as leaving a porch light on and checking it after dark. Serious moth aficionados use special lights and baits to attract them.
The Bohart Museum houses a global collection of nearly eight million specimens. It is also the home of the seventh largest insect collection in North America, and the California Insect Survey, a storehouse of the insect biodiversity. Noted entomologist Richard M. Bohart (1913-2007) founded the museum. It maintains a live "petting zoo," featuring Madagascar hissing cockroaches, walking sticks, tarantulas, and praying mantids. The museum's gift shop, open year around, includes T-shirts, sweatshirts, books, jewelry, posters, insect-collecting equipment and insect-themed candy.
The Bohart Museum's regular hours are from 9 a.m. to noon and 1 to 5 p.m. Mondays through Thursdays. It is closed to the public on Fridays, Saturdays and Sundays and on major holidays. Admission is free.
More information on the Bohart Museum is available on the website or by contacting (530) 752-0493 or email bmuseum@ucdavis.edu.
- Author: Kathy Keatley Garvey
And she's beautiful!
It all began with finding two anise swallowtail chrysalids clinging last July to the fennel stems in our pollinator garden in Vacaville, Calif.
To protect them from predators and the elements, we tucked them inside a zippered net butterfly habitat and placed “the prized package” in the corner of a laundry room to await the spring of 2018--and eclosure.
The first day of spring, March 20, came and went. Then 288 days slipped by. The chrysalids remained intact. Were they viable?
We showed images of the chrysalids to butterfly guru Art Shapiro, distinguished professor of evolution and ecology at the University of California, Davis, who's been researching the butterfly population of central California for more than four decades.
“They both look OK—the intersegmental membranes are not showing,” he said. “Stick them in the refrigerator for a month and try again. If they are a coast range population, some may diapause up to 5 years. If a valley population, multiyear diapause is very unusual.”
Shapiro advised that we “put them in a lidded container” to prevent their drying out. “Diapausing pupae only breathe once or twice a day.”
So, on June 5, in the refrigerator they went, joining assorted cups of yogurt, bags of fruits and vegetables, jars of peanut butter, cartons of fat-free milk and what-have-you.
What a life!
Then on July 4, Independence Day (but with no fanfare, ceremony or celebration) out they came. (The yogurt, fruits and vegetables, peanut butter, milk and what-have-you stayed behind.)
We placed the (probably) thoroughly confused chrysalids back in the butterfly habitat, but this time, outdoors, and right next to their host plant, fennel. Daytime temperatures climbed to 100 degrees and night temperatures dropped into the 50s.
Nothing happened. Nothing.
Just as we were wondering if they were still viable, we saw a winged burst of yellow, black and blue on Sunday night, July 14. A long-awaited eclosure!
It's a girl! (as identified by Professor Shapiro). (Read more about the anise swallowtail, Papilio zelicaon, on his website.)
Early Monday morning, we dipped a fennel blossom into a mixture of 10 parts water and one part honey. Food! She drank heartily. Then we placed her atop the towering fennel so she could warm her flight muscles.
Two hours later, Ms. Anise Swallowtail became part of the Wonderful World of Butterflies. She circled the house, returned to nectar on the Mexican sunflower (Tithonia), and left. No fanfare, no ceremony, no celebration. This is her world now.
The other chrysalis? It remains intact. Fingers crossed that it, too, will survive.
It doesn't get much better than this--in a world where kindness matters. It always has.
- Author: Kathy Keatley Garvey
They can also do something else.
Basically, if you're a plant and an insect is attacking you, you can communicate your stress to nearby plants as a way to alert them about potential danger--very similar to how animals communicate or respond to predators, according to UC Davis agricultural entomologist Christian Nansen of the Department of Entomology and Nematology.
In groundbreaking research published in the journal Plant Methods, Nansen and his team of six colleagues from Brazil discovered that plant-plant communication causes physiological changes in plants and these subtle changes can be detected via analyses of leaf reflectance or hyperspectral imaging. The article is titled “Hyperspectral Imaging to Characterize Plant-Plant Communication in Response to Insect Herbivory."
The growing knowledge about plant-plant communication and about plants' ability to assess their environment has led to concepts like “plant neuro-biology” and “plant behavior,” said Nansen, an associate professor who centers his research on host plant-stress detection, host selection by arthropods, pesticide performance, and use of reflectance-based imaging in a wide range of research applications.
“We know that plants don't have a neural system or brain,” said Nansen, “but respected scientists are studying plants as if they did, as if plants are able to assess conditions in their environments, and they can adapt/respond to those conditions.”
“In studies of plant stress signaling, a major challenge is the lack of non-invasive methods to detect physiological plant responses and to characterize plant-plant communication over time and space.” Nansen pointed out. He described the research as “initial evidence of how hyperspectral imaging may be considered a powerful non-invasive method to increase our current understanding of both direct plant responses to biotic stressors but also to the multiple ways plant communities are able to communicate.”
The UC Davis entomologist and his team used leaf reflectance data to detect and characterize plant responses to stressors, knowing that induced stress interferes with photosynthesis, chemical composition and physical structure of the plant, thus affecting the absorption of light energy and altering the reflectance spectrum of the plants.
“For several decades, it has been known that plants communicate – both among individuals of the same species and across species,” Nansen related. “That is, volatiles emitted by one plant can be received by another plant and trigger different physiological responses. It is also well-documented that plants communicate via roots, and sometimes the roots from different plants are brought together in a network of communication and exchange of nutrients through symbioses with mychorriza (soil fungi).”
Of the Nansen study, Karban said: "This study describes a technique that may provide a relatively quick and inexpensive way to evaluate levels of resistance in plants. If these results are repeatable by other workers in other systems, they will provide a very valuable tool for researchers and growers."
Both Karban and Nansen contributed chapters to the recently published book, The Language of Plants (University of Minnesota Press). The book explores "the idea that plants can think, feel, and communicate as a way of reconfiguring our relationship with the natural world," according to editors Monica Gagliano, John C. Ryan, and Patrícia Vieira.
"Within the last decade or so, extremely cutting-edge research in the field of plant-plant communication has been done by people like Dr. Monica Gagliano of the University of Western Australia," Nansen said. "She has elegantly demonstrated that plants can respond not only to aerial volatile compounds and root secretions but also to sound."
For the research project, Nansen and his team decided to conduct “a very simple experiment with corn plants and stink bugs.” They planted corn plants in separate pots or two in one pot. They subjected some plants to herbivory by stink bugs, while other plants served as control plants.
The scientists collected two types of data: phytocompounds (stress hormones and pigments) and leaf reflectance data (proximal remote sensing data).
“Our research hypothesis was that insect herbivory causes changes in leaf phytocompound levels, and these physiological defense responses are associated with detectable changes in phytocompound levels and in certain spectral bands of leaf reflectance profiles,” Nansen pointed out. As a secondary hypothesis, the researchers predicted that plant-plant communication (from plant with herbivory to an adjacent control plant without herbivory) will elicit both a change in phytocompound composition of leaves and also cause a corresponding change in leaf reflectance.
The result: The first published study, in which comprehensive phytocompound data have been shown to correlate with leaf reflectance. In addition, it is the first published study of leaf reflectance in plant-plant communication.
Nansen and co-author Leandro do Prado Ribeiro of the Research Center for Family Agriculture, Research and Rural Extension Company of Santa Catarina, Brazil, conceived and designed the experiments. The Brazilian National Counsel of Technological and Scientific Development provided partial financial support. Co-author Marilia Almeida Trapp received financial support from a Capes-Humboldt Research Fellowship.
- Author: Kathy Keatley Garvey
Congratulations to UC Davis entomology professor Diane Ullman who has just a received Fulbright to France to research plant virus-insect interactions. She will be studying plant viruses and the insects that transmit them.
Her sabbatical, to begin in November, will take her to Montpellier, France, to work with renowned vector biologists Stéphane Blanc and Marilyne Uzest at the National Institute of Agronomic Research (INRA) on the Campus International de Baillarguet near Montpellier. The Biologie et Génetique des Interactions Plante-Parasite (UMR-BGPI, CIRAD-INRA-SupAgro) focuses on plant pathogens and their interactions with arthropod vector in agroecosystems.
She will be studying plant viruses in the genus Orthotospovirus (family Tospoviridae). This family holds the only plant infecting members in the order Bunyaviriales. The other viruses in this order infect animals and humans and are transmitted primarily by mosquitoes and ticks.
Ullman, an international authority on orthotospoviruses, said that "new evidence suggests the bunyavirus, Rift valley fever virus (an animal infecting member of the Bunyavirales), uses a multicomponent system in which individual virions do not co-package all segments and infection requires virion populations, a possibility with profound implications for virus evolution and antiviral target discovery...I will test the hypothesis that orthotospoviruses use multicomponent genome organization and segment copy regulation occurs in their hosts.”
The UC Davis professor has researched insect-transmitted plant pathogens for 37 years, targeting numerous insect vector species--from thrips, whiteflies, and leafhoppers to mealybugs--and the plant pathogens they transmit, including viruses, phytoplasma and bacteria.
“Sustainable management of insect-transmitted pathogens is a key concern for food production in France and the United States,” Ullman wrote in her Fulbright application. “Both countries grow many of the same crops and growers face similar challenges from insect-transmitted plant viruses. Current management strategies rely heavily on pesticides that may cause significant health and environmental concerns, including damage to bees and other pollinators, as shown with neonicotinoid pesticides. Clearly, better knowledge about these insect-transmitted viral systems…has potential to reduce pesticide use by providing novel and innovative technologies to manage tospoviruses and thrips in France and the United States.”
Ullman, former chair of the Department of Entomology and Nematology and a former associate dean with the UC Davis College of Agricultural and Environmental Sciences, expects the project will build strong research relationships between UC Davis and Montpellier that will lead to grant applications for international research and scholarly exchange opportunities for scientists, students and post-doctoral scholars.
- Author: Kathy Keatley Garvey
So there they were, literally dozens of dragonflies flying around two separate Vacaville (Calif.) yards, feasting on swirling clouds of prey (gnatlike insects) and then touching down on blades of grass or fence posts.
They proved as elusive as a celebrities attempting to avoid a paparazzi.
Dragonflies, but what species?
Bohart Museum of Entomology associate Greg Kareofelas of Davis identified them as variegated meadowhawks, Sympetrum corruptum. "Notice how the pterostigma is two-toned," he said. "That is the only dragon with that, also the two black spots at the end of the tail. They kind of migrate--or maybe mass dispersal is a better name. A bunch can show up if there is something to eat, then the whole gaggle moves on."
The pterostigma cell, located in the outer wing of insects, is often thickened or colored and so it stands out from other cells, according to Wikipedia. It is particularly noticeable in dragonflies, but is also present in other insect groups, such as snakeflies, hymenopterans and megalopterans.
"The male is commonly dark brownish black with an abdomen of bright red, pink, and golden brown," Wikipedia relates. "The thorax may be marked with a pair of yellow dots on each side. The leading edges of the wings are marked with pinkish. The females are similar in color but not as brightly colored, with gray and yellow replacing the red of the male. Young variegated meadowhawks are much paler and mottled with pale green, pale yellow, golden brown, and orange."
According to Odonata Central, "this species may be seen on the ground more than other meadowhawks. It will also readily perch on the tips of grass stems and tree branches. It can be numerous flying over roads, lawns, meadows, marshes and ponds...Mating occurs while perched on twigs, stems or other vegetation. Females lay eggs accompanied by males in the open water of ponds and lakes. Mass movements of this species have been reported on several occasions."
The variegated meadowhawk, native to North America, belongs to the family, Libellulidae. They're found throughout the United States and southern Canada, according to Odonato Central. "Also, Mexico south to Belize and Honduras."
Coming soon to a yard near you?