- Author: Kathy Keatley Garvey
Who knew that you, along with billions of other people, could be infected with undetected microscopic parasitic nematodes, or round worms? And that they spit venom?
Parasitologist Adler Dillman of UC Riverside knows. In fact, he recently received a $1.8 million Outstanding Investigator Award from the National Institutes of Health (NIH) to study these parasitic nematodes, which infect a quarter of a billion of the world's population and can cause blindness, cognitive issues and sometimes death.
Want to learn more about this research? The UC Davis Department of Entomology and Nematology has booked him as a guest speaker as part of its fall weekly seminars, coordinated by nematologist and assistant professor Shahid Siddique.
Dillman will deliver his in-person seminar, "Nematode Venom Contains Potent Modulators of Insect Immunity," at 4:10 p.m., Wednesday, Oct. 27 in 122 Briggs Hall Drive, off Kleiber Hall Drive. It also will be broadcast live on Zoom at https://ucdavis.zoom.us/j/
"Parasitic nematodes are master manipulators of host immunity," Dillman says in his abstract. "Little is known about the identity and function of the cocktail of effectors they release during active infection. We have developed an effector discovery model using entomopathogenic nematodes and fruit flies, which we are using to identify and characterize potent modulators of insect immunity."
Dillman, who joined the UC Riverside faculty in February 2015 and is now an associate professor, focuses his research on identifying the specific proteins in a nematode's spit or venom that can trick the immune system to ignore its presence. His model organism is the fruit fly. He hopes that his research could lead to treatments for autoimmune diseases in humans, such as celiac, Crohn's or inflammatory bowel diseases.
UC Riverside featured him, his NIH grant and his research in a press release "Parasitic Worm Venom Evades Human Immune System," posted July 20, 2020 on EurekAlert. "By some estimates, nearly a quarter of the world's population is infected with various types of microscopic worms, or nematodes, with effects ranging from cognitive impairment and blindness to debilitation, elephantiasis, and death," writer Jules Berstein of UC Riverside related. "Examples include hookworm, which thrives in the American South, causing developmental delays and anemia; and pinworms, which commonly infect children and child care workers with an itchy perianal-area rash."
"You can have a person riddled with infection who never realized there's a 2-centimeter-long worm in their eye and thousands of parasites in their blood," Dlllman told her. "The immune system never signaled something was wrong. How is that possible? We know very little about how that works."
Devastating Parasites. Nematodes, he says, are "devastating parasites of humans, capable of modulating our biology in numerous ways, including suppressing our immune systems. The goal of my lab is to understand this modulation and to characterize the chemical pathways that allow it to happen. There's compelling data that parasites could even be used to treat autoimmune disorders such as Crohn's or inflammatory bowel disease. Parasitic worms are just the coolest things you could study because there are so many strange interactions, both positive and negative, that occur between the worms and their hosts."
Aylin Woodward of Business Insider spotlighted Dillman's work in a Sept. 13, 2020 news story headlined "A Scientist Won $1.8 Million to Study the Venom Parasitic Worms Use to Live Undetected in Our Bodies. He Thinks It Could Help Treat Celiac Disease. The Dillman lab is "looking at 500 or so different types of proteins released by nematodes that infect fruit flies," she wrote, quoting Dillman: "Flies are cheaper and easier to work with, and the parasites that affect insects release the same proteins as those that infect mammals."
"An analysis of research on this subject, published in 2017, described how the presence of nematodes and other parasites can lower inflammation in IBD and reduce the severity of multiple sclerosis, type 1 diabetes, asthma, and rheumatoid arthritis in animals," Woodward pointed out. "A 2010 study, in fact, described a patient with IBD who deliberately infected himself with a parasitic worm called a whipworm. The man's immune system started producing a type of protein crucial to healing his digestive tract, and the disease went into remission."
Dillman received his doctorate in 2012 from the California Institute of Technology (Caltech), a private research university in Pasadena, and then served as a postdoctoral fellow at Stanford from 2013 to 2014. He holds a bachelor's degree (2006) from Brigham Young University.
Shahid Siddique may be reached at ssiddique@ucdavis.edu.
/span>- Author: Kathy Keatley Garvey
This is a story of what might have been that never was and never will be and it all has to do with Hammock's cockroaches.
Hammock, who holds a joint appointment with the UC Davis Department of Entomology and Nematology and the UC Davis Comprehensive Cancer Center, remembers the scenario well.
While on the UC Riverside faculty, he worked on two cultures of very large roaches. One was the wingless Madagascar hissing cockroach, Gromphadorhina portentosa, and the other, the South American cave cockroach, Blaberus giganteus with "lovely translucent wings."
When he published a paper on his research, the U.S. Department of Food and Agriculture discovered that these 20-year-old cultures had never been registered.
“So, I registered, certified and chugged on with the research,” recalled Hammock. “Then one day both cultures vanished. I was frantic.”
The next day the chair of the department walked into his lab, gave him $10, and told him: “This is your share.”
The chair had sold the roaches that “no one was using” to a Hollywood movie company. “This was the main project in my lab so I went to Hollywood and tried to get the insects back,” Hammock lamented. “No way.”
Hammock's prized roaches, perhaps destined for greatness in the scientific world of cockroach literature, instead starred as evil roaches in the 1975-released movie, “Bug,” an American horror film based on Thomas Page's novel, ”The Hephaestus Plague (1973).”
The plot: A massive earthquake releases mutant cockroaches that create fire by rubbing together their cerci, a pair of small sensory appendages at the end of their abdomen that function somewhat like antennae. However, these mutant roaches die because they cannot survive in the low air pressure on the Earth's surface. Nonetheless, Professor James Parmiter (actor Bradford Dillman, 1930-2018), manages to keep one alive in a pressure chamber and breeds it with a modern cockroach, creating a breed of intelligent, flying, super-cockroaches. Chaos erupts in the small farming community.
Chaos also erupted on the movie set—and not just because some of the actors hated roaches.
“In a twist of fate,” Hammock said, “the movie company had rented the zoology building during the summer at UC Riverside for filming evil cockroaches from the center of the planet that got in people's hair and set them on fire.” In the process, the flames ignited a minor fire in the building.
An image of zoo building and a Hammock-reared roach appear on the IMDB poster. “After they finished shooting, I heard that they released the roaches on campus,” Hammock said.
“I would never find them,” he lamented. "But my son (Tom Hammock) who now is in the film industry loved the story."
Madagascar hissing cockroaches, nicknamed "hissers," measure two to three inches long and are big in the pet trade. They are a popular attraction in the UC Davis Bohart Museum of Entomology's live “petting zoo.”
Hammock's roach-rearing days at UC Riverside included giving a hissing roach to his mother because “she wanted a pet so I gave her one.”
“She had for several years as a pet. But she brought it back because she could not get her lady friends to babysit when she traveled. It terrified our cat but finally settled into an uneasy relationship.”
Viewers' description of Bug ranged from “the best of killer bug films” and “a scream fest” to “something that really freaked me out.” One reviewer, noting what happened to Professor Parmiter's wife, wrote “Bug, you light up my wife.”
Looking back, Hammock noted that "The science was actually a serious effort to work out the biosynthetic pathway of the hormone that regulates insect development, and then disrupt it for insect control. Sadly, I only published the first step before Hollywood turned the roaches into science fiction film history."
- Author: Kathy Keatley Garvey
The grant, titled "Strengthening Honey Bee Health and Crop Pollination to Safeguard Food Availability and Affordability," and headed by principal investigator Boris Baer, a UC Riverside professor of entomology, also includes Davis, San Diego and Merced campuses. “I'm very excited about so many different kinds of bee expertise joining forces through this project,” Baer said.
Honey bees pollinate more than 80 agricultural crops, including almonds, apples, blueberries and cherries. The pollination services of these tiny agricultural workers account for about a third of the American diet. However, pesticide exposure, spread of parasites and pathogens, habitat destruction and environmental changes are challenging beekeepers, resulting in decreased pollination services and increased food prices.
The grant is an important one. Co-principal investigator Extension apiculturist Elina Lastro Niño of the UC Davis Department of Entomology and Nematology, which operates the Harry H. Laidlaw Jr. Honey Bee Research Facility, says it well: "Most excitingly, this funding will not only support research that will help improve pollinator health so crucial for California's agriculture, but it will provide opportunities for training of students and postdoctoral scholars. Work focused on improving honey bee stocks via novel tools aligns well with ongoing work in the Niño lab and will further cement collaborations with beekeepers and growers.”
Niño, who works closely with California beekeepers, launched and directs the California Master Beekeeper Program, which uses science-based information to educate stewards and ambassadors for honey bees and beekeeping.
Other co-principal investigators are James Nieh and Joshua Kohn of UC San Diego, and a trio from UC Riverside: Kerry Mauck, Tsotras Vassilis, and Kim Hyoseung. At Merced, Marilia Palumbo Gaiarsa serves as a co-investigator.
The UC scientists plan a three-pronged approach to resolve the issue: develop better breeding programs, better medications and treatments, and better tools to monitor bee health in the hives. Small “listening and smelling” devices will be placed inside the hives to monitor bee health.
"Safeguarding honey bees and their pollination services requires beekeepers to be better able to manage the health and survival of colonies, which requires research into the causal factors and interactions affecting pollinator health, and the development and implementation of novel tools in close collaboration with industry partners. To do this, we will form a California wide, cross disciplinary research network and
- experimentally study the ecological and molecular factors and their interactions that affect honey bee health and their interactions to identify biomarkers of their health
- use the knowledge gained to develop and deliver new, effective solutions for stakeholders, including remote sensing of bee health, a marker-assisted breeding program, and the development of novel medications,
- build a research industry nexus to conduct collaborative research. We will also develop and deploy new extension and outreach modules that will be offered through UC Cooperative Extension statewide. We will support California beekeepers to build and maintain a sustainable and profitable beekeeping industry, which has implications for food security on a national level."
The co-principal investigators also noted in their grant proposal that "The current coronavirus pandemic and impending recession is putting more pressure on agriculture to provide sufficient and affordable food. Honey bees are key to such efforts, and supporting a California based beekeeping industry also decreases the state's dependence on managed pollination from elsewhere, thereby creating new jobs and income."
Funding also will help provide research opportunities for undergraduates, including underrepresented students, with the goal of ensuring that the pipeline of students who enter research, academia, industry, and multiple other professions reflects the diversity of the communities in which they learn and work.
This is all a win-win situation.
As Kohn said in a UC San Diego news release: “This network of bee researchers comprises a unique mixture of expertise that can apply highly multidisciplinary approaches to benefit the honey bee industry essential to the production of many of California's most economically important crops."
- Author: Kathy Keatley Garvey
And well they should.
UC Davis wasp expert and researcher Lynn Kimsey, director of the Bohart Museum of Entomology and professor of entomology, UC Davis Department of Entomology and Nematology, called the name "ridiculous" and said "it's no more likely to sting and kill a human than a honey bee." (See Bug Squad blog)
Kimsey, a two-term past president of the International Society of Hymenopterists, told us yesterday that “Actually it's less likely, as honey bee venom packs quite a punch and it is exclusively designed to defend against vertebrates."
“The colony everyone is hyperventilating over was actually found on Vancouver Island, British Columbia, last September when it was destroyed and then a single, dead hornet was found in December in Blaine, Wash.,” Kimsey said. “There is no evidence that there are any more hornets in the vicinity of Vancouver or anywhere else on the West Coast.”
A colony of the Asian giant hornet (AGH), Vespa mandarinia, was found and destroyed Sept. 18, 2019 in Nanaimo, Vancouver Island, and the single dead hornet was found Dec. 8, 2019 in Blaine.
These were the first detections of this species in North America, and no, the so-called "murder hornets" are not out to get us. They're not out to kill you. They're not taking over the world. (Expect some upcoming horror movies, though!)
Twenty Asian giant hornet (AGH) specimens are housed in the Bohart Museum of Entomology, home of a global collection of nearly 8 million species. The largest AGH, a queen, measures about an inch and a half long, Kimsey said. She's never seen any larger than that.
Meanwhile, entomologists are bemoaning the name, "murder hornet" and the sensationalism and fear-mongering ensuing. Apparently the name originated with a Japanese researcher; out of the translation came "murder hornet."
“It's a bloody dumpster fire,” said entomology advocate, traveler and photographer Stephane De Greef, administrator of a newly created Facebook page, “Is This a Murder Hornet?”
“Some poorly-worded media reports about Asian giant hornets have triggered a veritable avalanche of nonsense online, but I can help set the record straight, wrote senior museum scientist and hymenopterist Douglas Yanega of UC Riverside Entomology Research Museum.
“One colony was found and exterminated in Nanaimo on Vancouver Island in September of 2019, with a few sightings associated,” Yanega wrote. “One wasp believed to be from that colony was found--dead--on the U.S. side of the border near Nanaimo in December. Right now, all the authorities are doing is asking people to keep their eyes peeled JUST IN CASE there were queens that escaped the destruction of the Nanaimo nest, and established their own nests nearby. I was one of the authorities brought in to consult on this case, and to my knowledge there have not been any sightings in 2020 that would suggest the eradication attempt was unsuccessful. Put bluntly, as far as we know, there are no Asian giant hornets alive in either the U.S. or Canada as of 2020, and if there are, then they would be in the immediate vicinity of Vancouver Island (about a 50 mile radius or so).”
Want to know more about them? Read the fact sheet published by Washington State University Extension. It's the work of the husband-wife team of Susan Cobey, bee breeder-geneticist and Timothy Lawrence, county director of Island County Extension (both formerly of UC Davis), and also Mike Jensen, county director of Pend Oreille. (See https://bit.ly/2SA3TxS)
“It is critical that we identify, trap, and attempt to eliminate this new pest before it becomes established and widespread,” they wrote. “Attempts to contain the spread and eradication of this invasive insect will be most effective in trapping queens during early spring before their nests become established. Finding the nests can be a bit of a challenge. Their nests are typically in the ground though they can also be found under overhangs and within wall voids. The AGH is a strong flier and often will fly up and away and have an extensive flight range. Thus tracking can be difficult.”
They advise residents to “proceed with extreme caution and contact WSDA immediately. Do not try to exterminate the nest yourself.”
The sensationalism on the media is a concern, said Lawrence, "but...we need to find out just how extensive this infestation is."
Facebook users are posting images of so-called Asian giant hornets that are actually such species as cicada killers, European hornets, southern yellow jacket queens, sawflies, hoverflies, a beetle, and even a moth.
“Yes, it is possible this species could establish,” wrote Sloan Tomlinson, a parasitoid wasp specialist and educator. “Has it yet? No. Until concrete evidence is presented about any further establishment by this species, it's simply conjecture. Additionally, even IF this species is established, their infamy is overhyped and sensationalized. In Japan they do indeed kill around 30 people a year. Around 40 people are killed annually in the US by domestic dogs.”
Doctoral candidate and researcher Ellie Field of Iowa State University wrote on Facebook that “the murder hornet articles are making the rounds quickly and they seem to be doing more harm than good. Yes, it is awesome to track insect populations (particularly staying watchful for non-native and potentially invasive species). But no, the Asian giant hornet (Vespa mandarinia) is not going to destroy America. The one nest and individual that was found around Vancouver last year was destroyed, and this doesn't indicate any establishment. Introduction events happen all the time, all across the world! That region should continue to keep a watchful eye, but for everyone else this is not going to be relevant. There is no invasion, just a small possibility that some may have overwintered in that area.”
Those unsure about insect identification can email an image to Lynn Kimsey at lskimsey@ucdavis.edu or contact the Entomological Society of America at https://www.entsoc.org/ or https://bit.ly/2W2jRmi.
Entomologists also identify insects on such Facebook pages as “Insect Identification,” “Entomology,” and “Spider and Insect Enthusiast.”
Meanwhile, they're trying to douse the "bloody dumpster fires."
(Update: UC Davis distinguished professor Walter Leal, who studied and worked in Japan, asked a Japanese friend today about the origin of "murder hornet": The Asian giant hornet, Vespa mandarinia, is called “Kiiro Suzume Bachi (キイロスズメバチ)” in Japanese. It injects its venoms, sometimes inducing severe anaphylaxis. The article in BBC introduced Asian giant hornet, Vespa mandarinia as “murder hornet” is at https://www.bbc.com/news/52533
- Author: Kathy Keatley Garvey
That includes pollinator habitat.
In their paper, “Techno-Ecological Synergies of Solar Energy for Global Sustainability,” published today (July 9), the researchers propose a “techno–ecological synergy (TES), a framework for engineering mutually beneficial relationships between technological and ecological systems, as an approach to augment the sustainability of solar energy across a diverse suite of recipient environments, including land, food, water, and built-up systems.”
They provided “a conceptual model and framework to describe 16 TES of solar energy and characterize 20 potential techno–ecological synergistic outcomes of their use.”
The paper offers what is considered the most complete list yet of the advantages of solar energy. "The study also marks the launch of a partnership between the Center for Biological Diversity and UC Davis to advance a Wild Energy future, which emphasizes the potential of solar energy systems to benefit not only humans, but the entire planet," according to a UC Davis news release.
Despite solar energy's growing penetration in the global marketplace, “rarely discussed is an expansion of solar energy engineering principles beyond process and enterprise to account for both economic and ecological systems, including ecosystem goods and services,” wrote lead author Rebecca Hernandez of the UC Davis Department of Land, Air and Water Resources and the Wild Energy Initiative of the John Muir Institute of the Environment, UC Davis. She considers the first step in creating a wild-energy future is "understanding the true value of solar."
The researchers defined TES “as a systems-based approach to sustainable development emphasizing synergistic outcomes across technological and ecological boundaries…solar energy combined with TES may prove a promising solution for avoiding unintended consequences of a rapid renewable energy transition on nature by mitigating global change-type problems.”
Co-author and entomologist Leslie Saul-Gershenz, associate director of research for the Wild Energy Initiative, John Muir Institute of the Environment, said it is imperative to protect our ecological system, which includes pollinators and their required resources. Among them: nest sites, and pollen and nectar resources.
“Native pollinators face global pressure from many sources of habitat alteration, pesticide use, invasive non-native plants, and climate change,” said Saul-Gershenz, who received her doctorate in entomology from UC Davis. “We are proposing land sparing priorities in undisturbed ecosystems, such as arid lands in the Mojave and Sonoran deserts, which sustain some of the highest native pollinator species diversity in the United States. We add the valuation of these pollinators as essential resources into the calculation when selecting sites to deliver renewable energy goals to achieve true tech-ecological synergy and global sustainability.”
Solar cells, called photovoltaic (PV) solar energy, convert sunlight directly into electricity. For example, in Minnesota and Vermont, land adjacent to croplands is developed with PV solar energy, the authors noted. The low-growing flowering plants for native and managed pollinators help increase agricultural yields, reduce management (that is, mowing) costs, and confer the opportunity to produce honey and other honey-based commodities.
The researchers concluded that “achieving a rapid transition from fossil fuels to renewable energy sources on planet Earth to support human activities, in a manner benign to Earth's life support systems, is arguably the grandest challenge facing civilization today. The consequences of climate and other types of global environmental change are a cautionary flag against the extrapolation of past energy decisions.”
Hernandez initiated the research and led the conceptual design and writing of the manuscript All authors contributed to further content development and drafting of the manuscript. The team also included researchers from UC Berkeley, UC Riverside and UC San Diego, as well as scientists from Lancaster University in the United Kingdom; U.S. Fish and Wildlife Services, Sacramento; Center for Biological Services, Tucson, Ariz.; Université de Thiès, Senegal; Centers for Pollinators in Energy, Fresh Energy, St. Paul, Minn.; National Renewable Energy Laboratory, Golden, Co.; and Renewable Energy and Environmental Finance Group, Wells Fargo, San Francisco.
Look for more research on solar energy!
"Solar energy is the fastest-growing source of power worldwide," according to the UC Davis news release. "In 2019, solar is expected to provide more than 30 percent of all new U.S. electric capacity. According to the International Energy Agency, solar energy could become the largest electricity source by 2050. Solar has many advantages beyond providing power, particularly when built to maximize social, technological and environmental benefits."