- Author: Kathy Keatley Garvey
Allen-Diaz, vice president for UC Agriculture and Natural Resources (UC ANR), has agreed to participate in a stunt with thousands of buzzing honey bees clustered on either a UC ANR T-shirt or on a UC ANR banner in a project coordinated by the world-renowned bee wrangler Norm Gary, UC Davis emeritus professor of entomology.
Allen-Diaz holds several other titles: director of the Agricultural Experiment Station, director of Cooperative Extension, and professor and Russell Rustici Chair in Rangeland Management at UC Berkeley. But next spring, she will become “The Bee Lady” or “The Bee-liever,” surrounded by thousands of buzzing honey bees.
And, if the UC ANR administrator raises $5,000, she’s promised to eat insect larvae to promote awareness of alternative protein sources. (To donate, see http://promises.promiseforeducation.org/vpanr)
Allen-Diaz has never intentionally been near a cluster of bees. “I have to say that most of the bee interactions that I’ve had in the past have been stepping on them barefoot on the lawn as a child in Edmonds, Wash.; jumping off a rock wall into a bee hive as a child – 11 stings on my neck and face; and trying to control meat-eating wasps (protecting her families’ hands, faces and legs) at our Oregon home,” she said.
Norm Gary said he will set up the project sometime in the spring, when the weather warms and the bees begin their annual population build-up.
Gary, who turns 80 in November, retired in 1994 from UC Davis after a 32-year academic career. He also retired this year as a bee wrangler and as a 66-year beekeeper, but “I’m coming out of retirement to help with this cause,” he said.
“Bees are not inclined to sting if they are well-fed, happy and content and are ‘under the influence’ of powerful synthetic queen bee odors — pheromones — which tend to pacify them,” Gary said.
While at UC Davis, he formulated a pheromone solution that is very effective in controlling bee behavior. Bees, attracted to pheromones, cluster on the drops of pheromones, whether it be a sign, a t-shirt or a plastic flower.
“Bees wrangled by this procedure have no inclination to sting,” he said. “Stinging behavior occurs naturally near the hive in defense of the entire colony not for the defense of the individual bee, because bees that sting die within hours. Using this approach I have had as many as a million bees clustered on six people simultaneously.”
“Most people fear bees,” Gary acknowledged. “They think bees ‘want’ to sting them. Wrong! They sting only when the nest or colony is attacked or disturbed or when they are trapped in a physical situation where they are crushed.”
Gary holds a Guinness Book of World Records for most bees (109) in his mouth; he trained the bees to fly into his mouth to collect food from a small sponge saturated with his patented artificial nectar. He kept the bees inside his closed mouth for 10 seconds.
The retired bee scientist is the author of the popular book, “Honey Bee Hobbyist: The Care and Keeping of Bees,” now in its second printing. During his academic career, he published more 100 peer-reviewed scientific papers and four book chapters.
Gary, who received his doctorate in apiculture from Cornell University in 1959, is known internationally for his bee research. He was the first to document reproductive behavior of honey bees on film and the first to discover queen bee sex attractant pheromones. He invented a magnetic retrieval capture/recapture system for studying the foraging activities of bees, documenting the distribution and flight range in the field. His other studies revolved around honey bee pollination of agricultural crops, stinging and defensive behavior, and the effects of pesticides on foraging activities, among dozens of others.
A professional jazz and Dixieland musician, Gary is also known for playing the “B-Flat clarinet” while covered from head to toe with bees. He continues to play professionally in the Sacramento area—minus the bees.
“I’m looking forward to the big buzz next spring,” he said. “I promise it will be un-bee-lievable.”
Related links:
http://promises.promiseforeducation.org/vpanr
http://ucanr.edu/sites/anrstaff/Administration/Vice_President/Barbara_Allen-Diaz_Biography/
http://www.promiseforeducation.org/about
- Author: Jeannette E. Warnert
Ingels said he had no difficulty finding the pests on tree foliage and flying around when he visited the site last week.
“This is one of the worst invasive pests we’ve ever had in California,” Ingels said.
Brown marmorated stink bug affects many different crops and is a serious residential problem. It moves around easily, so can be expected to spread. It can fly up to a half mile at a time and also travels long distances by hitching rides in vehicles or inside furniture or other articles when they are moved, often during winter months. As a result, most new infestations are found in urban areas.
Brown marmorated stink bugs are native to China, Japan and Korea. They were first documented in the United States in Pennsylvania in 2001, but was likely established there several years earlier. The pest has spread throughout Pennsylvania, is believed to be established in at least 15 states, and has been found occasionally in more than a dozen additional states. In 2004, BMSB made its way to Oregon and is now established in northwest Oregon and a portion of Southern Washington. The National Agricultural Pest Information System maintains a map showing current infestations, but it does not yet show California finds. The pest has been present in Los Angeles County for 6 years.
BMSB feeds on dozens of California crops, including apples, pears, cherries, peaches, melons, corn, tomatoes, berries and grapes. Feeding on fruit creates pock marks and distortions that make the fruit unmarketable. In grapes, berries collapse and rot increases. Wine tasters have been able to detect stink bug odor in wines made from grapes that had 10 bugs in a 35-pound lug. It is also a pest of many ornamentals, especially the fruit-bearing trees, princess tree (Paulownia tomentosa), common Catalpa (Catalpa bignonioides) and tree-of–heaven (Ailanthus altissima).
In addition to the damage caused by the BMSB feeding, the “true bug” can cause disturbing problems for homeowners in the winter. When the weather cools down, bugs migrate in droves to sheltered areas, including inside homes and buildings.
“These bugs aggregate in such numbers that there are reports of people using manure shovels and five-gallon buckets to dispose of them,” Ingels said. “The strong, unpleasant odor the insects emit when disturbed makes cleanup still more daunting.
BSMB is a pest in its homeland, but is mostly controlled by parasitic wasps. USDA researchers have collected parasitic wasps in Asia, but they must be tested extensively before they can be released in California, a process that will take until 2016.
“Parasitism is our best hope for reducing populations,” Ingels said. “Chemical control of BMSB is very challenging.”
Ingels said the best way to keep them out of homes is to exclude them by sealing off any potential entry points, especially around window air conditioning units. Insecticides that have been shown to be effective in the lab are often less effective in the field. In and around the home, insecticides that have efficacy are mostly pyrethroids and neonicotinoids, both of which can have harmful off-site effects.
Pesticides showing efficacy on farms also include organophosphates and carbamates. But growers have worked hard to develop effective Integrated Pest Management programs, and the use of these broad spectrum sprays will set these programs back. There are also pest resistance concerns with increasing use of these products.
“Because they are strong fliers, it’s just a matter of time before they reach farms,” Ingels said.
The pest can be distinguished from ordinary brown stink bugs by its larger size, marble-like coloring on its shield and white markings on the extended edge of the abdomen. BSMB also has distinctive white bands on the antennae and legs. The UC Integrated Pest Management Program has posted a video on YouTube to aid in identifying the pest. (The video is also embedded below.)
Traps with sex pheromones or other attractants can be used to monitor for the pest, but they are often poor at trapping the bugs even when populations are high. The best monitoring method is to inspect foliage throughout the year, and larger branches in late summer and fall for aggregating bugs. A quick method is to beat foliage over a piece of cardboard or sheet. If suspected BSMB are found, place some in a container and note where and when they were collected. Take the sealed container to the county agricultural commissioner or local UC Cooperative Extension office.
The following UC IPM video was created to help identify brown marmorated stink bug:
- Author: Pamela Kan-Rice
UC scientists combat resurgence of bedbug in behavioral studies and monitor trials
Bedbugs are showing up more frequently in California and around the world, and new UC research shows that current methods for detecting the blood-sucking pests aren’t very reliable.
Detecting bedbugs is key to controlling them so a UC study tested three commercial monitors. At best, the monitors containing attractants captured 10 percent of the bedbugs, wrote UC scientists from UC Cooperative Extension, UC Berkeley and UC Riverside in the July–September 2013 issue of California Agriculture, UC's peer-reviewed journal of agricultural, natural and human resources.
As bedbugs become more prevalent, the researchers call for improving monitors as well as developing new methods to lure the insects more effectively.
“If we could put out bait and the bedbugs find it and die, wouldn’t that be great?” said Vernard Lewis, UC Cooperative Extension specialist in the Department of Environmental Science, Policy and Management at UC Berkeley and lead author of the article. Lewis is testing attractants for bedbugs and observing their behavior.
In Villa Termiti, a room built for studying insects, Lewis set up an experiment to see how far the bedbugs moved in a 24-hour period. He found that the bedbugs moved around to a bed, rug or low table, but most stayed close to the cardboard on which they were released in the middle of the floor. The monitors containing attractants captured up to 10 percent of the bedbugs, twice as many as the monitors that didn’t contain attractants, but not a statistically significant difference.
Lewis and his colleagues are studying new ways of detecting bedbugs and exterminating them.
Effective detection to determine the effectiveness of treatments made to eliminate bedbug infestations would be helpful. “When a property is treated and bedbugs reappear, at this point, we can’t tell whether the bedbugs survived the treatment or they are moving in from next door,” Lewis said.
The Lewis Lab is also exploring new methods of bedbug control that minimize the use of pesticides.
Co-author Dong-Hwan Choe, UC Cooperative Extension specialist in the Department of Entomology at UC Riverside, is currently studying essential oils from plants such as clove and wintergreen to see if they can be used as alternatives to synthetic insecticides.
Andrew Sutherland, UC Cooperative Extension advisor for the San Francisco Bay Area, has been meeting with pest control professionals to share the latest bedbug research results and integrated pest management approaches to minimize the amounts of pesticides used.
Sutherland also has begun training UC Master Gardener volunteers to answer questions about bedbugs and to share information about integrated pest management to control insects in the home.
“Master Gardeners in urban counties increasingly get requests regarding household pests,” said Sutherland. “UC ANR is interested in providing education and outreach on this topic because urban pest management significantly impacts water quality and other environmental resources. I have designed a 'Household Pests' unit used in 'Advanced IPM Training' for Master Gardeners.’”
“Master Gardeners will be able to help residents identify bedbug specimens and direct the general public to our Pest Note at http://www.ipm.ucdavis.edu/PMG/PESTNOTES/pn7454.html,” he said.
“Many clients think they may have bedbugs, but actually have recovered specimens of other insects,” Sutherland said. “In those cases we are able to prevent unnecessary and sometimes dangerous pesticide applications. When bed bugs are identified, our message is always to contact a professional pest control operator.”
The exact causes of the bedbug resurgence are not known, but increased international travel among people, pesticide resistance among bedbugs, the ease with which bedbugs can spread, and reduced indoor use of residual insecticides may be contributing factors.
The bedbug article in the July–September 2013 issue of California Agriculture can be downloaded at http://californiaagriculture.ucanr.edu.
More than half a century after its decline, agriculture has again become high profile in Los Angeles County, although the focus has shifted from rural to urban. Urban agriculture has gained momentum in the county, as it has in many metropolitan centers throughout the United States, with a growing number of small-scale city farmers, along with enthusiastic backyard beekeepers and poultry raisers. However, despite the apparent popularity of urban agriculture, a clear picture of its status in the county did not exist until very recently.
A new UCLA student report, “Cultivate LA,” was released on Aug. 15 and offered the first comprehensive picture of the local urban agriculture landscape. The report provides an important foundation for UC Cooperative Extension and other groups involved in developing policy and educational resources for urban farmers.
According to Rachel Surls, UC Cooperative Extension sustainable food systems advisor in Los Angeles County and the “client” of the student project, the report has generated tremendous interest. The students verified a total of 1,261 urban agriculture sites using a variety of data sources, and confirming sites with telephone calls and Google Earth. They looked closely at issues such as complex zoning codes that impact urban farming and the distribution of its products. As one of their final products, the students created a website (www.cultivatelosangeles.org) that contains an interactive map and a chart of agriculture zoning codes in each of the county’s 88 cities and its unincorporated areas.
Surls became involved in urban agriculture policy beginning in 2011, through her participation in the Los Angeles Food Policy Council. Due to the lack of information at that time, the task of crafting policy was a challenge. So, when UCLA faculty members offered to have urban planning graduate students produce a comprehensive report on urban agriculture in Los Angeles County, guided by her input, Surls embraced the opportunity. With Carol Goldstein, lecturer in urban planning, and Stephanie Pincetl, professor and director of the California Center for Sustainable Communities at UCLA’s Institute of the Environment and Sustainability, Surls helped the students develop their research questions and directed them towards important sources of data.
Surls points out a few relevant findings that will guide her work in further developing UC Cooperative Extension’s program in sustainable food systems.
School gardens are the most common form of urban agriculture. In Los Angeles County, there are more than 700 verified sites. The report suggests that more resources and training are needed to ensure that gardens are successful and integrated into the school curriculum. Surls plans to update resources for school gardens in the next few months.
Urban farmers face major challenges. They find it hard to compete with rural farmers. Their small growing spaces make it difficult for them to produce fruits and vegetables that are competitively priced with those produced on large rural farms.
“Also, urban farmers have to learn from the ground up,” said Surls, who plans on creating an online database of resources and best practices for urban farmers. "Often, they don’t know where to start and don’t realize they are entering a very complex business.”
Despite some challenges, urban farmers can enjoy advantages. Some have access to free or low-cost land if they operate within a public agency or nonprofit setting. Surls is currently developing resources that will help urban farmers test their soil and identify and mitigate problems, such as lead contamination. She also hopes to partner with nonprofit agencies to evaluate vacant lands for their suitability for farming.
Surls is currently leading a project that is assessing the needs of urban agriculture throughout the state. She is excited to see how the results of the UCLA student report will dovetail with the results of the statewide assessment.
“What’s happening in Los Angeles is mirrored in cities around California,” said Surls. "The public is enthusiastic about urban farming, and municipalities are struggling to find models that work in California’s urban communities. Both of these projects can help planners and citizens make common-sense decisions and help current and future urban farmers become successful.”
To learn more about the UCLA student project, visit http://cultivatelosangeles.org. For more information on UC Cooperative Extension’s sustainable food systems program, please visit http://celosangeles.ucanr.edu.
- Author: Pamela Kan-Rice
A special collection of original research on methyl bromide alternatives is part of the July–September 2013 issue of California Agriculture, UC's peer-reviewed journal of agricultural, natural and human resources (http://californiaagriculture.ucanr.edu). Related articles will appear in the October–December 2013 issue.
Methyl bromide contributes to ozone depletion high in the atmosphere and was banned by developed countries in 2005 under the Montreal Protocol, an international treaty to protect the stratospheric ozone layer. Since then, the treaty has allowed limited use of methyl bromide for certain crops, but many of these exemptions are gone and the rest will end soon.
To develop and evaluate alternatives to methyl bromide, a team of UC and U.S. Department of Agriculture researchers was awarded a $5 million, five-year USDA grant. The project — called the Pacific Area-Wide Pest Management Program for Integrated Methyl Bromide Alternatives (PAW-MBA) — includes production crops such as grapes, strawberries and tree nuts as well as nursery crops such as cut flowers, forest trees and sweet potatoes.
"One goal of the program was to identify methyl bromide alternatives that were immediately useful and economically feasible," says Greg Browne, a USDA plant pathologist at UC Davis who coordinates the PAW-MBA program. "Another was to foster development of nonfumigant strategies for managing soilborne pests."
The team has identified methyl bromide alternatives that are both effective and economical for key California crops. When the best alternative is another fumigant, the researchers found ways to use less and to cut emissions. In addition, the researchers are developing alternatives that go beyond fumigants, including steam sterilization and other nontoxic approaches.
Summaries of projects and links to articles:
TIF film, substrates and nonfumigant soil disinfestation maintain fruit yields
Strawberry growers use methyl bromide primarily to control soilborne diseases. Now, new UC research shows that this crop can be grown without fumigants at small scales. Three nontoxic methods — nonsoil substrates, anaerobic soil disinfestation and steam disinfestation — produced strawberry yields as high as those in conventionally fumigated soil. “Instead of understanding soil, we've just been fumigating it," says Steve Fennimore, a UC Cooperative Extension specialist in Salinas who led this team. "Using physical tools is a different approach." Researchers will next evaluate whether these alternative methods can be scaled up to commercial production fields, and whether they work in different strawberry production areas of California.
Managing the almond and stone fruit replant disease complex with less soil fumigant
Almond and stone fruit growers need methyl bromide alternatives to control nematodes and Prunus replant disease, a soilborne disorder that stunts new orchards and cuts yields. To help these growers, UC and USDA researchers tested alternative fumigants, spot and strip fumigation and nonfumigant methods including rotating orchards with sudangrass and using nematode-resistant rootstock. “Spot treatments provided adequate control of Prunus replant disease and may be very helpful to growers needing to use less fumigant for costs savings or regulatory restrictions,” Browne says. In addition, integrating the various treatments tested may also help control the replant disease with less fumigant use.
Preplant 1,3-D treatments test well for perennial crop nurseries, but challenges remain
California supplies nursery stock to the state's fruit, nut and vineyard industries, as well as more than 60 percent of the rose plants and fruit and nut trees sold nationwide. This perennial nursery stock must be completely nematode-free, and growers use methyl bromide primarily to control these tiny soilborne worms. However, alternative fumigants such as 1,3-dichloropropene (1,3-D) don't work as well in fine soils. "We asked how we could make them work better," says Brad Hanson, a UC Cooperative Extension specialist in the Department of Plant Sciences at UC Davis. The researchers showed that 1,3-D controlled nematodes in fine soil when they tilled it deeper, injected the fumigant deeper and used tarps that kept more of the fumigant in the soil.
Fumigant emission reductions with TIF warrant regulatory changes
Fumigants are regulated partly because they help make smog. Totally impermeable film (TIF) can help keep fumigants in the soil and out of the air. New UC research shows that fumigant emissions can drop 64 percent when fields are tarped with TIF for twice as long as usual (10 days instead of 5). "We're now working on safe use," says Suduan Gao, a USDA soil scientist in Parlier who led the team. "The goal is to keep the fumigant under the tarp long enough that there won't be a surge in emissions when it's cut open." This work gives regulatory agencies a new way to let growers keep using enough fumigant to control pests and diseases while minimizing the smog-forming emissions.
The entire July–September 2013 issue can be downloaded at http://californiaagriculture.ucanr.edu.
California Agriculture is the University of California's peer-reviewed journal of research in agricultural, human and natural resources. For a free subscription, go to: http://californiaagriculture.ucanr.edu, or write to calag@ucanr.edu.
The University of California's Division of Agriculture and Natural Resources is the bridge between local issues and the power of UC research. UC ANR's advisors, specialists and faculty bring practical, science-based answers to Californians. Visit http://ucanr.edu to learn more.
WRITERS/EDITORS: To request a hard copy of the journal, email crllopez@ucanr.edu.