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May 2017

Study shows mosquito pesticides do not cause honeybee mortality

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LSU AgCenter researchers in the Department of Entomology found mosquito control done properly has minimal effects on the health of honeybees. The three-part study, funded by a 2013 grant from the U.S. Environmental Protection Agency, evaluated the effects of pesticides on honeybees.

“You have a lot of attention focused on caring for bees and keeping them healthy,” said AgCenter entomologist Kristen Healy. “They produce honey, but they’re also important because they pollinate crops worldwide.”

LSU entomology graduate student Vivek Pokhrel views bees at the USDA Honey Bee Breeding, Genetics and Physiology Research Laboratory in Baton Rouge on July 22, 2016. Pokhrel has been studying bee enzymes to determine bee stress levels. Photo by Olivia McClure

LSU entomology graduate student Vivek Pokhrel views bees at the USDA Honey Bee Breeding, Genetics and Physiology Research Laboratory in Baton Rouge on July 22, 2016. Pokhrel has been studying bee enzymes to determine bee stress levels. Photo by Olivia McClure

The project was a collaboration among scientists at the LSU AgCenter, the U. S. Department of Agriculture Honey Bee Breeding, Genetics and Physiology Research Laboratory in Baton Rouge, East Baton Rouge Parish Mosquito Abatement and Rodent Control and USDA agricultural engineers from Texas. Local beekeepers were also involved in the study.

The research included laboratory, semi-field and field components. AgCenter researchers conducted lab tests using specific insecticides that target mosquitos to find toxicity levels for bees.

Research in the past focused on toxicity in a lab without real-world testing in the field. “We know the concentration that would kill a bee, but is it realistically going to get exposed to that concentration in the field?” Healy said.

After determining lethal concentrations, scientists conducted semi-field tests, where a truck sprayed six of the most common mosquito control insecticides toward pairs of cages containing bees and mosquitos. The cages were placed on poles from 50 feet apart to 300 feet apart, the typical distance insecticides can drift from spray trucks.

Honeybees crowd on a honeycomb at the USDA Honey Bee Breeding, Genetics and Physiology Research Laboratory in Baton Rouge on July 22, 2016. Photo by Olivia McClure

Honeybees crowd on a honeycomb at the USDA Honey Bee Breeding, Genetics and Physiology Research Laboratory in Baton Rouge on July 22, 2016. Photo by Olivia McClure

“This is the highest possible label rate that mosquito control would ever use out of a truck, and we didn’t see any bee mortality, even at 50 feet,” Healy said.

Mosquito control products use extremely small doses that target mosquitos, and the chemicals break down within hours. “Mosquitos are 100 times more susceptible to these pesticides than bees are,” she said.

The third stage included field tests. Local beekeepers volunteered, half of them with hives in areas of frequent mosquito treatment, with the other half in areas without control.

Scientists found no differences in the mortality rates of bees in both groups. “These pesticide concentrations used out in the field are not high enough to kill bees,” Healy said.

Researchers also measured stress by analyzing indicator enzymes from the field-test bees. They found no difference in stress between the two groups.

Mosquito control agencies do not indiscriminately spray chemicals, Healy said. They use science-based research like surveillance, trapping and population counts while testing for pathogens like West Nile virus and Zika virus to plan targeted mosquito control.

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Bees are contained in a cage in Baton Rouge where researchers conducted semi-field tests with a truck spraying mosquito pesticides at cages of bees and mosquitos. Photo by Olivia McClure

Bees stay inside their hives during the night when mosquito controls are usually sprayed and forage during the day when chemicals have disappeared. Still, it’s important for beekeepers and mosquito control agencies to communicate frequently.

“I’m happy that we’re not killing bees with mosquito control,” Healy said. “The exciting part was having people with both interests that were there every step of the way.”
Healy regularly gives presentations to the community, including beekeepers, who are understanding of the situation.

“They say I don’t like mosquitoes, so if it’s not having an effect on my bees, I think I’d rather opt for protecting my family and pets against West Nile and Zika,” she said.

Originally posted on: Thecreole.com

Study Highlights Diversity of Arthropods

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Distribution of dust mites detected in door trim dust from inside homes across the United States (purple) compared with the range where they are predicted to be most abundant (tan). Image credit: Anne A. Madden.

Researchers from North Carolina State University and the University of Colorado Boulder used DNA testing and citizen science to create an “atlas” that shows the range and diversity of arthropods found in homes across the continental United States.

Scanning electron micrograph of home dust including dust mites, animal fur, fibers, and pollen. Image credit: Anne A. Madden, with the assistance from Robert Mcgugan at the University of Colorado, Boulder Nanomaterials Characterization Facility. False-coloring done by Robin Hacker-Cary. Click to enlarge.Scanning electron micrograph of home dust including dust mites, animal fur, fibers, and pollen. Image credit: Anne A. Madden, with the assistance from Robert Mcgugan at the University of Colorado, Boulder Nanomaterials Characterization Facility. False-coloring done by Robin Hacker-Cary. Click to enlarge.

Previous research found a significant diversity of arthropods in homes in one part of North Carolina – we wanted to use advanced DNA sequencing-based approaches to get a snapshot of arthropod diversity in homes across the country,” says Anne Madden, a postdoctoral researcher at NC State and lead author of a paper on the new work. “This work is a significant step toward understanding the ecology of our own homes, with the goal of improving our understanding of how those organisms in our homes may affect our health and quality of life.”

To collect nationwide data, the researchers recruited more than 700 households across all 48 states in the continental United States. Study participants swabbed dust from the top of a doorway inside their house or apartment. The swab was then sealed and sent to the research team, which used high-throughput DNA analysis to identify every genus of arthropod DNA found in the dust samples.

“We found more than 600 genera of arthropods represented inside people’s homes – not including food species, such as crabs and shrimp, which also showed up,” Madden says. “That’s an incredible range of diversity from just a tiny swab of house dust.”

After analyzing the data, researchers identified several variables that were associated with greater arthropod diversity: having cats or dogs in the home; having a home in a rural area; or having a home with a basement.

“Greater diversity does not necessarily mean greater abundance,” Madden says. “We’re talking about more types of arthropods, not necessarily larger populations of arthropods.”

Researcher Anne Madden, looking at trays of samples containing DNA samples from homes. Image Credit: Adrianne A. Madden.
Researcher Anne Madden, looking at trays of samples containing DNA samples from homes. Image Credit: Adrianne A. Madden.

These findings expand on previous work that found pet ownership also increased the biodiversity of microbial organisms, such as bacteria and fungi.

“We were surprised to see that these three variables – which we have some control over – were more powerful predictors of biodiversity than climate,” Madden says. “We had expected environmental factors associated with regional climate to play a larger role than they actually did.”

However, the scope of the study data also allowed the researchers to create a national atlas they can use to track the range of specific arthropod genera. And, depending on the genus, climate factors were seen to play a significant role in determining the range of some arthropods.

For example, dust mites can be serious allergens in homes and the team found that they were more often associated with homes in humid regions of the country.

In addition, researchers were able to use the atlas to identify genera that had significantly expanded their range – but no one had previously noticed.

For example, the Turkestan cockroach (Shelfordella lateralis) was previously thought to be found only in the southern and western regions of the United States – but the data from this study showed that it had expanded as far as the Northeast.

“We’re just scratching the surface of how we can use this data set and the arthropod atlas,” Madden says. “What can it tell us about the food webs in our own homes? What can it tell us about how arthropod populations expand and contract across the country? What emerging allergens can it reveal? We’re just getting started.

“Also, we want to stress that this was a citizen science project,” Madden says. “This study would not have been possible without the participation of people from across the country who volunteered to be actively involved in the work.” [Note: anyone interested in participating in future citizen science projects with this research team can visit http://www.yourwildlife.org/participate/.]

The paper, “The diversity of arthropods in homes across the United States as determined by environmental DNA analyses,” is published in the journal Molecular Ecology. The paper was co-authored by Albert Barberán and Noah Fierer of the University of Colorado Boulder; Matthew Bertone and Holly Menninger of NC State; and Rob Dunn of NC State and the University of Copenhagen. The work was done with support from the Alfred P. Sloan Foundation.

Note to Editors: The study abstract follows.

“The diversity of arthropods in homes across the United States as determined by environmental DNA analyses”

Authors: Anne Madden, North Carolina State University and University of Colorado, Boulder; Albert Barberán and Noah Fierer, University of Colorado, Boulder; Matthew A. Bertone and Holly L. Menninger, North Carolina State University; Robert R. Dunn, North Carolina State University and University of Copenhagen

Published: Nov. 1, Molecular Ecology DOI: 10.1111/mec.13900

Abstract: We spend most of our lives inside homes, surrounded by 3 arthropods that impact our property as pests and our health as disease vectors and producers of sensitizing allergens. Despite their relevance to human health and well-being, we know relatively little about the arthropods that exist in our homes and the factors structuring their diversity. Since previous work has been limited in scale by the costs and time associated with collecting arthropods and the subsequent morphological identification we used a DNA-based method for investigating the arthropod diversity in homes via high-throughput marker gene sequencing of home dust. Settled dust samples were collected by citizen scientists from both inside and outside more than 700 homes across the United States, yielding the first continental-scale estimates of arthropod diversity associated with our residences. We were able to document food webs and previously unknown geographic distributions of diverse arthropods—from allergen producers to invasive species and nuisance pests. Home characteristics, including the presence of basements, home occupants, and surrounding land-use, were more useful than climate parameters at predicting arthropod diversity in homes. These non-invasive, scalable tools and resultant findings not only provide the first continental-scale maps of household arthropod diversity, our analyses also provide valuable baseline information on arthropod allergen exposures and the distributions of invasive pests inside homes.

Originally Posted on: news.ncsu.edu