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United States Department of Agriculture

Agricultural Research Service


Location: Invasive Insect Biocontrol & Behavior Laboratory

2011 Annual Report

1a. Objectives (from AD-416)
Objective 1: Develop new toxicants and application methods (e.g., attract-and-kill formulations) that provide novel modes of action or that have other properties desirable for efficacy, safety, and commercialization. Objective 2: Develop new repellent active ingredients and combinations that provide protection and product potential. Objective 3: Determine the fine scale elements of mosquito behaviors (e.g., host-seeking) and associate them with particular chemicals (agonists and antagonists) and physiological detection mechanisms, in order to develop novel behavior-altering chemicals. Objective 4: Develop and refine bioassay methodologies for blood-sucking arthropods that can serve as standards for EPA labeling of toxicant and repellent compounds.

1b. Approach (from AD-416)
Applied research will use the expertise of entomologists and a synthetic organic chemist to produce, develop and evaluate new toxicant and repellent products effective against blood-sucking arthropods. Fundamental research will elucidate the underlying mechanisms involved in mosquito attractancy and repellency, thereby leading to the discovery of even newer classes of chemicals that alter arthropod behavior. Consistent with these efforts, bioassays will be developed and refined that can be used by the research community and industry for discovery, product development and federal registration purposes.

3. Progress Report
The focus of our research is to discover and develop new methods to protect people from blood-sucking arthropods. Priority arthropod targets are mosquitoes, ticks, and the common bed bug. ARS scientists in Beltsville, MD have identified and synthesized new, fast-acting insecticides that have been shown to be toxic to numerous types of mosquitoes of public health importance. These new compounds presumably induce their toxic effect based on their on their high vapor pressure, which allows them to vaporize quickly, resulting in toxicity to exposed mosquitoes in minutes. An invention disclosure has been filed, which will hopefully result in a new product to control insects of medical importance. Fundamental research involving mosquito host attraction has characterized a receptor in the yellow fever mosquito for a host-produced attractant. ARS scientists in Beltsville MD have shown that mosquito receptors are quite specific to compounds involved in host attraction. This research has created a better understanding of odor reception in mosquitoes that may ultimately be used in the rational design of mosquito repellent compounds. Natural product compounds supplied by collaborating ARS scientists and other partners have been evaluated by ARS scientists in Beltsville, MD for their efficacy in repelling a tick species of veterinary and medical importance. Repeated testing of individual ticks, showed how often ticks can be reused in behavioral tests and how a tick’s responses to a repellent may vary. A considerable effort has been directed at bioassays of tick attractants, which have been more difficult to characterize. Tick attractants could potentially be used in conjunction with toxicants, resulting in an “attract and kill” strategy that would contribute to an overall, tick management program. Research with bed bugs has revolved around efficacy testing of proprietary compounds obtained from ARS chemists, and of compounds obtained from industry. Most compounds tested have proven ineffective in killing bed bugs, though several promising compounds are being further evaluated for immediate and residual activity. ARS scientists have also obtained several field infestations of bed bugs thought to be resistant to commercially-available pesticides, though further testing indicated only two of these strains were resistant at levels that make them useful for chemical screening purposes. However, rearing of these field-collected strains has proven to be difficult as these bugs seemingly lack feeding avidity, which results in decreased reproduction and lower numbers available for testing.

4. Accomplishments

Review Publications
Thanispong, K., Achee, N., Grieco, J., Chauhan, K.R., Bangs, M.J., Suwonkerd, W., Prabaripai, A., Tanasinchayakul, S., Chareonviriyaphap, T. 2010. A high throughput screening system for determining the three actions of insecticides against Aedes aegypti (Diptera: Culicidae) populations in Thailand. Journal of Medical Entomology. 47(5):833-841.

Weldon, P., Carroll, J.F., Kramer, M.H., Bedoukian, R., Coleman, R., Bernier, U.R. 2011. Anointing chemicals and ectoparasites: responses by ticks and mosquitoes to Citrus (Rutaceae) peel exudates and monoterpene constituents. Journal of Chemical Ecology. 37(4):348-359.

Bohbot, J.D., Dickens, J.C. 2010. Insect Repellents: Modulators of mosquito odorant receptor activity. PLoS One. 5(8):e12138.

Bohbot, J.D., Fu, L., Le, T.N., Chauhan, K.R., Cantrell, C.L., Dickens, J.C. 2011. Multiple activities of insect repellents on odorant receptors in mosquitoes. Medical and Veterinary Entomology.

Feldlaufer, M.F., Loudon, C. 2011. Undesirable dispersal of eggs and early-stage nymphs of the bed bug Hemiptera: cimicidae) by static electricity and air currents. Journal of Entomological Science. 46(2):1-2.

Grant, A.J., Dickens, J.C. 2011. Functional characterization of the octenol receptor neuron on the maxillary palps of the yellow fever mosquito, Aedes aegypti. PLoS One. 6(6):e21785.

Last Modified: 10/17/2017
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