A female Northern Pintail marked with a solar-powered satellite transmitter. Photo credit: Dr. Tetsuo Shimada, Izunuma-Uchinuma Environmental Foundation

Locations in Japan where Northern Pintail Ducks where captured and radiomarked.

Evaluating exchange of avian-borne pathogens between Asia and North America by migratory birds requires an understanding of patterns of contact among birds from each continent. Biologists at the Alaska Science Center (USGS) are comparing neutral nuclear and mitochondrial genetic similarities between Asian and North American pintails to evaluate the degree of reproductive isolation between these populations, and are assessing transcontinental transmission of avian influenza by comparing genetic similarities of low pathogenic (non-H5N1) virus strains in pintails wintering in California to those from Japan. Collaborators include the Laboratory of Biodiversity Science (University of Tokyo), USGS National Wildlife Health Center, Western Ecological Research Center, and the U.S. Fish and Wildlife Service.

Capture of Northern Pintails at Lake Izunuma-Uchinuma, Japan

Read about genetic analyses of avian influenza in Northern Pintails at following Progress Report:

Movements of Northern Pintail Ducks and Whooper Swans Marked with Satellite Transmitters in Japan

For more information contact Dirk V. Derksen, Alaska Science Center.

Rapid Molecular Techniques for Avian Influenza Detection in Wild Birds

Common shellduck (Tadorna tadorna) carrying a satellite transmitter as part of avian influenza surveillance efforts in Egypt. Photo credit: Eric C. Palm, USGS

Efficient methods for the detection of avian influenza (AI), particularly those subtypes that are lethal to humans, poultry and wild birds, are necessary for the prevention of outbreaks. Rapid detection methods also represent a breakthrough for research that seeks to unravel the role of wild birds in the spread of the virus. The ability to determine the host status of wild birds at the time of field sampling, makes it possible to deploy satellite transmitters to track the movement of the host. This information would enhance understanding of whether wild birds can act as vectors for highly pathogenic subtypes such as the lethal subtype, H5N1. Recently developed molecular methods, such as real-time reverse transcriptase polymerase chain reaction (rRT-PCR) offers one of the most accurate and sensitive techniques for diagnosis of AI in the laboratory. Most rRT-PCR assays are capable of characterizing the AI subtype, even at the low titer levels shed by wild birds. However, maintenance of wet PCR reagents at a constant cold temperature has prohibited the use of rRT-PCR in field settings. Our current work aims to validate the use of various portable rRT-PCR units that use freeze-dried reagents, eliminating the need for refrigeration in the field. Such technologies would lend themselves to use in remote locations throughout Eurasia where avian influenza H5N1 has become entrenched.

For more information view Satellite Tracking Migratory Birds: Determining Migratory Connectivity and Routes for Distinct Populations and contact John Y. Takekawa and Nichola J. Hill, Western Ecological Research Center.

Distribution of P. multocida serotype 1 isolates cultured from wild birds and environmental samples collected in Central California.  Isolates are represented on the map according to their collection location using dendrogram branch designations from figure 3a.  Collection sites are indicated with triangles. Larger view

Birds affected by avian cholera. Photo credit: USGS

Avian cholera, an infectious disease caused by the bacterium Pasteurella multocida, kills thousands of North American wild waterfowl annually.  Pasteurella multocida serotype 1 isolates cultured during a laboratory challenge study of mallard ducks (Anas platyrhynchos) and collected from wild birds and environmental samples during avian cholera outbreaks were characterized using amplified fragment length polymorphism (AFLP) analysis, a whole-genome DNA fingerprinting technique.  Comparison of the AFLP profiles of 53 isolates from the laboratory challenge demonstrated that P. multocida underwent genetic changes during a three month period. 

Principal components analysis of P. multocida serotype 1 isolates cultured from wild birds and environmental samples.  Each isolate is designated according to its collection location and the cluster encompassing 49 of the 61 Central California P. multocida isolates is circled. Larger view

Analysis of 120 P. multocida serotype 1 isolates collected from wild birds and environmental samples revealed that isolates were distinguishable from one another based upon regional and temporal genetic characteristics.  Thus, AFLP analysis had the ability to distinguish P. multocida isolates of the same serotype by detecting spatiotemporal genetic changes and provides a tool to advance the study of avian cholera epidemiology.  Further application of AFLP technology to the examination of wild bird avian cholera outbreaks may facilitate more effective management of this disease by providing the potential to investigate correlations between virulence and P. multocida genotypes, to identify affiliations between bird species and bacterial genotypes, and to elucidate the role of specific bird species in disease transmission.

For more information contact David S. Blehert, National Wildlife Health Center.