Jeffrey S Hall
Jeffrey Hall is a Research Virologist at the National Wildlife Health Center.
Professional Experience
Sept. 2007 - Present Research Virologist USGS National Wildlife Health Center, Madison, WI
Sept. 2003 - Sept. 2007 Virologist/ Laboratory Manager USDA-APHIS-NWRC. Ft. Collins, CO
July 1997 - Sept. 2003 Microbiologist USDA-ARS. Lincoln, NE
March 1991 - July 1997 Research Associate Department of Plant Pathology. University of Nebraska-Lincoln, Lincoln, NE
Education and Certifications
2001 Doctor of Philosophy, Comparative Pathobiology, University of Nebraska-Lincoln, Lincoln, NE
Science and Products
Demographic and spatiotemporal patterns of avian influenza infection at the continental scale, and in relation to annual life cycle of a migratory host
Dispersal of H9N2 influenza A viruses between East Asia and North America by wild birds
Rapidly expanding range of highly pathogenic avian influenza viruses
The dynamics of avian influenza in western Arctic snow geese: implications for annual and migratory infection patterns
Spatial and temporal patterns of avian paramyxovirus-1 outbreaks in Double-Crested Cormorants (Phalacrocorax auritus) in the USA
Evidence for seasonal patterns in the relative abundance of avian influenza virus subtypes in blue-winged teal (Anas discors)
Avian influenza virus ecology in Iceland shorebirds: intercontinental reassortment and movement
Respiratory transmission of an avian H3N8 influenza virus isolated from a harbour seal
Avian influenza virus antibodies in Pacific Coast Red Knots (Calidris canutus rufa)
North Atlantic migratory bird flyways provide routes for intercontinental movement of avian influenza viruses
Sampling strategies and biodiversity of influenza A subtypes in wild birds
Evolution of a reassortant North American gull influenza virus lineage: drift, shift and stability
Non-USGS Publications**
10.4269/ajtmh.2009.09-0136
https://doi.org/10.3201/eid1412.071371
https://doi.org/10.7589/0090-3558-44.2.362
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
Science and Products
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Filter Total Items: 48
Demographic and spatiotemporal patterns of avian influenza infection at the continental scale, and in relation to annual life cycle of a migratory host
Since the spread of highly pathogenic avian influenza (HPAI) H5N1 in the eastern hemisphere, numerous surveillance programs and studies have been undertaken to detect the occurrence, distribution, or spread of avian influenza viruses (AIV) in wild bird populations worldwide. To identify demographic determinants and spatiotemporal patterns of AIV infection in long distance migratory waterfowl in NoAuthorsRodolfo Nallar, Zsuzsanna Papp, Tasha Epp, Frederick A. Leighton, Seth R. Swafford, Thomas J. DeLiberto, Robert J. Dusek, Hon S. Ip, Jeffrey S. Hall, Yohannes Berhane, Samantha E. J. Gibbs, Catherine SoosDispersal of H9N2 influenza A viruses between East Asia and North America by wild birds
Samples were collected from wild birds in western Alaska to assess dispersal of influenza A viruses between East Asia and North America. Two isolates shared nearly identical nucleotide identity at eight genomic segments with H9N2 viruses isolated from China and South Korea providing evidence for intercontinental dispersal by migratory birds.AuthorsAndrew M. Ramey, Andrew B. Reeves, Sarah A. Sonsthagen, Joshua L. Teslaa, Sean W. Nashold, Tyrone F. Donnelly, Bruce Casler, Jeffrey S. HallRapidly expanding range of highly pathogenic avian influenza viruses
The movement of highly pathogenic avian influenza (H5N8) virus across Eurasia and into North America and the virus’ propensity to reassort with co-circulating low pathogenicity viruses raise concerns among poultry producers, wildlife biologists, aviculturists, and public health personnel worldwide. Surveillance, modeling, and experimental research will provide the knowledge required for intelligenAuthorsJeffrey S. Hall, Robert J. Dusek, Erica SpackmanThe dynamics of avian influenza in western Arctic snow geese: implications for annual and migratory infection patterns
Wild water birds are the natural reservoir for low-pathogenic avian influenza viruses (AIV). However, our ability to investigate the epizootiology of AIV in these migratory populations is challenging, and despite intensive worldwide surveillance, remains poorly understood. We conducted a cross-sectional, retrospective analysis in Pacific Flyway lesser snow geese Chen caerulescens to investigate AIAuthorsMichael D. Samuel, Jeffrey S. Hall, Justin D. Brown, Diana R. Goldberg, Hon S. Ip, Vasily V. BaranyukSpatial and temporal patterns of avian paramyxovirus-1 outbreaks in Double-Crested Cormorants (Phalacrocorax auritus) in the USA
Morbidity and mortality events caused by avian paramyxovirus-1 (APMV-1) in Double-crested Cormorant (DCCO; Phalacrocorax auritus) nesting colonies in the US and Canada have been sporadically documented in the literature. We describe APMV-1 associated outbreaks in DCCO in the US from the first reported occurrence in 1992 through 2012. The frequency of APMV-1 outbreaks has increased in the US over tAuthorsC. LeAnn White, Hon S. Ip, Carol U. Meteyer, Daniel P. Walsh, Jeffrey S. Hall, Michelle Carstensen, Paul C. WolfEvidence for seasonal patterns in the relative abundance of avian influenza virus subtypes in blue-winged teal (Anas discors)
Seasonal dynamics of influenza A viruses (IAVs) are driven by host density and population immunity. Through an analysis of subtypic data for IAVs isolated from Blue-winged Teal (Anas discors), we present evidence for seasonal patterns in the relative abundance of viral subtypes in spring and summer/autumn.AuthorsAndrew M. Ramey, Rebecca L. Poulson, Ana S. González-Reiche, Benjamin R. Wilcox, Patrick Walther, Paul Link, Deborah L. Carter, George M. Newsome, Maria L. Müller, Roy D. Berghaus, Daniel R. Perez, Jeffrey S. Hall, David E. StallknechtAvian influenza virus ecology in Iceland shorebirds: intercontinental reassortment and movement
Shorebirds are a primary reservoir of avian influenza viruses (AIV). We conducted surveillance studies in Iceland shorebird populations for 3 years, documenting high serological evidence of AIV exposure in shorebirds, primarily in Ruddy Turnstones (Arenaria interpres; seroprevalence = 75%). However, little evidence of virus infection was found in these shorebird populations and only two turnstoneAuthorsJeffrey S. Hall, Gunnar Thor Hallgrimsson, Kamol Suwannanarn, Srinand Sreevatsen, Hon S. Ip, Joshua L. TeSlaa, Sean W. Nashold, Robert J. DusekRespiratory transmission of an avian H3N8 influenza virus isolated from a harbour seal
The ongoing human H7N9 influenza infections highlight the threat of emerging avian influenza viruses. In 2011, an avian H3N8 influenza virus isolated from moribund New England harbour seals was shown to have naturally acquired mutations known to increase the transmissibility of highly pathogenic H5N1 influenza viruses. To elucidate the potential human health threat, here we evaluate a panel of aviAuthorsErik A. Karlsson, Hon S. Ip, Jeffrey S. Hall, Sun W. Yoon, Jordan Johnson, Melinda A. Beck, Richard J. Webby, Stacey Schultz-CherryAvian influenza virus antibodies in Pacific Coast Red Knots (Calidris canutus rufa)
Prevalence of avian influenza virus (AIV) antibodies in the western Atlantic subspecies of Red Knot (Calidris canutus rufa) is among the highest for any shorebird. To assess whether the frequency of detection of AIV antibodies is high for the species in general or restricted only to C. c. rufa, we sampled the northeastern Pacific Coast subspecies of Red Knot (Calidris canutus roselaari) breeding iAuthorsJames A. Johnson, Lucas H. DeCicco, Daniel R. Ruthrauff, Scott Krauss, Jeffrey S. HallNorth Atlantic migratory bird flyways provide routes for intercontinental movement of avian influenza viruses
Avian influenza virus (AIV) in wild birds has been of increasing interest over the last decade due to the emergence of AIVs that cause significant disease and mortality in both poultry and humans. While research clearly demonstrates that AIVs can move across the Pacific or Atlantic Ocean, there has been no data to support the mechanism of how this occurs. In spring and autumn of 2010 and autumn ofAuthorsRobert J. Dusek, Gunnar T. Hallgrimsson, Hon S. Ip, Jón E. Jónsson, Srinand Sreevatsan, Sean W. Nashold, Joshua L. TeSlaa, Shinichiro Enomoto, Rebecca A. Halpin, Xudong Lin, Nadia Federova, Timothy B. Stockwell, Vivien G. Dugan, David E. Wentworth, Jeffrey S. HallSampling strategies and biodiversity of influenza A subtypes in wild birds
Wild aquatic birds are recognized as the natural reservoir of avian influenza A viruses (AIV), but across high and low pathogenic AIV strains, scientists have yet to rigorously identify most competent hosts for the various subtypes. We examined 11,870 GenBank records to provide a baseline inventory and insight into patterns of global AIV subtype diversity and richness. Further, we conducted an extAuthorsSarah H. Olson, Jane Parmley, Catherine Soos, Martin Gilbert, Neus Latore-Margalef, Jeffrey S. Hall, Phillip M. Hansbro, Frank Leighton, Vincent Munster, Damien JolyEvolution of a reassortant North American gull influenza virus lineage: drift, shift and stability
Background: The role of gulls in the ecology of avian influenza (AI) is different than that of waterfowl. Different constellations of subtypes circulate within the two groups of birds and AI viruses isolated from North American gulls frequently possess reassortant genomes with genetic elements from both North America and Eurasian lineages. A 2008 isolate from a Newfoundland Great Black-backed GullAuthorsJeffrey S. Hall, Joshua L. TeSlaa, Sean W. Nashold, Rebecca A. Halpin, Timothy Stockwell, David E. Wentworth, Vivien Dugan, Hon S. IpNon-USGS Publications**
Kaci K. VanDalen, Jeffrey S. Hall, Larry Clark, Robert G. McLean, Cynthia Smeraski. (2013) West Nile virus infection in American robins: New insights on dose response. PLoS One. 10.1371/journal.pone.0068537.Paul Oesterle, Nicole Nemeth, Ginger Young, Nicole Mooers, Stacey Elmore, Richard Bowen, Paul Doherty, Jeffrey Hall, Robert McLean and Larry Clark. (2010) Cliff swallows, swallow bugs, and West Nile virus: an unlikely transmission mechanism. Vec. Borne Zoon. Dis. 10(5): 507-513.Oesterle P, Nemeth N, VanDalen K, Sullivan H, Bentler K, Young G, McLean R, Clark L, Smeraski C and Hall JS. (2009) Experimental infection of cliff swallows (Petrochelidon pyrrhonota) with varying doses of West Nile virus. Am. J. Trop. Med. Hyg. 81:1159-1164.
10.4269/ajtmh.2009.09-0136Jeffrey S. Hall, Kevin Bentler, Gabrielle Landolt, Richard B. Minnis, Tyler A. Campbell, Scott C. Barras, J. Jeffrey Root, Stacy Elmore, John Pilon, Kristy Pabilonia, Cindy Driscoll, Dennis Slate, Heather Sullivan and Robert G. McLean. (2008) Influenza infection in wild raccoons. Emerg. Inf. Dis. 14:1842-1848.
https://doi.org/10.3201/eid1412.071371Jeffrey S. Hall, Rich Minnis, Tyler A. Campbell, Scott Barras, Randy W. DeYoung, Kristy Pabilonia, Michael Avery, Heather Sullivan, Larry Clark and Robert G. McLean. (2008) Influenza exposure in United States feral swine populations. J. Wildlife Dis. 44:362-368.
https://doi.org/10.7589/0090-3558-44.2.362Britch, SC, Linthicum KJ, and Rift Valley Fever Working Group. (2007) Developing a research agenda and a comprehensive national prevention and response plan for Rift Valley fever in the United States. Emerg. Inf. Dis. [serial on the Internet] Available from http://www.cdc.gov/EID/content/13/8/e1.htm.McLean, R.G., J.S. Hall, A.B. Franklin, H. Sullivan, K. VanDalen, S. Shriner, M. Farnsworth, P. Oesterle, G. Young, J. Carlson, K. Cobble, T. Deliberto, S. Swafford, S. Elmore, T. Anderson, S. Hauser, K. Bentler, N. Mooers and K. Huyvaert . (2007) Avian influenza in wild birds: environmental sampling strategy for the rapid detection of avian influenza viruses. Proceedings of the 12th Wildlife Damage Management Conference, Corpus Christi, TX.Root, J., P. Oesterle, H. Sullivan, J.S. Hall, N. Marlenee, R.G. McLean, J.A. Montenieri and L. Clark. Fox squirrel (Sciuris niger) associations with West Nile virus. (2007) Am. J. Trop. Med. Hyg. 76:782-784.Bentler, K., J.S. Hall, J. Root, K. Klenk, B. Schmitt and L. Clark. (2007) West Nile Virus seroprevalence in North American mesopredators. Am. J. Trop. Med. Hyg. 76:173-179.Root, J.Jeffrey, P. Oesterle, N. Nemeth, K. Klenk, D.H. Gould, R.G. McLean, L. Clark and J.S. Hall. (2006) Experimental infection of fox squirrels (Sciurus niger) with West Nile virus. Am. J. Trop. Med. Hyg. 75:697-701.Clark, L., J.S. Hall, R. McLean, M. Dunbar, K. Klenk, Richard Bowen and C.A. Smeraski. (2006) Susceptibility of greater sage-grouse to experimental infection with West Nile virus. J. Wildlife Dis. 42:14-22.L. Clark and J. S. Hall. (2006) Avian influenza in wild birds: status as reservoirs and risks posed to humans and agriculture. Ornithological Monographs 60:3-29.Santaella-Tenorio, J., R. McLean, J.S. Gill, R. Bowen, J. S. Hall and L. Clark. (2005) West Nile virus serosurveillance in Iowa white-tailed deer (1999-2003). Am. J. Trop. Med. Hyg. 73: 1038-1042).Root, J.J., Hall J.S., McLean, R.G., Marlenee, N.L., Beaty, B.J., Gansowski, J. and Clark, L. (2005) Serologic evidence of exposure of wild mammals to Flaviviruses in the central and eastern United States. Am. J. Trop. Med. Hyg. 72: 622-630.Hall J.S., French R., Morris T.J. and Stenger D.C. (2001) Structure and temporal dynamics of populations within wheat streak mosaic virus isolates. J. Virol. 75: 10231-10243.Hall J.S., French R., Hein G.L., Morris T.J. and Stenger D.C. (2001) Three distinct mechanisms facilitate genetic isolation of sympatric wheat streak mosaic virus lineages. Virology 282: 230-236.Choi I.-R., Hall J.S., Henry M., Zhang L., Hein G.L., French R. and Stenger D.C. (2000) Contributions of genetic drift and negative selection on the evolution of three strains of wheat streak mosaic tritimovirus. Arch. Virol. 146: 619-628.Hall J.S., Adams B., Parsons T.J., French R., Lane L.C. and Jensen S.G. (1998) Molecular cloning, sequencing, and phylogenetic relationships of a new Potyvirus: sugarcane streak mosaic virus, and a reevaluation of the classification of the Potyviridae. Mol. Phylo. Evol. 10: 323-332.Stenger D.C., Hall J.S., Choi I.-R. and French R. (1998) Phylogenetic relationships within the family Potyviridae: Wheat streak mosaic virus and brome streak mosaic virus are not members of the genus Rymovirus. Phytopathology 88: 782-787.Marcon, A., Kaeppler, S.M. Jensen, S.G. and Hall, J.S. 1996. Characteristics of the High Plains Virus (HPV) and breeding for resistance in maize. Proceedings of the Latin American Workshop on Maize Diseases. Sete Lagoas, MG, Brazil May 20-24, 1996. Publisher EMBRAPA, E. de Oliveira Editor.S.G. Jensen and J.S. Hall. (1993) Characterization of a Krish-sorghum infecting potyvirus. Sorghum Newsletter 34:17F.L. Smith, S.W. Carper, J.S. Hall, B.J. Gilligan, E.L. Madsen and F.K. Storm. (1992) Cellular effects of piezoelectric versus electrohydraulic high energy shock waves. J. Urology 147:491-495.S.W. Carper, J.S. Hall and F.K. Storm. (1992) Thermal protection by prostaglandin E1, a preclinical study. Reg. Cancer Treatment 4:156-158.**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.