West Nile Virus: Reflections on 20 Years

Experts were asked about the biggest lessons learned about this mosquito-borne disease.

© Ary Farajollahi, Bugwood.org

In 1999, West Nile virus was detected in the United States for the first time, and within five years it had spread from New York across the contiguous United States and into Canada, Mexico, and Central and South America. Transmitted to humans by mosquitoes that feed on infected birds, West Nile virus has served as a wake-up call to the challenge of preventing the spread of mosquito-borne diseases in the era of globalized trade and travel.

Twenty years later, West Nile virus remains firmly established in the Americas, and other mosquito-borne diseases such as chikungunya, Zika, dengue, and strains of St. Louis and Eastern equine encephalitis have made incursions or reappearances as well. As the outbreak has continued, researchers have scrutinized West Nile virus and the mosquitoes that carry it. Though eradication of West Nile virus in the Americas remains yet beyond our capability, the body of knowledge built since 1999 is now empowering efforts to minimize its impact and better prevent and respond to other mosquito-borne diseases.

To take stock of these lessons learned, the Journal of Medical Entomology published a special collection of articles from an array of experts in public health, veterinary medicine, entomology, ecology and mosquito management, synthesizing their ideas gleaned from research conducted and progress made over the past 20 years.

On this page and on page 84, several experts whose perspectives appear in the collection offer their take on a central question: “What’s the biggest lesson we’ve learned from 20 years of research on West Nile virus?”

Lyle R. Petersen, M.D., Division of Vector-Borne Diseases, National Center for Emerging and Zoonotic Infectious Diseases, U.S. Centers for Disease Control and Prevention: “To expect the unexpected. Before the introduction of West Nile virus to the U.S. in 1999, we never expected that an exotic arbovirus would be imported to a major metropolitan area, become endemic in all 48 contiguous states, cause outbreaks of unprecedented size nearly every year, and threaten the U.S. blood supply. The societal costs have been enormous.”

Angela M. Bosco-Lauth, Ph.D., Department of Biomedical Sciences, Colorado State University: “West Nile virus has demonstrated the need for a truly ‘one health’ response to pathogen emergence. It is so vitally important that science and research is open and collaborative in nature and that human health, veterinary health, and environmental health do not exist as silos but rather work together toward a common goal.”

*WNV human disease cases or presumptive viremic blood donors. Presumptive viremic blood donors have a positive screening test which has not necessarily been confirmed. †WNV veterinary disease cases, or infections in mosquitoes, birds or sentinel animals.

Ilia Rochlin, Ph.D., Center for Vector Biology, Rutgers University: “West Nile virus is very adaptable. Its transmission cycle can be maintained by different Culex mosquito species and avian hosts. The virus can thrive under an amazing diversity of environmental conditions, from dry prairies to humid broadleaf forests and from the rural agricultural Southwest to the upscale suburban Northeast. Few other arboviruses display similar ecological plasticity.”

A. Marm Kilpatrick, Ph.D., Department of Ecology and Evolutionary Biology, University of California, Santa Cruz: “Disease invasions can have lasting effects on both human and wildlife health. The initial invasion often inspires fear and reactions that, in hindsight, are exaggerated. However, the lasting impacts are often unanticipated, and the combination of climate variability and the evolution of the pathogen, hosts and vectors can lead to re-emergence long after the initial invasion.”

William K. Reisen, Ph.D., Department of Pathology, Microbiology and Immunology, School of Veterinary Medicine, University of California, Davis: “Effective overwintering is critical for virus persistence and necessary for effective amplification to outbreak levels the following spring. However, despite detailed research on the invasive West Nile virus as well as related encephalitis strains, it still is not clear how these viruses spend the winter at temperate latitudes when temperatures are too cold for virus replication and vector mosquito blood-feeding activity. Multiple mechanisms have been explored, but definitive answers remain evasive.”

Roger S. Nasci, Ph.D., Vector-Borne Disease Consulting: “Though there is good evidence that intensive mosquito-control efforts can stop virus transmission and prevent human cases once a West Nile virus outbreak has started, preventing outbreaks from occurring in the first place remains a major challenge. However, examples of early-season mosquito control effectively reducing West Nile virus amplification and expansion indicate that outbreak prevention is feasible if sufficient information about the local West Nile virus transmission ecology and adequate mosquito-control resources are available.”

Editor’s Note: This article originally appeared in Entomology Today, a project of the Entomological Society of America with the goal of reporting interesting discoveries in the world of insect science and news from various entomological societies. To learn more, visit www.entomologytoday.org.

Read More in the Journal of Medical Entomology: “Special Collection: Twenty Years of West Nile Virus in the United States” at https://buff.ly/2mZT1wj.

March 2020
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