Literature DB >> 18941794

Ecological correlates of risk and incidence of West Nile virus in the United States.

Brian F Allan1, R Brian Langerhans, Wade A Ryberg, William J Landesman, Nicholas W Griffin, Rachael S Katz, Brad J Oberle, Michele R Schutzenhofer, Kristina N Smyth, Annabelle de St Maurice, Larry Clark, Kevin R Crooks, Daniel E Hernandez, Robert G McLean, Richard S Ostfeld, Jonathan M Chase.   

Abstract

West Nile virus, which was recently introduced to North America, is a mosquito-borne pathogen that infects a wide range of vertebrate hosts, including humans. Several species of birds appear to be the primary reservoir hosts, whereas other bird species, as well as other vertebrate species, can be infected but are less competent reservoirs. One hypothesis regarding the transmission dynamics of West Nile virus suggests that high bird diversity reduces West Nile virus transmission because mosquito blood-meals are distributed across a wide range of bird species, many of which have low reservoir competence. One mechanism by which this hypothesis can operate is that high-diversity bird communities might have lower community-competence, defined as the sum of the product of each species' abundance and its reservoir competence index value. Additional hypotheses posit that West Nile virus transmission will be reduced when either: (1) abundance of mosquito vectors is low; or (2) human population density is low. We assessed these hypotheses at two spatial scales: a regional scale near Saint Louis, MO, and a national scale (continental USA). We found that prevalence of West Nile virus infection in mosquito vectors and in humans increased with decreasing bird diversity and with increasing reservoir competence of the bird community. Our results suggest that conservation of avian diversity might help ameliorate the current West Nile virus epidemic in the USA.

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Year:  2008        PMID: 18941794     DOI: 10.1007/s00442-008-1169-9

Source DB:  PubMed          Journal:  Oecologia        ISSN: 0029-8549            Impact factor:   3.225


  31 in total

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3.  Culex restuans (Diptera: Culicidae) relative abundance and vector competence for West Nile Virus.

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Review 4.  West Nile virus transmission and ecology in birds.

Authors:  R G McLean; S R Ubico; D E Docherty; W R Hansen; L Sileo; T S McNamara
Journal:  Ann N Y Acad Sci       Date:  2001-12       Impact factor: 5.691

5.  Host heterogeneity dominates West Nile virus transmission.

Authors:  A Marm Kilpatrick; Peter Daszak; Matthew J Jones; Peter P Marra; Laura D Kramer
Journal:  Proc Biol Sci       Date:  2006-09-22       Impact factor: 5.349

6.  Avian hosts for West Nile virus in St. Tammany Parish, Louisiana, 2002.

Authors:  Nicholas Komar; Nicholas A Panella; Stanley A Langevin; Aaron C Brault; Manuel Amador; Eric Edwards; Jennifer C Owen
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7.  Land cover variation and West Nile virus prevalence: patterns, processes, and implications for disease control.

Authors:  Vanessa O Ezenwa; Lesley E Milheim; Michelle F Coffey; Marvin S Godsey; Raymond J King; Stephen C Guptill
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8.  West Nile virus risk assessment and the bridge vector paradigm.

Authors:  A Marm Kilpatrick; Laura D Kramer; Scott R Campbell; E Oscar Alleyne; Andrew P Dobson; Peter Daszak
Journal:  Emerg Infect Dis       Date:  2005-03       Impact factor: 6.883

9.  West Nile virus epidemics in North America are driven by shifts in mosquito feeding behavior.

Authors:  A Marm Kilpatrick; Laura D Kramer; Matthew J Jones; Peter P Marra; Peter Daszak
Journal:  PLoS Biol       Date:  2006-02-28       Impact factor: 8.029

10.  Experimental infection of North American birds with the New York 1999 strain of West Nile virus.

Authors:  Nicholas Komar; Stanley Langevin; Steven Hinten; Nicole Nemeth; Eric Edwards; Danielle Hettler; Brent Davis; Richard Bowen; Michel Bunning
Journal:  Emerg Infect Dis       Date:  2003-03       Impact factor: 6.883
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  64 in total

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Authors:  Catherine L Searle; Lindsay M Biga; Joseph W Spatafora; Andrew R Blaustein
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2.  Hosts as ecological traps for the vector of Lyme disease.

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Review 3.  Deforestation and avian infectious diseases.

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Journal:  J Exp Biol       Date:  2010-03-15       Impact factor: 3.312

Review 4.  Does alteration in biodiversity really affect disease outcome? - A debate is brewing.

Authors:  U R Zargar; M Z Chishti; Fayaz Ahmad; M I Rather
Journal:  Saudi J Biol Sci       Date:  2014-05-27       Impact factor: 4.219

Review 5.  Conservation of biodiversity as a strategy for improving human health and well-being.

Authors:  A Marm Kilpatrick; Daniel J Salkeld; Georgia Titcomb; Micah B Hahn
Journal:  Philos Trans R Soc Lond B Biol Sci       Date:  2017-06-05       Impact factor: 6.237

Review 6.  Human health impacts of ecosystem alteration.

Authors:  Samuel S Myers; Lynne Gaffikin; Christopher D Golden; Richard S Ostfeld; Kent H Redford; Taylor H Ricketts; Will R Turner; Steven A Osofsky
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7.  The roles of mosquito and bird communities on the prevalence of West Nile virus in urban wetland and residential habitats.

Authors:  Brian J Johnson; Kristin Munafo; Laura Shappell; Nellie Tsipoura; Mark Robson; Joan Ehrenfeld; Michael V K Sukhdeo
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8.  Local impact of temperature and precipitation on West Nile virus infection in Culex species mosquitoes in northeast Illinois, USA.

Authors:  Marilyn O Ruiz; Luis F Chaves; Gabriel L Hamer; Ting Sun; William M Brown; Edward D Walker; Linn Haramis; Tony L Goldberg; Uriel D Kitron
Journal:  Parasit Vectors       Date:  2010-03-19       Impact factor: 3.876

9.  Dry weather induces outbreaks of human West Nile virus infections.

Authors:  Guiming Wang; Richard B Minnis; Jerrold L Belant; Charles L Wax
Journal:  BMC Infect Dis       Date:  2010-02-24       Impact factor: 3.090

10.  Experimental evidence for reduced rodent diversity causing increased hantavirus prevalence.

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