Literature DB >> 28179512

Drought and immunity determine the intensity of West Nile virus epidemics and climate change impacts.

Sara H Paull1,2, Daniel E Horton3,4, Moetasim Ashfaq5, Deeksha Rastogi5, Laura D Kramer6,7, Noah S Diffenbaugh4, A Marm Kilpatrick8.   

Abstract

The effect of global climate change on infectious disease remains hotly debated because multiple extrinsic and intrinsic drivers interact to influence transmission dynamics in nonlinear ways. The dominant drivers of widespread pathogens, like West Nile virus, can be challenging to identify due to regional variability in vector and host ecology, with past studies producing disparate findings. Here, we used analyses at national and state scales to examine a suite of climatic and intrinsic drivers of continental-scale West Nile virus epidemics, including an empirically derived mechanistic relationship between temperature and transmission potential that accounts for spatial variability in vectors. We found that drought was the primary climatic driver of increased West Nile virus epidemics, rather than within-season or winter temperatures, or precipitation independently. Local-scale data from one region suggested drought increased epidemics via changes in mosquito infection prevalence rather than mosquito abundance. In addition, human acquired immunity following regional epidemics limited subsequent transmission in many states. We show that over the next 30 years, increased drought severity from climate change could triple West Nile virus cases, but only in regions with low human immunity. These results illustrate how changes in drought severity can alter the transmission dynamics of vector-borne diseases.
© 2017 The Author(s).

Entities:  

Keywords:  Culex; disease ecology; global warming; nonlinear temperature–disease relationship; vector-borne disease

Mesh:

Year:  2017        PMID: 28179512      PMCID: PMC5310598          DOI: 10.1098/rspb.2016.2078

Source DB:  PubMed          Journal:  Proc Biol Sci        ISSN: 0962-8452            Impact factor:   5.349


  53 in total

1.  Meteorological and hydrological influences on the spatial and temporal prevalence of West Nile virus in Culex mosquitoes, Suffolk County, New York.

Authors:  Jeffrey Shaman; Kerri Harding; Scott R Campbell
Journal:  J Med Entomol       Date:  2011-07       Impact factor: 2.278

2.  Weather factors influencing the population dynamics of Culex pipiens (Diptera: Culicidae) in the Po Plain Valley, Italy (1997-2011).

Authors:  Marco Carrieri; Piero Fariselli; Bettina Maccagnani; Paola Angelini; Mattia Calzolari; Romeo Bellini
Journal:  Environ Entomol       Date:  2014-04       Impact factor: 2.377

3.  Optimal temperature for malaria transmission is dramatically lower than previously predicted.

Authors:  Erin A Mordecai; Krijn P Paaijmans; Leah R Johnson; Christian Balzer; Tal Ben-Horin; Emily de Moor; Amy McNally; Samraat Pawar; Sadie J Ryan; Thomas C Smith; Kevin D Lafferty
Journal:  Ecol Lett       Date:  2012-10-11       Impact factor: 9.492

4.  Altitudinal changes in malaria incidence in highlands of Ethiopia and Colombia.

Authors:  A S Siraj; M Santos-Vega; M J Bouma; D Yadeta; D Ruiz Carrascal; M Pascual
Journal:  Science       Date:  2014-03-07       Impact factor: 47.728

5.  Drought-induced amplification and epidemic transmission of West Nile virus in southern Florida.

Authors:  Jeffrey Shaman; Jonathan F Day; Marc Stieglitz
Journal:  J Med Entomol       Date:  2005-03       Impact factor: 2.278

6.  Flushing effect of rain on container-inhabiting mosquitoes Aedes aegypti and Culex pipiens (Diptera: Culicidae).

Authors:  C J M Koenraadt; L C Harrington
Journal:  J Med Entomol       Date:  2008-01       Impact factor: 2.278

Review 7.  West Nile virus: review of the literature.

Authors:  Lyle R Petersen; Aaron C Brault; Roger S Nasci
Journal:  JAMA       Date:  2013-07-17       Impact factor: 56.272

8.  The role of hydrogeography and climate in the landscape epidemiology of West Nile virus in New York State from 2000 to 2010.

Authors:  Michael G Walsh
Journal:  PLoS One       Date:  2012-02-06       Impact factor: 3.240

9.  Evidence for co-evolution of West Nile Virus and house sparrows in North America.

Authors:  Nisha K Duggal; Angela Bosco-Lauth; Richard A Bowen; Sarah S Wheeler; William K Reisen; Todd A Felix; Brian R Mann; Hannah Romo; Daniele M Swetnam; Alan D T Barrett; Aaron C Brault
Journal:  PLoS Negl Trop Dis       Date:  2014-10-30

10.  Towards an early warning system for forecasting human west nile virus incidence.

Authors:  Carrie A Manore; Justin K Davis; Rebecca C Christofferson; Dawn M Wesson; James M Hyman; Christopher N Mores
Journal:  PLoS Curr       Date:  2014-05-30
View more
  40 in total

1.  A novel approach for predicting risk of vector-borne disease establishment in marginal temperate environments under climate change: West Nile virus in the UK.

Authors:  David A Ewing; Bethan V Purse; Christina A Cobbold; Steven M White
Journal:  J R Soc Interface       Date:  2021-05-26       Impact factor: 4.118

2.  Drought and immunity determine the intensity of West Nile virus epidemics and climate change impacts.

Authors:  Sara H Paull; Daniel E Horton; Moetasim Ashfaq; Deeksha Rastogi; Laura D Kramer; Noah S Diffenbaugh; A Marm Kilpatrick
Journal:  Proc Biol Sci       Date:  2017-02-08       Impact factor: 5.349

3.  Bovine tuberculosis disturbs parasite functional trait composition in African buffalo.

Authors:  Brianna R Beechler; Kate S Boersma; Peter E Buss; Courtney A C Coon; Erin E Gorsich; Brian S Henrichs; Adam M Siepielski; Johannie M Spaan; Robert S Spaan; Vanessa O Ezenwa; Anna E Jolles
Journal:  Proc Natl Acad Sci U S A       Date:  2019-07-01       Impact factor: 11.205

4.  Transmission of West Nile and five other temperate mosquito-borne viruses peaks at temperatures between 23°C and 26°C.

Authors:  Marta S Shocket; Anna B Verwillow; Mailo G Numazu; Hani Slamani; Jeremy M Cohen; Fadoua El Moustaid; Jason Rohr; Leah R Johnson; Erin A Mordecai
Journal:  Elife       Date:  2020-09-15       Impact factor: 8.140

5.  Impact of West Nile Virus on Bird Populations: Limited Lasting Effects, Evidence for Recovery, and Gaps in Our Understanding of Impacts on Ecosystems.

Authors:  A Marm Kilpatrick; Sarah S Wheeler
Journal:  J Med Entomol       Date:  2019-10-28       Impact factor: 2.278

6.  On the Fly: Interactions Between Birds, Mosquitoes, and Environment That Have Molded West Nile Virus Genomic Structure Over Two Decades.

Authors:  Nisha K Duggal; Kate E Langwig; Gregory D Ebel; Aaron C Brault
Journal:  J Med Entomol       Date:  2019-10-28       Impact factor: 2.278

7.  Introduction, Spread, and Establishment of West Nile Virus in the Americas.

Authors:  Laura D Kramer; Alexander T Ciota; A Marm Kilpatrick
Journal:  J Med Entomol       Date:  2019-10-28       Impact factor: 2.278

Review 8.  Influence of herd immunity in the cyclical nature of arboviruses.

Authors:  Guilherme S Ribeiro; Gabriel L Hamer; Mawlouth Diallo; Uriel Kitron; Albert I Ko; Scott C Weaver
Journal:  Curr Opin Virol       Date:  2020-03-17       Impact factor: 7.090

9.  Increased Human Incidence of West Nile Virus Disease near Rice Fields in California but Not in Southern United States.

Authors:  Tony J Kovach; A Marm Kilpatrick
Journal:  Am J Trop Med Hyg       Date:  2018-04-19       Impact factor: 2.345

10.  Light pollution affects West Nile virus exposure risk across Florida.

Authors:  Meredith E Kernbach; Lynn B Martin; Thomas R Unnasch; Richard J Hall; Rays H Y Jiang; Clinton D Francis
Journal:  Proc Biol Sci       Date:  2021-03-24       Impact factor: 5.349
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.