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Thermal biology of mosquito‐borne disease

Mosquito‐borne diseases cause a major burden of disease worldwide. The vital rates of these ectothermic vectors and parasites respond strongly and nonlinearly to temperature and therefore to climate change. Here, we review how trait‐based approaches can synthesise and mechanistically predict the tem...

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Autores principales: Mordecai, Erin A., Caldwell, Jamie M., Grossman, Marissa K., Lippi, Catherine A., Johnson, Leah R., Neira, Marco, Rohr, Jason R., Ryan, Sadie J., Savage, Van, Shocket, Marta S., Sippy, Rachel, Stewart Ibarra, Anna M., Thomas, Matthew B., Villena, Oswaldo
Formato: Online Artículo Texto
Lenguaje:English
Publicado: John Wiley and Sons Inc. 2019
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6744319/
https://www.ncbi.nlm.nih.gov/pubmed/31286630
http://dx.doi.org/10.1111/ele.13335
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author Mordecai, Erin A.
Caldwell, Jamie M.
Grossman, Marissa K.
Lippi, Catherine A.
Johnson, Leah R.
Neira, Marco
Rohr, Jason R.
Ryan, Sadie J.
Savage, Van
Shocket, Marta S.
Sippy, Rachel
Stewart Ibarra, Anna M.
Thomas, Matthew B.
Villena, Oswaldo
author_facet Mordecai, Erin A.
Caldwell, Jamie M.
Grossman, Marissa K.
Lippi, Catherine A.
Johnson, Leah R.
Neira, Marco
Rohr, Jason R.
Ryan, Sadie J.
Savage, Van
Shocket, Marta S.
Sippy, Rachel
Stewart Ibarra, Anna M.
Thomas, Matthew B.
Villena, Oswaldo
author_sort Mordecai, Erin A.
collection PubMed
description Mosquito‐borne diseases cause a major burden of disease worldwide. The vital rates of these ectothermic vectors and parasites respond strongly and nonlinearly to temperature and therefore to climate change. Here, we review how trait‐based approaches can synthesise and mechanistically predict the temperature dependence of transmission across vectors, pathogens, and environments. We present 11 pathogens transmitted by 15 different mosquito species – including globally important diseases like malaria, dengue, and Zika – synthesised from previously published studies. Transmission varied strongly and unimodally with temperature, peaking at 23–29ºC and declining to zero below 9–23ºC and above 32–38ºC. Different traits restricted transmission at low versus high temperatures, and temperature effects on transmission varied by both mosquito and parasite species. Temperate pathogens exhibit broader thermal ranges and cooler thermal minima and optima than tropical pathogens. Among tropical pathogens, malaria and Ross River virus had lower thermal optima (25–26ºC) while dengue and Zika viruses had the highest (29ºC) thermal optima. We expect warming to increase transmission below thermal optima but decrease transmission above optima. Key directions for future work include linking mechanistic models to field transmission, combining temperature effects with control measures, incorporating trait variation and temperature variation, and investigating climate adaptation and migration.
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spelling pubmed-67443192019-11-22 Thermal biology of mosquito‐borne disease Mordecai, Erin A. Caldwell, Jamie M. Grossman, Marissa K. Lippi, Catherine A. Johnson, Leah R. Neira, Marco Rohr, Jason R. Ryan, Sadie J. Savage, Van Shocket, Marta S. Sippy, Rachel Stewart Ibarra, Anna M. Thomas, Matthew B. Villena, Oswaldo Ecol Lett Reviews and Syntheses Mosquito‐borne diseases cause a major burden of disease worldwide. The vital rates of these ectothermic vectors and parasites respond strongly and nonlinearly to temperature and therefore to climate change. Here, we review how trait‐based approaches can synthesise and mechanistically predict the temperature dependence of transmission across vectors, pathogens, and environments. We present 11 pathogens transmitted by 15 different mosquito species – including globally important diseases like malaria, dengue, and Zika – synthesised from previously published studies. Transmission varied strongly and unimodally with temperature, peaking at 23–29ºC and declining to zero below 9–23ºC and above 32–38ºC. Different traits restricted transmission at low versus high temperatures, and temperature effects on transmission varied by both mosquito and parasite species. Temperate pathogens exhibit broader thermal ranges and cooler thermal minima and optima than tropical pathogens. Among tropical pathogens, malaria and Ross River virus had lower thermal optima (25–26ºC) while dengue and Zika viruses had the highest (29ºC) thermal optima. We expect warming to increase transmission below thermal optima but decrease transmission above optima. Key directions for future work include linking mechanistic models to field transmission, combining temperature effects with control measures, incorporating trait variation and temperature variation, and investigating climate adaptation and migration. John Wiley and Sons Inc. 2019-07-08 2019-10 /pmc/articles/PMC6744319/ /pubmed/31286630 http://dx.doi.org/10.1111/ele.13335 Text en © 2019 The Authors Ecology Letters published by CNRS and John Wiley & Sons Ltd This is an open access article under the terms of the http://creativecommons.org/licenses/by/4.0/ License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.
spellingShingle Reviews and Syntheses
Mordecai, Erin A.
Caldwell, Jamie M.
Grossman, Marissa K.
Lippi, Catherine A.
Johnson, Leah R.
Neira, Marco
Rohr, Jason R.
Ryan, Sadie J.
Savage, Van
Shocket, Marta S.
Sippy, Rachel
Stewart Ibarra, Anna M.
Thomas, Matthew B.
Villena, Oswaldo
Thermal biology of mosquito‐borne disease
title Thermal biology of mosquito‐borne disease
title_full Thermal biology of mosquito‐borne disease
title_fullStr Thermal biology of mosquito‐borne disease
title_full_unstemmed Thermal biology of mosquito‐borne disease
title_short Thermal biology of mosquito‐borne disease
title_sort thermal biology of mosquito‐borne disease
topic Reviews and Syntheses
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6744319/
https://www.ncbi.nlm.nih.gov/pubmed/31286630
http://dx.doi.org/10.1111/ele.13335
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