The Effect of Resource Limitation on the Temperature Dependence of Mosquito Population Fitness

Overview

Journal Proc Biol Sci

Specialty Biology

Date 2021 Apr 28

PMID 33906411

Citations 14

Authors

Paul J Huxley

Kris A Murray

Samraat Pawar

Lauren J Cator

Affiliations

Soon will be listed here.

Abstract

Laboratory-derived temperature dependencies of life-history traits are increasingly being used to make mechanistic predictions for how climatic warming will affect vector-borne disease dynamics, partially by affecting abundance dynamics of the vector population. These temperature-trait relationships are typically estimated from juvenile populations reared on optimal resource supply, even though natural populations of vectors are expected to experience variation in resource supply, including intermittent resource limitation. Using laboratory experiments on the mosquito , a principal arbovirus vector, combined with stage-structured population modelling, we show that low-resource supply in the juvenile life stages significantly depresses the vector's maximal population growth rate across the entire temperature range (22-32°C) and causes it to peak at a lower temperature than at high-resource supply. This effect is primarily driven by an increase in juvenile mortality and development time, combined with a decrease in adult size with temperature at low-resource supply. Our study suggests that most projections of temperature-dependent vector abundance and disease transmission are likely to be biased because they are based on traits measured under optimal resource supply. Our results provide compelling evidence for future studies to consider resource supply when predicting the effects of climate and habitat change on vector-borne disease transmission, disease vectors and other arthropods.

Citing Articles

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Divergence of discrete- versus continuous-time calculations of the temperature dependence of maximum population growth rate.

Huxley P, Johnson L, Cator L, Pawar S Res Sq. 2024; .

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