Carried over: Heat stress in the egg stage reduces subsequent performance in a butterfly.

Michael Klockmann,Friederike Kleinschmidt,Klaus Fischer,Casper J Breuker

doi:10.1371/journal.pone.0180968

Michael Klockmann, Friederike Kleinschmidt + Show 2 more

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https://doi.org/10.1371/journal.pone.0180968

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Journal: PloS one	Publication Date: Jul 14, 2017
Citations: 43	License type: CC BY 4.0

Affiliation: University of Greifswald

Abstract

Increasing heat stress caused by anthropogenic climate change may pose a substantial challenge to biodiversity due to associated detrimental effects on survival and reproduction. Therefore, heat tolerance has recently received substantial attention, but its variation throughout ontogeny and effects carried over from one developmental stage to another remained largely neglected. To explore to what extent stress experienced early in life affects later life stages, we here investigate effects of heat stress experienced in the egg stage throughout ontogeny in the tropical butterfly Bicyclus anynana. We found that detrimental effects of heat stress in the egg stage were detectable in hatchlings, larvae and even resulting adults, as evidenced by decreased survival, growth, and body mass. This study shows that even in holometabalous insects with discrete life stages effects of stress experienced early in life are carried over to later stages, substantially reducing subsequent fitness. We argue that such effects need to be considered when trying to forecast species responses to climate change.

Highlights

Temperature is one of the most important ecological factors for ectothermic organisms, and the ability to cope with different temperatures is of key importance for species survival and distributions [1,2]
Due to ongoing anthropogenic climate change, stressfully high temperatures will be more frequently encountered in the future, which may strongly affect biodiversity [5,6]
Similar considerations may apply to the increased mortality found in hatchlings exposed to heat stress (37 ̊C)

Summary

Introduction

Temperature is one of the most important ecological factors for ectothermic organisms, and the ability to cope with different temperatures is of key importance for species survival and distributions [1,2]. Exposure to high temperatures typically decreases individual fitness and does cause death [3,4]. Due to ongoing anthropogenic climate change, stressfully high temperatures will be more frequently encountered in the future, which may strongly affect biodiversity [5,6]. Upper critical thermal limits have recently received substantial attention [9,10,11]. Tropical ectotherms may be sensitive, as they live already close to their upper thermal limits [8,12,13,14]

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