Systematic approaches to assessing high-temperature limits to fertility in animals

Amanda Bretman; Claudia Fricke; Julian Baur; David Berger; Merel C. Breedveld; Diego Dierick; Berta Canal Domenech; Szymon M. Drobniak; Jacintha Ellers; Sinead English; Clelia Gasparini; Graziella Iossa; Malgorzata Lagisz; Shinichi Nakagawa; Daniel W.A. Noble; Patrice Pottier; Steven A. Ramm; Melissah Rowe; Eva Schultner; Mads Schou; Pedro Simões; Paula Stockley; Ramakrishnan Vasudeva; Hester Weaving; Tom A.R. Price; Rhonda R. Snook

doi:10.1093/jeb/voae021

Systematic approaches to assessing high-temperature limits to fertility in animals

Amanda Bretman^*, Claudia Fricke, Julian Baur, David Berger, Merel C. Breedveld, Diego Dierick, Berta Canal Domenech, Szymon M. Drobniak, Jacintha Ellers, Sinead English, Clelia Gasparini, Graziella Iossa, Malgorzata Lagisz, Shinichi Nakagawa, Daniel W.A. Noble, Patrice Pottier, Steven A. Ramm, Melissah Rowe, Eva Schultner, Mads SchouPedro Simões, Paula Stockley, Ramakrishnan Vasudeva, Hester Weaving, Tom A.R. Price, Rhonda R. Snook

^*Corresponding author for this work

Ecology & Evolution

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

Critical thermal limits (CTLs) gauge the physiological impact of temperature on survival or critical biological function, aiding predictions of species range shifts and climatic resilience. Two recent Drosophila species studies, using similar approaches to determine temperatures that induce sterility (thermal fertility limits [TFLs]), reveal that TFLs are often lower than CTLs and that TFLs better predict both current species distributions and extinction probability. Moreover, many studies show fertility is more sensitive at less extreme temperatures than survival (thermal sensitivity of fertility [TSF]). These results present a more pessimistic outlook on the consequences of climate change. However, unlike CTLs, TFL data are limited to Drosophila, and variability in TSF methods poses challenges in predicting species responses to increasing temperature. To address these data and methodological gaps, we propose 3 standardized approaches for assessing thermal impacts on fertility. We focus on adult obligate sexual terrestrial invertebrates but also provide modifications for other animal groups and life-history stages. We first outline a "gold-standard" protocol for determining TFLs, focussing on the effects of short-term heat shocks and simulating more frequent extreme heat events predicted by climate models. As this approach may be difficult to apply to some organisms, we then provide a standardized TSF protocol. Finally, we provide a framework to quantify fertility loss in response to extreme heat events in nature, given the limitations in laboratory approaches. Applying these standardized approaches across many taxa, similar to CTLs, will allow robust tests of the impact of fertility loss on species responses to increasing temperatures.

Original language	English
Pages (from-to)	471-485
Number of pages	15
Journal	Journal of evolutionary biology
Volume	37
Issue number	4
Early online date	13 Feb 2024
DOIs	https://doi.org/10.1093/jeb/voae021
Publication status	Published - Apr 2024

Bibliographical note

Publisher Copyright:
© The Author(s) 2024. Published by Oxford University Press on behalf of the European Society of Evolutionary Biology.

Funding

This work was funded by the European Society for Evolutionary Biology which funds a Special Topic Network on Evolutionary Ecology of Thermal Fertility Limits (to C.F., A.B., R.R.S. and T.A.R.P.), by the Natural Environment Research Council (NE/P002692/1 to T.A.R.P., A.B. and R.R.S.), the Biotechnology and Biosciences Research Council (BB/W016753/1 to A.B., T.A.R.P. and R.R.S.), Australian Research Council (DE180100202), National Science Centre of Poland (to S.M.D.) and a Heisenberg fellowship from the Deutsche Forschungsgemeinschaft to C.F. (FR 2973/11-1).

Funders	Funder number
Narodowe Centrum Nauki
European Society for Evolutionary Biology
Natural Environment Research Council	NE/P002692/1
Natural Environment Research Council
Biotechnology and Biosciences Research Council	BB/W016753/1
Australian Research Council	DE180100202
Australian Research Council
Deutsche Forschungsgemeinschaft	FR 2973/11-1
Deutsche Forschungsgemeinschaft

Keywords

critical thermal limit
heat
reproduction
thermal fertility limit
thermal sensitivity of fertility

Access to Document

10.1093/jeb/voae021

Persistent URL (handle)

Persistent link

Cite this

Bretman, A., Fricke, C., Baur, J., Berger, D., Breedveld, M. C., Dierick, D., Canal Domenech, B., Drobniak, S. M., Ellers, J., English, S., Gasparini, C., Iossa, G., Lagisz, M., Nakagawa, S., Noble, D. W. A., Pottier, P., Ramm, S. A., Rowe, M., Schultner, E., ... Snook, R. R. (2024). Systematic approaches to assessing high-temperature limits to fertility in animals. Journal of evolutionary biology, 37(4), 471-485. https://doi.org/10.1093/jeb/voae021

@article{587b99e0c2e44c7298b503e222e61388,

title = "Systematic approaches to assessing high-temperature limits to fertility in animals",

abstract = "Critical thermal limits (CTLs) gauge the physiological impact of temperature on survival or critical biological function, aiding predictions of species range shifts and climatic resilience. Two recent Drosophila species studies, using similar approaches to determine temperatures that induce sterility (thermal fertility limits [TFLs]), reveal that TFLs are often lower than CTLs and that TFLs better predict both current species distributions and extinction probability. Moreover, many studies show fertility is more sensitive at less extreme temperatures than survival (thermal sensitivity of fertility [TSF]). These results present a more pessimistic outlook on the consequences of climate change. However, unlike CTLs, TFL data are limited to Drosophila, and variability in TSF methods poses challenges in predicting species responses to increasing temperature. To address these data and methodological gaps, we propose 3 standardized approaches for assessing thermal impacts on fertility. We focus on adult obligate sexual terrestrial invertebrates but also provide modifications for other animal groups and life-history stages. We first outline a {"}gold-standard{"} protocol for determining TFLs, focussing on the effects of short-term heat shocks and simulating more frequent extreme heat events predicted by climate models. As this approach may be difficult to apply to some organisms, we then provide a standardized TSF protocol. Finally, we provide a framework to quantify fertility loss in response to extreme heat events in nature, given the limitations in laboratory approaches. Applying these standardized approaches across many taxa, similar to CTLs, will allow robust tests of the impact of fertility loss on species responses to increasing temperatures.",

keywords = "critical thermal limit, heat, reproduction, thermal fertility limit, thermal sensitivity of fertility",

author = "Amanda Bretman and Claudia Fricke and Julian Baur and David Berger and Breedveld, {Merel C.} and Diego Dierick and {Canal Domenech}, Berta and Drobniak, {Szymon M.} and Jacintha Ellers and Sinead English and Clelia Gasparini and Graziella Iossa and Malgorzata Lagisz and Shinichi Nakagawa and Noble, {Daniel W.A.} and Patrice Pottier and Ramm, {Steven A.} and Melissah Rowe and Eva Schultner and Mads Schou and Pedro Sim{\~o}es and Paula Stockley and Ramakrishnan Vasudeva and Hester Weaving and Price, {Tom A.R.} and Snook, {Rhonda R.}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024. Published by Oxford University Press on behalf of the European Society of Evolutionary Biology.",

year = "2024",

month = apr,

doi = "10.1093/jeb/voae021",

language = "English",

volume = "37",

pages = "471--485",

journal = "Journal of evolutionary biology",

issn = "1420-9101",

publisher = "Oxford University Press",

number = "4",

}

Bretman, A, Fricke, C, Baur, J, Berger, D, Breedveld, MC, Dierick, D, Canal Domenech, B, Drobniak, SM, Ellers, J, English, S, Gasparini, C, Iossa, G, Lagisz, M, Nakagawa, S, Noble, DWA, Pottier, P, Ramm, SA, Rowe, M, Schultner, E, Schou, M, Simões, P, Stockley, P, Vasudeva, R, Weaving, H, Price, TAR & Snook, RR 2024, 'Systematic approaches to assessing high-temperature limits to fertility in animals', Journal of evolutionary biology, vol. 37, no. 4, pp. 471-485. https://doi.org/10.1093/jeb/voae021

TY - JOUR

T1 - Systematic approaches to assessing high-temperature limits to fertility in animals

AU - Bretman, Amanda

AU - Fricke, Claudia

AU - Baur, Julian

AU - Berger, David

AU - Breedveld, Merel C.

AU - Dierick, Diego

AU - Canal Domenech, Berta

AU - Drobniak, Szymon M.

AU - Ellers, Jacintha

AU - English, Sinead

AU - Gasparini, Clelia

AU - Iossa, Graziella

AU - Lagisz, Malgorzata

AU - Nakagawa, Shinichi

AU - Noble, Daniel W.A.

AU - Pottier, Patrice

AU - Ramm, Steven A.

AU - Rowe, Melissah

AU - Schultner, Eva

AU - Schou, Mads

AU - Simões, Pedro

AU - Stockley, Paula

AU - Vasudeva, Ramakrishnan

AU - Weaving, Hester

AU - Price, Tom A.R.

AU - Snook, Rhonda R.

PY - 2024/4

Y1 - 2024/4

N2 - Critical thermal limits (CTLs) gauge the physiological impact of temperature on survival or critical biological function, aiding predictions of species range shifts and climatic resilience. Two recent Drosophila species studies, using similar approaches to determine temperatures that induce sterility (thermal fertility limits [TFLs]), reveal that TFLs are often lower than CTLs and that TFLs better predict both current species distributions and extinction probability. Moreover, many studies show fertility is more sensitive at less extreme temperatures than survival (thermal sensitivity of fertility [TSF]). These results present a more pessimistic outlook on the consequences of climate change. However, unlike CTLs, TFL data are limited to Drosophila, and variability in TSF methods poses challenges in predicting species responses to increasing temperature. To address these data and methodological gaps, we propose 3 standardized approaches for assessing thermal impacts on fertility. We focus on adult obligate sexual terrestrial invertebrates but also provide modifications for other animal groups and life-history stages. We first outline a "gold-standard" protocol for determining TFLs, focussing on the effects of short-term heat shocks and simulating more frequent extreme heat events predicted by climate models. As this approach may be difficult to apply to some organisms, we then provide a standardized TSF protocol. Finally, we provide a framework to quantify fertility loss in response to extreme heat events in nature, given the limitations in laboratory approaches. Applying these standardized approaches across many taxa, similar to CTLs, will allow robust tests of the impact of fertility loss on species responses to increasing temperatures.

AB - Critical thermal limits (CTLs) gauge the physiological impact of temperature on survival or critical biological function, aiding predictions of species range shifts and climatic resilience. Two recent Drosophila species studies, using similar approaches to determine temperatures that induce sterility (thermal fertility limits [TFLs]), reveal that TFLs are often lower than CTLs and that TFLs better predict both current species distributions and extinction probability. Moreover, many studies show fertility is more sensitive at less extreme temperatures than survival (thermal sensitivity of fertility [TSF]). These results present a more pessimistic outlook on the consequences of climate change. However, unlike CTLs, TFL data are limited to Drosophila, and variability in TSF methods poses challenges in predicting species responses to increasing temperature. To address these data and methodological gaps, we propose 3 standardized approaches for assessing thermal impacts on fertility. We focus on adult obligate sexual terrestrial invertebrates but also provide modifications for other animal groups and life-history stages. We first outline a "gold-standard" protocol for determining TFLs, focussing on the effects of short-term heat shocks and simulating more frequent extreme heat events predicted by climate models. As this approach may be difficult to apply to some organisms, we then provide a standardized TSF protocol. Finally, we provide a framework to quantify fertility loss in response to extreme heat events in nature, given the limitations in laboratory approaches. Applying these standardized approaches across many taxa, similar to CTLs, will allow robust tests of the impact of fertility loss on species responses to increasing temperatures.

KW - critical thermal limit

KW - heat

KW - reproduction

KW - thermal fertility limit

KW - thermal sensitivity of fertility

UR - http://www.scopus.com/inward/record.url?scp=85189148017&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85189148017&partnerID=8YFLogxK

U2 - 10.1093/jeb/voae021

DO - 10.1093/jeb/voae021

M3 - Article

C2 - 38350467

AN - SCOPUS:85189148017

SN - 1420-9101

VL - 37

SP - 471

EP - 485

JO - Journal of evolutionary biology

JF - Journal of evolutionary biology

IS - 4

ER -

Systematic approaches to assessing high-temperature limits to fertility in animals

Abstract

Bibliographical note

Funding

Keywords

Access to Document

Persistent URL (handle)

Other files and links

Fingerprint

Cite this