Transcriptome resilience predicts thermotolerance in Caenorhabditis elegans

Transcriptome resilience predicts thermotolerance in Caenorhabditis elegans

Abstract Background The detrimental effects of a short bout of stress can persist and potentially turn lethal, long after the return to normal conditions. Thermotolerance, which is the capacity of an organism to withstand relatively extreme temperatures, is influenced by the response during stress e...

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Main Authors: Katharina Jovic, Jacopo Grilli, Mark G. Sterken, Basten L. Snoek, Joost A. G. Riksen, Stefano Allesina, Jan E. Kammenga
Format: Article
Language:English
Published: BMC 2019-12-01
Series:BMC Biology
Subjects:
Heat stress
Recovery
C. elegans
Resilience
Thermotolerance
Gene expression dynamics
Online Access:https://doi.org/10.1186/s12915-019-0725-6
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spelling doaj-e7b73162ed32440c8b0728b98f6f9b9c2020-12-13T12:23:54ZengBMCBMC Biology1741-70072019-12-0117111210.1186/s12915-019-0725-6Transcriptome resilience predicts thermotolerance in Caenorhabditis elegansKatharina Jovic0Jacopo Grilli1Mark G. Sterken2Basten L. Snoek3Joost A. G. Riksen4Stefano Allesina5Jan E. Kammenga6Laboratory of Nematology, Wageningen UniversityDepartment of Ecology and Evolution, University of ChicagoLaboratory of Nematology, Wageningen UniversityLaboratory of Nematology, Wageningen UniversityLaboratory of Nematology, Wageningen UniversityDepartment of Ecology and Evolution, University of ChicagoLaboratory of Nematology, Wageningen UniversityAbstract Background The detrimental effects of a short bout of stress can persist and potentially turn lethal, long after the return to normal conditions. Thermotolerance, which is the capacity of an organism to withstand relatively extreme temperatures, is influenced by the response during stress exposure, as well as the recovery process afterwards. While heat-shock response mechanisms have been studied intensively, predicting thermal tolerance remains a challenge. Results Here, we use the nematode Caenorhabditis elegans to measure transcriptional resilience to heat stress and predict thermotolerance. Using principal component analysis in combination with genome-wide gene expression profiles collected in three high-resolution time series during control, heat stress, and recovery conditions, we infer a quantitative scale capturing the extent of stress-induced transcriptome dynamics in a single value. This scale provides a basis for evaluating transcriptome resilience, defined here as the ability to depart from stress-expression dynamics during recovery. Independent replication across multiple highly divergent genotypes reveals that the transcriptional resilience parameter measured after a spike in temperature is quantitatively linked to long-term survival after heat stress. Conclusion Our findings imply that thermotolerance is an intrinsic property that pre-determines long-term outcome of stress and can be predicted by the transcriptional resilience parameter. Inferring the transcriptional resilience parameters of higher organisms could aid in evaluating rehabilitation strategies after stresses such as disease and trauma.https://doi.org/10.1186/s12915-019-0725-6Heat stressRecoveryC. elegansResilienceThermotoleranceGene expression dynamics
collection DOAJ
language English
format Article
sources DOAJ
author Katharina Jovic
Jacopo Grilli
Mark G. Sterken
Basten L. Snoek
Joost A. G. Riksen
Stefano Allesina
Jan E. Kammenga
spellingShingle Katharina Jovic
Jacopo Grilli
Mark G. Sterken
Basten L. Snoek
Joost A. G. Riksen
Stefano Allesina
Jan E. Kammenga
Transcriptome resilience predicts thermotolerance in Caenorhabditis elegans
BMC Biology
Heat stress
Recovery
C. elegans
Resilience
Thermotolerance
Gene expression dynamics
author_facet Katharina Jovic
Jacopo Grilli
Mark G. Sterken
Basten L. Snoek
Joost A. G. Riksen
Stefano Allesina
Jan E. Kammenga
author_sort Katharina Jovic
title Transcriptome resilience predicts thermotolerance in Caenorhabditis elegans
title_short Transcriptome resilience predicts thermotolerance in Caenorhabditis elegans
title_full Transcriptome resilience predicts thermotolerance in Caenorhabditis elegans
title_fullStr Transcriptome resilience predicts thermotolerance in Caenorhabditis elegans
title_full_unstemmed Transcriptome resilience predicts thermotolerance in Caenorhabditis elegans
title_sort transcriptome resilience predicts thermotolerance in caenorhabditis elegans
publisher BMC
series BMC Biology
issn 1741-7007
publishDate 2019-12-01
description Abstract Background The detrimental effects of a short bout of stress can persist and potentially turn lethal, long after the return to normal conditions. Thermotolerance, which is the capacity of an organism to withstand relatively extreme temperatures, is influenced by the response during stress exposure, as well as the recovery process afterwards. While heat-shock response mechanisms have been studied intensively, predicting thermal tolerance remains a challenge. Results Here, we use the nematode Caenorhabditis elegans to measure transcriptional resilience to heat stress and predict thermotolerance. Using principal component analysis in combination with genome-wide gene expression profiles collected in three high-resolution time series during control, heat stress, and recovery conditions, we infer a quantitative scale capturing the extent of stress-induced transcriptome dynamics in a single value. This scale provides a basis for evaluating transcriptome resilience, defined here as the ability to depart from stress-expression dynamics during recovery. Independent replication across multiple highly divergent genotypes reveals that the transcriptional resilience parameter measured after a spike in temperature is quantitatively linked to long-term survival after heat stress. Conclusion Our findings imply that thermotolerance is an intrinsic property that pre-determines long-term outcome of stress and can be predicted by the transcriptional resilience parameter. Inferring the transcriptional resilience parameters of higher organisms could aid in evaluating rehabilitation strategies after stresses such as disease and trauma.
topic Heat stress
Recovery
C. elegans
Resilience
Thermotolerance
Gene expression dynamics
url https://doi.org/10.1186/s12915-019-0725-6
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