Divergent expression of hypoxia response systems under deoxygenation in reef-forming corals aligns with bleaching susceptibility

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Divergent expression of hypoxia response systems under deoxygenation in reef-forming corals aligns with bleaching susceptibility. / Alderdice, Rachel; Suggett, David J.; Cárdenas, Anny; Hughes, David J.; Kühl, Michael; Pernice, Mathieu; Voolstra, Christian R.

In: Global Change Biology, Vol. 27, No. 2, 2021, p. 312-326.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Alderdice, R, Suggett, DJ, Cárdenas, A, Hughes, DJ, Kühl, M, Pernice, M & Voolstra, CR 2021, 'Divergent expression of hypoxia response systems under deoxygenation in reef-forming corals aligns with bleaching susceptibility', Global Change Biology, vol. 27, no. 2, pp. 312-326. https://doi.org/10.1111/gcb.15436

APA

Alderdice, R., Suggett, D. J., Cárdenas, A., Hughes, D. J., Kühl, M., Pernice, M., & Voolstra, C. R. (2021). Divergent expression of hypoxia response systems under deoxygenation in reef-forming corals aligns with bleaching susceptibility. Global Change Biology, 27(2), 312-326. https://doi.org/10.1111/gcb.15436

Vancouver

Alderdice R, Suggett DJ, Cárdenas A, Hughes DJ, Kühl M, Pernice M et al. Divergent expression of hypoxia response systems under deoxygenation in reef-forming corals aligns with bleaching susceptibility. Global Change Biology. 2021;27(2):312-326. https://doi.org/10.1111/gcb.15436

Author

Alderdice, Rachel ; Suggett, David J. ; Cárdenas, Anny ; Hughes, David J. ; Kühl, Michael ; Pernice, Mathieu ; Voolstra, Christian R. / Divergent expression of hypoxia response systems under deoxygenation in reef-forming corals aligns with bleaching susceptibility. In: Global Change Biology. 2021 ; Vol. 27, No. 2. pp. 312-326.

Bibtex

@article{2b15f8f03fa44578aa0c92679da7fd2e,
title = "Divergent expression of hypoxia response systems under deoxygenation in reef-forming corals aligns with bleaching susceptibility",
abstract = "Exposure of marine life to low oxygen is accelerating worldwide via climate change and localized pollution. Mass coral bleaching and mortality have recently occurred where reefs have experienced chronic low oxygen events. However, the mechanistic basis of tolerance to oxygen levels inadequate to sustain normal functioning (i.e. hypoxia) and whether it contributes to bleaching susceptibility, remain unknown. We therefore experimentally exposed colonies of the environmentally resilient Acropora tenuis, a common reef-building coral from the Great Barrier Reef, to deoxygenation–reoxygenation stress that was aligned to their natural night–day light cycle. Specifically, the treatment involved removing the {\textquoteleft}night-time O2 buffer{\textquoteright} to challenge the inherent hypoxia thresholds. RNA-Seq analysis revealed that coral possess a complete and active hypoxia-inducible factor (HIF)-mediated hypoxia response system (HRS) homologous to other metazoans. As expected, A. tenuis exhibited bleaching resistance and showed a strong inducibility of HIF target genes in response to deoxygenation stress. We applied this same approach in parallel to a colony of Acropora selago, known to be environmnetally susceptible, which conversely exhibited a bleaching phenotype response. This phenotypic divergence of A. selago was accompanied by contrasting gene expression profiles indicative of varied effectiveness of their HIF-HRS. Based on our RNA-Seq analysis, we propose (a) that the HIF-HRS is central for corals to manage deoxygenation stress and (b) that key genes of this system (and the wider gene network) may contribute to variation in coral bleaching susceptibility. Our analysis suggests that heat shock protein (hsp) 70 and 90 are important for low oxygen stress tolerance and further highlights how hsp90 expression might also affect the inducibility of coral HIF-HRS in overcoming a metabolic crisis under deoxygenation stress. We propose that differences in coral HIF-HRS could be central in regulating sensitivity to other climate change stressors—notably thermal stress—that commonly drive bleaching.",
keywords = "bleaching, coral reef, hypoxia stress, metabolic crisis, ocean deoxygenation, stress regulation",
author = "Rachel Alderdice and Suggett, {David J.} and Anny C{\'a}rdenas and Hughes, {David J.} and Michael K{\"u}hl and Mathieu Pernice and Voolstra, {Christian R.}",
year = "2021",
doi = "10.1111/gcb.15436",
language = "English",
volume = "27",
pages = "312--326",
journal = "Global Change Biology",
issn = "1354-1013",
publisher = "Wiley-Blackwell",
number = "2",

}

RIS

TY - JOUR

T1 - Divergent expression of hypoxia response systems under deoxygenation in reef-forming corals aligns with bleaching susceptibility

AU - Alderdice, Rachel

AU - Suggett, David J.

AU - Cárdenas, Anny

AU - Hughes, David J.

AU - Kühl, Michael

AU - Pernice, Mathieu

AU - Voolstra, Christian R.

PY - 2021

Y1 - 2021

N2 - Exposure of marine life to low oxygen is accelerating worldwide via climate change and localized pollution. Mass coral bleaching and mortality have recently occurred where reefs have experienced chronic low oxygen events. However, the mechanistic basis of tolerance to oxygen levels inadequate to sustain normal functioning (i.e. hypoxia) and whether it contributes to bleaching susceptibility, remain unknown. We therefore experimentally exposed colonies of the environmentally resilient Acropora tenuis, a common reef-building coral from the Great Barrier Reef, to deoxygenation–reoxygenation stress that was aligned to their natural night–day light cycle. Specifically, the treatment involved removing the ‘night-time O2 buffer’ to challenge the inherent hypoxia thresholds. RNA-Seq analysis revealed that coral possess a complete and active hypoxia-inducible factor (HIF)-mediated hypoxia response system (HRS) homologous to other metazoans. As expected, A. tenuis exhibited bleaching resistance and showed a strong inducibility of HIF target genes in response to deoxygenation stress. We applied this same approach in parallel to a colony of Acropora selago, known to be environmnetally susceptible, which conversely exhibited a bleaching phenotype response. This phenotypic divergence of A. selago was accompanied by contrasting gene expression profiles indicative of varied effectiveness of their HIF-HRS. Based on our RNA-Seq analysis, we propose (a) that the HIF-HRS is central for corals to manage deoxygenation stress and (b) that key genes of this system (and the wider gene network) may contribute to variation in coral bleaching susceptibility. Our analysis suggests that heat shock protein (hsp) 70 and 90 are important for low oxygen stress tolerance and further highlights how hsp90 expression might also affect the inducibility of coral HIF-HRS in overcoming a metabolic crisis under deoxygenation stress. We propose that differences in coral HIF-HRS could be central in regulating sensitivity to other climate change stressors—notably thermal stress—that commonly drive bleaching.

AB - Exposure of marine life to low oxygen is accelerating worldwide via climate change and localized pollution. Mass coral bleaching and mortality have recently occurred where reefs have experienced chronic low oxygen events. However, the mechanistic basis of tolerance to oxygen levels inadequate to sustain normal functioning (i.e. hypoxia) and whether it contributes to bleaching susceptibility, remain unknown. We therefore experimentally exposed colonies of the environmentally resilient Acropora tenuis, a common reef-building coral from the Great Barrier Reef, to deoxygenation–reoxygenation stress that was aligned to their natural night–day light cycle. Specifically, the treatment involved removing the ‘night-time O2 buffer’ to challenge the inherent hypoxia thresholds. RNA-Seq analysis revealed that coral possess a complete and active hypoxia-inducible factor (HIF)-mediated hypoxia response system (HRS) homologous to other metazoans. As expected, A. tenuis exhibited bleaching resistance and showed a strong inducibility of HIF target genes in response to deoxygenation stress. We applied this same approach in parallel to a colony of Acropora selago, known to be environmnetally susceptible, which conversely exhibited a bleaching phenotype response. This phenotypic divergence of A. selago was accompanied by contrasting gene expression profiles indicative of varied effectiveness of their HIF-HRS. Based on our RNA-Seq analysis, we propose (a) that the HIF-HRS is central for corals to manage deoxygenation stress and (b) that key genes of this system (and the wider gene network) may contribute to variation in coral bleaching susceptibility. Our analysis suggests that heat shock protein (hsp) 70 and 90 are important for low oxygen stress tolerance and further highlights how hsp90 expression might also affect the inducibility of coral HIF-HRS in overcoming a metabolic crisis under deoxygenation stress. We propose that differences in coral HIF-HRS could be central in regulating sensitivity to other climate change stressors—notably thermal stress—that commonly drive bleaching.

KW - bleaching

KW - coral reef

KW - hypoxia stress

KW - metabolic crisis

KW - ocean deoxygenation

KW - stress regulation

U2 - 10.1111/gcb.15436

DO - 10.1111/gcb.15436

M3 - Journal article

C2 - 33197302

AN - SCOPUS:85096648381

VL - 27

SP - 312

EP - 326

JO - Global Change Biology

JF - Global Change Biology

SN - 1354-1013

IS - 2

ER -

ID: 252513942