Bleaching resistant corals retain heat tolerance following acclimatization to environmentally distinct reefs

Barott, Katie L.; Huffmyer, Ariana S.; Davidson, Jennifer; Lenz, Elizabeth A.; Matsuda, Shayle B.; Hancock, Joshua R.; Innis, Teegan; Drury, Crawford; Putnam, Hollie M.; Gates, Ruth D.

doi:10.1101/2020.09.25.314203

Cited by 5 publications

(8 citation statements)

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“…This study was conducted at a coral‐dominated patch reef (PR) in the outer lagoon (PR13; 21.4515°N, 157.7966°W), where the most abundant reef‐building corals were M. capitata and P. compressa . This region of Kāne'ohe Bay is characterized by relatively short seawater residence times (<24 h; Lowe et al, 2009) and diel pH ranges twofold to threefold higher than other regions of the bay with longer residence times (Barott, Huffmyer, et al, 2020; Page et al, 2018). Hourly sea surface temperatures on the reef from the 2015 and 2019 heatwaves were obtained from the NOAA temperature sensor on Moku o Lo'e in Kāne'ohe Bay (Station ID: 1612480).…”

Section: Methodsmentioning

confidence: 99%

Marine heatwaves depress metabolic activity and impair cellular acid–base homeostasis in reef‐building corals regardless of bleaching susceptibility

Innis

Allen-Waller

Brown

et al. 2021

Global Change Biology

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Section: Methodsmentioning

confidence: 99%

Marine heatwaves depress metabolic activity and impair cellular acid–base homeostasis in reef‐building corals regardless of bleaching susceptibility

Innis

Allen-Waller

Brown

et al. 2021

Global Change Biology

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“…Acid-base homeostasis is energetically expensive, and the costs of this vital maintenance process increase following stress, and so may be particularly exacerbated during coral bleaching. There is a growing understanding of coral acid-base sensing mechanisms (Barott, Barron, and Tresguerres 2017; Barott, Venn, et al 2020) and the downstream effectors involved in maintaining acid-base homeostasis in the cytosol (Laurent et al 2014), calcifying fluid (Zoccola et al 2015; Barott, Perez, et al 2015; Zoccola et al 2004), and symbiosome (Barott, Venn, et al 2015; Bertucci et al 2009; Barott, Perez, et al 2015). While previous work in corals has shown corals can upregulate active acid-base regulation processes under ambient temperature conditions, the relative contribution of passive (e.g.…”

Section: Discussionmentioning

confidence: 99%

“…This study was conducted at a coral-dominated patch reef (PR) in the outer lagoon (PR13; 21.4515°N, 157.7966°W), where the most abundant reef-building corals were Montipora capitata and Porites compressa . This region of Kāne’ohe Bay is characterized by relatively short seawater residence times (<24 hours, Lowe et al 2009) and diel pH ranges 2 – 3 fold higher than other regions of the bay with longer residence times (Barott, Huffmyer, et al 2020; Page et al 2018). Hourly sea surface temperatures on the reef from the 2015 and 2019 heatwaves were obtained from the NOAA temperature sensor on Moku o Lo’e in Kāne’ohe Bay (Station ID: 1612480).…”

Section: Methodsmentioning

confidence: 99%

“…However, little is known about how climate change affects acid-base homeostasis in corals. The potential effects of heat stress on acid-base regulation pose a particular challenge for maintaining coral calcification, as biomineralization is highly pH-dependent (Barott, Venn, et al 2020; Venn et al 2011; McCulloch et al 2012). Indeed, recent studies have found that temperature stress alters the pH of the external calcifying fluid and depresses calcification (Schoepf et al 2021; Guillermic et al 2021), highlighting the need to better understand the physiology of coral climate change responses across biological scales.…”

Section: Introductionmentioning

confidence: 99%

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Marine heatwaves depress metabolic activity and impair cellular acid-base homeostasis in reef-building corals regardless of bleaching susceptibility

Innis

Allen-Waller

Brown

et al. 2021

Preprint

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Ocean warming is causing global coral bleaching events to increase in frequency, resulting in widespread coral mortality and disrupting the function of coral reef ecosystems. However, even during mass bleaching events, many corals resist bleaching despite exposure to abnormally high temperatures. While the physiological effects of bleaching have been well documented, the consequences of heat stress for bleaching resistant individuals are not well understood. In addition, much remains to be learned about how heat stress affects cellular level processes that may be overlooked at the organismal level, yet are crucial for coral performance in the short term and ecological success over the long term. Here we compared the physiological and cellular responses of bleaching resistant and bleaching susceptible corals throughout the 2019 marine heatwave in Hawaii, a repeat bleaching event that occurred four years after the previous regional event. Relative bleaching susceptibility within species was consistent between the two bleaching events, yet corals of both resistant and susceptible phenotypes exhibited pronounced metabolic depression during the heatwave. At the cellular level, bleaching susceptible corals had lower intracellular pH than bleaching resistant corals at the peak of bleaching for both symbiont-hosting and symbiont-free cells, indicating greater disruption of acid-base homeostasis in bleaching susceptible individuals. Notably, cells from both phenotypes were unable to compensate for experimentally induced cellular acidosis, indicating that acid-base regulation was significantly impaired at the cellular level even in bleaching resistant corals and in cells containing symbionts. Thermal disturbances may thus have substantial ecological consequences, as even small reallocations in energy budgets to maintain homeostasis during stress can negatively affect fitness. These results suggest concern is warranted for corals coping with ocean acidification alongside ocean warming, as the feedback between temperature stress and acid-base regulation may further exacerbate the physiological effects of climate change.

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“…The targeted selection of corals using any of these techniques should be expected to come with trade-offs because there Palumbi et al, 2014;Howells et al, 2016;Kenkel and Matz, 2016;Jury and Toonen, 2019;Schoepf et al, 2019;Quigley et al, 2020b;Voolstra et al, 2020 Known performance Observed past performance of a colony is predictive of future performance Need pre-established individuals monitored over time Reliable, in situ, inexpensive, can be integrated into nursery propagation Drury et al, 2017a;Fisch et al, 2019;Barott et al, 2020*;Matsuda et al, 2020;Ritson-Williams and Gates, 2020;Drury and Lirman, 2021 Stress tests A sample representing the source colony undergoes heat stress, which is predictive of future performance Not fully representative of natural performance, ex situ, requires aquaria infrastructure, limited scalability Fast, reproducible, inexpensive once established Barshis et al, 2013;Palumbi et al, 2014;Thomas et al, 2018;Morikawa and Palumbi, 2019;Voolstra et al, 2020 Host genetics Using adaptive variants, epigenetics, or gene expression profiles to predict performance Requires molecular work, expensive, high technical dependencies, unlikely to be single large-effect genes, may be species-specific Mechanistic, targeted (within species), scalable, reproducible Bay and Palumbi, 2014;Dixon et al, 2015;Rose et al, 2015;Kirk et al, 2018;Fuller et al, 2020;Quigley et al, 2020a;Drury and Lirman, 2021 Algal symbiosis Algal symbiont communities influence holobiont performance…”

Section: Trade-offs In Proactive Coral Reef Restorationmentioning

confidence: 99%

Selecting Heat-Tolerant Corals for Proactive Reef Restoration

2021

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Coral reef restoration is an attractive tool for the management of degraded reefs; however, conventional restoration approaches will not be effective under climate change. More proactive restoration approaches must integrate future environmental conditions into project design to ensure long-term viability of restored corals during worsening bleaching events. Corals exist along a continuum of stress-tolerant phenotypes that can be leveraged to enhance the thermal resilience of reefs through selective propagation of heat-tolerant colonies. Several strategies for selecting thermally tolerant stock are currently available and range broadly in scalability, cost, reproducibility, and specificity. Different components of the coral holobiont have different utility to practitioners as diagnostics and drivers of long-term phenotypes, so selection strategies can be tailored to the resources and goals of individual projects. There are numerous unknowns and potential trade-offs to consider, but we argue that a focus on thermal tolerance is critical because corals that do not survive bleaching cannot contribute to future reef communities at all. Selective propagation uses extant corals and can be practically incorporated into existing restoration frameworks, putting researchers in a position to perform empirical tests and field trials now while there is still a window to act.

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Bleaching resistant corals retain heat tolerance following acclimatization to environmentally distinct reefs

Cited by 5 publications

References 89 publications

Marine heatwaves depress metabolic activity and impair cellular acid–base homeostasis in reef‐building corals regardless of bleaching susceptibility

Marine heatwaves depress metabolic activity and impair cellular acid–base homeostasis in reef‐building corals regardless of bleaching susceptibility

Marine heatwaves depress metabolic activity and impair cellular acid-base homeostasis in reef-building corals regardless of bleaching susceptibility

Selecting Heat-Tolerant Corals for Proactive Reef Restoration

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