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Mitigating the ecological collapse of coral reef ecosystems

2023; Springer Nature; Volume: 24; Issue: 4 Linguagem: Inglês

10.15252/embr.202356826

1469-3178

Christian R. Voolstra, Raquel S. Peixoto, Christine Ferrier‐Pagès,

Marine and coastal plant biology

Science & Society2 March 2023Open Access Transparent process Mitigating the ecological collapse of coral reef ecosystems Effective strategies to preserve coral reef ecosystems Christian R Voolstra Corresponding Author Christian R Voolstra [email protected] orcid.org/0000-0003-4555-3795 Department of Biology, University of Konstanz, Konstanz, Germany Contribution: Conceptualization, Writing - original draft, Writing - review & editing Search for more papers by this author Raquel S Peixoto Corresponding Author Raquel S Peixoto [email protected] orcid.org/0000-0002-9536-3132 Red Sea Research Center, King Abdullah University of Science and Technology (KAUST), Thuwal, Saudi Arabia Contribution: Conceptualization, Writing - original draft, Writing - review & editing Search for more papers by this author Christine Ferrier-Pagès Corresponding Author Christine Ferrier-Pagès [email protected] orcid.org/0000-0002-0357-4486 Coral Ecophysiology Team, Centre Scientifique de Monaco, Monte Carlo, Monaco Contribution: Conceptualization, Writing - original draft, Writing - review & editing Search for more papers by this author Christian R Voolstra Corresponding Author Christian R Voolstra [email protected] orcid.org/0000-0003-4555-3795 Department of Biology, University of Konstanz, Konstanz, Germany Contribution: Conceptualization, Writing - original draft, Writing - review & editing Search for more papers by this author Raquel S Peixoto Corresponding Author Raquel S Peixoto [email protected] orcid.org/0000-0002-9536-3132 Red Sea Research Center, King Abdullah University of Science and Technology (KAUST), Thuwal, Saudi Arabia Contribution: Conceptualization, Writing - original draft, Writing - review & editing Search for more papers by this author Christine Ferrier-Pagès Corresponding Author Christine Ferrier-Pagès [email protected] orcid.org/0000-0002-0357-4486 Coral Ecophysiology Team, Centre Scientifique de Monaco, Monte Carlo, Monaco Contribution: Conceptualization, Writing - original draft, Writing - review & editing Search for more papers by this author Author Information Christian R Voolstra *,1, Raquel S Peixoto *,2 and Christine Ferrier-Pagès *,3 1Department of Biology, University of Konstanz, Konstanz, Germany 2Red Sea Research Center, King Abdullah University of Science and Technology (KAUST), Thuwal, Saudi Arabia 3Coral Ecophysiology Team, Centre Scientifique de Monaco, Monte Carlo, Monaco *Corresponding author. E-mail: [email protected] author. E-mail: [email protected] author. E-mail: [email protected] EMBO Reports (2023)24:e56826https://doi.org/10.15252/embr.202356826 PDFDownload PDF of article text and main figures. Peer ReviewDownload a summary of the editorial decision process including editorial decision letters, reviewer comments and author responses to feedback. ToolsAdd to favoritesDownload CitationsTrack CitationsPermissions ShareFacebookTwitterLinked InMendeleyWechatReddit Figures & Info Coral reef ecosystems are biodiversity hotspots that provide a habitat for about a third of all marine species (Fisher et al, 2015)—which is why colloquially they are referred to as the "rainforests of the sea". In addition to their immense ecological importance, coral reefs offer a wealth of ecosystem services to millions of people, including the provision of food and commercial fisheries, tourism, sand production, carbon sequestration, and coastal protection from storms (Eddy et al, 2021). The crucial organisms that establish and expand coral reefs are corals, sessile animals that build impressive three-dimensional structures through their calcium carbonate skeletons, rivaling busy cityscapes. … coral holobionts are fragile organisms that are threatened by local and global stressors to the point where the very existence of coral reef ecosystems globally is now at stake. But corals cannot achieve these impressive constructions alone. Rather, they have to rely on a multitude of little helpers. In fact, corals are so-called holobionts or metaorganisms that encompass a myriad of associated symbiotic microorganisms, collectively referred to as the microbiome that includes archaea, bacteria, fungi, viruses, and microeukaryotes, most importantly, Symbiodiniaceae (LaJeunesse et al, 2018; Voolstra et al, 2021). These dinoflagellate photosynthetic microalgae live inside the coral cells and provide them with the energy to construct their calcium carbonate skeletons. Despite the massive and lasting structures they create, coral holobionts are fragile organisms that are threatened by local and global stressors to the point where the very existence of coral reef ecosystems globally is now at stake (Allen et al, 2018). Climate change, owing to increasing greenhouse gas (GHG) emissions caused by human activities, is the greatest threat to coral reefs. GHG emissions change marine conditions in several ways, including ocean warming, ocean acidification, and an increased frequency and intensity of tropical storms and heatwaves (Allen et al, 2018; Frölicher et al, 2018). While storms can locally devastate coral reefs and seawater acidification reduces calcification rates of reef taxa and thus skeletal and reef growth (Mollica et al, 2018), warmer waters pose the most significant threat to reefs (Kleypas et al, 2021; Knowlton et al, 2021). Extended periods of high temperature cause heat stress, which triggers the breakdown of the symbiosis between corals and Symbiodiniaceae, a phenomenon known as bleaching (Suggett & Smith, 2020). Mass coral bleaching has been increasing in frequency and intensity over the past decade(s) and caused a 30% decline in the global coral population (Eakin et al, 2022). Recent estimations predict that, if global warming exceeds 1.5°C, 70–90% of reef corals are at risk to be lost, and 99% will be lost if global warming exceeds 2°C above pre-industrial temperatures (Hoegh-Guldberg et al, 2018; Knowlton et al, 2021). … all actions to save coral reefs are connected with each other by 'and' not 'or'. The effects of climate change are amplified by local stressors, such as pollution, sedimentation, and eutrophication, caused by land clearing and fertilizer use (Wiedenmann et al, 2012). The latter causes overgrowth of corals by macroalgae and bioerosion of algal and coral skeletons by endolithic algae. It affects the coral microbiome, for instance, by increasing the abundance of pathogens (Leite et al, 2018). Taken together, coral bleaching driven by ocean warming (Eakin et al, 2022) along with local and global stressors reduce calcification rates of important reef-forming taxa, decrease reef accretion through bioerosion and dissolution of carbonate sediments (Eyre et al, 2018), and further weaken coral stress resilience (Donovan et al, 2021) (Fig 1). Figure 1.(A) A healthy reef with a moderate level of bleaching. The bleached coral colonies appear white and can recover if stressful conditions subside. (B) A degraded reef where the corals are dead and the remaining skeleton is overgrown by algae. Some bleached colonies are visible in the lower middle. Download figure Download PowerPoint CO2 emission mitigation is a pre-requisite It follows that corals must be protected in order to save the reefs (Fig 2). The International Coral Reef Society (ICRS) proposed three equally important pillars for saving and restoring coral reefs (Knowlton et al, 2021) (Fig 2). The first one is mitigating CO2 emissions and global climate threats. Importantly, all other options rely on the premise that we are becoming carbon neutral in due time; in other words, all actions to save coral reefs are connected with each other by "and" not "or" (Kleypas et al, 2021). Figure 2.Global and local pressures have led to the loss of 30% of global reef cover (left). The International Coral Reef Society (ICRS) has proposed three pillars for restoring coral reefs and mitigating their further loss (right): (A) reduce CO2 emissions; (B) mitigate local stressors (e.g., by managing fish stocks or improving water quality); and (C) active restoration/rehabilitation. It is important to note that without reducing CO2 emissions to curb global warming to below 2°C and eventually becoming carbon neutral, we will still lose the majority of coral reefs (C, right-hand side). Download figure Download PowerPoint … interventions for reef protection must occur over large areas to be effective and should be reinforced with socio-economic incentives and regulatory measures. Mitigating carbon emissions is necessary to limit the mean global temperature increase to about 1.5°C, the threshold above which 99% of reefs are on a trajectory to become permanently lost (Hoegh-Guldberg et al, 2018). Staying below this threshold will allow us to protect still healthy and resilient reefs and restore damaged reefs. Other actions to decrease sea surface temperature (SST), such as pumping deep cool seawater into reef areas or modifying solar radiation—through reef shading, surface albedo enhancement, stratospheric aerosol injection, and so on—represent geoengineering approaches to offset impacts of climate change (National Academies of Sciences, Engineering, and Medicine, 2019). These are very expensive options that can be at best considered only on a small and local scale (Kleypas et al, 2021). Some reefs that exhibit increased thermal stress resilience deserve special protection, because these coral communities have evolved a natural higher tolerance… Saving corals through conservation Failure to address climate change will undermine most attempts to mitigate the impacts of local threats, which is the second pillar of the ICRS's guideline to save coral reefs as global and local stressors can synergistically interact to affect coral reefs (Knowlton et al, 2021). Although accretion of some reefs under global warming of more than 1.5°C will still be present but slow, model estimates indicate that a combination of reduced emissions and improved local conditions, such as improving water quality, can maintain a positive carbonate budget, that is, growth (Kennedy et al, 2013). Improving local conditions requires a variety of actions that directly or indirectly affect coral health and recovery, such as the reduction of overfishing through the establishment of complete or partial marine protected areas (MPAs) and/or the management of coastal zones and watersheds to reduce nutrient loading and river runoff (Mellin et al, 2016). There are several reefs in the Caribbean, Australia, and Kenya, which demonstrate that the management of local stressors has a positive impact on coral recovery (Mellin et al, 2016). However, interventions for reef protection must occur over large areas to be effective and should be reinforced with socio-economic incentives and regulatory measures. These actions also must be adapted to the particular threats at each location (Voolstra et al, 2021). For example, the Gulf of Aqaba (GoA) in the northern Red Sea has been coined a coral refuge to SST rise because corals can withstand temperatures of up to +6°C above their maximum summer mean ex situ and no mass bleaching has been observed in situ (Osman et al, 2018). Yet, these corals are not immune to other, local threats and are, indeed, affected by increasing pollution, such as seawater eutrophication, antiscalants from desalination plants, or light pollution. Long-term monitoring through national programs, science-guided management, and engagement from policymakers, as well as the support of local communities, is essential to identify appropriate interventions and manage local reef conditions. Saving corals through restoration and rehabilitation While global and local anthropogenic stressors are being addressed, the third pillar put forward by the ICRS, which is restoration and rehabilitation (Knowlton et al, 2021), is under active development and implementation (Voolstra et al, 2021). Given the pace and severity of current impacts, restoration and rehabilitation efforts have become a mandatory step to maintain coral reefs while achieving carbon neutrality (Voolstra et al, 2021). Such interventions can be customized to target different entities of the coral holobiont, such as the algal symbionts, the prokaryotic community, or other associated microeukaryotes (National Academies of Sciences, Engineering, and Medicine, 2019; Peixoto et al, 2019; Voolstra et al, 2021), and can combine different approaches for reef restoration and rehabilitation (van Oppen et al, 2015; Boström-Einarsson et al, 2020; Peixoto et al, 2021; Santoro et al, 2021). Different impacts and levels of degradation require different approaches (Peixoto et al, 2019; Voolstra et al, 2021; Fig 3). In fact, considering the current stage of degradation of some reefs and ongoing climate change and widespread marine pollution, modern restoration approaches will necessarily need to integrate rehabilitation and prevention concepts to succeed, and the two terms can therefore be used interchangeably (Box 1) (Knowlton et al, 2021). Figure 3.Examples of actions to restore/rehabilitate reefs and mitigate their global loss. Restoration refers to processes that help the recovery of degraded or damaged ecosystems; rehabilitation refers to processes that improve reefs through active interventions that expand their adaptive capacity or increase resilience. Many of these actions go hand-in-hand and many restoration approaches entail a component of rehabilitation so that restoration and rehabilitation are often used interchangeably. Download figure Download PowerPoint Box 1. Restoration versus rehabilitation. The definition of "restoration" proposed by the "Society for Ecological Restoration" is "the process of assisting the recovery of an ecosystem that has been degraded, damaged, or destroyed". While the goals of "restoration" include the re-establishment of the pre-existing species composition and community structure, the ongoing change of environmental conditions faced by coral reefs results in future reefs harboring different compositions from the original reefs. This is recognized in UNEP's guide to coral reef restoration, where the term "coral reef restoration" is used to describe measures that "aim to assist the recovery of reef structure, function, and key reef species in the face of rising climate and anthropogenic pressures, therefore promoting reef resilience and the sustainable delivery of reef ecosystem services". By comparison, the term "rehabilitation" is centered on the notion that to "future-proof" reefs, it is not sufficient to merely restore reefs to their original composition, but to enhance reefs through active interventions, such as probiotic provision, environmental hardening, or similar measures, in order to promote protection, extend adaptation, and increase resilience. Thus, while the term restoration is used throughout this document for consistency, current efforts to save reefs should more accurately be understood as a form of rehabilitation. At the reef scale, restoration approaches to counter coral decline are particularly effective for areas that have been physically damaged by storms, disease outbreaks, mass bleaching, or human activities. It is also a useful option to support reef regrowth where coral recruitment is limited and disturbances can be reduced. The most commonly used restoration methods involve removal of predators and reintroduction of fish to control macroalgal overgrowth, along with transplantation of coral fragments with or without an intervening nursery phase (Boström-Einarsson et al, 2020). One difference is between sexually and asexually propagated restoration, the latter of which addresses reef regrowth but not genetic diversity (Voolstra et al, 2021). Other measures include the in situ deployment of artificial reef structures to enhance coral recruitment and fish aggregation, substrate manipulations, or the release of coral larvae after an intermediate rearing phase on land (Boström-Einarsson et al, 2020). The selected restoration measure(s) should be informed by the specific local conditions and engage local communities. Some reefs that exhibit increased thermal stress resilience deserve special protection because these coral communities have evolved a natural higher tolerance, thus constituting "super reefs" (https://superreefs.whoi.edu), "priority reefs" (https://www.50reefs.org), or "bright spots" (Cinner et al, 2016). Other reefs also deserve special consideration due to their potential to constitute "coral reef oases" (Guest et al, 2018), such as turbid reefs near mangroves, high latitude reefs, or reefs in upwelling areas, all of which are nutrient-rich and often sheltered from heat waves. However, the extent to which thermal protection of corals from such reefs can be transferred to other reefs is debatable, in particular, because these corals reside in marginal environments featuring unique adjustments that are either lost or reduced when transplanted into other, more common reef environments. Consequently, reefs should provide long-term buffering against multiple stressors, which is rarely found. For instance, GoA corals—and other "bleaching resistant" reefs—that have an exceptionally high bleaching threshold (Savary et al, 2021) may constitute a refuge from global warming, but they are exposed to (local) pollution and other anthropogenic stressors which affect their resilience (Donovan et al, 2021). At large, we need to improve our understanding of what underlies the resilience of some corals to various stressors and the potential costs or trade-offs (Cornwell et al, 2021). In addition to reintroducing or enhancing coral biomass in reefs, active rehabilitation and environmental management/prevention approaches can help corals adapt to future global changes. For example, laboratory experiments have shown that feeding corals with planktonic prey significantly increases their resilience and resistance to environmental stress (Grottoli et al, 2006). Recent in situ observations have also found a correlation between patterns of food availability and resilience in coral populations around the world, suggesting that reefs with high phyto- and/or zooplankton concentrations are better able to recover from thermal stress disturbance. A heterotrophic diet provides essential macronutrients and metals that sustain algal growth and photosynthesis and enhances nutrient translocation from algal symbionts to the coral host (Ferrier-Pagès et al, 2018). Increasing the nutritional quality of the plankton provided to corals—by manipulating the content of essential fatty acids, metals, and antioxidant compounds—might therefore be one strategy to enhance coral health. However, to our knowledge, no studies have directly attempted to increase zooplankton concentrations or alter zooplankton composition in reefs during heat waves, partially because it is a broad measure that may affect reef biota at large with unknown consequences. In total, the US National Academies of Science, Engineering, and Medicine lists 23 types of interventions, including approaches such as assisted gene flow (AGF), assisted evolution, and assisted colonization, cryopreservation, and microbiome manipulation to mitigate coral loss (National Academies of Sciences, Engineering, and Medicine, 2019). AGF interventions aim to identify genotypes within existing coral populations that are optimally suited to specific environments (Humanes et al, 2022), which can be used to improve the fitness of distant populations by introducing the respective alleles into target populations. Corals that have survived heat waves or those that live in the Persian/Arabian Gulf (PAG), where the highest ocean temperatures in the world occur, are also good candidates for exploring mechanisms of heat stress resistance by means of AGF. PAG corals are associated with a heat-specialized algal endosymbiont, Cladocopium thermophilum (Hume et al, 2016), and the coral host has a higher antioxidant capacity and expression of heat-responsive genes. Assisted translocation and colonization of these stress-resistant variants may help AGF, although other environmental factors may need to be considered, coming back to the above-mentioned trade-offs. As such, this can only occur if coral restoration material is reproduced sexually to generate novel allele combinations that convey increased resilience but also harbor compatibility with prevailing environments (Voolstra et al, 2021). More sophisticated breeding methods may use genetically-modified organisms, in which new alleles and traits that do not exist in natural populations are created to promote coral resilience… Nurseries can accelerate the process of genetic restoration by out-planting coral larvae produced from such crosses. Nurseries can also use cryopreserved sperm to produce offspring, especially for endangered species (Hagedorn et al, 2017). However, one of the biggest challenges is scaling up from smaller, laboratory-sized experiments to high-throughput reproduction. More sophisticated breeding methods may use genetically modified organisms, in which new alleles and traits that do not exist in natural populations are created to promote coral resilience (van Oppen et al, 2015). To this end, different genetic manipulation approaches are available, such as repeated exposure to stress to produce transgenerational acclimation through epigenetic mechanisms, although controversy remains (Torda et al, 2017). Another approach discussed is the induction of mutagenesis in algal symbionts to generate more resistant strains, but fidelity of the host–symbiont associations needs to be addressed (Hume et al, 2020; Howells et al, 2021), which may work better in coral larvae (Buerger et al, 2020). A further approach to enhance coral resilience is the assisted restructuring or restoration of prokaryotic and microeukaryotic communities associated with corals, for instance, through the use of probiotics or microbiome transplantation (Ziegler et al, 2017; Peixoto et al, 2019, 2021; Santoro et al, 2021; Zhang et al, 2021). Although the exact underlying mechanisms are still unclear, corals seem to rely on their associated microbiome for nutrient provision, pathogen protection, or toxic compound mitigation among others. Continuous environmental insult effectively alters the beneficial microbiome into a more pathogenic assemblage that affects coral resilience and well-being. The underlying premise is that rather than reintroducing coral biomass, efforts could focus on microbiome restoration of extant corals (Peixoto et al, 2022). Microbiome-based approaches are customizable and can be applied as a preventive or remediation measure (Peixoto et al, 2017) to promote holobiont growth (Zhang et al, 2021), pathogen mitigation (Rosado et al, 2019), remediation of oil impact (Silva et al, 2021), or recovery from thermally driven coral bleaching (Rosado et al, 2019; Santoro et al, 2021), and effectively prevent coral mortality in laboratory experiments (Santoro et al, 2021). The current challenge is to evaluate the efficiency of microbiome stewardship in situ and develop ways to scale up associated applications (Peixoto et al, 2022). Although the exact underlying mechanisms are still unclear, corals seem to rely on their associated microbiome for nutrient provision, pathogen protection, or toxic compound mitigation among others. Securing a future for coral reefs "Modern" coral reefs have existed for ~ 250 million years and are highly adaptable. A study conducted on the species Oculina patagonica showed that some corals can withstand severe seawater acidification by losing their skeletons while the tissues remain alive (Fine & Tchernov, 2007); corals never really disappear, even if reef ecosystems do. Thus, as long as there are corals, there is hope for reefs. It is understood that we cannot save all reefs from a cost and effort perspective, but enough to repopulate degraded areas once carbon neutrality is reached and the climate has stabilized. However, pristine coral reefs no longer exist, and corals are now under massive pressure: although the most tolerant corals have survived recent repeat bleaching events, and there is evidence that they increased their thermal tolerance, certain species are clearly more likely to survive than others. Thus, survival comes at the expense of biodiversity, and the reefs of the future will not be the same as the reefs of the past. One of the emphases should thus be placed on securing ecosystem functions and ecosystem services. It is understood that we cannot save all reefs from a cost and effort perspective, but enough to repopulate degraded areas once carbon neutrality is reached and the climate has stabilized. Under such constraint, we must recognize that not all coral reefs have the same ability to survive or adapt to climate change and consider prioritizing those reefs with the highest chance of survival that also promotes regeneration in other areas through, for instance, larval dispersal. Importantly, this requires that coral reefs must be protected at local, regional, and global scales in ways that allow for the propagation of evolutionary adaptive traits (Colton et al, 2022). This can only be achieved through coordinated action by science, policy, and local stakeholders (Hoegh-Guldberg et al, 2018; Kleypas et al, 2021). A combination of strategies, policies, and active interventions (Voolstra et al, 2021) as outlined above can help reefs recover and survive in different places, depending on local environmental conditions, financial resources, and socioeconomic circumstances. We have a chance if we are to integrate the triad of mitigating CO2 emissions, improving local conditions, and undertaking active restoration/rehabilitation, but it is a closing window of opportunity to secure a future for coral reef ecosystems—for us and future generations. Acknowledgement Open Access funding enabled and organized by Projekt DEAL. Author contributions Christian R Voolstra: Conceptualization; writing—original draft; writing—review and editing. Raquel S Peixoto: Conceptualization; writing—original draft; writing—review and editing. Christine Ferrier-Pagès: Conceptualization; writing—original draft; writing—review and editing. 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