Lethal and sublethal effects of thermal stress on octocorals early life‐history stages

The frequency and severity of marine heatwaves causing mass mortality events in tropical and temperate coral species increases every year, with serious consequences on the stability and resilience of coral populations. Although recovery and persistence of coral populations after stress events is clo...

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Veröffentlicht in:	Global change biology 2022-12, Vol.28 (23), p.7049-7062
Hauptverfasser:	Viladrich, Núria, Linares, Cristina, Padilla‐Gamiño, Jacqueline L.
Format:	Artikel
Sprache:	eng
Schlagworte:	Animals Anthozoa - physiology Breeding brooding Colonies Coral Reefs Corals Depletion energetic consumption gorgonians Heat resistance Heat waves Heatwaves High temperature Larva Larvae Life Cycle Stages Local population marine heatwaves Marine invertebrates Mass mortality Mortality Ocean temperature Ocean warming Populations Reproductive behavior Reproductive behaviour reproductive phenology settlement Species Sublethal effects Survival Symbionts Symbiosis Temperature Temperature effects Thermal resistance Thermal stress Water temperature
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creator	Viladrich, Núria Linares, Cristina Padilla‐Gamiño, Jacqueline L.
description	The frequency and severity of marine heatwaves causing mass mortality events in tropical and temperate coral species increases every year, with serious consequences on the stability and resilience of coral populations. Although recovery and persistence of coral populations after stress events is closely related to adult fitness, as well as larval survival and settlement, much remains unknown about the effects of thermal stress on early life‐history stages of temperate coral species. In the present study, the reproductive phenology and the effect of increased water temperature (+4°C and +6°C above ambient, 20°C) on larval survival and settlement was evaluated for two of the most representative Mediterranean octocoral species (Eunicella singularis and Corallium rubrum). Our study shows that reproductive behavior is more variable than previously reported and breeding period occurs over a longer period in both species. Thermal stress did not affect the survival of symbiotic E. singularis larvae but drastically reduced the survival of the non‐symbiotic C. rubrum larvae. Results on larval biomass and caloric consumption suggest that higher mortality rates of C. rubrum exposed to increased temperature were not related to depletion of endogenous energy in larvae. The results also show that settlement rates of E. singularis did not change in response to elevated temperature after 20 days of exposure, but larvae may settle fast and close to their native population at 26°C (+6°C). Although previous experimental studies found that adult colonies of both octocoral species are mostly resistant to thermal stress, our results on early life‐history stages suggest that the persistence and inter‐connectivity of local populations may be severely compromised under continued trends in ocean warming. The frequency and severity of marine heatwaves causing mass mortality events in tropical and temperate coral species increases every year, with serious consequences on the stability and resilience of coral populations. Although recovery and persistence of coral populations after stress events is closely related to adult fitness, as well as larval survival and settlement, much remains unknown about the effects of thermal stress on early life history stages of temperate coral species. Although previous experimental studies found that adult colonies of both octocoral species studied here are mostly resistant to thermal stress, our results on early life history stages suggest that the p
doi_str_mv	10.1111/gcb.16433
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Although recovery and persistence of coral populations after stress events is closely related to adult fitness, as well as larval survival and settlement, much remains unknown about the effects of thermal stress on early life‐history stages of temperate coral species. In the present study, the reproductive phenology and the effect of increased water temperature (+4°C and +6°C above ambient, 20°C) on larval survival and settlement was evaluated for two of the most representative Mediterranean octocoral species (Eunicella singularis and Corallium rubrum). Our study shows that reproductive behavior is more variable than previously reported and breeding period occurs over a longer period in both species. Thermal stress did not affect the survival of symbiotic E. singularis larvae but drastically reduced the survival of the non‐symbiotic C. rubrum larvae. Results on larval biomass and caloric consumption suggest that higher mortality rates of C. rubrum exposed to increased temperature were not related to depletion of endogenous energy in larvae. The results also show that settlement rates of E. singularis did not change in response to elevated temperature after 20 days of exposure, but larvae may settle fast and close to their native population at 26°C (+6°C). Although previous experimental studies found that adult colonies of both octocoral species are mostly resistant to thermal stress, our results on early life‐history stages suggest that the persistence and inter‐connectivity of local populations may be severely compromised under continued trends in ocean warming. The frequency and severity of marine heatwaves causing mass mortality events in tropical and temperate coral species increases every year, with serious consequences on the stability and resilience of coral populations. 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Although recovery and persistence of coral populations after stress events is closely related to adult fitness, as well as larval survival and settlement, much remains unknown about the effects of thermal stress on early life‐history stages of temperate coral species. In the present study, the reproductive phenology and the effect of increased water temperature (+4°C and +6°C above ambient, 20°C) on larval survival and settlement was evaluated for two of the most representative Mediterranean octocoral species (Eunicella singularis and Corallium rubrum). Our study shows that reproductive behavior is more variable than previously reported and breeding period occurs over a longer period in both species. Thermal stress did not affect the survival of symbiotic E. singularis larvae but drastically reduced the survival of the non‐symbiotic C. rubrum larvae. Results on larval biomass and caloric consumption suggest that higher mortality rates of C. rubrum exposed to increased temperature were not related to depletion of endogenous energy in larvae. The results also show that settlement rates of E. singularis did not change in response to elevated temperature after 20 days of exposure, but larvae may settle fast and close to their native population at 26°C (+6°C). Although previous experimental studies found that adult colonies of both octocoral species are mostly resistant to thermal stress, our results on early life‐history stages suggest that the persistence and inter‐connectivity of local populations may be severely compromised under continued trends in ocean warming. The frequency and severity of marine heatwaves causing mass mortality events in tropical and temperate coral species increases every year, with serious consequences on the stability and resilience of coral populations. Although recovery and persistence of coral populations after stress events is closely related to adult fitness, as well as larval survival and settlement, much remains unknown about the effects of thermal stress on early life history stages of temperate coral species. 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Although recovery and persistence of coral populations after stress events is closely related to adult fitness, as well as larval survival and settlement, much remains unknown about the effects of thermal stress on early life‐history stages of temperate coral species. In the present study, the reproductive phenology and the effect of increased water temperature (+4°C and +6°C above ambient, 20°C) on larval survival and settlement was evaluated for two of the most representative Mediterranean octocoral species (Eunicella singularis and Corallium rubrum). Our study shows that reproductive behavior is more variable than previously reported and breeding period occurs over a longer period in both species. Thermal stress did not affect the survival of symbiotic E. singularis larvae but drastically reduced the survival of the non‐symbiotic C. rubrum larvae. Results on larval biomass and caloric consumption suggest that higher mortality rates of C. rubrum exposed to increased temperature were not related to depletion of endogenous energy in larvae. The results also show that settlement rates of E. singularis did not change in response to elevated temperature after 20 days of exposure, but larvae may settle fast and close to their native population at 26°C (+6°C). Although previous experimental studies found that adult colonies of both octocoral species are mostly resistant to thermal stress, our results on early life‐history stages suggest that the persistence and inter‐connectivity of local populations may be severely compromised under continued trends in ocean warming. The frequency and severity of marine heatwaves causing mass mortality events in tropical and temperate coral species increases every year, with serious consequences on the stability and resilience of coral populations. Although recovery and persistence of coral populations after stress events is closely related to adult fitness, as well as larval survival and settlement, much remains unknown about the effects of thermal stress on early life history stages of temperate coral species. Although previous experimental studies found that adult colonies of both octocoral species studied here are mostly resistant to thermal stress, our results on early life history stages suggest that the persistence and inter‐connectivity of local populations may be severely compromised under continued trends in ocean warming.</abstract><cop>England</cop><pub>Blackwell Publishing Ltd</pub><pmid>36106689</pmid><doi>10.1111/gcb.16433</doi><tpages>14</tpages><orcidid>https://orcid.org/0000-0003-3855-2743</orcidid><orcidid>https://orcid.org/0000-0003-0478-9953</orcidid><orcidid>https://orcid.org/0000-0001-8456-4812</orcidid><oa>free_for_read</oa></addata></record>
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subjects	Animals Anthozoa - physiology Breeding brooding Colonies Coral Reefs Corals Depletion energetic consumption gorgonians Heat resistance Heat waves Heatwaves High temperature Larva Larvae Life Cycle Stages Local population marine heatwaves Marine invertebrates Mass mortality Mortality Ocean temperature Ocean warming Populations Reproductive behavior Reproductive behaviour reproductive phenology settlement Species Sublethal effects Survival Symbionts Symbiosis Temperature Temperature effects Thermal resistance Thermal stress Water temperature
title	Lethal and sublethal effects of thermal stress on octocorals early life‐history stages
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