Photosynthetically stimulated bioerosion in symbiotic sponges : the role of glycerol and oxygen

On coral reefs, some of the most aggressive calcium carbonate eroders are dinoflagellate-hosting sponges of the genus Cliona. Like in other marine taxa, the influence of these symbiotic microorganisms on the metabolism of the host sponge, and thereby on erosion of the surrounding ecosystem, is increasingly acknowledged. Despite elevating pH (and hence carbonate saturation state), dinoflagellate photosynthesis promotes bioerosion by their hosts. This paradox might be solved by a spatial isolation of photosynthesis from carbonate dissolution, but it remains unknown which mechanism connects the dinoflagellates’ photosynthesis with the sponge’s bioerosion. Here, we simulate the outcomes of photosynthesis in two separate ways, namely as production of carbon-rich compounds (in this case glycerol) and as an increase in oxygen content. This allows testing their potential to enhance bioerosion rates of sponge holobionts that were preconditioned under variable photosynthetic regimes. We find that glycerol, a commonly shared photosynthate in marine symbioses, stimulates chemical bioerosion rates in the dark of photosynthetically impaired sponges. Chemical bioerosion was all the more limited by availability of sufficient oxygen, while the combination of added glycerol and oxygen boosted chemical bioerosion rates. We argue that under normal physiological conditions, bioerosion is promoted by both organic carbon and oxygen production, and we provide evidence for the storage of photosynthates for night-time use. We further discuss our findings in the context of the current knowledge of the bioerosion mechanism, which we expand by integrating the effects of carbon-rich compounds and oxygen as drivers for bioerosion by Cliona.

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Main Authors: Achlatis, Michelle, van der Zande, Rene M., Webb, Alice E., de Bakker, Didier M., de Nooijer, Lennart J., de Goeij, Jasper M.
Format: Article/Letter to editor biblioteca
Language:English
Subjects:Bioerosion, Cliona, Glycerol, Oxygen, Photosynthesis, Symbiodiniaceae,
Online Access:https://research.wur.nl/en/publications/photosynthetically-stimulated-bioerosion-in-symbiotic-sponges-the
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spelling dig-wur-nl-wurpubs-5828942024-12-04 Achlatis, Michelle van der Zande, Rene M. Webb, Alice E. de Bakker, Didier M. de Nooijer, Lennart J. de Goeij, Jasper M. Article/Letter to editor Coral Reefs 40 (2021) ISSN: 0722-4028 Photosynthetically stimulated bioerosion in symbiotic sponges : the role of glycerol and oxygen 2021 On coral reefs, some of the most aggressive calcium carbonate eroders are dinoflagellate-hosting sponges of the genus Cliona. Like in other marine taxa, the influence of these symbiotic microorganisms on the metabolism of the host sponge, and thereby on erosion of the surrounding ecosystem, is increasingly acknowledged. Despite elevating pH (and hence carbonate saturation state), dinoflagellate photosynthesis promotes bioerosion by their hosts. This paradox might be solved by a spatial isolation of photosynthesis from carbonate dissolution, but it remains unknown which mechanism connects the dinoflagellates’ photosynthesis with the sponge’s bioerosion. Here, we simulate the outcomes of photosynthesis in two separate ways, namely as production of carbon-rich compounds (in this case glycerol) and as an increase in oxygen content. This allows testing their potential to enhance bioerosion rates of sponge holobionts that were preconditioned under variable photosynthetic regimes. We find that glycerol, a commonly shared photosynthate in marine symbioses, stimulates chemical bioerosion rates in the dark of photosynthetically impaired sponges. Chemical bioerosion was all the more limited by availability of sufficient oxygen, while the combination of added glycerol and oxygen boosted chemical bioerosion rates. We argue that under normal physiological conditions, bioerosion is promoted by both organic carbon and oxygen production, and we provide evidence for the storage of photosynthates for night-time use. We further discuss our findings in the context of the current knowledge of the bioerosion mechanism, which we expand by integrating the effects of carbon-rich compounds and oxygen as drivers for bioerosion by Cliona. en application/pdf https://research.wur.nl/en/publications/photosynthetically-stimulated-bioerosion-in-symbiotic-sponges-the 10.1007/s00338-021-02091-0 https://edepot.wur.nl/547719 Bioerosion Cliona Glycerol Oxygen Photosynthesis Symbiodiniaceae https://creativecommons.org/licenses/by/4.0/ https://creativecommons.org/licenses/by/4.0/ Wageningen University & Research
institution WUR NL
collection DSpace
country Países bajos
countrycode NL
component Bibliográfico
access En linea
databasecode dig-wur-nl
tag biblioteca
region Europa del Oeste
libraryname WUR Library Netherlands
language English
topic Bioerosion
Cliona
Glycerol
Oxygen
Photosynthesis
Symbiodiniaceae
Bioerosion
Cliona
Glycerol
Oxygen
Photosynthesis
Symbiodiniaceae
spellingShingle Bioerosion
Cliona
Glycerol
Oxygen
Photosynthesis
Symbiodiniaceae
Bioerosion
Cliona
Glycerol
Oxygen
Photosynthesis
Symbiodiniaceae
Achlatis, Michelle
van der Zande, Rene M.
Webb, Alice E.
de Bakker, Didier M.
de Nooijer, Lennart J.
de Goeij, Jasper M.
Photosynthetically stimulated bioerosion in symbiotic sponges : the role of glycerol and oxygen
description On coral reefs, some of the most aggressive calcium carbonate eroders are dinoflagellate-hosting sponges of the genus Cliona. Like in other marine taxa, the influence of these symbiotic microorganisms on the metabolism of the host sponge, and thereby on erosion of the surrounding ecosystem, is increasingly acknowledged. Despite elevating pH (and hence carbonate saturation state), dinoflagellate photosynthesis promotes bioerosion by their hosts. This paradox might be solved by a spatial isolation of photosynthesis from carbonate dissolution, but it remains unknown which mechanism connects the dinoflagellates’ photosynthesis with the sponge’s bioerosion. Here, we simulate the outcomes of photosynthesis in two separate ways, namely as production of carbon-rich compounds (in this case glycerol) and as an increase in oxygen content. This allows testing their potential to enhance bioerosion rates of sponge holobionts that were preconditioned under variable photosynthetic regimes. We find that glycerol, a commonly shared photosynthate in marine symbioses, stimulates chemical bioerosion rates in the dark of photosynthetically impaired sponges. Chemical bioerosion was all the more limited by availability of sufficient oxygen, while the combination of added glycerol and oxygen boosted chemical bioerosion rates. We argue that under normal physiological conditions, bioerosion is promoted by both organic carbon and oxygen production, and we provide evidence for the storage of photosynthates for night-time use. We further discuss our findings in the context of the current knowledge of the bioerosion mechanism, which we expand by integrating the effects of carbon-rich compounds and oxygen as drivers for bioerosion by Cliona.
format Article/Letter to editor
topic_facet Bioerosion
Cliona
Glycerol
Oxygen
Photosynthesis
Symbiodiniaceae
author Achlatis, Michelle
van der Zande, Rene M.
Webb, Alice E.
de Bakker, Didier M.
de Nooijer, Lennart J.
de Goeij, Jasper M.
author_facet Achlatis, Michelle
van der Zande, Rene M.
Webb, Alice E.
de Bakker, Didier M.
de Nooijer, Lennart J.
de Goeij, Jasper M.
author_sort Achlatis, Michelle
title Photosynthetically stimulated bioerosion in symbiotic sponges : the role of glycerol and oxygen
title_short Photosynthetically stimulated bioerosion in symbiotic sponges : the role of glycerol and oxygen
title_full Photosynthetically stimulated bioerosion in symbiotic sponges : the role of glycerol and oxygen
title_fullStr Photosynthetically stimulated bioerosion in symbiotic sponges : the role of glycerol and oxygen
title_full_unstemmed Photosynthetically stimulated bioerosion in symbiotic sponges : the role of glycerol and oxygen
title_sort photosynthetically stimulated bioerosion in symbiotic sponges : the role of glycerol and oxygen
url https://research.wur.nl/en/publications/photosynthetically-stimulated-bioerosion-in-symbiotic-sponges-the
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