Modelling coral polyp calcification in relation to ocean acidification
Rising atmospheric CO2 concentrations due to anthropogenic emissions induce changes in the carbonate chemistry of the oceans and, ultimately, a drop in ocean pH. This acidification process can harm calcifying organisms like coccolithophores, molluscs, echinoderms, and corals. It is expected that oce...
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ftzbmed:oai:frl.publisso.de:frl:6404652 2023-10-09T21:54:50+02:00 Modelling coral polyp calcification in relation to ocean acidification Hohn, Sönke Merico, Agostino 2012 https://repository.publisso.de/resource/frl:6404652 https://doi.org/10.5194/bg-9-4441-2012 eng eng https://repository.publisso.de/resource/frl:6404652 https://doi.org/10.5194/bg-9-4441-2012 https://creativecommons.org/licenses/by/3.0/ Biogeosciences, 9(11): 4441-4454 pCO2 Atmospheric CO2 concentrations calcium carbonate coral polyp Zeitschriftenartikel 2012 ftzbmed https://doi.org/10.5194/bg-9-4441-2012 2023-09-10T22:07:24Z Rising atmospheric CO2 concentrations due to anthropogenic emissions induce changes in the carbonate chemistry of the oceans and, ultimately, a drop in ocean pH. This acidification process can harm calcifying organisms like coccolithophores, molluscs, echinoderms, and corals. It is expected that ocean acidification in combination with other anthropogenic stressors will cause a severe decline in coral abundance by the end of this century, with associated disastrous effects on reef ecosystems. Despite the growing importance of the topic, little progress has been made with respect to modelling the impact of acidification on coral calcification. Here we present a model for a coral polyp that simulates the carbonate system in four different compartments: the seawater, the polyp tissue, the coelenteron, and the calcifying fluid. Precipitation of calcium carbonate takes place in the metabolically controlled calcifying fluid beneath the polyp tissue. The model is adjusted to a state of activity as observed by direct microsensor measurements in the calcifying fluid. We find that a transport mechanism for bicarbonate is required to supplement carbon into the calcifying fluid because CO2 diffusion alone is not sufficient to sustain the observed calcification rates. Simulated CO2 perturbation experiments reveal decreasing calcification rates under elevated pCO2 despite the strong metabolic control of the calcifying fluid. Diffusion of CO2 through the tissue into the calcifying fluid increases with increasing seawater pCO2, leading to decreased aragonite saturation in the calcifying fluid. Our modelling study provides important insights into the complexity of the calcification process at the organism level and helps to quantify the effect of ocean acidification on corals. Article in Journal/Newspaper Ocean acidification PUBLISSO Fachrepositorium Lebenswissenschaften (ZB MED) Biogeosciences 9 11 4441 4454 |
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PUBLISSO Fachrepositorium Lebenswissenschaften (ZB MED) |
op_collection_id |
ftzbmed |
language |
English |
topic |
pCO2 Atmospheric CO2 concentrations calcium carbonate coral polyp |
spellingShingle |
pCO2 Atmospheric CO2 concentrations calcium carbonate coral polyp Hohn, Sönke Merico, Agostino Modelling coral polyp calcification in relation to ocean acidification |
topic_facet |
pCO2 Atmospheric CO2 concentrations calcium carbonate coral polyp |
description |
Rising atmospheric CO2 concentrations due to anthropogenic emissions induce changes in the carbonate chemistry of the oceans and, ultimately, a drop in ocean pH. This acidification process can harm calcifying organisms like coccolithophores, molluscs, echinoderms, and corals. It is expected that ocean acidification in combination with other anthropogenic stressors will cause a severe decline in coral abundance by the end of this century, with associated disastrous effects on reef ecosystems. Despite the growing importance of the topic, little progress has been made with respect to modelling the impact of acidification on coral calcification. Here we present a model for a coral polyp that simulates the carbonate system in four different compartments: the seawater, the polyp tissue, the coelenteron, and the calcifying fluid. Precipitation of calcium carbonate takes place in the metabolically controlled calcifying fluid beneath the polyp tissue. The model is adjusted to a state of activity as observed by direct microsensor measurements in the calcifying fluid. We find that a transport mechanism for bicarbonate is required to supplement carbon into the calcifying fluid because CO2 diffusion alone is not sufficient to sustain the observed calcification rates. Simulated CO2 perturbation experiments reveal decreasing calcification rates under elevated pCO2 despite the strong metabolic control of the calcifying fluid. Diffusion of CO2 through the tissue into the calcifying fluid increases with increasing seawater pCO2, leading to decreased aragonite saturation in the calcifying fluid. Our modelling study provides important insights into the complexity of the calcification process at the organism level and helps to quantify the effect of ocean acidification on corals. |
format |
Article in Journal/Newspaper |
author |
Hohn, Sönke Merico, Agostino |
author_facet |
Hohn, Sönke Merico, Agostino |
author_sort |
Hohn, Sönke |
title |
Modelling coral polyp calcification in relation to ocean acidification |
title_short |
Modelling coral polyp calcification in relation to ocean acidification |
title_full |
Modelling coral polyp calcification in relation to ocean acidification |
title_fullStr |
Modelling coral polyp calcification in relation to ocean acidification |
title_full_unstemmed |
Modelling coral polyp calcification in relation to ocean acidification |
title_sort |
modelling coral polyp calcification in relation to ocean acidification |
publishDate |
2012 |
url |
https://repository.publisso.de/resource/frl:6404652 https://doi.org/10.5194/bg-9-4441-2012 |
genre |
Ocean acidification |
genre_facet |
Ocean acidification |
op_source |
Biogeosciences, 9(11): 4441-4454 |
op_relation |
https://repository.publisso.de/resource/frl:6404652 https://doi.org/10.5194/bg-9-4441-2012 |
op_rights |
https://creativecommons.org/licenses/by/3.0/ |
op_doi |
https://doi.org/10.5194/bg-9-4441-2012 |
container_title |
Biogeosciences |
container_volume |
9 |
container_issue |
11 |
container_start_page |
4441 |
op_container_end_page |
4454 |
_version_ |
1779318543723003904 |