Modelling paralytic shellfish toxins (PST) accumulation in Crassostrea gigas by using Dynamic Energy Budgets (DEB)

As other filter-feeders, Crassostrea gigas can concentrate paralytic shellfish toxins (PST) by consuming dinoflagellate phytoplankton species like Alexandrium minutum. Intake of PST in oyster tissues mainly results from feeding processes, i.e. clearance rate, pre-ingestive sorting and ingestion that...

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Main Authors: Pousse, Emilien, Flye-Sainte-Marie, Jonathan, Alunno-Bruscia, Marianne, Hegaret, Helene, Rannou, Eric, Pecquerie, Laure, Marques, Goncalo M, Thomas, Yoann, Castrec, Justine, Fabioux, Caroline, Long, Marc, Lassudrie, Malwenn, Hermabessiere, Ludovic, Amzil, Zouher, Soudant, Philippe, Jean, Fred
Format: Article in Journal/Newspaper
Language:unknown
Published: Research Online 2018
Subjects:
Crassostrea gigas
Online Access:https://ro.uow.edu.au/smhpapers1/253
https://ro.uow.edu.au/cgi/viewcontent.cgi?article=1257&context=smhpapers1
id ftunivwollongong:oai:ro.uow.edu.au:smhpapers1-1257
record_format openpolar
spelling ftunivwollongong:oai:ro.uow.edu.au:smhpapers1-1257 2023-05-15T15:58:28+02:00 Modelling paralytic shellfish toxins (PST) accumulation in Crassostrea gigas by using Dynamic Energy Budgets (DEB) Pousse, Emilien Flye-Sainte-Marie, Jonathan Alunno-Bruscia, Marianne Hegaret, Helene Rannou, Eric Pecquerie, Laure Marques, Goncalo M Thomas, Yoann Castrec, Justine Fabioux, Caroline Long, Marc Lassudrie, Malwenn Hermabessiere, Ludovic Amzil, Zouher Soudant, Philippe Jean, Fred 2018-01-01T08:00:00Z application/pdf https://ro.uow.edu.au/smhpapers1/253 https://ro.uow.edu.au/cgi/viewcontent.cgi?article=1257&context=smhpapers1 unknown Research Online https://ro.uow.edu.au/smhpapers1/253 https://ro.uow.edu.au/cgi/viewcontent.cgi?article=1257&context=smhpapers1 Faculty of Science, Medicine and Health - Papers: Part B article 2018 ftunivwollongong 2021-08-23T22:24:38Z As other filter-feeders, Crassostrea gigas can concentrate paralytic shellfish toxins (PST) by consuming dinoflagellate phytoplankton species like Alexandrium minutum. Intake of PST in oyster tissues mainly results from feeding processes, i.e. clearance rate, pre-ingestive sorting and ingestion that are directly influenced by environmental conditions (trophic sources, temperature). This study aimed to develop a mechanistic model coupling the kinetics of PST accumulation and bioenergetics in C. gigas based on Dynamic Energy Budget (DEB) theory. For the first time, the Synthesizing Units (SU) concept was applied to formalize the feeding preference of oysters between non-toxic and toxic microalgae. Toxin intake and accumulation were both dependent on the physiological status of oysters. The accumulation was modelled through the dynamics of two toxin compartments: (1) a compartment of ingested but non-assimilated toxins, with labile toxins within the digestive gland eliminated via faeces production; (2) a compartment of assimilated toxins with a rapid detoxification rate (within a few days). Firstly, the DEB-PST model was calibrated using data from two laboratory experiments where oysters have been exposed to A. minutum. Secondly, it was validated using data from another laboratory experiment and from three field surveys carried out in the Bay of Brest (France) from 2012 to 2014. To account for the variability in PST content of A. minutum cells, the saxitoxin (STX) amount per energy units in a toxic algae (ρPST) was adjusted for each dataset. Additionally, the effects of PST on the oyster bioenergetics were calibrated during the first laboratory experiment. However, these effects were shown to depend on the strain of A. minutum. Results of this study could be of great importance for monitoring agencies and decision makers to identify risky conditions (e.g. production areas, seawater temperature), to properly assess detoxification step (e.g. duration, modalities) before any commercialization or to improve predictions regarding closing of shellfish areas. Article in Journal/Newspaper Crassostrea gigas University of Wollongong, Australia: Research Online
institution Open Polar
collection University of Wollongong, Australia: Research Online
op_collection_id ftunivwollongong
language unknown
description As other filter-feeders, Crassostrea gigas can concentrate paralytic shellfish toxins (PST) by consuming dinoflagellate phytoplankton species like Alexandrium minutum. Intake of PST in oyster tissues mainly results from feeding processes, i.e. clearance rate, pre-ingestive sorting and ingestion that are directly influenced by environmental conditions (trophic sources, temperature). This study aimed to develop a mechanistic model coupling the kinetics of PST accumulation and bioenergetics in C. gigas based on Dynamic Energy Budget (DEB) theory. For the first time, the Synthesizing Units (SU) concept was applied to formalize the feeding preference of oysters between non-toxic and toxic microalgae. Toxin intake and accumulation were both dependent on the physiological status of oysters. The accumulation was modelled through the dynamics of two toxin compartments: (1) a compartment of ingested but non-assimilated toxins, with labile toxins within the digestive gland eliminated via faeces production; (2) a compartment of assimilated toxins with a rapid detoxification rate (within a few days). Firstly, the DEB-PST model was calibrated using data from two laboratory experiments where oysters have been exposed to A. minutum. Secondly, it was validated using data from another laboratory experiment and from three field surveys carried out in the Bay of Brest (France) from 2012 to 2014. To account for the variability in PST content of A. minutum cells, the saxitoxin (STX) amount per energy units in a toxic algae (ρPST) was adjusted for each dataset. Additionally, the effects of PST on the oyster bioenergetics were calibrated during the first laboratory experiment. However, these effects were shown to depend on the strain of A. minutum. Results of this study could be of great importance for monitoring agencies and decision makers to identify risky conditions (e.g. production areas, seawater temperature), to properly assess detoxification step (e.g. duration, modalities) before any commercialization or to improve predictions regarding closing of shellfish areas.
format Article in Journal/Newspaper
author Pousse, Emilien
Flye-Sainte-Marie, Jonathan
Alunno-Bruscia, Marianne
Hegaret, Helene
Rannou, Eric
Pecquerie, Laure
Marques, Goncalo M
Thomas, Yoann
Castrec, Justine
Fabioux, Caroline
Long, Marc
Lassudrie, Malwenn
Hermabessiere, Ludovic
Amzil, Zouher
Soudant, Philippe
Jean, Fred
spellingShingle Pousse, Emilien
Flye-Sainte-Marie, Jonathan
Alunno-Bruscia, Marianne
Hegaret, Helene
Rannou, Eric
Pecquerie, Laure
Marques, Goncalo M
Thomas, Yoann
Castrec, Justine
Fabioux, Caroline
Long, Marc
Lassudrie, Malwenn
Hermabessiere, Ludovic
Amzil, Zouher
Soudant, Philippe
Jean, Fred
Modelling paralytic shellfish toxins (PST) accumulation in Crassostrea gigas by using Dynamic Energy Budgets (DEB)
author_facet Pousse, Emilien
Flye-Sainte-Marie, Jonathan
Alunno-Bruscia, Marianne
Hegaret, Helene
Rannou, Eric
Pecquerie, Laure
Marques, Goncalo M
Thomas, Yoann
Castrec, Justine
Fabioux, Caroline
Long, Marc
Lassudrie, Malwenn
Hermabessiere, Ludovic
Amzil, Zouher
Soudant, Philippe
Jean, Fred
author_sort Pousse, Emilien
title Modelling paralytic shellfish toxins (PST) accumulation in Crassostrea gigas by using Dynamic Energy Budgets (DEB)
title_short Modelling paralytic shellfish toxins (PST) accumulation in Crassostrea gigas by using Dynamic Energy Budgets (DEB)
title_full Modelling paralytic shellfish toxins (PST) accumulation in Crassostrea gigas by using Dynamic Energy Budgets (DEB)
title_fullStr Modelling paralytic shellfish toxins (PST) accumulation in Crassostrea gigas by using Dynamic Energy Budgets (DEB)
title_full_unstemmed Modelling paralytic shellfish toxins (PST) accumulation in Crassostrea gigas by using Dynamic Energy Budgets (DEB)
title_sort modelling paralytic shellfish toxins (pst) accumulation in crassostrea gigas by using dynamic energy budgets (deb)
publisher Research Online
publishDate 2018
url https://ro.uow.edu.au/smhpapers1/253
https://ro.uow.edu.au/cgi/viewcontent.cgi?article=1257&context=smhpapers1
genre Crassostrea gigas
genre_facet Crassostrea gigas
op_source Faculty of Science, Medicine and Health - Papers: Part B
op_relation https://ro.uow.edu.au/smhpapers1/253
https://ro.uow.edu.au/cgi/viewcontent.cgi?article=1257&context=smhpapers1
_version_ 1766394208376061952

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