Exoskeleton dissolution with mechanoreceptor damage in larval Dungeness crab related to severity of present-day ocean acidification vertical gradients

Ocean acidification (OA) along the US West Coast is intensifying faster than observed in the global ocean. This is particularly true in nearshore regions (<200 m) that experience a lower buffering capacity while at the same time providing important habitats for ecologically and economically signi...

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Published in:Science of The Total Environment
Main Authors: Bednaršek, Nina, Feely, Richard A., Beck, Marcus W., Alin, Simone R., Siedlecki, Samantha A., Calosi, Piero, Norton, Emily L., Saenger, Casey, Štrus, Jasna, Greeley, Dana, Nezlin, Nikolay P., Roethler, Miranda, Spicer, John I.
Format: Article in Journal/Newspaper
Language:French
Published: 2020
Subjects:
Ocean acidification
Online Access:https://semaphore.uqar.ca/id/eprint/2171/
https://semaphore.uqar.ca/id/eprint/2171/1/Nina_Bednarsek_et_al_mai2020.pdf
https://doi.org/10.1016/j.scitotenv.2020.136610
id ftunivquebecar:oai:semaphore.uqar.ca:2171
record_format openpolar
spelling ftunivquebecar:oai:semaphore.uqar.ca:2171 2023-11-05T03:44:27+01:00 Exoskeleton dissolution with mechanoreceptor damage in larval Dungeness crab related to severity of present-day ocean acidification vertical gradients Bednaršek, Nina Feely, Richard A. Beck, Marcus W. Alin, Simone R. Siedlecki, Samantha A. Calosi, Piero Norton, Emily L. Saenger, Casey Štrus, Jasna Greeley, Dana Nezlin, Nikolay P. Roethler, Miranda Spicer, John I. 2020-05 application/pdf https://semaphore.uqar.ca/id/eprint/2171/ https://semaphore.uqar.ca/id/eprint/2171/1/Nina_Bednarsek_et_al_mai2020.pdf https://doi.org/10.1016/j.scitotenv.2020.136610 fr fre https://semaphore.uqar.ca/id/eprint/2171/1/Nina_Bednarsek_et_al_mai2020.pdf Bednaršek, Nina, Feely, Richard A., Beck, Marcus W., Alin, Simone R., Siedlecki, Samantha A., Calosi, Piero orcid:0000-0003-3378-2603 , Norton, Emily L., Saenger, Casey, Štrus, Jasna, Greeley, Dana, Nezlin, Nikolay P., Roethler, Miranda et Spicer, John I. (2020). Exoskeleton dissolution with mechanoreceptor damage in larval Dungeness crab related to severity of present-day ocean acidification vertical gradients. Science of the Total Environment, 716 (136610). Article Évalué par les pairs 2020 ftunivquebecar https://doi.org/10.1016/j.scitotenv.2020.136610 2023-10-07T23:10:41Z Ocean acidification (OA) along the US West Coast is intensifying faster than observed in the global ocean. This is particularly true in nearshore regions (<200 m) that experience a lower buffering capacity while at the same time providing important habitats for ecologically and economically significant species. While the literature on the effects of OA from laboratory experiments is voluminous, there is little understanding of present-day OA in-situ effects on marine life. Dungeness crab (Metacarcinus magister) is perennially one of the most valuable commercial and recreational fisheries. We focused on establishing OA-related vulnerability of larval crustacean based on mineralogical and elemental carapace to external and internal carapace dissolution by using a combination of different methods ranging from scanning electron microscopy, energy dispersive X-ray spectroscopy, elemental mapping and X-ray diffraction. By integrating carapace features with the chemical observations and biogeochemical model hindcast, we identify the occurrence of external carapace dissolution related to the steepest Ω calcite gradients (∆Ωcal,60) in the water column. Dissolution features are observed across the carapace, pereopods (legs), and around the calcified areas surrounding neuritic canals of mechanoreceptors. The carapace dissolution is the most extensive in the coastal habitats under prolonged (1-month) long exposure, as demonstrated by the use of the model hindcast. Such dissolution has a potential to destabilize mechanoreceptors with important sensory and behavioral functions, a pathway of sensitivity to OA. Carapace dissolution is negatively related to crab larval width, demonstrating a basis for energetic trade-offs. Using a retrospective prediction from a regression models, we estimate an 8.3% increase in external carapace dissolution over the last two decades and identified a set of affected OA-related sublethal pathways to inform future risk assessment studies of Dungeness crabs. -- Keywords : Dungeness crab Larval ... Article in Journal/Newspaper Ocean acidification Université du Québec à Rimouski (UQAR): Sémaphore Science of The Total Environment 716 136610
institution Open Polar
collection Université du Québec à Rimouski (UQAR): Sémaphore
op_collection_id ftunivquebecar
language French
description Ocean acidification (OA) along the US West Coast is intensifying faster than observed in the global ocean. This is particularly true in nearshore regions (<200 m) that experience a lower buffering capacity while at the same time providing important habitats for ecologically and economically significant species. While the literature on the effects of OA from laboratory experiments is voluminous, there is little understanding of present-day OA in-situ effects on marine life. Dungeness crab (Metacarcinus magister) is perennially one of the most valuable commercial and recreational fisheries. We focused on establishing OA-related vulnerability of larval crustacean based on mineralogical and elemental carapace to external and internal carapace dissolution by using a combination of different methods ranging from scanning electron microscopy, energy dispersive X-ray spectroscopy, elemental mapping and X-ray diffraction. By integrating carapace features with the chemical observations and biogeochemical model hindcast, we identify the occurrence of external carapace dissolution related to the steepest Ω calcite gradients (∆Ωcal,60) in the water column. Dissolution features are observed across the carapace, pereopods (legs), and around the calcified areas surrounding neuritic canals of mechanoreceptors. The carapace dissolution is the most extensive in the coastal habitats under prolonged (1-month) long exposure, as demonstrated by the use of the model hindcast. Such dissolution has a potential to destabilize mechanoreceptors with important sensory and behavioral functions, a pathway of sensitivity to OA. Carapace dissolution is negatively related to crab larval width, demonstrating a basis for energetic trade-offs. Using a retrospective prediction from a regression models, we estimate an 8.3% increase in external carapace dissolution over the last two decades and identified a set of affected OA-related sublethal pathways to inform future risk assessment studies of Dungeness crabs. -- Keywords : Dungeness crab Larval ...
format Article in Journal/Newspaper
author Bednaršek, Nina
Feely, Richard A.
Beck, Marcus W.
Alin, Simone R.
Siedlecki, Samantha A.
Calosi, Piero
Norton, Emily L.
Saenger, Casey
Štrus, Jasna
Greeley, Dana
Nezlin, Nikolay P.
Roethler, Miranda
Spicer, John I.
spellingShingle Bednaršek, Nina
Feely, Richard A.
Beck, Marcus W.
Alin, Simone R.
Siedlecki, Samantha A.
Calosi, Piero
Norton, Emily L.
Saenger, Casey
Štrus, Jasna
Greeley, Dana
Nezlin, Nikolay P.
Roethler, Miranda
Spicer, John I.
Exoskeleton dissolution with mechanoreceptor damage in larval Dungeness crab related to severity of present-day ocean acidification vertical gradients
author_facet Bednaršek, Nina
Feely, Richard A.
Beck, Marcus W.
Alin, Simone R.
Siedlecki, Samantha A.
Calosi, Piero
Norton, Emily L.
Saenger, Casey
Štrus, Jasna
Greeley, Dana
Nezlin, Nikolay P.
Roethler, Miranda
Spicer, John I.
author_sort Bednaršek, Nina
title Exoskeleton dissolution with mechanoreceptor damage in larval Dungeness crab related to severity of present-day ocean acidification vertical gradients
title_short Exoskeleton dissolution with mechanoreceptor damage in larval Dungeness crab related to severity of present-day ocean acidification vertical gradients
title_full Exoskeleton dissolution with mechanoreceptor damage in larval Dungeness crab related to severity of present-day ocean acidification vertical gradients
title_fullStr Exoskeleton dissolution with mechanoreceptor damage in larval Dungeness crab related to severity of present-day ocean acidification vertical gradients
title_full_unstemmed Exoskeleton dissolution with mechanoreceptor damage in larval Dungeness crab related to severity of present-day ocean acidification vertical gradients
title_sort exoskeleton dissolution with mechanoreceptor damage in larval dungeness crab related to severity of present-day ocean acidification vertical gradients
publishDate 2020
url https://semaphore.uqar.ca/id/eprint/2171/
https://semaphore.uqar.ca/id/eprint/2171/1/Nina_Bednarsek_et_al_mai2020.pdf
https://doi.org/10.1016/j.scitotenv.2020.136610
genre Ocean acidification
genre_facet Ocean acidification
op_relation https://semaphore.uqar.ca/id/eprint/2171/1/Nina_Bednarsek_et_al_mai2020.pdf
Bednaršek, Nina, Feely, Richard A., Beck, Marcus W., Alin, Simone R., Siedlecki, Samantha A., Calosi, Piero orcid:0000-0003-3378-2603 , Norton, Emily L., Saenger, Casey, Štrus, Jasna, Greeley, Dana, Nezlin, Nikolay P., Roethler, Miranda et Spicer, John I. (2020). Exoskeleton dissolution with mechanoreceptor damage in larval Dungeness crab related to severity of present-day ocean acidification vertical gradients. Science of the Total Environment, 716 (136610).
op_doi https://doi.org/10.1016/j.scitotenv.2020.136610
container_title Science of The Total Environment
container_volume 716
container_start_page 136610
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