Image_1_El Niño-Related Thermal Stress Coupled With Upwelling-Related Ocean Acidification Negatively Impacts Cellular to Population-Level Responses in Pteropods Along the California Current System With Implications for Increased Bioenergetic Costs.PNG
Understanding the interactive effects of multiple stressors on pelagic mollusks associated with global climate change is especially important in highly productive coastal ecosystems of the upwelling regime, such as the California Current System (CCS). Due to temporal overlap between a marine heatwav...
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ftfrontimediafig:oai:figshare.com:article/7453241 2023-05-15T17:51:05+02:00 Image_1_El Niño-Related Thermal Stress Coupled With Upwelling-Related Ocean Acidification Negatively Impacts Cellular to Population-Level Responses in Pteropods Along the California Current System With Implications for Increased Bioenergetic Costs.PNG Nina Bednaršek Richard A. Feely Marcus W. Beck Olivier Glippa Mirella Kanerva Jonna Engström-Öst 2018-12-12T04:02:48Z https://doi.org/10.3389/fmars.2018.00486.s001 https://figshare.com/articles/Image_1_El_Ni_o-Related_Thermal_Stress_Coupled_With_Upwelling-Related_Ocean_Acidification_Negatively_Impacts_Cellular_to_Population-Level_Responses_in_Pteropods_Along_the_California_Current_System_With_Implications_for_Increased_Bioenergetic_Costs_PNG/7453241 unknown doi:10.3389/fmars.2018.00486.s001 https://figshare.com/articles/Image_1_El_Ni_o-Related_Thermal_Stress_Coupled_With_Upwelling-Related_Ocean_Acidification_Negatively_Impacts_Cellular_to_Population-Level_Responses_in_Pteropods_Along_the_California_Current_System_With_Implications_for_Increased_Bioenergetic_Costs_PNG/7453241 CC BY 4.0 CC-BY Oceanography Marine Biology Marine Geoscience Biological Oceanography Chemical Oceanography Physical Oceanography Marine Engineering El Niño coastal ecosystem pelagic mollusks oxidative stress ocean acidification interaction effects antioxidant defense strategies bioenergetics Image Figure 2018 ftfrontimediafig https://doi.org/10.3389/fmars.2018.00486.s001 2018-12-12T23:58:29Z Understanding the interactive effects of multiple stressors on pelagic mollusks associated with global climate change is especially important in highly productive coastal ecosystems of the upwelling regime, such as the California Current System (CCS). Due to temporal overlap between a marine heatwave, an El Niño event, and springtime intensification of the upwelling, pteropods of the CCS were exposed to co-occurring increased temperature, low Ω ar and pH, and deoxygenation. The variability in the natural gradients during NOAA’s WCOA 2016 cruise provided a unique opportunity for synoptic study of chemical and biological interactions. We investigated the effects of in situ multiple drivers and their interactions across cellular, physiological, and population levels. Oxidative stress biomarkers were used to assess pteropods’ cellular status and antioxidant defenses. Low aragonite saturation state (Ω ar ) is associated with significant activation of oxidative stress biomarkers, as indicated by increased levels of lipid peroxidation (LPX), but the antioxidative activity defense might be insufficient against cellular stress. Thermal stress in combination with low Ω ar additively increases the level of LPX toxicity, while food availability can mediate the negative effect. On the physiological level, we found synergistic interaction between low Ω ar and deoxygenation and thermal stress (Ω ar :T, O 2 :T). On the population level, temperature was the main driver of abundance distribution, with low Ω ar being a strong driver of secondary importance. The additive effects of thermal stress and low Ω ar on abundance suggest a negative effect of El Niño at the population level. Our study clearly demonstrates Ω ar and temperature are master variables in explaining biological responses, cautioning the use of a single parameter in the statistical analyses. High quantities of polyunsaturated fatty acids are susceptible to oxidative stress because of LPX, resulting in the loss of lipid reserves and structural damage to cell ... Still Image Ocean acidification Frontiers: Figshare |
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Open Polar |
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Frontiers: Figshare |
op_collection_id |
ftfrontimediafig |
language |
unknown |
topic |
Oceanography Marine Biology Marine Geoscience Biological Oceanography Chemical Oceanography Physical Oceanography Marine Engineering El Niño coastal ecosystem pelagic mollusks oxidative stress ocean acidification interaction effects antioxidant defense strategies bioenergetics |
spellingShingle |
Oceanography Marine Biology Marine Geoscience Biological Oceanography Chemical Oceanography Physical Oceanography Marine Engineering El Niño coastal ecosystem pelagic mollusks oxidative stress ocean acidification interaction effects antioxidant defense strategies bioenergetics Nina Bednaršek Richard A. Feely Marcus W. Beck Olivier Glippa Mirella Kanerva Jonna Engström-Öst Image_1_El Niño-Related Thermal Stress Coupled With Upwelling-Related Ocean Acidification Negatively Impacts Cellular to Population-Level Responses in Pteropods Along the California Current System With Implications for Increased Bioenergetic Costs.PNG |
topic_facet |
Oceanography Marine Biology Marine Geoscience Biological Oceanography Chemical Oceanography Physical Oceanography Marine Engineering El Niño coastal ecosystem pelagic mollusks oxidative stress ocean acidification interaction effects antioxidant defense strategies bioenergetics |
description |
Understanding the interactive effects of multiple stressors on pelagic mollusks associated with global climate change is especially important in highly productive coastal ecosystems of the upwelling regime, such as the California Current System (CCS). Due to temporal overlap between a marine heatwave, an El Niño event, and springtime intensification of the upwelling, pteropods of the CCS were exposed to co-occurring increased temperature, low Ω ar and pH, and deoxygenation. The variability in the natural gradients during NOAA’s WCOA 2016 cruise provided a unique opportunity for synoptic study of chemical and biological interactions. We investigated the effects of in situ multiple drivers and their interactions across cellular, physiological, and population levels. Oxidative stress biomarkers were used to assess pteropods’ cellular status and antioxidant defenses. Low aragonite saturation state (Ω ar ) is associated with significant activation of oxidative stress biomarkers, as indicated by increased levels of lipid peroxidation (LPX), but the antioxidative activity defense might be insufficient against cellular stress. Thermal stress in combination with low Ω ar additively increases the level of LPX toxicity, while food availability can mediate the negative effect. On the physiological level, we found synergistic interaction between low Ω ar and deoxygenation and thermal stress (Ω ar :T, O 2 :T). On the population level, temperature was the main driver of abundance distribution, with low Ω ar being a strong driver of secondary importance. The additive effects of thermal stress and low Ω ar on abundance suggest a negative effect of El Niño at the population level. Our study clearly demonstrates Ω ar and temperature are master variables in explaining biological responses, cautioning the use of a single parameter in the statistical analyses. High quantities of polyunsaturated fatty acids are susceptible to oxidative stress because of LPX, resulting in the loss of lipid reserves and structural damage to cell ... |
format |
Still Image |
author |
Nina Bednaršek Richard A. Feely Marcus W. Beck Olivier Glippa Mirella Kanerva Jonna Engström-Öst |
author_facet |
Nina Bednaršek Richard A. Feely Marcus W. Beck Olivier Glippa Mirella Kanerva Jonna Engström-Öst |
author_sort |
Nina Bednaršek |
title |
Image_1_El Niño-Related Thermal Stress Coupled With Upwelling-Related Ocean Acidification Negatively Impacts Cellular to Population-Level Responses in Pteropods Along the California Current System With Implications for Increased Bioenergetic Costs.PNG |
title_short |
Image_1_El Niño-Related Thermal Stress Coupled With Upwelling-Related Ocean Acidification Negatively Impacts Cellular to Population-Level Responses in Pteropods Along the California Current System With Implications for Increased Bioenergetic Costs.PNG |
title_full |
Image_1_El Niño-Related Thermal Stress Coupled With Upwelling-Related Ocean Acidification Negatively Impacts Cellular to Population-Level Responses in Pteropods Along the California Current System With Implications for Increased Bioenergetic Costs.PNG |
title_fullStr |
Image_1_El Niño-Related Thermal Stress Coupled With Upwelling-Related Ocean Acidification Negatively Impacts Cellular to Population-Level Responses in Pteropods Along the California Current System With Implications for Increased Bioenergetic Costs.PNG |
title_full_unstemmed |
Image_1_El Niño-Related Thermal Stress Coupled With Upwelling-Related Ocean Acidification Negatively Impacts Cellular to Population-Level Responses in Pteropods Along the California Current System With Implications for Increased Bioenergetic Costs.PNG |
title_sort |
image_1_el niño-related thermal stress coupled with upwelling-related ocean acidification negatively impacts cellular to population-level responses in pteropods along the california current system with implications for increased bioenergetic costs.png |
publishDate |
2018 |
url |
https://doi.org/10.3389/fmars.2018.00486.s001 https://figshare.com/articles/Image_1_El_Ni_o-Related_Thermal_Stress_Coupled_With_Upwelling-Related_Ocean_Acidification_Negatively_Impacts_Cellular_to_Population-Level_Responses_in_Pteropods_Along_the_California_Current_System_With_Implications_for_Increased_Bioenergetic_Costs_PNG/7453241 |
genre |
Ocean acidification |
genre_facet |
Ocean acidification |
op_relation |
doi:10.3389/fmars.2018.00486.s001 https://figshare.com/articles/Image_1_El_Ni_o-Related_Thermal_Stress_Coupled_With_Upwelling-Related_Ocean_Acidification_Negatively_Impacts_Cellular_to_Population-Level_Responses_in_Pteropods_Along_the_California_Current_System_With_Implications_for_Increased_Bioenergetic_Costs_PNG/7453241 |
op_rights |
CC BY 4.0 |
op_rightsnorm |
CC-BY |
op_doi |
https://doi.org/10.3389/fmars.2018.00486.s001 |
_version_ |
1766158094238220288 |