Interactive effects of temperature, food and skeletal mineralogy mediate biological responses to ocean acidification in a widely distributed bryozoan

Marine invertebrates with skeletons made of high-magnesium calcite may be especially susceptible to ocean acidification (OA) due to the elevated solubility of this form of calcium carbonate. However, skeletal composition can vary plastically within some species, and it is largely unknown how concurr...

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Main Authors: Swezey, Daniel S, Bean, Jessica R, Ninokawa, Aaron T, Hill, Tessa M, Gaylord, Brian, Sanford, Eric
Format: Article in Journal/Newspaper
Language:unknown
Published: eScholarship, University of California 2017
Subjects:
Life Below Water
Animals
Bryozoa
Calcium Carbonate
California
Carbon Dioxide
Food
Magnesium
Oceans and Seas
Seawater
calcification
global environmental change
magnesium regulation
phenotypic plasticity
bryozoan
colonial marine invertebrates
Biological Sciences
Agricultural and Veterinary Sciences
Medical and Health Sciences
Ocean acidification
Online Access:https://escholarship.org/uc/item/95f0k4kj
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spelling ftcdlib:oai:escholarship.org:ark:/13030/qt95f0k4kj 2023-09-05T13:22:12+02:00 Interactive effects of temperature, food and skeletal mineralogy mediate biological responses to ocean acidification in a widely distributed bryozoan Swezey, Daniel S Bean, Jessica R Ninokawa, Aaron T Hill, Tessa M Gaylord, Brian Sanford, Eric 20162349 2017-04-26 application/pdf https://escholarship.org/uc/item/95f0k4kj unknown eScholarship, University of California qt95f0k4kj https://escholarship.org/uc/item/95f0k4kj public Proceedings of the Royal Society B, vol 284, iss 1853 Life Below Water Animals Bryozoa Calcium Carbonate California Carbon Dioxide Food Magnesium Oceans and Seas Seawater calcification global environmental change magnesium regulation phenotypic plasticity bryozoan colonial marine invertebrates Biological Sciences Agricultural and Veterinary Sciences Medical and Health Sciences article 2017 ftcdlib 2023-08-21T18:03:55Z Marine invertebrates with skeletons made of high-magnesium calcite may be especially susceptible to ocean acidification (OA) due to the elevated solubility of this form of calcium carbonate. However, skeletal composition can vary plastically within some species, and it is largely unknown how concurrent changes in multiple oceanographic parameters will interact to affect skeletal mineralogy, growth and vulnerability to future OA. We explored these interactive effects by culturing genetic clones of the bryozoan Jellyella tuberculata (formerly Membranipora tuberculata) under factorial combinations of dissolved carbon dioxide (CO2), temperature and food concentrations. High CO2 and cold temperature induced degeneration of zooids in colonies. However, colonies still maintained high growth efficiencies under these adverse conditions, indicating a compensatory trade-off whereby colonies degenerate more zooids under stress, redirecting energy to the growth and maintenance of new zooids. Low-food concentration and elevated temperatures also had interactive effects on skeletal mineralogy, resulting in skeletal calcite with higher concentrations of magnesium, which readily dissolved under high CO2 For taxa that weakly regulate skeletal magnesium concentration, skeletal dissolution may be a more widespread phenomenon than is currently documented and is a growing concern as oceans continue to warm and acidify. Article in Journal/Newspaper Ocean acidification University of California: eScholarship
institution Open Polar
collection University of California: eScholarship
op_collection_id ftcdlib
language unknown
topic Life Below Water
Animals
Bryozoa
Calcium Carbonate
California
Carbon Dioxide
Food
Magnesium
Oceans and Seas
Seawater
calcification
global environmental change
magnesium regulation
phenotypic plasticity
bryozoan
colonial marine invertebrates
Biological Sciences
Agricultural and Veterinary Sciences
Medical and Health Sciences
spellingShingle Life Below Water
Animals
Bryozoa
Calcium Carbonate
California
Carbon Dioxide
Food
Magnesium
Oceans and Seas
Seawater
calcification
global environmental change
magnesium regulation
phenotypic plasticity
bryozoan
colonial marine invertebrates
Biological Sciences
Agricultural and Veterinary Sciences
Medical and Health Sciences
Swezey, Daniel S
Bean, Jessica R
Ninokawa, Aaron T
Hill, Tessa M
Gaylord, Brian
Sanford, Eric
Interactive effects of temperature, food and skeletal mineralogy mediate biological responses to ocean acidification in a widely distributed bryozoan
topic_facet Life Below Water
Animals
Bryozoa
Calcium Carbonate
California
Carbon Dioxide
Food
Magnesium
Oceans and Seas
Seawater
calcification
global environmental change
magnesium regulation
phenotypic plasticity
bryozoan
colonial marine invertebrates
Biological Sciences
Agricultural and Veterinary Sciences
Medical and Health Sciences
description Marine invertebrates with skeletons made of high-magnesium calcite may be especially susceptible to ocean acidification (OA) due to the elevated solubility of this form of calcium carbonate. However, skeletal composition can vary plastically within some species, and it is largely unknown how concurrent changes in multiple oceanographic parameters will interact to affect skeletal mineralogy, growth and vulnerability to future OA. We explored these interactive effects by culturing genetic clones of the bryozoan Jellyella tuberculata (formerly Membranipora tuberculata) under factorial combinations of dissolved carbon dioxide (CO2), temperature and food concentrations. High CO2 and cold temperature induced degeneration of zooids in colonies. However, colonies still maintained high growth efficiencies under these adverse conditions, indicating a compensatory trade-off whereby colonies degenerate more zooids under stress, redirecting energy to the growth and maintenance of new zooids. Low-food concentration and elevated temperatures also had interactive effects on skeletal mineralogy, resulting in skeletal calcite with higher concentrations of magnesium, which readily dissolved under high CO2 For taxa that weakly regulate skeletal magnesium concentration, skeletal dissolution may be a more widespread phenomenon than is currently documented and is a growing concern as oceans continue to warm and acidify.
format Article in Journal/Newspaper
author Swezey, Daniel S
Bean, Jessica R
Ninokawa, Aaron T
Hill, Tessa M
Gaylord, Brian
Sanford, Eric
author_facet Swezey, Daniel S
Bean, Jessica R
Ninokawa, Aaron T
Hill, Tessa M
Gaylord, Brian
Sanford, Eric
author_sort Swezey, Daniel S
title Interactive effects of temperature, food and skeletal mineralogy mediate biological responses to ocean acidification in a widely distributed bryozoan
title_short Interactive effects of temperature, food and skeletal mineralogy mediate biological responses to ocean acidification in a widely distributed bryozoan
title_full Interactive effects of temperature, food and skeletal mineralogy mediate biological responses to ocean acidification in a widely distributed bryozoan
title_fullStr Interactive effects of temperature, food and skeletal mineralogy mediate biological responses to ocean acidification in a widely distributed bryozoan
title_full_unstemmed Interactive effects of temperature, food and skeletal mineralogy mediate biological responses to ocean acidification in a widely distributed bryozoan
title_sort interactive effects of temperature, food and skeletal mineralogy mediate biological responses to ocean acidification in a widely distributed bryozoan
publisher eScholarship, University of California
publishDate 2017
url https://escholarship.org/uc/item/95f0k4kj
op_coverage 20162349
genre Ocean acidification
genre_facet Ocean acidification
op_source Proceedings of the Royal Society B, vol 284, iss 1853
op_relation qt95f0k4kj
https://escholarship.org/uc/item/95f0k4kj
op_rights public
_version_ 1776202728689631232

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