Seagrass ecosystem metabolic carbon capture in response to green turtle grazing across Caribbean meadows

Seagrass ecosystem metabolic carbon capture in response to green turtle grazing across Caribbean meadows

Increasing green turtle abundance will lead to increased grazing within seagrass habitats—ecosystems that are important for carbon sequestration and storage. However, it is not well understood how carbon dynamics in these ecosystems respond to grazing and whether a response differs among meadows or...

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Veröffentlicht in:The Journal of ecology 2020-05, Vol.108 (3), p.1101-1114
Hauptverfasser: Johnson, Robert A., Gulick, Alexandra G., Constant, Nerine, Bolten, Alan B., Smulders, Fee O. H., Christianen, Marjolijn J. A., Nava, Mabel I., Kolasa, Keith, Bjorndal, Karen A., Randall Hughes, A.
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Carbon
Carbon capture and storage
carbon dynamics
Carbon sequestration
Dynamics
Ecosystems
Foraging
Foraging habitats
Grazing
green turtle
Halophila stipulacea
Indigenous species
invasive
Locations (working)
Meadows
Metabolism
Native organisms
plant–herbivore interactions
Remineralization
Sea grasses
Storage
Thalassia testudinum
Turtles
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container_end_page 1114
container_issue 3
container_start_page 1101
container_title The Journal of ecology
container_volume 108
creator Johnson, Robert A.
Gulick, Alexandra G.
Constant, Nerine
Bolten, Alan B.
Smulders, Fee O. H.
Christianen, Marjolijn J. A.
Nava, Mabel I.
Kolasa, Keith
Bjorndal, Karen A.
Randall Hughes, A.
description Increasing green turtle abundance will lead to increased grazing within seagrass habitats—ecosystems that are important for carbon sequestration and storage. However, it is not well understood how carbon dynamics in these ecosystems respond to grazing and whether a response differs among meadows or locations. We measured seagrass ecosystem metabolism in grazed and ungrazed areas of Thalassia testudinum meadows with established green turtle foraging areas across the Greater Caribbean and Gulf of Mexico. We sampled meadows from five locations that differed in seagrass and environmental characteristics. Established meadows of the invasive seagrass Halophila stipulacea were also present at two of these locations, and we measured ecosystem metabolism in these meadows for comparison to grazed and ungrazed areas of the native T. testudinum. Across all individual sites, rates of net ecosystem production (NEP) ranged from 56% to 96% lower in grazed areas than ungrazed areas of T. testudinum meadows. Rates of NEP were also strongly, positively correlated with above‐ground seagrass biomass across sites. While metabolic carbon capture rates were lower in grazed areas, heterotrophic respiration was not stimulated, and grazing therefore did not result in significant metabolic remineralization of carbon in these meadows. NEP in H. stipulacea meadows was similar to rates in T. testudinum meadows at all three sites, suggesting that metabolic carbon capture may remain similar in Caribbean meadows where this invasive seagrass is replacing native species. Synthesis. Our results show that there is a consistent response in metabolic carbon dynamics to green turtle grazing in T. testudinum meadows across the Greater Caribbean region. An increase in grazing will not likely stimulate remineralization of carbon as these important habitats are returned to a natural grazed state. Increasing green turtle abundance will lead to increased grazing within seagrass habitats. We show there is a consistent response in metabolic carbon dynamics to green turtle grazing in Thalassia testudinum meadows across the Greater Caribbean region, and an increase in grazing will not likely stimulate remineralization of carbon as these important habitats are returned to a natural grazed state. Editor's Choice
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H. ; Christianen, Marjolijn J. A. ; Nava, Mabel I. ; Kolasa, Keith ; Bjorndal, Karen A. ; Randall Hughes, A.</creator><contributor>Randall Hughes, A.</contributor><creatorcontrib>Johnson, Robert A. ; Gulick, Alexandra G. ; Constant, Nerine ; Bolten, Alan B. ; Smulders, Fee O. H. ; Christianen, Marjolijn J. A. ; Nava, Mabel I. ; Kolasa, Keith ; Bjorndal, Karen A. ; Randall Hughes, A. ; Randall Hughes, A.</creatorcontrib><description>Increasing green turtle abundance will lead to increased grazing within seagrass habitats—ecosystems that are important for carbon sequestration and storage. However, it is not well understood how carbon dynamics in these ecosystems respond to grazing and whether a response differs among meadows or locations. We measured seagrass ecosystem metabolism in grazed and ungrazed areas of Thalassia testudinum meadows with established green turtle foraging areas across the Greater Caribbean and Gulf of Mexico. We sampled meadows from five locations that differed in seagrass and environmental characteristics. Established meadows of the invasive seagrass Halophila stipulacea were also present at two of these locations, and we measured ecosystem metabolism in these meadows for comparison to grazed and ungrazed areas of the native T. testudinum. Across all individual sites, rates of net ecosystem production (NEP) ranged from 56% to 96% lower in grazed areas than ungrazed areas of T. testudinum meadows. Rates of NEP were also strongly, positively correlated with above‐ground seagrass biomass across sites. While metabolic carbon capture rates were lower in grazed areas, heterotrophic respiration was not stimulated, and grazing therefore did not result in significant metabolic remineralization of carbon in these meadows. NEP in H. stipulacea meadows was similar to rates in T. testudinum meadows at all three sites, suggesting that metabolic carbon capture may remain similar in Caribbean meadows where this invasive seagrass is replacing native species. Synthesis. Our results show that there is a consistent response in metabolic carbon dynamics to green turtle grazing in T. testudinum meadows across the Greater Caribbean region. An increase in grazing will not likely stimulate remineralization of carbon as these important habitats are returned to a natural grazed state. Increasing green turtle abundance will lead to increased grazing within seagrass habitats. We show there is a consistent response in metabolic carbon dynamics to green turtle grazing in Thalassia testudinum meadows across the Greater Caribbean region, and an increase in grazing will not likely stimulate remineralization of carbon as these important habitats are returned to a natural grazed state. 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H.</creatorcontrib><creatorcontrib>Christianen, Marjolijn J. A.</creatorcontrib><creatorcontrib>Nava, Mabel I.</creatorcontrib><creatorcontrib>Kolasa, Keith</creatorcontrib><creatorcontrib>Bjorndal, Karen A.</creatorcontrib><creatorcontrib>Randall Hughes, A.</creatorcontrib><title>Seagrass ecosystem metabolic carbon capture in response to green turtle grazing across Caribbean meadows</title><title>The Journal of ecology</title><description>Increasing green turtle abundance will lead to increased grazing within seagrass habitats—ecosystems that are important for carbon sequestration and storage. However, it is not well understood how carbon dynamics in these ecosystems respond to grazing and whether a response differs among meadows or locations. We measured seagrass ecosystem metabolism in grazed and ungrazed areas of Thalassia testudinum meadows with established green turtle foraging areas across the Greater Caribbean and Gulf of Mexico. We sampled meadows from five locations that differed in seagrass and environmental characteristics. Established meadows of the invasive seagrass Halophila stipulacea were also present at two of these locations, and we measured ecosystem metabolism in these meadows for comparison to grazed and ungrazed areas of the native T. testudinum. Across all individual sites, rates of net ecosystem production (NEP) ranged from 56% to 96% lower in grazed areas than ungrazed areas of T. testudinum meadows. Rates of NEP were also strongly, positively correlated with above‐ground seagrass biomass across sites. While metabolic carbon capture rates were lower in grazed areas, heterotrophic respiration was not stimulated, and grazing therefore did not result in significant metabolic remineralization of carbon in these meadows. NEP in H. stipulacea meadows was similar to rates in T. testudinum meadows at all three sites, suggesting that metabolic carbon capture may remain similar in Caribbean meadows where this invasive seagrass is replacing native species. Synthesis. Our results show that there is a consistent response in metabolic carbon dynamics to green turtle grazing in T. testudinum meadows across the Greater Caribbean region. An increase in grazing will not likely stimulate remineralization of carbon as these important habitats are returned to a natural grazed state. Increasing green turtle abundance will lead to increased grazing within seagrass habitats. We show there is a consistent response in metabolic carbon dynamics to green turtle grazing in Thalassia testudinum meadows across the Greater Caribbean region, and an increase in grazing will not likely stimulate remineralization of carbon as these important habitats are returned to a natural grazed state. 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subjects Carbon
Carbon capture and storage
carbon dynamics
Carbon sequestration
Dynamics
Ecosystems
Foraging
Foraging habitats
Grazing
green turtle
Halophila stipulacea
Indigenous species
invasive
Locations (working)
Meadows
Metabolism
Native organisms
plant–herbivore interactions
Remineralization
Sea grasses
Storage
Thalassia testudinum
Turtles
title Seagrass ecosystem metabolic carbon capture in response to green turtle grazing across Caribbean meadows
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