Effects of elevated pCO\(_2\) on the productivity of marine microbes and the remineralisation of nutrients in coastal Antarctic waters

High-latitude oceans are anticipated to be some of the first regions affected by ocean acidification. Marine microbes are the base of the food web and support the wealth of life in Antarctica. They are also a critical link in biogeochemical processes, such as the cycling of nutrients and carbon. Des...

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Main Author: Deppeler, SL
Format: Thesis
Language:unknown
Published: University of Tasmania 2018
Subjects:
Antarctic
Southern Ocean
The Antarctic
Prydz Bay
Antarc*
Antarctica
Ocean acidification
Online Access:https://dx.doi.org/10.25959/100.00030036
https://eprints.utas.edu.au/id/eprint/30036
id ftdatacite:10.25959/100.00030036
record_format openpolar
spelling ftdatacite:10.25959/100.00030036 2023-05-15T13:34:57+02:00 Effects of elevated pCO\(_2\) on the productivity of marine microbes and the remineralisation of nutrients in coastal Antarctic waters Deppeler, SL 2018 https://dx.doi.org/10.25959/100.00030036 https://eprints.utas.edu.au/id/eprint/30036 unknown University of Tasmania Text Thesis article-journal ScholarlyArticle 2018 ftdatacite https://doi.org/10.25959/100.00030036 2021-11-05T12:55:41Z High-latitude oceans are anticipated to be some of the first regions affected by ocean acidification. Marine microbes are the base of the food web and support the wealth of life in Antarctica. They are also a critical link in biogeochemical processes, such as the cycling of nutrients and carbon. Despite this, the effect of ocean acidification on natural communities of Antarctic marine microbes is poorly understood. This thesis sets out to address this lack of scientific knowledge of how the base of the Antarctic food web, both as individual taxa and communities, will respond to elevated CO\(_2\). Much of the results of this thesis are derived from an ocean acidification study performed on an early spring, coastal marine microbial community from Prydz Bay, Antarctica. Such studies are currently rare in Antarctic waters and can provide valuable insights into how future changes in CO\(_2\) will affect the marine microbial community. In this study, the microbial community was exposed to increasing \(f\)CO\(_2\) levels from ambient (343 μatm) to 1641 μatm in 650 L minicosms. Measurements of abundance and primary and bacterial productivity were taken to determine the effect of CO\(_2\) on different community groups. Photophysiological measurements were also performed to identify possible mechanisms driving changes in the phytoplankton community. The limits for CO\(_2\) tolerance were broad, likely due to the naturally variable environment this community inhabits. However, there were thresholds to this CO\(_2\) tolerance that elicited responses by different community groups. An important tipping point was identified in the phytoplankton community’s ability to cope with the energetic requirements of maintaining efficient productivity under high CO\(_2\). These results highlighted the strong interplay between enrichment of CO\(_2\) enhancing physiology and metabolic costs imposed by increased H\(^+\). In addition, elevated CO\(_2\) slowed the growth of heterotrophic nanoflagellates, releasing their prey (picophytoplankton and prokaryotes). Thus, increasing CO\(_2\) has the potential to change the composition of Antarctic microbial communities by altering interactions among trophic levels. A diatom was isolated from the community-level study and exposed to \(f\)CO\(_2\) levels from 276 to 1063 μatm in a unialgal culture study to determine taxon-specific CO\(_2\) sensitivities. Comparing these results with those reported for this species in the community-level study assessed the utility of unialgal studies for predicting the sensitivity of Antarctic phytoplankton taxa to elevated \(f\)CO\(_2\). A difference in growth response between the two studies confirmed that factors other than CO\(_2\) affected this species when it is part of a natural community. This research showed that ocean acidification altered microbial productivity, trophodynamics and biogeochemistry in Antarctic coastal waters. Changes in phytoplankton community production and predator-prey interactions with ocean acidification could have a significant effect on the food web and biogeochemistry in the Southern Ocean. In addition, while culture studies are useful for evaluating mechanisms of CO\(_2\)-induced tolerance and stress, such studies proved to be of limited value for predicting responses in nature as they fail to include interactions among species and trophic levels. Thesis Antarc* Antarctic Antarctica Ocean acidification Prydz Bay Southern Ocean DataCite Metadata Store (German National Library of Science and Technology) Antarctic Southern Ocean The Antarctic Prydz Bay
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language unknown
description High-latitude oceans are anticipated to be some of the first regions affected by ocean acidification. Marine microbes are the base of the food web and support the wealth of life in Antarctica. They are also a critical link in biogeochemical processes, such as the cycling of nutrients and carbon. Despite this, the effect of ocean acidification on natural communities of Antarctic marine microbes is poorly understood. This thesis sets out to address this lack of scientific knowledge of how the base of the Antarctic food web, both as individual taxa and communities, will respond to elevated CO\(_2\). Much of the results of this thesis are derived from an ocean acidification study performed on an early spring, coastal marine microbial community from Prydz Bay, Antarctica. Such studies are currently rare in Antarctic waters and can provide valuable insights into how future changes in CO\(_2\) will affect the marine microbial community. In this study, the microbial community was exposed to increasing \(f\)CO\(_2\) levels from ambient (343 μatm) to 1641 μatm in 650 L minicosms. Measurements of abundance and primary and bacterial productivity were taken to determine the effect of CO\(_2\) on different community groups. Photophysiological measurements were also performed to identify possible mechanisms driving changes in the phytoplankton community. The limits for CO\(_2\) tolerance were broad, likely due to the naturally variable environment this community inhabits. However, there were thresholds to this CO\(_2\) tolerance that elicited responses by different community groups. An important tipping point was identified in the phytoplankton community’s ability to cope with the energetic requirements of maintaining efficient productivity under high CO\(_2\). These results highlighted the strong interplay between enrichment of CO\(_2\) enhancing physiology and metabolic costs imposed by increased H\(^+\). In addition, elevated CO\(_2\) slowed the growth of heterotrophic nanoflagellates, releasing their prey (picophytoplankton and prokaryotes). Thus, increasing CO\(_2\) has the potential to change the composition of Antarctic microbial communities by altering interactions among trophic levels. A diatom was isolated from the community-level study and exposed to \(f\)CO\(_2\) levels from 276 to 1063 μatm in a unialgal culture study to determine taxon-specific CO\(_2\) sensitivities. Comparing these results with those reported for this species in the community-level study assessed the utility of unialgal studies for predicting the sensitivity of Antarctic phytoplankton taxa to elevated \(f\)CO\(_2\). A difference in growth response between the two studies confirmed that factors other than CO\(_2\) affected this species when it is part of a natural community. This research showed that ocean acidification altered microbial productivity, trophodynamics and biogeochemistry in Antarctic coastal waters. Changes in phytoplankton community production and predator-prey interactions with ocean acidification could have a significant effect on the food web and biogeochemistry in the Southern Ocean. In addition, while culture studies are useful for evaluating mechanisms of CO\(_2\)-induced tolerance and stress, such studies proved to be of limited value for predicting responses in nature as they fail to include interactions among species and trophic levels.
format Thesis
author Deppeler, SL
spellingShingle Deppeler, SL
Effects of elevated pCO\(_2\) on the productivity of marine microbes and the remineralisation of nutrients in coastal Antarctic waters
author_facet Deppeler, SL
author_sort Deppeler, SL
title Effects of elevated pCO\(_2\) on the productivity of marine microbes and the remineralisation of nutrients in coastal Antarctic waters
title_short Effects of elevated pCO\(_2\) on the productivity of marine microbes and the remineralisation of nutrients in coastal Antarctic waters
title_full Effects of elevated pCO\(_2\) on the productivity of marine microbes and the remineralisation of nutrients in coastal Antarctic waters
title_fullStr Effects of elevated pCO\(_2\) on the productivity of marine microbes and the remineralisation of nutrients in coastal Antarctic waters
title_full_unstemmed Effects of elevated pCO\(_2\) on the productivity of marine microbes and the remineralisation of nutrients in coastal Antarctic waters
title_sort effects of elevated pco\(_2\) on the productivity of marine microbes and the remineralisation of nutrients in coastal antarctic waters
publisher University of Tasmania
publishDate 2018
url https://dx.doi.org/10.25959/100.00030036
https://eprints.utas.edu.au/id/eprint/30036
geographic Antarctic
Southern Ocean
The Antarctic
Prydz Bay
geographic_facet Antarctic
Southern Ocean
The Antarctic
Prydz Bay
genre Antarc*
Antarctic
Antarctica
Ocean acidification
Prydz Bay
Southern Ocean
genre_facet Antarc*
Antarctic
Antarctica
Ocean acidification
Prydz Bay
Southern Ocean
op_doi https://doi.org/10.25959/100.00030036
_version_ 1766059462519422976

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