Bacterial Community Structure, Function and Diversity in Antarctic Sea Ice
Antarctic sea ice is an important feature of the southern ocean where at its maximum it can cover 8 % of the Southern Hemisphere. It provides a stable environment for the colonisation of diverse and highly specialised microbes which play a central role in the assimilation and regulation of energy th...
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ftsmithonian:oai:figshare.com:article/16992562 2023-05-15T13:37:42+02:00 Bacterial Community Structure, Function and Diversity in Antarctic Sea Ice Cowie, Rebecca Olivia MacLennan (11682955) 2011-01-01T00:00:00Z https://doi.org/10.26686/wgtn.16992562.v1 unknown https://figshare.com/articles/thesis/Bacterial_Community_Structure_Function_and_Diversity_in_Antarctic_Sea_Ice/16992562 doi:10.26686/wgtn.16992562.v1 Author Retains Copyright Biological Sciences not elsewhere classified Microbial ecology Prokaryotic diversity School: School of Biological Sciences 069999 Biological Sciences not elsewhere classified Marsden: 270307 Microbial Ecology Degree Discipline: Ecology and Biodiversity Degree Level: Doctoral Degree Name: Doctor of Philosophy Text Thesis 2011 ftsmithonian https://doi.org/10.26686/wgtn.16992562.v1 2021-12-19T22:06:09Z Antarctic sea ice is an important feature of the southern ocean where at its maximum it can cover 8 % of the Southern Hemisphere. It provides a stable environment for the colonisation of diverse and highly specialised microbes which play a central role in the assimilation and regulation of energy through the Antarctic food web. Polar environments are sensitive to changes in the environment. Small changes in temperature can have large effects on sea ice thickness and extent and Antarctic sea ice cover is expected to shrink by 25 % over the next century. It is unknown how the sea ice microbiota will respond. In order to understand the effects of climate change on the sea ice ecosystem it is necessary to obtain information about the community structure, function and diversity and their reactions with the environment. Studies have focused on algal diversity and physiology in Antarctic sea ice and in comparison studies on the prokaryotic community are few. Although prokaryotic diversity has been investigated using clone libraries and culture based methods, it is likely that certain species have still not been described. Almost nothing is known about the Antarctic sea ice bacterial community spatial and temporal dynamics under changing abiotic and biotic conditions or their role in biogeochemical cycles. This is the first study linking Antarctic bacterial communities to function by using statistics to investigate the relationships between environmental variables and community structure. Bacterial community structure was investigated by extracting both the DNA and RNA from the environment to understand both the metabolically active (RNA) and total (DNA) bacterial community. The thickness of the sea ice and nutrient concentrations were key factors regulating bacterial community composition in Antarctic sea ice. Sea ice thickness is likely to have an effect on the physiological responses of algae leading to changes in photosynthate concentrations and composition of dissolved organic matter (DOM). Further investigations into the relationships between enzymatic activity and community structure revealed that the composition of the DOM drove variation between bacterial communities. There was no relationship between bacterial abundance and chlorophyll-a (as a measure of algal biomass), suggesting a un-coupling of the microbial loop. However bacteria were actively involved in the hydrolysis of polymers throughout the sea ice core. Investigations using quantitative PCR (qPCR) found that the functional genes involved in denitrification and light energy utilisation were in low abundance therefore these processes are minor in Antarctic sea ice. These results confirm that sea ice bacteria are predominantly heterotrophs and have a major role in the cycling of carbon and nitrogen through the microbial loop . Thesis Antarc* Antarctic ice core Sea ice Southern Ocean Unknown Antarctic Southern Ocean The Antarctic Marsden ENVELOPE(66.067,66.067,-67.867,-67.867) |
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ftsmithonian |
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Biological Sciences not elsewhere classified Microbial ecology Prokaryotic diversity School: School of Biological Sciences 069999 Biological Sciences not elsewhere classified Marsden: 270307 Microbial Ecology Degree Discipline: Ecology and Biodiversity Degree Level: Doctoral Degree Name: Doctor of Philosophy |
spellingShingle |
Biological Sciences not elsewhere classified Microbial ecology Prokaryotic diversity School: School of Biological Sciences 069999 Biological Sciences not elsewhere classified Marsden: 270307 Microbial Ecology Degree Discipline: Ecology and Biodiversity Degree Level: Doctoral Degree Name: Doctor of Philosophy Cowie, Rebecca Olivia MacLennan (11682955) Bacterial Community Structure, Function and Diversity in Antarctic Sea Ice |
topic_facet |
Biological Sciences not elsewhere classified Microbial ecology Prokaryotic diversity School: School of Biological Sciences 069999 Biological Sciences not elsewhere classified Marsden: 270307 Microbial Ecology Degree Discipline: Ecology and Biodiversity Degree Level: Doctoral Degree Name: Doctor of Philosophy |
description |
Antarctic sea ice is an important feature of the southern ocean where at its maximum it can cover 8 % of the Southern Hemisphere. It provides a stable environment for the colonisation of diverse and highly specialised microbes which play a central role in the assimilation and regulation of energy through the Antarctic food web. Polar environments are sensitive to changes in the environment. Small changes in temperature can have large effects on sea ice thickness and extent and Antarctic sea ice cover is expected to shrink by 25 % over the next century. It is unknown how the sea ice microbiota will respond. In order to understand the effects of climate change on the sea ice ecosystem it is necessary to obtain information about the community structure, function and diversity and their reactions with the environment. Studies have focused on algal diversity and physiology in Antarctic sea ice and in comparison studies on the prokaryotic community are few. Although prokaryotic diversity has been investigated using clone libraries and culture based methods, it is likely that certain species have still not been described. Almost nothing is known about the Antarctic sea ice bacterial community spatial and temporal dynamics under changing abiotic and biotic conditions or their role in biogeochemical cycles. This is the first study linking Antarctic bacterial communities to function by using statistics to investigate the relationships between environmental variables and community structure. Bacterial community structure was investigated by extracting both the DNA and RNA from the environment to understand both the metabolically active (RNA) and total (DNA) bacterial community. The thickness of the sea ice and nutrient concentrations were key factors regulating bacterial community composition in Antarctic sea ice. Sea ice thickness is likely to have an effect on the physiological responses of algae leading to changes in photosynthate concentrations and composition of dissolved organic matter (DOM). Further investigations into the relationships between enzymatic activity and community structure revealed that the composition of the DOM drove variation between bacterial communities. There was no relationship between bacterial abundance and chlorophyll-a (as a measure of algal biomass), suggesting a un-coupling of the microbial loop. However bacteria were actively involved in the hydrolysis of polymers throughout the sea ice core. Investigations using quantitative PCR (qPCR) found that the functional genes involved in denitrification and light energy utilisation were in low abundance therefore these processes are minor in Antarctic sea ice. These results confirm that sea ice bacteria are predominantly heterotrophs and have a major role in the cycling of carbon and nitrogen through the microbial loop . |
format |
Thesis |
author |
Cowie, Rebecca Olivia MacLennan (11682955) |
author_facet |
Cowie, Rebecca Olivia MacLennan (11682955) |
author_sort |
Cowie, Rebecca Olivia MacLennan (11682955) |
title |
Bacterial Community Structure, Function and Diversity in Antarctic Sea Ice |
title_short |
Bacterial Community Structure, Function and Diversity in Antarctic Sea Ice |
title_full |
Bacterial Community Structure, Function and Diversity in Antarctic Sea Ice |
title_fullStr |
Bacterial Community Structure, Function and Diversity in Antarctic Sea Ice |
title_full_unstemmed |
Bacterial Community Structure, Function and Diversity in Antarctic Sea Ice |
title_sort |
bacterial community structure, function and diversity in antarctic sea ice |
publishDate |
2011 |
url |
https://doi.org/10.26686/wgtn.16992562.v1 |
long_lat |
ENVELOPE(66.067,66.067,-67.867,-67.867) |
geographic |
Antarctic Southern Ocean The Antarctic Marsden |
geographic_facet |
Antarctic Southern Ocean The Antarctic Marsden |
genre |
Antarc* Antarctic ice core Sea ice Southern Ocean |
genre_facet |
Antarc* Antarctic ice core Sea ice Southern Ocean |
op_relation |
https://figshare.com/articles/thesis/Bacterial_Community_Structure_Function_and_Diversity_in_Antarctic_Sea_Ice/16992562 doi:10.26686/wgtn.16992562.v1 |
op_rights |
Author Retains Copyright |
op_doi |
https://doi.org/10.26686/wgtn.16992562.v1 |
_version_ |
1766096883662454784 |