Microbial community composition, extracellular enzymatic activities, and structure-function relationships in the central Arctic Ocean, a high-latitude fjord, and the North Atlantic Ocean
Due to their abundance, diversity, and capabilities to transform and metabolize diverse compounds, microbial communities regulate biogeochemical cycles on micro-, regional, and global scales. The activities of microbial communities affect the flow of matter, energy sources of other organisms, and hu...
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| Other Authors: | , , , , , |
| Format: | Doctoral or Postdoctoral Thesis |
| Language: | English |
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University of North Carolina at Chapel Hill
2018
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| Online Access: | https://doi.org/10.17615/awwt-vg37 https://cdr.lib.unc.edu/downloads/8049g6270?file=thumbnail https://cdr.lib.unc.edu/downloads/8049g6270 |
| Summary: | Due to their abundance, diversity, and capabilities to transform and metabolize diverse compounds, microbial communities regulate biogeochemical cycles on micro-, regional, and global scales. The activities of microbial communities affect the flow of matter, energy sources of other organisms, and human health, as well as other aspects of life. Yet, the composition, diversity, and ecological roles of microbes in parts of the global oceans—from the high latitudes to the deep water column—remain underexplored. Drawing from microbiological, oceanographic, and ecological concepts, this dissertation explores several fundamental topics: 1) the manner in which hydrographic conditions influence microbial community composition; 2) the ability of these microbial communities across environmental and depth gradients to hydrolyze organic compounds; and 3) microbial structure-function relationships in different habitats and under altered environmental conditions. In the central Arctic Ocean, the composition and enzymatic function of pelagic, particle associated, and benthic bacterial communities varied with depth and region, in parallel with specific hydrographic features. The microbial structure-function relationship in the pelagic realm indicated functional redundancy, suggesting that bacterial compositional shifts—in response to the changing Arctic—may have complex and less predictable functional consequences than previously anticipated. In Tyrolerfjord-Young Sound, northeast Greenland, microbial enzymatic activity patterns were investigated in rivers and within the fjord. Activity patterns correlated with the composition of bacterial communities and dissolved organic matter in the same waters, suggesting that factors extrinsic (organic matter supply) and intrinsic (composition) to microbial communities may, in concert, influence their heterotrophic activities. Finally, functional consequences of differences in community composition were further explored in the North Atlantic. Enriched with high molecular weight organic ... |
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