Microbial Contributions to Phosphorus Cycling in Eutrophic Lakes and Wastewater

Phosphorus is a key element controlling the productivity of freshwater ecosystems, and microbes drive most of its relevant biogeochemistry. Eutrophic lakes are generally dominated by cyanobacteria that compete fiercely with algae and heterotrophs for the element. In wastewater treatment, engineers s...

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Veröffentlicht in:	Annual review of microbiology 2013-01, Vol.67 (1), p.199-219
Hauptverfasser:	McMahon, Katherine D, Read, Emily K
Format:	Artikel
Sprache:	eng
Schlagworte:	Accumulibacter activated sludge Algae Aquatic ecosystems Bacteria - metabolism Biodiversity Biogeochemistry Biogeography Candidatus cyanobacteria Dissolved organic phosphorus Ecosystem Ecosystem biology Eutrophic lakes Eutrophication Freshwater Freshwater ecosystems Lakes Lakes - chemistry Lakes - microbiology Metabolism Mineralization Phosphorus Phosphorus - analysis Phosphorus - metabolism Surface water Tetrasphaera Waste Water - chemistry Waste Water - microbiology Wastewater treatment plants
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container_title	Annual review of microbiology
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creator	McMahon, Katherine D Read, Emily K
description	Phosphorus is a key element controlling the productivity of freshwater ecosystems, and microbes drive most of its relevant biogeochemistry. Eutrophic lakes are generally dominated by cyanobacteria that compete fiercely with algae and heterotrophs for the element. In wastewater treatment, engineers select for specialized bacteria capable of sequestering phosphorus from the water, to protect surface waters from further loading. The intracellular storage molecule polyphosphate plays an important role in both systems, allowing key taxa to control phosphorus availability. The importance of dissolved organic phosphorus in eutrophic lakes and mineralization mechanisms is still underappreciated and understudied. The need for functional redundancy through biological diversity in wastewater treatment plants is also clear. In both systems, a holistic ecosystems biology approach is needed to understand the molecular mechanisms controlling phosphorus metabolism and the ecological interactions and factors controlling ecosystem-level process rates.
doi_str_mv	10.1146/annurev-micro-092412-155713
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subjects	Accumulibacter activated sludge Algae Aquatic ecosystems Bacteria - metabolism Biodiversity Biogeochemistry Biogeography Candidatus cyanobacteria Dissolved organic phosphorus Ecosystem Ecosystem biology Eutrophic lakes Eutrophication Freshwater Freshwater ecosystems Lakes Lakes - chemistry Lakes - microbiology Metabolism Mineralization Phosphorus Phosphorus - analysis Phosphorus - metabolism Surface water Tetrasphaera Waste Water - chemistry Waste Water - microbiology Wastewater treatment plants
title	Microbial Contributions to Phosphorus Cycling in Eutrophic Lakes and Wastewater
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