Molybdenum limitation of microbial nitrogen assimilation in aquatic ecosystems and pure cultures
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Authors
Glass, Jennifer B.
Axler, Richard P.
Chandra, Sudeep
Goldman, Charles R.
Issue Date
2012
Type
Article
Language
Keywords
enzyme activity , Limnology , Microbes , Molybdenum , Nitrate Reductase , Nitrogen Fixation , nutrient limitation , Trace Elements
Alternative Title
Abstract
Molybdenum (Mo) is an essential micronutrient for biological assimilation of nitrogen gas and nitrate because it is present in the cofactors of nitrogenase and nitrate reductase enzymes. Although Mo is the most abundant transition metal in seawater (107 nM), it is present in low concentrations in most freshwaters, typically <20 nM. In 1960, it was discovered that primary productivity was limited by Mo scarcity (2-4 nM) in Castle Lake, a small, meso-oligotrophic lake in northern California. Follow up studies demonstrated that Mo also limited primary productivity in lakes in New Zealand, Alaska and the Sierra Nevada. Research in the 1970s and 1980s showed that Mo limited primary productivity and nitrate uptake in Castle Lake only during periods of the growing season when nitrate concentrations were relatively high because ammonium assimilation does not require Mo. In the years since, research has shifted to investigate whether Mo limitation also occurs in marine and soil environments. Here we review studies of Mo limitation of nitrogen assimilation in natural communities and pure microbial cultures. We also summarize new data showing that the simultaneous addition of Mo and nitrate causes increased activity of proteins involved in nitrogen assimilation in the hypolimnion of Castle Lake when ammonium is scarce. Furthermore, we suggest that meter-scale Mo and oxygen profiles from Castle Lake are consistent with the hypothesis that nitrogen-fixing cyanobacteria in freshwater periphyton communities have higher Mo requirements than other microbial communities. Finally, we present topics for future research related to Mo bioavailability through time and with changing oxidation state.
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Citation
Publisher
License
Creative Commons Attribution 4.0 United States
Journal
Volume
Issue
PubMed ID
ISSN
1664-302X