Phosphate limitation intensifies negative effects of ocean acidification on globally important nitrogen fixing cyanobacterium

Growth of the prominent nitrogen-fixing cyanobacterium Trichodesmium is often limited by phosphorus availability in the ocean. How nitrogen fixation by phosphorus-limited Trichodesmium may respond to ocean acidification remains poorly understood. Here, we use phosphate-limited chemostat experiments...

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Bibliographic Details
Published in:Nature communications 2022-11, Vol.13 (1), p.6730-6730, Article 6730
Main Authors: Zhang, Futing, Wen, Zuozhu, Wang, Shanlin, Tang, Weiyi, Luo, Ya-Wei, Kranz, Sven A., Hong, Haizheng, Shi, Dalin
Format: Article
Language:English
Subjects:
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Acidification
Bioreactors
Carbon dioxide
Chlorophyll
Cyanobacteria
Homeostasis
Humanities and Social Sciences
Hydrogen-Ion Concentration
multidisciplinary
Nitrogen
Nitrogen - pharmacology
Nitrogen Fixation
Nitrogenation
Ocean acidification
Oceans
Oceans and Seas
pH effects
Phosphorus
Phosphorus - pharmacology
Polyphosphates
Science
Science (multidisciplinary)
Seawater
Seawater - chemistry
Trichodesmium
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Summary:Growth of the prominent nitrogen-fixing cyanobacterium Trichodesmium is often limited by phosphorus availability in the ocean. How nitrogen fixation by phosphorus-limited Trichodesmium may respond to ocean acidification remains poorly understood. Here, we use phosphate-limited chemostat experiments to show that acidification enhanced phosphorus demands and decreased phosphorus-specific nitrogen fixation rates in Trichodesmium . The increased phosphorus requirements were attributed primarily to elevated cellular polyphosphate contents, likely for maintaining cytosolic pH homeostasis in response to acidification. Alongside the accumulation of polyphosphate, decreased NADP(H):NAD(H) ratios and impaired chlorophyll synthesis and energy production were observed under acidified conditions. Consequently, the negative effects of acidification were amplified compared to those demonstrated previously under phosphorus sufficiency. Estimating the potential implications of this finding, using outputs from the Community Earth System Model, predicts that acidification and dissolved inorganic and organic phosphorus stress could synergistically cause an appreciable decrease in global Trichodesmium nitrogen fixation by 2100. How reduced seawater pH and increased carbon dioxide might affect the prominent nitrogen fixer Trichodesmium in phosphorus-limited oceans is poorly understood. This study used phosphate-limited chemostat experiments to show that Trichodesmium may fix less nitrogen for a given amount of phosphorus at low pH. Thus, marine productivity is likely to decline in a future, more acidic ocean.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-022-34586-x