Alkaline phosphatase activity in the subtropical ocean: insights from nutrient, dust and trace metal addition experiments
Alkaline phosphatase activity in the subtropical ocean: insights from nutrient, dust and trace metal addition experiments
Phosphorus is an essential nutrient for all life on earth. In the ocean, the most bioavailable form of phosphorus is inorganic phosphate, but in the extensive subtropical gyres, phosphate concentrations can be chronically low and limit primary productivity and nitrogen fixation. In these regions, organisms produce hydrolytic enzymes, such as alkaline phosphatase (AP), that enable them to utilize the more replete dissolved organic phosphorus (DOP) pool to meet their cellular phosphorus demands. In this study, we synthesized data from 14 published studies and present our own findings from two research cruises (D326 and D361) in the eastern subtropical Atlantic to explore the relationship between AP activity (APA) and nutrients, Saharan dust and trace metals. We found that below a threshold phosphate concentration of ~30 nM, APA increased with an inverse hyperbolic relationship with phosphate concentration. Meanwhile, DOP concentrations decreased with enhanced APA, indicating utilization of the DOP pool. We found APA rates were significantly higher in the subtropical Atlantic compared to the subtropical Pacific Ocean, even over the same low phosphate concentration range (0–50 nM). While the phosphate concentration may have a first order control on the APA rates, we speculate that other factors influence this basin scale contrast. Using bioassay experiments, we show that the addition of Saharan dust and zinc significantly increased the rate of APA. To our knowledge, our results are the first direct field-based evidence that APA is limited by zinc in the subtropical ocean. Further work is required to explore the relationship between trace metals such as iron and zinc, which are co-factors of phosphohydrolytic enzymes, specifically PhoX and PhoA, respectively, and APA in the ocean.
Mahaffey, Claire
6c868a01-2c9b-48b0-ae08-9ecf6b870032
Reynolds, Sarah
4c3bbdf6-5dfb-4e02-8699-a34a172df6d0
Davis, Clare E.
65fc2085-7fe4-4af4-b4de-32c06d98c8e7
Lohan, Maeve C.
6ca10597-2d0f-40e8-8e4f-7619dfac5088
2014
Mahaffey, Claire
6c868a01-2c9b-48b0-ae08-9ecf6b870032
Reynolds, Sarah
4c3bbdf6-5dfb-4e02-8699-a34a172df6d0
Davis, Clare E.
65fc2085-7fe4-4af4-b4de-32c06d98c8e7
Lohan, Maeve C.
6ca10597-2d0f-40e8-8e4f-7619dfac5088
Mahaffey, Claire, Reynolds, Sarah, Davis, Clare E. and Lohan, Maeve C.
(2014)
Alkaline phosphatase activity in the subtropical ocean: insights from nutrient, dust and trace metal addition experiments.
Frontiers in Marine Science, 1, [00073].
(doi:10.3389/fmars.2014.00073).
Abstract
Phosphorus is an essential nutrient for all life on earth. In the ocean, the most bioavailable form of phosphorus is inorganic phosphate, but in the extensive subtropical gyres, phosphate concentrations can be chronically low and limit primary productivity and nitrogen fixation. In these regions, organisms produce hydrolytic enzymes, such as alkaline phosphatase (AP), that enable them to utilize the more replete dissolved organic phosphorus (DOP) pool to meet their cellular phosphorus demands. In this study, we synthesized data from 14 published studies and present our own findings from two research cruises (D326 and D361) in the eastern subtropical Atlantic to explore the relationship between AP activity (APA) and nutrients, Saharan dust and trace metals. We found that below a threshold phosphate concentration of ~30 nM, APA increased with an inverse hyperbolic relationship with phosphate concentration. Meanwhile, DOP concentrations decreased with enhanced APA, indicating utilization of the DOP pool. We found APA rates were significantly higher in the subtropical Atlantic compared to the subtropical Pacific Ocean, even over the same low phosphate concentration range (0–50 nM). While the phosphate concentration may have a first order control on the APA rates, we speculate that other factors influence this basin scale contrast. Using bioassay experiments, we show that the addition of Saharan dust and zinc significantly increased the rate of APA. To our knowledge, our results are the first direct field-based evidence that APA is limited by zinc in the subtropical ocean. Further work is required to explore the relationship between trace metals such as iron and zinc, which are co-factors of phosphohydrolytic enzymes, specifically PhoX and PhoA, respectively, and APA in the ocean.
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fmars-01-00073
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Published date: 2014
Organisations:
Marine Biogeochemistry
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Local EPrints ID: 406489
URI: http://eprints.soton.ac.uk/id/eprint/406489
PURE UUID: 9abf6cf0-ea7d-4505-bb09-e01dd722f016
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Date deposited: 18 Mar 2017 02:20
Last modified: 16 Mar 2024 04:13
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Author:
Claire Mahaffey
Author:
Sarah Reynolds
Author:
Clare E. Davis
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