Classes of dissolved and particulate phosphorus compounds and their spatial distributions in the water of a eutrophic lake: a 31P NMR study

Bai, Xin; Zhou, Yunkai; Sun, Jinhua; Ma, Jianzhong; Zhao, Hongyan; Liu, Xuefang

doi:10.1007/s10533-015-0155-7

Cited by 24 publications

(16 citation statements)

References 54 publications

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“…Results from 31 P NMR analyses showed that Ortho-P was the dominant fraction (on average 49.15%) of all PP compound groups detected, which was in accordance with a previous report [ 28 ]. The peak of Ortho-P concentrations was found in May in the phytoplankton-dominated zone and lake center zone; this phenomenon demonstrated that the concentration of Ortho-P in these two zones was affected by phytoplankton-derived particulate matter.…”

Section: Discussionsupporting

confidence: 92%

Spatial and Temporal Distribution of Particulate Phosphorus and Their Correlation with Environmental Factors in a Shallow Eutrophic Chinese Lake (Lake Taihu)

Kong

Chao

Zhuang

et al. 2018

IJERPH

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Spatial and seasonal variations of particulate phosphorus (PP) in a large shallow, eutrophic Lake Taihu with different ecotypes (including a phytoplankton-dominated zone, lake center zone, estuary zone and macrophyte-dominated zone) were investigated. The results showed that particulate organic phosphorus (POP) was the dominant form of PP (>88.0%). The concentration of POP showed higher levels in the bloom-sensitive northwestern zone (phytoplankton-dominated zone and estuary zone) during warm seasons, phytoplankton blooms and input of exogenous particulate matter were the main sources of POP in the lake water. Based on 31P nuclear magnetic resonance (31P NMR) analysis, orthophosphate (Ortho-P) was the dominant molecular species of PP and positively correlated with soluble reactive phosphorus (SRP) (p < 0.01). This suggested that the release of Ortho-P from suspended particulate matter (SPM) was the main source of SRP in the lake water. Pyrophosphate (Pyro-P), which is regarded as a highly labile species of P compounds, represented a large fraction of PP, and its significant positive correlations with chlorophyll a (Chl a), indicated that the concentration of Pyro-P could be used as an important indicator for the degree of eutrophication of Lake Taihu. These results proved that PP in lake water was a significant factor supporting lake eutrophication and must be controlled.

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Section: Discussionsupporting

confidence: 92%

Spatial and Temporal Distribution of Particulate Phosphorus and Their Correlation with Environmental Factors in a Shallow Eutrophic Chinese Lake (Lake Taihu)

Kong

Chao

Zhuang

et al. 2018

IJERPH

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“…This is not unexpected, as previous estimates have calculated ATP to be less than 2% of the DOP pool (Björkman et al 2018). While our observed pyroP signal includes contributions from polyP and nucleoP α classes, several other studies have found pyroP to account for the majority of phosphoanhydrides in marine particulate material (Paytan et al 2003), cellular cultures (Cade-Menun and Paytan 2010), sediment (Sundareshwar et al 2001), and freshwater particulate and dissolved P (Bai et al 2015). Furthermore, work by Blake et al (2005) has demonstrated the significance of pyrophosphatase and pyroP, the later sourced from triphosate nucleotides, in regulating the δ 18 O signature of P i in seawater.…”

Section: Phosphoanhydridessupporting

confidence: 79%

Resolving marine dissolved organic phosphorus (DOP) composition in a coastal estuary

Bell

Pellechia

Ingall

et al. 2020

Limnology & Oceanography

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A mechanistic understanding of dissolved organic phosphorus (DOP) utilization, and its role in the marine P cycle, requires knowledge of DOP molecular composition. In this study, a recently developed approach coupling electrodialysis and reverse osmosis with solution 31 P-NMR analysis was used to examine DOP composition within a tidally dominated salt-marsh estuary (North Inlet, South Carolina) over seasonal and tidal time frames. The isolation technique allowed for near complete recovery of the DOP pool (90% AE 13%; n = 12) with six broad compound classes quantified: phosphonates, phosphomonoesters, phosphodiesters, pyrophosphate, diand tri-phosphate nucleotides (nucleoP α), and polyphosphate. Our results indicate that phosphomonoesters (ca. 61%) and phosphodiesters (ca. 31%) comprise the majority of the DOP pool, with relatively small contributions from pyrophosphates (ca. 4%), phosphonates (ca. 2%), nucleoP α (ca. 1%), and polyphosphates (ca. 1%). The study found no significant differences in DOP composition or concentration between tidal stages, despite significant tidal changes in dissolved organic nitrogen (DON):DOP stoichiometry. Significant seasonal variation was observed, with higher concentrations of phosphonates, nucleoP α , and monophosphates and lower phosphomonoester concentrations in Fall relative to all other seasons. We hypothesize that these seasonal variations reflect the balance between specific compound class seasonal production, lability, and local P demands associated with marine vs. terrestrial sources. Our results indicate that DOP composition exists at a dynamic equilibrium that is strongly conserved across diverse marine environments.

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“…However, use of a highly alkaline solvent skewed the proportion of long‐chain polyphosphate to short‐chain (Table ), enhancing the terminal phosphoanhydride signal, and also promoted diester hydrolysis, enhancing the monoester signal (Table ). These findings may impact the overall dominance of the monoester class previously found (Paytan et al ; Read et al ; Bai et al ), as well as potential overestimation of pyrophosphates (Sundareshwar et al ; Paytan et al ). In response to this challenge, Read et al () and Bai et al () have grouped pyrophosphates and polyP contributions of each class (Fig.…”

Section: Discussionmentioning

confidence: 88%

“…These findings may impact the overall dominance of the monoester class previously found (Paytan et al 2003;Read et al 2014;Bai et al 2015), as well as potential overestimation of pyrophosphates (Sundareshwar et al 2001;Paytan et al 2003). In response to this challenge, Read et al (2014) and Bai et al (2015) have grouped pyrophosphates and polyP contributions of each class (Fig. 6).…”

Section: Bell Et Almentioning

confidence: 90%

Isolation and molecular characterization of dissolved organic phosphorus using electrodialysis‐reverse osmosis and solution ³¹P‐NMR

Bell

Pellechia

Chambers

et al. 2017

Limnology & Ocean Methods

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The composition of dissolved organic phosphorus (DOP), which directly impacts its biological and chemical reactivity, remains poorly constrained due to methodological and operational challenges. A series of compound‐specific isolation experiments and bulk estuarine seawater isolations were conducted to assess the ability of coupled electrodialysis (ED) and reverse osmosis (RO) to isolate DOP from seawater for molecular characterization using solution 31P‐NMR analysis. These isolations were carried out using a recently developed small‐volume (24 L) ED/RO system. Compound‐specific isolation experiments (n = 7) averaged 64.1% ± 9.2% for final DOP recovery, while recoveries for estuarine seawater (n = 7) were on average 83.8% ± 10.7%. Nearly complete mass balance of DOP was observed for the compound‐specific isolations (88.1% ± 11.2%) with ED responsible for the majority of DOP loss (16% ± 5%). Isolation recovery was impacted by compound molecular weight rather than charge‐to‐size ratio. Isolation bias between bulk dissolved organic carbon and DOP was negligible. Solution 31P‐NMR confirmed that ED/RO isolation does not impact molecular integrity or DOP composition. In addition, solution 31P‐NMR accurately estimated several components (phosphonomethyl‐glycine, D‐glucose‐6‐phosphate, L‐α‐phosphatidylcholine) of an artificial complex DOP matrix. However, we suggest further refinements for ED/RO operation and significant caveats remain for 31P‐NMR sample preparation and the interpretation of 31P‐NMR spectra. Hydrolysis from NaOH dissolution was found to impact the ability to accurately resolve diester composition (ca. 40% underestimation) and discrimination between terminal and central phosphoanhydride atoms. Nonetheless, our results describe a viable option for the isolation and molecular characterization of marine DOP.

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Classes of dissolved and particulate phosphorus compounds and their spatial distributions in the water of a eutrophic lake: a 31P NMR study

Cited by 24 publications

References 54 publications

Spatial and Temporal Distribution of Particulate Phosphorus and Their Correlation with Environmental Factors in a Shallow Eutrophic Chinese Lake (Lake Taihu)

Spatial and Temporal Distribution of Particulate Phosphorus and Their Correlation with Environmental Factors in a Shallow Eutrophic Chinese Lake (Lake Taihu)

Resolving marine dissolved organic phosphorus (DOP) composition in a coastal estuary

Isolation and molecular characterization of dissolved organic phosphorus using electrodialysis‐reverse osmosis and solution ³¹P‐NMR

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Classes of dissolved and particulate phosphorus compounds and their spatial distributions in the water of a eutrophic lake: a 31P NMR study

Cited by 24 publications

References 54 publications

Spatial and Temporal Distribution of Particulate Phosphorus and Their Correlation with Environmental Factors in a Shallow Eutrophic Chinese Lake (Lake Taihu)

Spatial and Temporal Distribution of Particulate Phosphorus and Their Correlation with Environmental Factors in a Shallow Eutrophic Chinese Lake (Lake Taihu)

Resolving marine dissolved organic phosphorus (DOP) composition in a coastal estuary

Isolation and molecular characterization of dissolved organic phosphorus using electrodialysis‐reverse osmosis and solution 31P‐NMR

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Product

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Isolation and molecular characterization of dissolved organic phosphorus using electrodialysis‐reverse osmosis and solution ³¹P‐NMR