Coupled dynamics of iron, manganese, and phosphorus in brackish coastal sediments populated by cable bacteria

Hermans, Martijn; Pascual, Marina Astudillo; Behrends, Thilo; Lenstra, Wytze K.; Conley, Daniel J.; Slomp, Caroline P.

doi:10.1002/lno.11776

Cited by 22 publications

(11 citation statements)

References 79 publications

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“…Manganese oxides found in aquatic systems are typically characterized as poorly crystalline birnessite phases. , Birnessite phases of varying symmetry and structure have also been directly associated with Mn oxide production by bacteria and fungi. , Thus, the Mn(IV) phases in Siders Pond and found in our dark unfiltered incubation experiment are consistent with those within other natural systems and produced biologically. , Additionally, the occurrence of more reduced Mn oxides like feitknechtite and triclinic birnessite within XAS samples from the pond, which were present in substantial fractions in light unfiltered incubations but not dark unfiltered incubations, indicates that photoreduction likely also plays a role in Mn mineralogy in Siders Pond.…”

Section: Discussionsupporting

confidence: 75%

“…The XANES spectrum of this sample (Figure S11) is missing the feature found at ∼6560 eV in the rhodochrosite spectrum as measured by Boulard et al 62 Manganese oxides found in aquatic systems are typically characterized as poorly crystalline birnessite phases. 63,64 Birnessite phases of varying symmetry and structure have also been directly associated with Mn oxide production by bacteria and fungi. 49,57 Thus, the Mn(IV) phases in Siders Pond and found in our dark unfiltered incubation experiment are consistent with those within other natural systems and produced biologically.…”

Section: ■ Resultsmentioning

confidence: 99%

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Particle- and Light-Mediated Processes Control Seasonal Manganese Oxide Cycling in a Meromictic Pond

Gadol,

Ostrander,

Villarroel

et al. 2023

ACS Earth Space Chem.

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Manganese (Mn) oxides are strong oxidants and sorbents of nutrients and contaminants, thus their formation mechanisms impact multiple biogeochemical cycles. Manganese in oxic surface waters is often found as dissolved Mn species, such as Mn(II) and Mn(III)-ligand complexes, rather than Mn oxides. This is believed to be a result of Mn oxide reduction by hydrogen peroxide associated with photolysis of organic matter and direct organic matter-mediated reduction within sunlit waters. Nevertheless, Mn oxides can persist in some surface environments, which indicates an incomplete understanding of controls on Mn oxide distributions. Here, we couple field- and lab-based analyses to explore Mn oxide distributions, Mn oxidation rates, and underlying controls on Mn oxide formation within Siders Pond, a brackish and meromictic pond on Cape Cod (Massachusetts, USA) during the summer and fall of 2020. Manganese oxides were observed consistently in sunlit surface waters with concentrations declining to undetectable at the base of the chemocline. Surface Mn oxide concentrations were highest in late summer, reaching concentrations of ∼1 μM, and lowest in late fall, reaching only ∼50 nM. Minerals identified using synchrotron-based absorbance measurements were structurally similar to δ-MnO2 and feitknechtite. Substantial light-mediated Mn oxidation only took place in live incubations of Siders Pond water while net Mn reduction proceeded in killed incubations. Thus, total particle-mediated oxidation by microbes and minerals combined outpaced photoreduction, leading to net accumulation of Mn oxides within Siders Pond. Our results identify important roles for microbial- and mineral-mediated oxidation in determining Mn oxide distributions within surface waters of a natural setting, a finding that may help explain comparable distributions in other locations.

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Section: Discussionsupporting

confidence: 75%

Section: ■ Resultsmentioning

confidence: 99%

Particle- and Light-Mediated Processes Control Seasonal Manganese Oxide Cycling in a Meromictic Pond

Gadol,

Ostrander,

Villarroel

et al. 2023

ACS Earth Space Chem.

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“…Phosphorus is also a key player in the geochemical cycle of TOC (Arif et al, 2021) and is easily fixed or affected by Fe minerals (März et al, 2018). The leading states of phosphorus nutrients in marine sediments include exchangeable, organic, iron-bound, autoecological apatite, detrital, and refractory organic (Fang and Wang, 2021), two-thirds of which are related to poorly crystalline iron and manganese oxides (Hermans et al, 2021). In aquatic and terrestrial systems, the interaction between phosphate and ferric oxides typically involves adsorption/desorption (Boujelben et al, 2008;Yoon et al, 2014), precipitation/dissolution of surface Fephosphate phases (Weng et al, 2012), and precipitation of phosphate in iron (III) oxides (Cheng et al, 2015;März et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Vertical distribution of Fe, P and correlation with organic carbon in coastal sediments of Yellow Sea, Eastern China

Gao

Chen

et al. 2023

Front. Mar. Sci.

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The coastal zone is considered as a major carbon pool. Iron minerals and phosphates are vital factors affecting the amounts and occurrence of total organic carbon (TOC) in sediments. However, coupling mechanisms of iron (Fe) and phosphorous (P) in the source-sink transition of TOC in coastal sediments is poorly understood. This study characterized the distribution of Fe, P and TOC contents of three independent 170 cm sediment cores sampled from a coastal aquaculture area in the eastern Jiangsu Province, and quantified the correlations among Fe, P, median grain diameter (Dx(50)), and TOC. The results showed total phosphorus (TP) content ranges in a scope of 337.4-578.0 mg/kg, and many depths recorded moderate P eutrophication. Inorganic phosphorus (DA + IP) and biogenic apatite were the primary components of TP, accounting for 25.19–55.00 and 26.71–49.62%, respectively. The Fe contents varied from 987.9 mg/kg to 2900.7 mg/kg, in which oxidized iron (Feox) accounted for about 62.2–79.4%. In the vertical profile, the TOC was positively correlated with the contents of low-crystallinity Fe-bearing carbonates (Fecarb), high crystallinity pyrite (FePy), iron-bound phosphorus (PCDB), manganeses (Mn), and nitrogen (N), while it was negatively correlated with DA + IP, organic phosphorus (OP), and Dx(50). Based on the the partial least squares (PLS) model, we proposed that the higher FePy, Mn, magnetite (FeMag), Fecarb, PCDB, amorphous exchangeable Fe (Ex-Fe), and authigenic apatite phosphorus (Bio-P) in sediments represent the high capacity for TOC sink, whereas, higher DA + IP, and OP indicate a TOC conversion to the source. The non-siginificat indication of Feox on TOC source-sink is due to its surplus and strong reactivity relative to TOC content. These revealed correlations provide a theoretical reference for understanding and regulating the burial rate and storage of TOC by changing the input of Fe minerals and P components into coastal sediments.

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“…Although anaerobic mineralization of org‐P continuously sustains sediment pore water with dissolved P that support P release to the water column, a significant proportion of the org‐P present in the surface sediment resists degradation and therefore becomes a major sink for permanent P burial (Mort et al 2010; Hermans et al 2021). Various forms of org‐P differ in resistance to degradation during sediment diagenesis (Ahlgren et al 2006), depending on organic matter supply and its composition, and bottom water O 2 conditions (Defforey and Paytan 2018).…”

mentioning

confidence: 99%

“…Typically, declining org-P contents with depth in Baltic Sea sediments indicate mineralization of org-P in areas where sediment accumulates, either in coastal zones (Lukkari et al 2009;Rydin et al 2011;van Helmond et al 2020) or offshore (Mort et al 2010;Malmaeus and Karlsson 2012). In sediments overlain by oxic bottom water, dissolved phosphate can be temporarily trapped by iron (Fe) and manganese (Mn) (oxy)(hydr)oxides (Conley et al 2002), scavenged by calcium-rich Mn carbonates (Mort et al 2010), precipitated as Mn(II) phosphates (Hermans et al 2019(Hermans et al , 2021, or stored as polyphosphate (poly-P) in prokaryotic organisms (Hupfer et al 1995). Deoxygenation, in turn, can mobilize stored phosphate due to reductive dissolution of P bearing Fe and Mn (oxy)(hydr)oxides (Jilbert et al 2011) and preferential degradation of poly-P (Brock and Schulz-Vogt 2011;Jones et al 2016), and can then be recycled to the bottom water.…”

mentioning

confidence: 99%

Contrasting distribution and speciation of sedimentary organic phosphorus among different basins of the Baltic Sea

Rydin

Broman

Reitzel

et al. 2023

Limnology & Oceanography

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Recycling of phosphorus (P) from deoxygenated sediments perpetuates eutrophic conditions in parts of the Baltic Sea. Sedimentary organic P is a major source of dissolved P to the water column, but also a sink for permanent P burial. The mechanisms behind these two pathways are, however, largely unknown. Using new methods, we determined P in DNA and phospholipids, which are both found in all organisms. We also identified inositol phosphates that are particularly important in eukaryotes. Sediment cores were collected from contrasting basins in the Baltic Sea to study their relative contribution to the total P pool. We found high DNA-P/phospholipid-P ratios in surface sediments from the Bothnian Bay and Bothnian Sea. However, these ratios were low throughout profiles in euxinic Baltic Proper sediments. The elevated ratios present in sediments overlain by oxic bottom waters might indicate the presence of a microbial community stimulated by bioturbation, whereas the low DNA-P/phospholipid-P ratios in Baltic Proper sediments likely indicate an energy-limited microbial community, typical to the "deep biosphere" environment. Inositol-P was almost absent in euxinic Baltic Proper sediments that had a low total P amount compared to those in the other basins. We suggest that variability in the composition of sedimentary microbial communities among the Baltic Sea basins might cause differences in organic P forms that in turn affects its turnover.

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Coupled dynamics of iron, manganese, and phosphorus in brackish coastal sediments populated by cable bacteria

Cited by 22 publications

References 79 publications

Particle- and Light-Mediated Processes Control Seasonal Manganese Oxide Cycling in a Meromictic Pond

Particle- and Light-Mediated Processes Control Seasonal Manganese Oxide Cycling in a Meromictic Pond

Vertical distribution of Fe, P and correlation with organic carbon in coastal sediments of Yellow Sea, Eastern China

Contrasting distribution and speciation of sedimentary organic phosphorus among different basins of the Baltic Sea

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