Uranium Speciation and Bioavailability in Aquatic Systems: An Overview

Markich, Scott J.

doi:10.1100/tsw.2002.130

Cited by 201 publications

(154 citation statements)

References 90 publications

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“…The role of phosphate in the speciation of hexavalent uranium is well studied (Markich, 2002). However its role in the speciation of reduced uranium in environmentally relevant systems is less well known.…”

Section: Discussionmentioning

confidence: 99%

Products of abiotic U(VI) reduction by biogenic magnetite and vivianite

Veeramani

Alessi

Suvorova

et al. 2011

Geochimica et Cosmochimica Acta

138

122

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Reductive immobilization of uranium by the stimulation of dissimilatory metal-reducing bacteria (DMRB) has been investigated as a remediation strategy for subsurface U(VI) contamination. In those environments, DMRB may utilize a variety of electron acceptors, such as ferric iron which can lead to the formation of reactive biogenic Fe(II) phases. These biogenic phases could potentially mediate abiotic U(VI) reduction. In this work, the DMRB Shewanella putrefaciens strain CN32 was used to synthesize two biogenic Fe(II)-bearing minerals: magnetite (a mixed Fe(II)-Fe(III) oxide) and vivianite (an Fe(II)-phosphate). Analysis of abiotic redox interactions between these biogenic minerals and U(VI) showed that both biogenic minerals reduced U(VI) completely. XAS analysis indicates significant differences in speciation of the reduced uranium after reaction with the two biogenic Fe(II)-bearing minerals. While biogenic magnetite favored the formation of structurally ordered, crystalline UO 2 , biogenic vivianite led to the formation of a monomeric U(IV) species lacking U-U associations in the corresponding EXAFS spectrum. To investigate the role of phosphate in the formation of monomeric U(IV) such as sorbed U(IV) species complexed by mineral surfaces, versus a U(IV) mineral, uranium was reduced by biogenic magnetite that was pre-sorbed with phosphate. XAS analysis of this sample also revealed the formation of monomeric U(IV) species suggesting that the presence of phosphate hinders formation of UO 2 . This work shows that U(VI) reduction products formed during in situ biostimulation can be influenced by the mineralogical and geochemical composition of the surrounding environment, as well as by the interfacial solute-solid chemistry of the solid-phase reductant.

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Section: Discussionmentioning

confidence: 99%

Products of abiotic U(VI) reduction by biogenic magnetite and vivianite

Veeramani

Alessi

Suvorova

et al. 2011

Geochimica et Cosmochimica Acta

138

122

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“…Generally, uranium occurs in surface waters in a variety of physicochemical forms, including the free metal ion (U 4þ or UO 2 2þ ) and complexes with inorganic ligands (e.g., uranyl carbonate or uranyl phosphate), and humic substances (e.g., uranyl fulvate) in dissolved, colloidal, or particulate forms (Markich, 2002). The major bioavailable forms of U(VI) are likely UO 2 2þ and UO 2 OH þ rather than uranium complexed or adsorbed to colloidal or particulate matter (unpublished data).…”

Section: Interactions Of Uranium Ions and Phosphate In The Mediummentioning

confidence: 99%

“…The major bioavailable forms of U(VI) are likely UO 2 2þ and UO 2 OH þ rather than uranium complexed or adsorbed to colloidal or particulate matter (unpublished data). U(VI) complexed with inorganic ligands (e.g., carbonate, sulfate, or phosphate) and humic substances apparently reduce the bioavailability of uranium by reducing the activity of UO 2 2þ and UO 2 OH þ (Kohler et al, 1996;Dodge and Francis, 1997;Markich, 2002).…”

Section: Interactions Of Uranium Ions and Phosphate In The Mediummentioning

confidence: 99%

Phosphate regulates uranium(VI) toxicity to Lemna gibba L. G3

Mkandawire

Vogel

Taubert

et al. 2007

Environmental Toxicology

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The influence of phosphate on the toxicity of uranium to Lemna gibba G3 was tested in semicontinuous culture with synthetic mine water developed as an analogue of surface water of two abandoned uranium mining and ore processing sites in Saxony, Germany. Six concentrations of uranium were investigated under five different supply regimes of PO 4 3À at constant pH (7.0 6 0.5) and alkalinity (7.0 6 1.6 mg L À1 total CO 3 2À). The results showed significant inhibition of specific growth rates in cultures exposed to the highest uranium concentrations (3500 and 7000 g U L À1 ) at lowest PO 4 3À supply of 0.01 mg LÀ1 . An increase of phosphate concentration from 0.01 to 8.0 mg L À1 resulted in an increase of EC 50 from 0.9 6 0.2 to 7.4 6 1.9 mg L À1 (significant with Student's t test, P > 0.05). The accumulation of uranium in L. gibba increased exponentially with the increase in uranium concentration in cultures with 0.01 and 0.14 mg PO 4 3À L À1. Accumulation also increased significantly when PO 4 3À supply was increased from 0.14 to 1.36 mg PO 4 3À L À1 for all uranium concentrations. However, as the supply of PO 4 3À gradually increased from 1.36 to 8.0 mg PO 4 3À L À1 , uranium bioaccumulation increased slightly but insignificantly before leveling off. Uranium speciation modeling with PhreeqC geochemical code predicted increases in the proportions of uranyl phosphate species when PO 4 3À concentrations increase in the media. Most of these uranyl phosphate species have a high probability of precipitation [saturation indices (SI) > 0.93]. Therefore, the alleviation of uranium toxicity to L. gibba with phosphates is due to interactions among components of the media, mainly uranyl and phosphate which results in precipitation. Consequently, bioavailable fractions of uranium to L. gibba are reduced. This might explain lack of consistent EC 50 values for uranium to most aquatic organisms. # 2007 Wiley Periodicals, Inc. Environ Toxicol 22: 9-16, 2007.

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“…It is important to understand how these different U species interact with bacterial cellular surfaces, especially for designing biological wastewater treatment systems. However, studies evaluating the effect of aqueous U speciation have been largely limited to biosorption, bioaccumulation, and bioreduction (9,15,16,20).Among the biological mechanisms involved in metal remediation, enzymatic bioprecipitation of heavy metals as metal phosphates is particularly attractive and is considered to be a promising approach for biological treatment of U effluents due to its high efficiency (14, 21). Bioprecipitation of metals as phosphates is mediated by phosphatases that cleave a phosphomonoester substrate (such as ␤-glycerophosphate) to release the phosphate moiety, which in turn precipitates heavy metals, such as U, Cd, Ni, Am, etc., from solutions (22, 23).…”

mentioning

confidence: 99%

Interaction of Uranium with Bacterial Cell Surfaces: Inferences from Phosphatase-Mediated Uranium Precipitation

Kulkarni

Misra

Gupta

et al. 2016

Appl Environ Microbiol

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Deinococcus radiodurans and Escherichia coli expressing either PhoN, a periplasmic acid phosphatase, or PhoK, an extracellular alkaline phosphatase, were evaluated for uranium (U) bioprecipitation under two specific geochemical conditions (GCs): (i) a carbonate-deficient condition at near-neutral pH (GC1), and (ii) a carbonate-abundant condition at alkaline pH (GC2). Transmission electron microscopy revealed that recombinant cells expressing PhoN/PhoK formed cell-associated uranyl phosphate precipitate under GC1, whereas the same cells displayed extracellular precipitation under GC2. These results implied that the cell-bound or extracellular location of the precipitate was governed by the uranyl species prevalent at that particular GC, rather than the location of phosphatase. MINTEQ modeling predicted the formation of predominantly positively charged uranium hydroxide ions under GC1 and negatively charged uranyl carbonate-hydroxide complexes under GC2. Both microbes adsorbed 6-to 10-fold more U under GC1 than under GC2, suggesting that higher biosorption of U to the bacterial cell surface under GC1 may lead to cell-associated U precipitation. In contrast, at alkaline pH and in the presence of excess carbonate under GC2, poor biosorption of negatively charged uranyl carbonate complexes on the cell surface might have resulted in extracellular precipitation. The toxicity of U observed under GC1 being higher than that under GC2 could also be attributed to the preferential adsorption of U on cell surfaces under GC1. This work provides a vivid description of the interaction of U complexes with bacterial cells. The findings have implications for the toxicity of various U species and for developing biological aqueous effluent waste treatment strategies. IMPORTANCEThe present study provides illustrative insights into the interaction of uranium (U) complexes with recombinant bacterial cells overexpressing phosphatases. This work demonstrates the effects of aqueous speciation of U on the biosorption of U and the localization pattern of uranyl phosphate precipitated as a result of phosphatase action. Transmission electron microscopy revealed that location of uranyl phosphate (cell associated or extracellular) was primarily influenced by aqueous uranyl species present under the given geochemical conditions. The data would be useful for understanding the toxicity of U under different geochemical conditions. Since cell-associated precipitation of metal facilitates easy downstream processing by simple gravitybased settling down of metal-loaded cells, compared to cumbersome separation techniques, the results from this study are of considerable relevance to effluent treatment using such cells. Bioremediation strategies, such as bioreduction (1-3), biosorption (4-8), bioaccumulation (9, 10), and bioprecipitation (5, 11, 12, 13), have been studied for their potential to immobilize U from solutions. There is also a large body of work on microbial interactions with uranium relevant to environmental in situ bioremediation. The...

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Uranium Speciation and Bioavailability in Aquatic Systems: An Overview

Cited by 201 publications

References 90 publications

Products of abiotic U(VI) reduction by biogenic magnetite and vivianite

Products of abiotic U(VI) reduction by biogenic magnetite and vivianite

Phosphate regulates uranium(VI) toxicity to Lemna gibba L. G3

Interaction of Uranium with Bacterial Cell Surfaces: Inferences from Phosphatase-Mediated Uranium Precipitation

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