Microbial Degradation of Perchlorate: Principles and Applications

Xu, Jinying; Song, Yanguang; Min, Booki; Steinberg, Lisa M.; Logan, Bruce E.

doi:10.1089/109287503768335904

Cited by 165 publications

(99 citation statements)

References 72 publications

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“…Perchlorate-reducing organisms can use a variety of organic carbon substrates as electron donors, such as glucose, acetate, vegetable oils, and natural organic carbon compounds present in soils and sediments (6,8,14,15). Biological transformation of perchlorate has been successfully utilized for drinking water treatment (16)(17) and for in situ groundwater remediation (18)(19)(20)(21).…”

Section: Introductionmentioning

confidence: 99%

Perchlorate Behavior in a Municipal Lake Following Fireworks Displays

Wilkin

Fine

Burnett

2007

Environ. Sci. Technol.

102

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After the fireworks displays, perchlorate concentrations decreased toward the background level within 20 to 80 days, with the rate of attenuation correlating to surface water temperature. Adsorption tests indicate that sediments underlying the water column have limited (<100 nmol/g) capacity to remove perchlorate via chemical adsorption. Microcosms showed comparatively rapid intrinsic perchlorate degradation in the absence of nitrate consistent with the observed disappearance of perchlorate from the study site. This suggests that at sites with appropriate biogeochemical conditions, natural attenuation may be an important factor affecting the fate of perchlorate following fireworks displays.

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Section: Introductionmentioning

confidence: 99%

Perchlorate Behavior in a Municipal Lake Following Fireworks Displays

Wilkin

Fine

Burnett

2007

Environ. Sci. Technol.

102

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“…Chlorate, for example, is highly toxic to brown algae (25,35), and perchlorate may have a direct influence on human health, as it affects the function of iodide transporters in the thyroid and mammary glands (9,17,38). The main source of chlorate contamination is chlorine dioxide (ClO 2 ) bleaching in the pulp and paper industry (8), and the most efficient remediation techniques for both chlorate and perchlorate are based on degradation performed by microorganisms (13,33,43). More than 40 bacterial strains that are able to grow by dissimilatory perchlorate or chlorate reduction have been isolated (2,6,10,13,15,18,21,22,24,36,37,39,40).…”

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confidence: 99%

Expression of Chlorite Dismutase and Chlorate Reductase in the Presence of Oxygen and/or Chlorate as the Terminal Electron Acceptor in Ideonella dechloratans

Lindqvist

Johansson

Nilsson

et al. 2012

Appl Environ Microbiol

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ABSTRACTThe ability of microorganisms to perform dissimilatory (per)chlorate reduction is, for most species, known to be oxygen sensitive. Consequently, bioremediation processes for the removal of oxochlorates will be disturbed if oxygen is present. We measured the expression of chlorite dismutase and chlorate reductase in the presence of different terminal electron acceptors in the chlorate reducerIdeonella dechloratans. Enzyme activity assays and mRNA analyses by real-time quantitative reverse transcription (qRT)-PCR were performed on cell extracts from cells grown aerobically with and without chlorate and on cells grown anaerobically in the presence of chlorate. Our results showed that both chlorite dismutase and chlorate reductase are expressed during aerobic growth. However, transfer to anaerobic conditions with chlorate resulted in significantly enhanced enzyme activities and mRNA levels for both enzymes. Absence of oxygen was necessary for the induction to occur, since chlorate addition under aerobic conditions produced neither increased enzyme activities nor higher relative levels of mRNA. For chlorite dismutase, the observed increase in activity was on the same order of magnitude as the increase in the relative mRNA level, indicating gene regulation at the transcriptional level. However, chlorate reductase showed about 200 times higher enzyme activity in anaerobically induced cells, whereas the increase in mRNA was only about 10-fold, suggesting additional mechanisms influence the enzyme activity.

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“…For its unique chemistry, it has been highly challenging to remove perchlorate from water by traditional water treatment approaches (Hatzinger, 2005). In recent years, various treatment technologies have been developed and/or tested, including biological reduction (Logan and LaPoint, 2002;Min et al, 2004;Xu et al, 2003), ion exchange (IX) (Gu et al, 2001(Gu et al, , 2003Clifford, 2004, 2006;Xiong et al, 2006), tailored activated carbon sorption (Chen et al, 2005;Parette et al, 2005), filtration (Yoon et al, 2003), and chemical reduction (Moore et al, 2003;Gu et al, 2006). However, these technologies are limited by some critical technical and/or economic drawbacks such as slow degradation kinetics and production of large volumes of concentrated process waste residuals.…”

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confidence: 99%

Rapid and complete destruction of perchlorate in water and ion-exchange brine using stabilized zero-valent iron nanoparticles

2007

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Because of the unique chemistry of perchlorate, it has been challenging to destroy perchlorate. This study tested the feasibility of using a new class of stabilized zero-valent iron (ZVI) nanoparticles for complete transformation of perchlorate in water or ionexchange brine. Batch kinetic tests showed that at an iron dosage of 1.8 g L À1 and at moderately elevated temperatures (90-95 1C), $90% of perchlorate in both fresh water and a simulated ion-exchange brine (NaCl ¼ 6% (w/w)) was destroyed within 7 h.

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Microbial Degradation of Perchlorate: Principles and Applications

Cited by 165 publications

References 72 publications

Perchlorate Behavior in a Municipal Lake Following Fireworks Displays

Perchlorate Behavior in a Municipal Lake Following Fireworks Displays

Expression of Chlorite Dismutase and Chlorate Reductase in the Presence of Oxygen and/or Chlorate as the Terminal Electron Acceptor in Ideonella dechloratans

Rapid and complete destruction of perchlorate in water and ion-exchange brine using stabilized zero-valent iron nanoparticles

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