Uranyl Precipitation by<i>Pseudomonas aeruginosa</i>via Controlled Polyphosphate Metabolism

Renninger, Neil S.; Knopp, R.; Nitsche, H.; Clark, Douglas S.; Keasling, Jay D.

doi:10.1128/aem.70.12.7404-7412.2004

Cited by 108 publications

(61 citation statements)

References 62 publications

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“…The tolerance to U exhibited by gram-positive and gramnegative microorganisms may be explained by several different cellular mechanisms, as previously reported by other investigators (30,49,55). One mechanism, bioadsorption, has recently been hypothesized to occur in a well-characterized Arthrobacter type strain, the A. nicotianae type strain (59).…”

Section: Vol 72 2006 Horizontal Gene Transfer Of P Ib -Type Atpasesmentioning

confidence: 62%

Horizontal Gene Transfer of P _IB -Type ATPases among Bacteria Isolated from Radionuclide- and Metal-Contaminated Subsurface Soils

Martinez

Wang

Raimondo

et al. 2006

Appl Environ Microbiol

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Aerobic heterotrophs were isolated from subsurface soil samples obtained from the U.S. Department of Energy's (DOE) Field Research Center (FRC) located at Oak Ridge, Tenn. The FRC represents a unique, extreme environment consisting of highly acidic soils with cooccurring heavy metals, radionuclides, and high nitrate concentrations. Four hundred isolates obtained from contaminated soil were assayed for heavy metal resistance, and a smaller subset was assayed for tolerance to uranium. The vast majority of the isolates were gram-positive bacteria and belonged to the high-G؉C-and low-G؉C-content genera Arthrobacter and Bacillus, respectively. Genomic DNA from a randomly chosen subset of 50 Pb-resistant (Pb r ) isolates was amplified with PCR primers specific for P IB -type ATPases (i.e., pbrA/cadA/zntA). A total of 10 pbrA/cadA/zntA loci exhibited evidence of acquisition by horizontal gene transfer. A remarkable dissemination of the horizontally acquired P IB -type ATPases was supported by unusual DNA base compositions and phylogenetic incongruence. Numerous Pb r P IB -type ATPase-positive FRC isolates belonging to the genus Arthrobacter tolerated toxic concentrations of soluble U(VI) (UO 2 2؉ ) at pH 4. These unrelated, yet synergistic, physiological traits observed in Arthrobacter isolates residing in the contaminated FRC subsurface may contribute to the survival of the organisms in such an extreme environment. This study is, to the best of our knowledge, the first study to report broad horizontal transfer of P IB -type ATPases in contaminated subsurface soils and is among the first studies to report uranium tolerance of aerobic heterotrophs obtained from the acidic subsurface at the DOE FRC.The remediation of hazardous mixed-waste sites, particularly those cocontaminated with heavy metals and radionuclides, is one of the most costly environmental challenges currently faced by the United States and other countries. Interactions between microorganisms, radionuclides, and metals that promote their precipitation and immobilization in situ are promising strategies for treatment and cleanup of the contaminated subsurface (1, 15). At mixed-waste sites where the concentrations of metal contaminants can reach toxic levels, the metal resistance of indigenous microbial populations could be critical for the success of in situ biostimulation efforts. For example, while a number of microbes can carry out reductive precipitation of radionuclides (e.g., Desulfovibrio sp., Geobacter sp., and Shewanella sp.) (28,44,63), the sensitivity of these organisms to heavy metals could possibly limit their in situ activities. Thus, the metal sensitivity of some radionuclide-reducing microbes suggests that the acquisition of metal resistance traits (e.g., P IB -type ATPases that regulate the transport of heavy metals) might be conducive to facilitating and/or enhancing microbial metabolism during subsequent biostimulation activities in metal-and radionuclide-contaminated subsurface environments.The P-type ATPases represent a chromosomally en...

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Section: Vol 72 2006 Horizontal Gene Transfer Of P Ib -Type Atpasesmentioning

confidence: 62%

Horizontal Gene Transfer of P _IB -Type ATPases among Bacteria Isolated from Radionuclide- and Metal-Contaminated Subsurface Soils

Martinez

Wang

Raimondo

et al. 2006

Appl Environ Microbiol

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“…Electron microscopy analyses of cells exposed to these elements demonstrated intracellular localization with phosphate-rich granules, suggesting that contaminant sequestration may be achieved by polyphosphates and may protect sensitive cytosolic molecules from oxidative damage. In addition to polyphosphate chelation of metals and radionuclides, an engineered Pseudomonas aeruginosa strain overexpressing the ppk gene was shown to enhance intracellular phosphate concentrations when compared to the wildtype strain [133]. Upon nutrient starvation, polyphosphate depolymerization and efflux of phosphate into the media containing U(VI) promoted the removal of 80% of the soluble U(VI) as a uranyl phosphate precipitate.…”

Section: Biological Approaches To Phosphate-mediated Immobilization Omentioning

confidence: 99%

“…In response to the local geochemistry of contaminated environments, production of intracellular polyphosphate provides microorganisms with a means to sequester toxic ions within the cell cytosol as well as the regulation of gene(s) expressed in response to cellular stress (e.g., DNA repair, RNA polymerase sigma factor, and pH extremes) [55,[127][128][129][130][131]. The reactivity of cytosolic polyphosphates has been shown to facilitate intracellular sequestration of Cd, Cu, Hg, Pb, U, and Zn in genetically engineered bacterial strains as well as naturally occurring archaeal and bacterial strains [52,55,[132][133][134][135][136]. Electron microscopy analyses of cells exposed to these elements demonstrated intracellular localization with phosphate-rich granules, suggesting that contaminant sequestration may be achieved by polyphosphates and may protect sensitive cytosolic molecules from oxidative damage.…”

Section: Biological Approaches To Phosphate-mediated Immobilization Omentioning

confidence: 99%

Phosphate-Mediated Remediation of Metals and Radionuclides

Martinez

Beazley

Sobecky

2014

Advances in Ecology

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Worldwide industrialization activities create vast amounts of organic and inorganic waste streams that frequently result in significant soil and groundwater contamination. Metals and radionuclides are of particular concern due to their mobility and longterm persistence in aquatic and terrestrial environments. As the global population increases, the demand for safe, contaminantfree soil and groundwater will increase as will the need for effective and inexpensive remediation strategies. Remediation strategies that include physical and chemical methods (i.e., abiotic) or biological activities have been shown to impede the migration of radionuclide and metal contaminants within soil and groundwater. However, abiotic remediation methods are often too costly owing to the quantities and volumes of soils and/or groundwater requiring treatment. The in situ sequestration of metals and radionuclides mediated by biological activities associated with microbial phosphorus metabolism is a promising and less costly addition to our existing remediation methods. This review highlights the current strategies for abiotic and microbial phosphatemediated techniques for uranium and metal remediation.

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“…Such intracellular sequestration within phosphate-rich granules or polyphosphates decreases the intracellular U concentration thereby protecting sensitive cytosolic molecules from U toxicity (6,20,21). On the other hand, the hydrolysis or degradation of polyphosphates in response to heavy metals or nutrient stress has been proposed to precipitate heavy metals extracellularly, enabling metal detoxification (23,24). The overexpression of the polyphosphate kinase (ppk) gene in Pseudomonas aeruginosa results in the significant accumulation of polyphosphates which degrade under carbon-starved conditions, and the phosphates released therefrom precipitate uranyl out of the solutions (24).…”

mentioning

confidence: 99%

“…On the other hand, the hydrolysis or degradation of polyphosphates in response to heavy metals or nutrient stress has been proposed to precipitate heavy metals extracellularly, enabling metal detoxification (23,24). The overexpression of the polyphosphate kinase (ppk) gene in Pseudomonas aeruginosa results in the significant accumulation of polyphosphates which degrade under carbon-starved conditions, and the phosphates released therefrom precipitate uranyl out of the solutions (24). Several environmental strains, such as Cellulomonas, Arthrobacter, Rahnella, and Bacillus, isolated from contaminated subsurface soils of the Department of Energy's Field Research Centre (ORFRC) were shown to immobilize uranium as a biogenic phosphate mineral resulting from polyphosphate metabolism or organophosphate hydrolase activity (25)(26)(27).…”

mentioning

confidence: 99%

Unusual Versatility of the Filamentous, Diazotrophic Cyanobacterium Anabaena torulosa Revealed for Its Survival during Prolonged Uranium Exposure

Acharya

Chandwadkar

Nayak

2017

Appl Environ Microbiol

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Reports on interactions between cyanobacteria and uranyl carbonate are rare. Here, we present an interesting succession of the metabolic responses employed by a marine, filamentous, diazotrophic cyanobacterium, Anabaena torulosa for its survival following prolonged exposure to uranyl carbonate extending up to 384 h at pH 7.8 under phosphate-limited conditions. The cells sequestered uranium (U) within polyphosphates on initial exposure to 100 M uranyl carbonate for 24 to 28 h. Further incubation until 120 h resulted in (i) significant degradation of cellular polyphosphates causing extensive chlorosis and cell lysis, (ii) akinete differentiation followed by (iii) extracellular uranyl precipitation. X-ray diffraction (XRD) analysis, fluorescence spectroscopy, X-ray absorption near edge structure (XANES), and extended X-ray absorption fine structure (EXAFS) spectroscopy established the identity of the bioprecipitated uranium as a U(VI) autunite-type mineral, which settled at the bottom of the vessel. Surprisingly, A. torulosa cells resurfaced as small green flakes typical of actively growing colonies on top of the test solutions within 192 to 240 h of U exposure. A consolidated investigation using kinetics, microscopy, and physiological and biochemical analyses suggested a role of inducible alkaline phosphatase activity of cell aggregates/akinetes in facilitating the germination of akinetes leading to substantial regeneration of A. torulosa by 384 h of uranyl incubation. The biomineralized uranium appeared to be stable following cell regeneration. Altogether, our results reveal novel insights into the survival mechanism adopted by A. torulosa to resist sustained uranium toxicity under phosphate-limited oxic conditions. IMPORTANCE Long-term effects of uranyl exposure in cyanobacteria under oxic phosphate-limited conditions have been inadequately explored. We conducted a comprehensive examination of the metabolic responses displayed by a marine cyanobacterium, Anabaena torulosa, to cope with prolonged exposure to uranyl carbonate at pH 7.8 under phosphate limitation. Our results highlight distinct adaptive mechanisms harbored by this cyanobacterium that enabled its natural regeneration following extensive cell lysis and uranium biomineralization under sustained uranium exposure. Such complex interactions between environmental microbes such as Anabaena torulosa and uranium over a broader time range advance our understanding on the impact of microbial processes on uranium biogeochemistry.KEYWORDS biomineralization, cyanobacteria, phosphatase, polyphosphates, regeneration, uranium M icroorganisms have existed on earth for at least 3.5 billion years (1) and are the most successful life forms to date (2). They have been exposed to their immediate environments comprising essential elements or complex mixtures of naturally occur-

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Uranyl Precipitation byPseudomonas aeruginosavia Controlled Polyphosphate Metabolism

Cited by 108 publications

References 62 publications

Horizontal Gene Transfer of P _IB -Type ATPases among Bacteria Isolated from Radionuclide- and Metal-Contaminated Subsurface Soils

Horizontal Gene Transfer of P _IB -Type ATPases among Bacteria Isolated from Radionuclide- and Metal-Contaminated Subsurface Soils

Phosphate-Mediated Remediation of Metals and Radionuclides

Unusual Versatility of the Filamentous, Diazotrophic Cyanobacterium Anabaena torulosa Revealed for Its Survival during Prolonged Uranium Exposure

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Uranyl Precipitation byPseudomonas aeruginosavia Controlled Polyphosphate Metabolism

Cited by 108 publications

References 62 publications

Horizontal Gene Transfer of P IB -Type ATPases among Bacteria Isolated from Radionuclide- and Metal-Contaminated Subsurface Soils

Horizontal Gene Transfer of P IB -Type ATPases among Bacteria Isolated from Radionuclide- and Metal-Contaminated Subsurface Soils

Phosphate-Mediated Remediation of Metals and Radionuclides

Unusual Versatility of the Filamentous, Diazotrophic Cyanobacterium Anabaena torulosa Revealed for Its Survival during Prolonged Uranium Exposure

Contact Info

Product

Resources

About

Horizontal Gene Transfer of P _IB -Type ATPases among Bacteria Isolated from Radionuclide- and Metal-Contaminated Subsurface Soils

Horizontal Gene Transfer of P _IB -Type ATPases among Bacteria Isolated from Radionuclide- and Metal-Contaminated Subsurface Soils