Eukaryote-Dominated Biofilms and Their Significance in Acidic Environments

Brake, Sandra S.; Hasiotis, Stephen T.

doi:10.1080/01490451003702966

Cited by 35 publications

(18 citation statements)

References 169 publications

(233 reference statements)

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“…The most conspicuous feature of this AMD system is the presence of Fe-rich stromatolites overlain by E. mutabilis-dominated biofilms. It has been proposed that E. mutabilis directly or indirectly produced stromatolites through phototactic and aerotactic activities by binding Fe and Al chemical precipitates that periodically covered the biofilms, in a way similar to stromatolite-building prokaryotes in marine settings (Brake et al, 2002;Brake and Hasiotis, 2010).…”

Section: Euglena Under Extreme Conditions and As An Organism For Biormentioning

confidence: 99%

Euglenoid flagellates: A multifaceted biotechnology platform

Krajčovič

Vesteg

Schwartzbach

2015

Journal of Biotechnology

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Section: Euglena Under Extreme Conditions and As An Organism For Biormentioning

confidence: 99%

Euglenoid flagellates: A multifaceted biotechnology platform

Krajčovič

Vesteg

Schwartzbach

2015

Journal of Biotechnology

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“…Fungi are known to be metal resistant and occur in abundance in acidic, metal-rich environments observed in terrestrial ecosystems, such as aquifers (e.g., see references 14 and 15); thus, they could play an important role in contaminant transformation in the subsurface of U.S. DOE sites. Traits that favor the survival of fungi under the extreme conditions found in the radionuclide-contaminated acidic subsurface include facultative anaerobic growth, resistance to acidic pH, resistance to toxic metals, spore formation, and in some cases, radiation-enhanced growth (14,16). Additionally, previous research has also demonstrated a role of fungi in denitrification (17,18).…”

mentioning

confidence: 99%

“…To our knowledge, the occurrence of fungi has been described for few pristine and contaminated aquifers (28,29), and the community composition of these microbial eukaryotes in subsurface environments remains poorly characterized. We hypothesized that the structure and composition of the subsurface fungal community are impacted by the subsurface pH gradient across the contaminated watershed and that this group of organisms contributes significantly to in situ denitrification in the contaminated subsurface, in part due to a greater tolerance of acidity by many fungi relative to that by bacteria (14,15). Thus, the objective of this study was to interrogate subsurface fungal communities through a close coupling of microbiological and biogeochemical approaches.…”

mentioning

confidence: 99%

Watershed-Scale Fungal Community Characterization along a pH Gradient in a Subsurface Environment Cocontaminated with Uranium and Nitrate

Jasrotia

Green

Canion

et al. 2014

Appl Environ Microbiol

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The objective of this study was to characterize fungal communities in a subsurface environment cocontaminated with uranium and nitrate at the watershed scale and to determine the potential contribution of fungi to contaminant transformation (nitrate attenuation). The abundance, distribution, and diversity of fungi in subsurface groundwater samples were determined using quantitative and semiquantitative molecular techniques, including quantitative PCR of eukaryotic small-subunit rRNA genes and pyrosequencing of fungal internal transcribed spacer (ITS) regions. Potential bacterial and fungal denitrification was assessed in sediment-groundwater slurries amended with antimicrobial compounds and in fungal pure cultures isolated from the subsurface. Our results demonstrate that subsurface fungal communities are dominated by members of the phylum Ascomycota, and a pronounced shift in fungal community composition occurs across the groundwater pH gradient at the field site, with lower diversity observed under acidic (pH <4.5) conditions. Fungal isolates recovered from subsurface sediments, including cultures of the genus Coniochaeta, which were detected in abundance in pyrosequence libraries of site groundwater samples, were shown to reduce nitrate to nitrous oxide. Denitrifying fungal isolates recovered from the site were classified and found to be distributed broadly within the phylum Ascomycota and within a single genus of the Basidiomycota. Potential denitrification rate assays with sediment-groundwater slurries showed the potential for subsurface fungi to reduce nitrate to nitrous oxide under in situ acidic pH conditions.

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“…Thus, there is only limited information available on the immobilization behavior of eukaryotes or microbial biofilms on metal removal in AMD environments [11,12]. However, biofilm communities, containing large amounts of eukaryotes, may play a significant role in mediating their environment by actively and passively contributing to metal attenuation through various processes of biosorption and via formation of laminated organosedimentary structures [13]. Some representatives of the euglenoids -which contain about 44 free-living genera and more than 800 species [14] -e.g.…”

Section: Introductionmentioning

confidence: 99%

“…In this study, for the first time the bioaccumulation of uranium by Euglena mutabilis, a eukaryotic organisms often observed in microbial communities forming biofilms and mats in AMD environments [13,15] was investigated by laser-induced fluorescence spectroscopy (LIFS) at pH 3 and 4. This technique has superior sensitivity for fluorescent metal ions, e.g.…”

Section: Introductionmentioning

confidence: 99%

Speciation of bioaccumulated uranium(VI) by Euglena mutabilis cells obtained by laser fluorescence spectroscopy

Brockmann¹,

Arnold

Bernhard

2014

Radiochimica Acta

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The ability of Euglena mutabilis cells -a unicellular protozoan with a flexible pellicle, which is typically found in acid mine drainage (AMD) environments -to bioaccumulate uranium under acid conditions was studied in batch sorption experiments at pH 3 and 4 using Na 2 SO 4 and NaClO 4 as background media. It was found that axenic cultures of Euglena mutabilis Schmitz were able to bioaccumulate in 5 days 94.9 to 99.2% of uranium from a 1 × 10 −5 mol/L uranium solution in perchlorate medium and 95.1 to 95.9% in sodium sulfate medium, respectively. The speciation of uranium in solution and uranium bioaccumulated by Euglena mutabilis cells, were studied by laser induced fluorescence spectroscopy (LIFS). The LIFS investigations showed that the uranium speciation in the NaClO 4 systems was dominated by free uranyl(VI) species and that the UO 2 SO 4 species was dominating in the Na 2 SO 4 medium. Fluorescence spectra of the bioaccumulated uranium revealed that aqueous uranium binds to carboxylic and/or (organo)phosphate groups located on the euglenid pellicle or inside the Euglena mutabilis cells.Reduced uranium immobilization rates of 0.93-1.43 mg uranium per g Euglena mutabilis biomass were observed in similar experiments, using sterile filtrated AMD waters containing, 4.4 × 10 −5 mol/L uranium. These lower rates were attributed to competition with other cations for available sorption sites. Additional LIFS measurements, however, showed that the speciation of the bioaccumulated uranium by the Euglena mutabilis cells was found to be identical with the uranium speciation found in the bioaccumulation experiments carried out in Na 2 SO 4 and NaClO 4 media.The results indicate that Euglena mutabilis has the potential to immobilize aqueous uranium under acid condition and thus may be used in future as promising agent for immobilizing uranium in low pH waste water environments.

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Eukaryote-Dominated Biofilms and Their Significance in Acidic Environments

Cited by 35 publications

References 169 publications

Euglenoid flagellates: A multifaceted biotechnology platform

Euglenoid flagellates: A multifaceted biotechnology platform

Watershed-Scale Fungal Community Characterization along a pH Gradient in a Subsurface Environment Cocontaminated with Uranium and Nitrate

Speciation of bioaccumulated uranium(VI) by Euglena mutabilis cells obtained by laser fluorescence spectroscopy

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