Structure and Species Composition of Mercury-Reducing Biofilms

Wagner‐Döbler, Irene; Lünsdorf, Heinrich; Lübbehüsen, Tina Louise; Canstein, H.F. von; Li, Y.

doi:10.1128/aem.66.10.4559-4563.2000

Cited by 58 publications

(33 citation statements)

References 15 publications

(7 reference statements)

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“…The metallic mercury is retained in the matrix of the bioreactor in the form of mercury droplets (3,30). This energy-dependent reaction is an ancient and ubiquitous mechanism of bacteria to detoxify their surrounding environment (11,16,18,24).…”

mentioning

confidence: 99%

“…Mercury-reducing bioreactors operated with nonsterile chloralkali wastewater have been shown to be colonized by invading mercury-resistant bacteria, and they exhibited increased microbial diversity and stable performance (7,28,30). To better understand the structure and activity of microbial communities in response to an invasion of Hg(II)-resistant or Hg(II)-sensitive bacteria and in response to the selection pressure of the pollutant, the culture-independent 16S-23S ribosomal DNA intergenic spacer polymorphism analysis (RISA) was applied to examine the bacterial community on the strain level.…”

mentioning

confidence: 99%

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Spatially Oscillating Activity and Microbial Succession of Mercury-Reducing Biofilms in a Technical-Scale Bioremediation System

Canstein

Leonhäuser

et al. 2002

Appl Environ Microbiol

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Mercury-contaminated chemical wastewater of a mercury cell chloralkali plant was cleaned on site by a technical-scale bioremediation system. Microbial mercury reduction of soluble Hg(II) to precipitating Hg(0) decreased the mercury load of the wastewater during its flow through the bioremediation system by up to 99%. The system consisted of a packed-bed bioreactor, where most of the wastewater's mercury load was retained, and an activated carbon filter, where residual mercury was removed from the bioreactor effluent by both physical adsorption and biological reduction. In response to the oscillation of the mercury concentration in the bioreactor inflow, the zone of maximum mercury reduction oscillated regularly between the lower and the upper bioreactor horizons or the carbon filter. At low mercury concentrations, maximum mercury reduction occurred near the inflow at the bottom of the bioreactor. At high concentrations, the zone of maximum activity moved to the upper horizons. The composition of the bioreactor and carbon filter biofilms was investigated by 16S-23S ribosomal DNA intergenic spacer polymorphism analysis. Analysis of spatial biofilm variation showed an increasing microbial diversity along a gradient of decreasing mercury concentrations. Temporal analysis of the bioreactor community revealed a stable abundance of two prevalent strains and a succession of several invading mercury-resistant strains which was driven by the selection pressure of high mercury concentrations. In the activated carbon filter, a lower selection pressure permitted a steady increase in diversity during 240 days of operation and the establishment of one mercury-sensitive invader.

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mentioning

confidence: 99%

mentioning

confidence: 99%

Spatially Oscillating Activity and Microbial Succession of Mercury-Reducing Biofilms in a Technical-Scale Bioremediation System

Canstein

Leonhäuser

et al. 2002

Appl Environ Microbiol

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“…The biological mercury reduction mechanism has been applied for the detoxification of mercury-contaminated wastewater (6,31,32) and drinking water (19). The reduced form of mercury can then be removed by stripping into the gaseous phase and subsequent adsorption (8).…”

mentioning

confidence: 99%

“…Mercury is the most toxic heavy metal, with no associated biological function (31). Mercury pollution arises from sources such as the chlor-alkali industry, coal burning and gold mining, and is one of the most frequently found heavy metals in industrial wastewater (11).…”

mentioning

confidence: 99%

“…The reduced form of mercury can then be removed by stripping into the gaseous phase and subsequent adsorption (8). These studies have generally employed pure cultures (30,31), although mixed cultures are advantageous in wastewater treatment due to the difficulty in maintaining aseptic conditions. Biological mercury reduction requires an external carbon source to industrial wastewater in order to promote bacterial growth.…”

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confidence: 99%

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Microbial Characterization of Mercury-Reducing Mixed Cultures Enriched with Different Carbon Sources

et al. 2011

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The use of mixed microbial cultures enriched for biological mercury removal is explored in this paper, focusing on the ecological shifts occurring throughout acclimatization to mercury and on the long-term stability of four microbial enrichments. The 16S rRNA genetic profiles obtained by denaturing gradient gel electrophoresis (DGGE) revealed that the glucose and ethanol cultures had similar profiles, whereas the acetate cultures diverged into a totally dissimilar cluster. Quantification of the merA gene copies in each enrichment showed higher values for the glucose culture, followed by the ethanol and then the acetate cultures, which was consistent with the mercury removal performance throughout the study. Isolates were obtained from the four cultures and analyzed with respect to their genetic (16S rRNA) and functional (merA) phylogenies in order to identify mercury-resistant species enriched with different carbon sources. All mercury-resistant isolates obtained from the glucose and ethanol cultures belonged to the Gammaproteobacteria, whereas acetate cultures also contained members of other phyla, with differences in merA sequences. Higher phylogenetic than functional diversity of the isolates, together with increasing merA copies even after culture stabilisation, highlight the role of horizontal gene transfer in the acclimatization process.

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Strain stability in biological systems treating recalcitrant organic compounds

Emanuelsson

Baptista

Mantalaris

et al. 2005

Biotech & Bioengineering

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The availability of molecular probing technology in recent years has facilitated investigation of microbial community composition during bio-treatment of organic wastes. Particularly, it has allowed the study of microbial culture stability and correlation between stability and treatment performance. However, most studies to date have only addressed mixed cultures and there is limited information regarding single strain stability. Here we have investigated the microbial community dynamics in two bioreactors, each inoculated with a pure bacterial strain capable of degrading a recalcitrant substrate, namely Xanthobacter aut. GJ10 degrading 1,2-dichloroethane (DCE) and Burkholderia sp. JS150 degrading monochlorobenzene (MCB). Universal and strain specific 16S rRNA oligonucleotide probes were designed and used to follow strain stability. The bioreactor fed with DCE was functionally stable and the percentage of GJ10 cells in the community remained high (around 95% of total cells) throughout, even after introduction of foreign microorganisms. The bioreactor fed with MCB was also functionally stable, but in contrast to the DCE bioreactor, probing results revealed the disappearance of strain JS150 from the bioreactor within a week. The difference in behavior between the two systems is attributed to the specific pathway required to degrade DCE.

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Structure and Species Composition of Mercury-Reducing Biofilms

Cited by 58 publications

References 15 publications

Spatially Oscillating Activity and Microbial Succession of Mercury-Reducing Biofilms in a Technical-Scale Bioremediation System

Spatially Oscillating Activity and Microbial Succession of Mercury-Reducing Biofilms in a Technical-Scale Bioremediation System

Microbial Characterization of Mercury-Reducing Mixed Cultures Enriched with Different Carbon Sources

Strain stability in biological systems treating recalcitrant organic compounds

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