Diversity of Thermophilic Iron-Pyrite-Oxidizing Enrichments from Solfataric Hot Springs in the Chilean Altiplano

Sergio Barahona; Johanna Cortés; Martha Hengst; Cristina Dorador; Francisco Remonsellez

doi:10.4028/www.scientific.net/SSP.262.526

Paper Titles

Revisiting the Chrome Azurol S Assay for Various Metal Ions
p.509

Gallium Mobilization in Soil by Bacterial Metallophores
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On the Immobilization of Desferrioxamine-Like Siderophores for Selective Metal Binding
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Are there Viruses in Industrial Bioleaching Econiches?
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Diversity of Thermophilic Iron-Pyrite-Oxidizing Enrichments from Solfataric Hot Springs in the Chilean Altiplano
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Comparative Analysis of Functional Gene Diversity of Acid Mine Drainage and its Sediment by Geochip Technology
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Investigation of a Bioflotation Interface with Infrared Spectroscopy
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Leaching of Pyrite by Acidithiobacillus ferrooxidans Monitored by Electrochemical Methods
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X-Ray Diffraction of Iron Containing Samples: The Importance of a Suitable Configuration
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Diversity of Thermophilic Iron-Pyrite-Oxidizing Enrichments from Solfataric Hot Springs in the Chilean Altiplano

Abstract:

Relatively little is known about the microbial communities present in natural environments that meet physico-chemical conditions for the development of potential leaching microorganisms such as thermal ecosystems from the Chilean Altiplano. Thermophilic leaching enrichments were obtained and identified from a high altitude solfataric pound in Lirima hot springs in the Chilean Altiplano. This ecosystem is characterized by hot underground freshwaters, enriched in sulfur compounds showing pH from neutral to acidic. Microbial diversity has been scarcely explored here, and preliminary results demonstrate that hydrothermal pounds are represented by thermophilic anaerobic and acidophilic taxa. Thermophilic leaching cultures in shake flasks were obtained using ferrous iron and pyrite as energy source. The presence of Bacteria and Archaea in oxidizing enrichments was determined by PCR amplification of 16S rRNA genes. A preliminary analysis of microbial diversity using massive sequencing revealed that Bacteria were more abundant than Archaea in both enrichments. Specifically for the iron-oxidizing culture, the majority of the sequences clustered within the Proteobacteria phylum (79%). Among Proteobacteria, the proportion of Betaproteobacteria (42.2%) and Gammaproteobacteria (21.27%) was much higher than that of Alphaproteobacteria (15.5%). Within the Betaproteobacteria class, the most frequent genus was Leptothrix-like. Similar results were obtained for the pyrite oxidizing culture. Interestingly, this study shows the presence of microorganisms close to the Leptothrix genus under low pH conditions (1.7-2.8) and their capacity to grow at high temperatures with ferrous iron or pyrite as sole energy source

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Solid State Phenomena (Volume 262)

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526-530

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https://doi.org/10.4028/www.scientific.net/SSP.262.526

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Online since:

August 2017

Authors:

Sergio Barahona, Johanna Cortés, Martha Hengst, Cristina Dorador, Francisco Remonsellez*

Keywords:

16S rRNA Gene, Chilean Altiplano, Hot Springs, Iron-Oxidizing, Thermophilic

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