New Group in the Leptospirillum Clade: Cultivation-Independent Community Genomics, Proteomics, and Transcriptomics of the New Species “Leptospirillum Group IV UBA BS”

Goltsman, Daniela S. Aliaga; Dasari, Mauna; Thomas, Brian C.; Shah, Manesh; VerBerkmoes, Nathan C.; Hettich, Robert L.; Banfield, Jillian F.

doi:10.1128/aem.00202-13

Cited by 48 publications

(40 citation statements)

References 54 publications

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“…Genes for the respiratory [NiFe]‐hydrogenase ( hydAB ), a [NiFe]‐hydrogenase large subunit ( hoxH ), and the hydrogenase maturation protein were found in Leptospirillum group IV (Goltsman et al ., ). However, previous results revealed that strains belonging to L. ferriphilum and L. ferrodiazotrophum did not grow on hydrogen, indicating that ferrous iron was used as the sole electron donor in these acidophiles (Hedrich and Johnson, ).…”

Section: Metabolic Diversity Of Iron‐ And/or Sulfur‐oxidizing Autotromentioning

confidence: 97%

“…Genomic analyses revealed that A. ferrooxidans, A. ferrivorans, and members of groups I, III, and IV of the Leptospirillum genus harbor several genes encoding the nitrogenase complex (Table 2) (Levic an et al, 2008;Goltsman et al, 2013). However, A. thiooxidans and A. caldus, both of which lack genes encoding the nitrogenase complex, carry genes associated with the Fig.…”

Section: Nitrogen Assimilationmentioning

confidence: 99%

“…Metabolic diversity and adaptive mechanisms 745 V C 2016 Society for Applied Microbiology and John Wiley & Sons Ltd,Environmental Microbiology Reports,8,[738][739][740][741][742][743][744][745][746][747][748][749][750][751] Genes for the respiratory [NiFe]-hydrogenase (hydAB), a [NiFe]-hydrogenase large subunit (hoxH), and the hydrogenase maturation protein were found in Leptospirillum group IV (Goltsman et al, 2013). However, previous results revealed that strains belonging to L. ferriphilum and L. ferrodiazotrophum did not grow on hydrogen, indicating that ferrous iron was used as the sole electron donor in these acidophiles (Hedrich and Johnson, 2013).…”

Section: Hydrogen and Formate Utilizationmentioning

confidence: 99%

“…The genus Acidithiobacillus includes at least four species: A. ferrooxidans, A. thiooxidans, A. caldus, and A. ferrivorans. To date, Leptospirillum spp., an iron oxidizer abundant in various acidophilic microbial communities, includes four recognized groups: group I (L. ferrooxidans), group II (L. ferriphilum and L. rubarum), group III (L. ferrodiazotrophum), and group IV, a novel member (Goltsman et al, 2013). The availability of the genome sequences for these iron and/or sulfur oxidizers belonging to the genera Acidithiobacillus and Leptospirillum is rapidly increasing because of the development of highthroughput sequencing and bioinformatics-based approaches.…”

Section: Introductionmentioning

confidence: 99%

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Metabolic diversity and adaptive mechanisms of iron‐ and/or sulfur‐oxidizing autotrophic acidophiles in extremely acidic environments

Zhang

Liu

Liang

et al. 2016

Environ Microbiol Rep

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Many studies have investigated the mechanisms underlying the survival and growth of certain organisms in extremely acidic environments known to be harmful to most prokaryotes and eukaryotes. Acidithiobacillus and Leptospirillum spp. are dominant bioleaching bacteria widely used in bioleaching systems, which are characterized by extremely acidic environments. To survive and grow in such settings, these acidophiles utilize shared molecular mechanisms that allow life in extreme conditions. In this review, we have summarized the results of published genomic analyses, which underscore the ability of iron- and/or sulfur-oxidizing autotrophic acidophiles belonging to the genera Acidithiobacillus and Leptospirillum to adapt to acidic environmental conditions. Several lines of evidence point at the metabolic diversity and multiplicity of pathways involved in the survival of these organisms. The ability to thrive in adverse environments requires versatile activation of structural and functional adaptive responses, including bacterial adhesion, motility, and resistance to heavy metals. We have highlighted recent developments centered on the key survival mechanisms employed by dominant extremophiles, and have laid the foundation for future studies focused on the ability of acidophiles to thrive in extremely acidic environments.

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Section: Metabolic Diversity Of Iron‐ And/or Sulfur‐oxidizing Autotromentioning

confidence: 97%

Section: Nitrogen Assimilationmentioning

confidence: 99%

Section: Hydrogen and Formate Utilizationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Metabolic diversity and adaptive mechanisms of iron‐ and/or sulfur‐oxidizing autotrophic acidophiles in extremely acidic environments

Zhang

Liu

Liang

et al. 2016

Environ Microbiol Rep

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“…As a result, many acidophile studies have utilized “omics” techniques, including proteomics to investigate not only whole communities (Belnap et al, 2011; Mueller et al, 2011; Goltsman et al, 2013) but also specific responses in a single species (Baker-Austin et al, 2010; Mykytczuk et al, 2011; Potrykus et al, 2011; Mangold et al, 2013). In this study, iron oxidation and biomining studies along with a proteomic strategy are used to investigate the differing responses to chloride by the salt susceptible and tolerant acidophiles At.…”

Section: Introductionmentioning

confidence: 99%

Multiple Osmotic Stress Responses in Acidihalobacter prosperus Result in Tolerance to Chloride Ions

et al. 2017

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Extremely acidophilic microorganisms (pH optima for growth of ≤3) are utilized for the extraction of metals from sulfide minerals in the industrial biotechnology of “biomining.” A long term goal for biomining has been development of microbial consortia able to withstand increased chloride concentrations for use in regions where freshwater is scarce. However, when challenged by elevated salt, acidophiles experience both osmotic stress and an acidification of the cytoplasm due to a collapse of the inside positive membrane potential, leading to an influx of protons. In this study, we tested the ability of the halotolerant acidophile Acidihalobacter prosperus to grow and catalyze sulfide mineral dissolution in elevated concentrations of salt and identified chloride tolerance mechanisms in Ac. prosperus as well as the chloride susceptible species, Acidithiobacillus ferrooxidans. Ac. prosperus had optimum iron oxidation at 20 g L−1 NaCl while At. ferrooxidans iron oxidation was inhibited in the presence of 6 g L−1 NaCl. The tolerance to chloride in Ac. prosperus was consistent with electron microscopy, determination of cell viability, and bioleaching capability. The Ac. prosperus proteomic response to elevated chloride concentrations included the production of osmotic stress regulators that potentially induced production of the compatible solute, ectoine uptake protein, and increased iron oxidation resulting in heightened electron flow to drive proton export by the F0F1 ATPase. In contrast, At. ferrooxidans responded to low levels of Cl− with a generalized stress response, decreased iron oxidation, and an increase in central carbon metabolism. One potential adaptation to high chloride in the Ac. prosperus Rus protein involved in ferrous iron oxidation was an increase in the negativity of the surface potential of Rus Form I (and Form II) that could help explain how it can be active under elevated chloride concentrations. These data have been used to create a model of chloride tolerance in the salt tolerant and susceptible species Ac. prosperus and At. ferrooxidans, respectively.

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Bioleaching of Minerals by Acidophile Microorganisms

Parada¹,

Bobadilla-Fazzini²

2014

Encyclopedia of Industrial Biotechnology

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In this article, we review the state of the art in the field of bioleaching applications for sulfide minerals, including beneficiation of copper, nickel, zinc, cobalt, uranium, and pyrite bearing gold and silver. A special emphasis is given to the specific acidophile microorganisms participating in the process, with insights into their particular physiology and also into the industrial applications being reported to date, such as dump and heap bioleaching, and stirred‐tank bioleaching. Some challenges are presented, such as declining mineral ore grade, proper control of operational parameters, adequate microbial supply, water and energy management, and effective integration of multidisciplinary teams to understand and solve complex technical problems.

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New Group in the Leptospirillum Clade: Cultivation-Independent Community Genomics, Proteomics, and Transcriptomics of the New Species “Leptospirillum Group IV UBA BS”

Cited by 48 publications

References 54 publications

Metabolic diversity and adaptive mechanisms of iron‐ and/or sulfur‐oxidizing autotrophic acidophiles in extremely acidic environments

Metabolic diversity and adaptive mechanisms of iron‐ and/or sulfur‐oxidizing autotrophic acidophiles in extremely acidic environments

Multiple Osmotic Stress Responses in Acidihalobacter prosperus Result in Tolerance to Chloride Ions

Bioleaching of Minerals by Acidophile Microorganisms

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