Light-dependent microbial metabolisms drive carbon fluxes on glacier surfaces

Franzetti, Andrea; Tagliaferri, Ilario; Gandolfi, Isabella; Bestetti, Giuseppina; Minora, Umberto; Mayer, Christoph; Azzoni, Roberto Sergio; Diolaiuti, Guglielmina; Smiraglia, Claudio; Ambrosini, Roberto

doi:10.1038/ismej.2016.72

Cited by 53 publications

(51 citation statements)

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Section: Accumulation Of Pollutants and Microbiological Response In Csupporting

confidence: 63%

“…A whole shotgun metagenomics analysis of the bacteria occurring in the cryoconite of the same glacier allowed the genome reconstruction of a bacterial population that could be responsible of the pesticide biodegradation [31]. These putative CPF-degrading bacteria resulted to be photoheterotrophic Burkholderiales, thus strengthening previous findings on the metabolic versatility and the importance of Betaproteobacteria in the heterotrophic metabolisms of cold environments [37,61,62]. Ferrario and colleagues [16,31] detected high concentrations (2-3 mg kg −1 ) of the pesticide chlorpyrifos (CPF) in the cryoconite and meltwater of an Alpine glacier, while in agriculture and termiticidal initial soils (i.e., in the application area) its concentrations vary from 10 to 1000 mg per kg of soil respectively [59].…”

Section: Accumulation Of Pollutants and Microbiological Response In Csupporting

confidence: 62%

“…Cryoconite in holes has higher concentration of organic matter and inorganic nutrients (nitrogen, phosphorus...) than the surrounding ice and supraglacial sediments [35,36]. This characteristic leads, on the one hand, to the incorporation of hydrophobic compounds such as POPs into the cryoconite organic matter [6] and, on the other hand, it promotes the presence of biodiverse and active microbial communities [37], which can biodegrade the contaminants.…”

Section: Accumulation Of Pollutants and Microbiological Response In Cmentioning

confidence: 99%

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Post-Depositional Biodegradation Processes of Pollutants on Glacier Surfaces

et al. 2018

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Abstract:Glaciers are important fresh-water reservoirs for our planet. Although they are often located at high elevations or in remote areas, glacial ecosystems are not pristine, as many pollutants can undergo long-range atmospheric transport and be deposited on glacier surface, where they can be stored for long periods of time, and then be released into the down-valley ecosystems. Understanding the dynamics of these pollutants in glaciers is therefore important for assessing their environmental fate. To this aim, it is important to study cryoconite holes, small ponds filled with water and with a layer of sediment, the cryoconite, at the bottom, which occur on the surface of most glaciers. Indeed, these environments are hotspots of biodiversity on glacier surface as they host metabolically active bacterial communities that include generalist taxa able to degrade pollutants. In this work, we aim to review the studies that have already investigated pollutant (e.g., chlorpyrifos and polychlorinated-biphenyls (PCBs)) degradation in cryoconite holes and other supraglacial environmental matrices. These studies have revealed that bacteria play a significant role in pollutant degradation in these habitats and can be positively selected in contaminated environments. We will also provide indication for future research in this field.

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Section: Accumulation Of Pollutants and Microbiological Response In Csupporting

confidence: 63%

Section: Accumulation Of Pollutants and Microbiological Response In Csupporting

confidence: 62%

Section: Accumulation Of Pollutants and Microbiological Response In Cmentioning

confidence: 99%

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Post-Depositional Biodegradation Processes of Pollutants on Glacier Surfaces

et al. 2018

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“…Nevertheless, a lot of uncertainty still exists regarding its formation and evolution. Moreover, most of the literature focused on Arctic, Antarctic and Asian glaciers, while little information is available for the European Alps Franzetti et al, 2016), despite their high sensitivity to environmental and climatic changes (Beniston, 2005). The Alps rise on the top of the Po river plain, one of the most industrialized and densely populated areas of Europe.…”

Section: Introductionmentioning

confidence: 99%

Impact of impurities and cryoconite on the optical properties of the Morteratsch Glacier (Swiss Alps)

et al. 2017

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Abstract. The amount of reflected energy by snow and ice plays a fundamental role in their melting processes. Different non-ice materials (carbonaceous particles, mineral dust (MD), microorganisms, algae, etc.) can decrease the reflectance of snow and ice promoting the melt. The object of this paper is to assess the capability of field and satellite (EO-1 Hyperion) hyperspectral data to characterize the impact of light-absorbing impurities (LAIs) on the surface reflectance of ice and snow of the Vadret da Morteratsch, a large valley glacier in the Swiss Alps. The spatial distribution of both narrow-band and broad-band indices derived from Hyperion was analyzed in relation to ice and snow impurities. In situ and laboratory reflectance spectra were acquired to characterize the optical properties of ice and cryoconite samples. The concentrations of elemental carbon (EC), organic carbon (OC) and levoglucosan were also determined to characterize the impurities found in cryoconite. Multi-wavelength absorbance spectra were measured to compare the optical properties of cryoconite samples and local moraine sediments. In situ reflectance spectra showed that the presence of impurities reduced ice reflectance in visible wavelengths by 80-90 %. Satellite data also showed the outcropping of dust during the melting season in the upper parts of the glacier, revealing that seasonal input of atmospheric dust can decrease the reflectance also in the accumulation zone of the glacier. The presence of EC and OC in cryoconite samples suggests a relevant role of carbonaceous and organic material in the darkening of the ablation zone. This darkening effect is added to that caused by fine debris from lateral moraines, which is assumed to represent a large fraction of cryoconite. Possible input of anthropogenic activity cannot be excluded and further research is needed to assess the role of human activities in the darkening process of glaciers observed in recent years.

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“…However, evidence is emerging of unexpected light-driven metabolisms in glacial systems, such as carbon monoxide oxidation 9 . This may introduce older sources of inorganic and organic carbon into the pool of actively cycled organic material on the surface of glaciers.…”

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confidence: 99%

The power of glacial microbes

Kujawinski

2017

Nature Geosci

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Organic carbon fluxes from glaciers are a key control on biogeochemical cycles in polar regions. Two analyses of carbon cycling in glaciers show the importance of glacier-surface microbial communities in setting these inputs. Elizabeth B. KujawinskiGlaciers were once considered inhospitable environments for life. However, over the past 15-20 years, vibrant and diverse microbial communities have been documented in all areas of the ice 1 . These communities are generally found in association with liquid water, either between the base of the glacier and the bedrock, or in pores that range in scale from micrometre-scale structures within the ice lattice to larger holes and streams atop the ice itself. However, the balance between the amount of fixed carbon produced by these microbes and that consumed has remained unclear. Writing in Nature Geoscience, Smith et al 2 . and Musilova et al 3 . show that the microbial communities fix more carbon than expected and thus play important roles in the glacial carbon cycle in Antarctica and the Greenland Ice Sheet, respectively.

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Light-dependent microbial metabolisms drive carbon fluxes on glacier surfaces

Cited by 53 publications

References 23 publications

Post-Depositional Biodegradation Processes of Pollutants on Glacier Surfaces

Post-Depositional Biodegradation Processes of Pollutants on Glacier Surfaces

Impact of impurities and cryoconite on the optical properties of the Morteratsch Glacier (Swiss Alps)

The power of glacial microbes

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