Metagenomic Analysis of Stress Genes in Microbial Mat Communities from Antarctica and the High Arctic

Varin, Thibault; Lovejoy, Connie; Jungblut, Anne D.; Vincent, Warwick F.; Corbeil, Jacques

doi:10.1128/aem.06354-11

Cited by 164 publications

(137 citation statements)

References 58 publications

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“…Consistently, coverage of psbD (photosystem II P680 reaction center D2 protein gene) was (mean ± s.e.) 128.0 ± 9.5 on Forni and 74.5 ± 12.5 on Baltoro, similar to that reported for Arctic and Antarctic supraglacial microbial mats (Varin et al, 2013). This suggests that oxygenic photosynthesis is among the dominant metabolisms in cryoconite holes.…”

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confidence: 71%

Light-dependent microbial metabolisms drive carbon fluxes on glacier surfaces

et al. 2016

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Biological processes on glacier surfaces affect glacier reflectance, influence surface energy budget and glacier response to climate warming, and determine glacier carbon exchange with the atmosphere. Currently, carbon balance of supraglacial environment is assessed as the balance between the activity of oxygenic phototrophs and the respiration rate of heterotrophic organisms. Here we present a metagenomic analysis of tiny wind-blown supraglacial sediment (cryoconite) from Baltoro (Pakistani Karakoram) and Forni (Italian Alps) glaciers, providing evidence for the occurrence in these environments of different and previously neglected metabolic pathways. Indeed, we observed high abundance of heterotrophic anoxygenic phototrophs, suggesting that light might directly supplement the energy demand of some bacterial strains allowing them to use as carbon source organic molecules, which otherwise would be respired. Furthermore, data suggest that CO 2 could be produced also by microbiologically mediated oxidation of CO, which may be produced by photodegradation of organic matter. The ISME Journal Climate change is determining a global cryosphere shrinkage and mountain glacier environments are declining (IPPC, 2014). The consequent loss of biodiversity is yet to be fully assessed, particularly the loss of functional biodiversity in extreme environments (Stibal et al., 2012;Boetius et al., 2015). Cryoconite holes, that is, small depressions on glacier surfaces whose formation is because of windborne debris (cryoconite), are the most biologically active environments on glaciers (Boetius et al., 2015).We used whole-metagenomic sequencing to investigate the main functions of six cryoconite holes from Forni (Italian Alps) and six from Baltoro (Pakistani Karakoram) glaciers. We focused on carbon and energy metabolisms by comparing the total coverage of marker genes for photosynthesis, use of inorganic and organic compounds as energy source and autotrophy/heterotrophy. We also used metagenomic sequences for the taxonomic attribution of microorganisms carrying specific metabolic genes Table S4 reports the marker genes whose coverage (mean number per base of reads mapping the genes) was used to infer the abundance of each metabolism. Supplementary Table S5 and Figure 1 report their normalized coverages. Finally, we measured chemical/physical parameters of cryoconite holes and oxygen consumption rates on the days of sampling, both under light and dark conditions (Supplementary Table S3 and Supplementary Figure S2). The main hypothesis tested was whether oxygenic phototrophy and organotrophic respiration represent the only significant metabolisms affecting carbon balance on glacier surface, as currently conceived, or other microbial processes could contribute to it.On the basis of 16S rRNA gene sequencing, Cyanobacteria represented 22 and 3% of the microbial community on Forni and Baltoro, respectively (Supplementary Figure S3). High abundance of cyanobacteria has been already observed in polar and alpine cryoconite (Segawa et al....

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confidence: 71%

Light-dependent microbial metabolisms drive carbon fluxes on glacier surfaces

et al. 2016

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“…Factors such as habitat stability (Varin et al 2012b), as well as the interactions and activities that occur within (Tolker-Nielsen and Molin 2000), could generate the structural and compositional differences observed between lake and stream microbial mats. The physical heterogeneity intrinsic to streams and temporal heterogeneity in flow has been suggested as the cause of species accumulation and diversification and explains the coexistence of species with diverse adaptations and requirements in stream phototrophic biofilms (Larson and Passy 2013).…”

Section: Aquatic Habitatsmentioning

confidence: 99%

“…Planktic organisms also play a relevant role in these ecosystems (Lizotte 2008). Filamentous cyanobacteria, namely heterocytous Nostocales and non-heterocystous Oscillatoriales are critical in structuring these microbial mats (Vincent 2000); although other microbes, such as diatoms (eukaryotes) and heterotrophic bacteria are also commonly found (Varin et al 2012b;Stanish et al 2013). In addition, cyanobacteria contribute significantly to the productivity in these ecosystems (Taton et al 2003a;Koma´rek et al 2008).…”

Section: Aquatic Habitatsmentioning

confidence: 99%

Ecology and biogeochemistry of cyanobacteria in soils, permafrost, aquatic and cryptic polar habitats

et al. 2015

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Polar Regions (continental Antarctica and the Arctic) are characterized by a range of extreme environmental conditions, which impose severe pressures on biological life. Polar cold-active cyanobacteria are uniquely adapted to withstand the environmental conditions of the high latitudes. These adaptations include high ultra-violet radiation and desiccation tolerance, and mechanisms to protect cells from freeze-thaw damage. As the most widely distributed photoautotrophs in these regions, cyanobacteria are likely the dominant contributors of critically essential ecosystem services, particularly carbon and nitrogen turnover in terrestrial polar habitats. These habitats include soils, permafrost, cryptic niches (including biological soil crusts, hypoliths and endoliths), ice and snow, and a range of aquatic habitats. Here we review current literature on the ecology, and the functional role played by cyanobacteria in various Arctic and Antarctic environments. We focus on the ecological importance of cyanobacterial communities in Polar Regions and assess what is known regarding the toxins they produce. We also review the responses and adaptations of cyanobacteria to extreme environments.

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“…Actinobacteria are prominent colonists of cold soil biotopes and have been linked to a range of functional processes such as stress response and nitrogen cycling [29,30,31 ]. Recent draft genomes of Actinobacterial isolates from cold soil environments have provided some new insights into the metabolic adaptation of these bacteria to cold environments [32,33].…”

Section: Microbial Diversity In Cold Environmentsmentioning

confidence: 99%

“…Copiotrophic a-and b-Proteobacteria were more responsive to shifts in nutrient status in Arctic soils than other taxa [28], supporting their proposed role as keystone taxa. Whether similar microbial community structural changes might be expected in oligotrophic Antarctic desert soils remains uncertain.Actinobacteria are prominent colonists of cold soil biotopes and have been linked to a range of functional processes such as stress response and nitrogen cycling [29,30,31 ]. Recent draft genomes of Actinobacterial isolates from cold soil environments have provided some new insights into the metabolic adaptation of these bacteria to cold environments [32,33].…”

mentioning

confidence: 99%

Microbial diversity and functional capacity in polar soils

Makhalanyane

Goethem

Cowan

2016

Current Opinion in Biotechnology

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Global change is disproportionately affecting cold environments (polar and high elevation regions), with potentially negative impacts on microbial diversity and functional processes. In most cold environments the combination of low temperatures, and physical stressors, such as katabatic wind episodes and limited water availability result in biotic systems, which are in trophic terms very simple and primarily driven by microbial communities. Metagenomic approaches have provided key insights on microbial communities in these systems and how they may adapt to stressors and contribute towards mediating crucial biogeochemical cycles. Here we review, the current knowledge regarding edaphic-based microbial diversity and functional processes in Antarctica, and the Artic. Such insights are crucial and help to establish a baseline for understanding the impact of climate change on Polar Regions. AddressCentre for Microbial Ecology and Genomics, Department of Genetics, University of Pretoria, Pretoria 0028, South Africa Corresponding author: Cowan, Don Arthur (don.cowan@up.ac.za) IntroductionThe Congress of Parties (COP) 21 meeting in Paris (November 2015) highlighted the urgency of global climate change, and the critical need to reduce global average temperatures through curbing greenhouse gas emissions [1]. Nowhere are the effects of global change more apparent than in cold environments (polar and alpine regions), which are subject to accelerated rates of warming compared to other ecosystems [2 ,3]. Climatic models have predicted that temperatures in high latitude regions of the Northern Hemisphere are likely to increase by between 0.38C and 4.88C before the end of the twenty first century [4]. There is also evidence that regions in the Southern Hemisphere have experienced the fastest warming globally, with average increases of as much as 2.48C in the last fifty years [5].A major consequence of climate change in cold environments is the thawing of submerged and surface ice, which alters the hydrology of the systems and may have adverse effects on microbial processes [6 ]. In cold environments, microorganisms (bacteria, archaea and fungi) are major constituents of the total biomass, and are estimated to mediate the cycling of key biogeochemical elements such as nitrogen and carbon, with potentially important implications for the productivity of these systems [7]. Although the precise contribution of microbial processes to global change processes are not well known, there are efforts to incorporate biological processes into Earth systems models with the realization that they may be crucial in regulating soil organic matter (SOM) [8 ]. For instance, permafrost (defined as ground which remains frozen for at least two years) in cold environments stores roughly 1600 Pg of carbon, which if released would significantly contribute towards increasing global CO 2 levels [9]. The current contribution of microbial communities to constraining carbon losses in permafrost and the influence on CO 2 levels remains virtually unknown. In ...

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Metagenomic Analysis of Stress Genes in Microbial Mat Communities from Antarctica and the High Arctic

Cited by 164 publications

References 58 publications

Light-dependent microbial metabolisms drive carbon fluxes on glacier surfaces

Light-dependent microbial metabolisms drive carbon fluxes on glacier surfaces

Ecology and biogeochemistry of cyanobacteria in soils, permafrost, aquatic and cryptic polar habitats

Microbial diversity and functional capacity in polar soils

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