Your search keyword '"Whyte, Lyle G"' showing total 55 results

1. Metagenomic survey reveals hydrocarbon biodegradation potential of Canadian high Arctic beaches.

Author

Góngora, Esteban, Lirette, Antoine-O., Freyria, Nastasia J., Greer, Charles W., and Whyte, Lyle G.

Subjects

PHOSPHATE fertilizers, NORTHWEST Passage, ELECTRON donors, ELECTRON sources, AROMATIC compounds

Abstract

Background: Decreasing sea ice coverage across the Arctic Ocean due to climate change is expected to increase shipping activity through previously inaccessible shipping routes, including the Northwest Passage (NWP). Changing weather conditions typically encountered in the Arctic will still pose a risk for ships which could lead to an accident and the uncontrolled release of hydrocarbons onto NWP shorelines. We performed a metagenomic survey to characterize the microbial communities of various NWP shorelines and to determine whether there is a metabolic potential for hydrocarbon degradation in these microbiomes. Results: We observed taxonomic and functional gene evidence supporting the potential of NWP beach microbes to degrade various types of hydrocarbons. The metagenomic and metagenome-assembled genome (MAG) taxonomy showed that known hydrocarbon-degrading taxa are present in these beaches. Additionally, we detected the presence of biomarker genes of aerobic and anaerobic degradation pathways of alkane and aromatic hydrocarbons along with complete degradation pathways for aerobic alkane degradation. Alkane degradation genes were present in all samples and were also more abundant (33.8 ± 34.5 hits per million genes, HPM) than their aromatic hydrocarbon counterparts (11.7 ± 12.3 HPM). Due to the ubiquity of MAGs from the genus Rhodococcus (23.8% of the MAGs), we compared our MAGs with Rhodococcus genomes from NWP isolates obtained using hydrocarbons as the carbon source to corroborate our results and to develop a pangenome of Arctic Rhodococcus. Our analysis revealed that the biodegradation of alkanes is part of the core pangenome of this genus. We also detected nitrogen and sulfur pathways as additional energy sources and electron donors as well as carbon pathways providing alternative carbon sources. These pathways occur in the absence of hydrocarbons allowing microbes to survive in these nutrient-poor beaches. Conclusions: Our metagenomic analyses detected the genetic potential for hydrocarbon biodegradation in these NWP shoreline microbiomes. Alkane metabolism was the most prevalent type of hydrocarbon degradation observed in these tidal beach ecosystems. Our results indicate that bioremediation could be used as a cleanup strategy, but the addition of adequate amounts of N and P fertilizers, should be considered to help bacteria overcome the oligotrophic nature of NWP shorelines. [ABSTRACT FROM AUTHOR]

Published

2024

2. Characterization of hydrocarbon degraders from Northwest Passage beach sediments and assessment of their ability for bioremediation.

Author

Lirette, Antoine-O., Chen, Ya-Jou, Freyria, Nastasia J., Góngora, Esteban, Greer, Charles W., and Whyte, Lyle G.

Subjects

NORTHWEST Passage, BIOREMEDIATION, OIL spills, HYDROCARBONS, PETROLEUM as fuel

Abstract

Global warming-induced sea ice loss in the Canadian Northwest Passage (NWP) will result in more shipping traffic, increasing the risk of oil spills. Microorganisms inhabiting NWP beach sediments may degrade hydrocarbons, offering a potential bioremediation strategy. In this study, the characterization and genomic analyses of 22 hydrocarbon-biodegradative bacterial isolates revealed that they contained a diverse range of key alkane and aromatic hydrocarbon-degradative genes, as well as cold and salt tolerance genes indicating they are highly adapted to the extreme Arctic environment. Some isolates successfully degraded Ultra Low Sulfur Fuel Oil (ULSFO) at temperatures as low as −5 °C and high salinities (3%–10%). Three isolates were grown in liquid medium containing ULSFO as sole carbon source over 3 months and variation of hydrocarbon concentration was measured at three time points to determine their rate of hydrocarbon biodegradation. Our results demonstrate that two isolates (Rhodococcus sp. R1B_2T and Pseudarthrobacter sp. R2D_1T) possess complete degradation pathways and can grow on alkane and aromatic components of ULSFO under Arctic conditions. Overall, these results demonstrate that diverse hydrocarbon-degrading microorganisms exist in the NWP beach sediments, offering a potential bioremediation strategy in the events of a marine fuel spill reaching the shores of the NWP. [ABSTRACT FROM AUTHOR]

Published

2024

3. Biosignature Detection and MinION Sequencing of Antarctic Cryptoendoliths After Exposure to Mars Simulation Conditions.

Author

Maggiori, Catherine, Fernández-Martínez, Miguel Angel, Bourdages, Louis-Jacques, Sánchez-García, Laura, Moreno-Paz, Mercedes, Sobrado, Jesús Manuel, Carrizo, Daniel, Vicente-Retortillo, Álvaro, Goordial, Jacqueline, and Whyte, Lyle G.

Published

2024

4. Sulfur-cycling chemolithoautotrophic microbial community dominates a cold, anoxic, hypersaline Arctic spring.

Author

Magnuson, Elisse, Altshuler, Ianina, Freyria, Nastasia J., Leveille, Richard J., and Whyte, Lyle G.

Subjects

SULFUR cycle, SPRING, MICROBIAL communities, ANOXIC zones, GENETIC transcription regulation, NON-coding RNA, MICROORGANISMS

Abstract

Background : Gypsum Hill Spring, located in Nunavut in the Canadian High Arctic, is a rare example of a cold saline spring arising through thick permafrost. It perennially discharges cold (~ 7 °C), hypersaline (7–8% salinity), anoxic (~ 0.04 ppm O2), and highly reducing (~ − 430 mV) brines rich in sulfate (2.2 g.L−1) and sulfide (9.5 ppm), making Gypsum Hill an analog to putative sulfate-rich briny habitats on extraterrestrial bodies such as Mars. Results : Genome-resolved metagenomics and metatranscriptomics were utilized to describe an active microbial community containing novel metagenome-assembled genomes and dominated by sulfur-cycling Desulfobacterota and Gammaproteobacteria. Sulfate reduction was dominated by hydrogen-oxidizing chemolithoautotrophic Desulfovibrionaceae sp. and was identified in phyla not typically associated with sulfate reduction in novel lineages of Spirochaetota and Bacteroidota. Highly abundant and active sulfur-reducing Desulfuromusa sp. highly transcribed non-coding RNAs associated with transcriptional regulation, showing potential evidence of putative metabolic flexibility in response to substrate availability. Despite low oxygen availability, sulfide oxidation was primarily attributed to aerobic chemolithoautotrophic Halothiobacillaceae. Low abundance and transcription of photoautotrophs indicated sulfur-based chemolithoautotrophy drives primary productivity even during periods of constant illumination. Conclusions: We identified a rare surficial chemolithoautotrophic, sulfur-cycling microbial community active in a unique anoxic, cold, hypersaline Arctic spring. We detected Mars-relevant metabolisms including hydrogenotrophic sulfate reduction, sulfur reduction, and sulfide oxidation, which indicate the potential for microbial life in analogous S-rich brines on past and present Mars. CDmZk6dAQUX4zKwy7_vWAs Video Abstract [ABSTRACT FROM AUTHOR]

Published

2023

5. Microbial Characterization of Arctic Glacial Ice Cores with a Semiautomated Life Detection System.

Author

Touchette, David, Maggiori, Catherine, Altshuler, Ianina, Tettenborn, Alex, Bourdages, Louis-Jacques, Magnuson, Elisse, Blenner-Hassett, Olivia, Raymond-Bouchard, Isabelle, Ellery, Alex, and Whyte, Lyle G.

Published

2023

6. Unique high Arctic methane metabolizing community revealed through in situ 13CH4-DNA-SIP enrichment in concert with genome binning.

Author

Altshuler, Ianina, Raymond-Bouchard, Isabelle, Magnuson, Elisse, Tremblay, Julien, Greer, Charles W., and Whyte, Lyle G.

Subjects

COMMUNITIES, BIOGEOCHEMICAL cycles, METHANE, GREENHOUSE gases, GENOMES, STABLE isotopes, AMMONIA

Abstract

Greenhouse gas (GHG) emissions from Arctic permafrost soils create a positive feedback loop of climate warming and further GHG emissions. Active methane uptake in these soils can reduce the impact of GHG on future Arctic warming potential. Aerobic methane oxidizers are thought to be responsible for this apparent methane sink, though Arctic representatives of these organisms have resisted culturing efforts. Here, we first used in situ gas flux measurements and qPCR to identify relative methane sink hotspots at a high Arctic cytosol site, we then labeled the active microbiome in situ using DNA Stable Isotope Probing (SIP) with heavy 13CH4 (at 100 ppm and 1000 ppm). This was followed by amplicon and metagenome sequencing to identify active organisms involved in CH4 metabolism in these high Arctic cryosols. Sequencing of 13C-labeled pmoA genes demonstrated that type II methanotrophs (Methylocapsa) were overall the dominant active methane oxidizers in these mineral cryosols, while type I methanotrophs (Methylomarinovum) were only detected in the 100 ppm SIP treatment. From the SIP-13C-labeled DNA, we retrieved nine high to intermediate quality metagenome-assembled genomes (MAGs) belonging to the Proteobacteria, Gemmatimonadetes, and Chloroflexi, with three of these MAGs containing genes associated with methanotrophy. A novel Chloroflexi MAG contained a mmoX gene along with other methane oxidation pathway genes, identifying it as a potential uncultured methane oxidizer. This MAG also contained genes for copper import, synthesis of biopolymers, mercury detoxification, and ammonia uptake, indicating that this bacterium is strongly adapted to conditions in active layer permafrost and providing new insights into methane biogeochemical cycling. In addition, Betaproteobacterial MAGs were also identified as potential cross-feeders with methanotrophs in these Arctic cryosols. Overall, in situ SIP labeling combined with metagenomics and genome binning demonstrated to be a useful tool for discovering and characterizing novel organisms related to specific microbial functions or biogeochemical cycles of interest. Our findings reveal a unique and active Arctic cryosol microbial community potentially involved in CH4 cycling. [ABSTRACT FROM AUTHOR]

Published

2022

7. Microfluidics Microbial Activity MicroAssay: An Automated In Situ Microbial Metabolic Detection System.

Author

Touchette, David, Altshuler, Ianina, Raymond-Bouchard, Isabelle, Fernández-Martínez, Miguel Ángel, Bourdages, Louis-Jacques, O'Connor, Brady, Ricco, Antonio J., and Whyte, Lyle G.

Published

2022

8. Unique high Arctic methane metabolizing community revealed through in situ 13CH4-DNA-SIP enrichment in concert with genome binning.

Author

Altshuler, Ianina, Raymond-Bouchard, Isabelle, Magnuson, Elisse, Tremblay, Julien, Greer, Charles W., and Whyte, Lyle G.

Subjects

BIOGEOCHEMICAL cycles, METHANE, GENOMES, GREENHOUSE gases, STABLE isotopes, CLIMATE feedbacks, AMMONIA

Abstract

Greenhouse gas (GHG) emissions from Arctic permafrost soils create a positive feedback loop of climate warming and further GHG emissions. Active methane uptake in these soils can reduce the impact of GHG on future Arctic warming potential. Aerobic methane oxidizers are thought to be responsible for this apparent methane sink, though Arctic representatives of these organisms have resisted culturing efforts. Here, we first used in situ gas flux measurements and qPCR to identify relative methane sink hotspots at a high Arctic cytosol site, we then labeled the active microbiome in situ using DNA Stable Isotope Probing (SIP) with heavy 13CH4 (at 100 ppm and 1000 ppm). This was followed by amplicon and metagenome sequencing to identify active organisms involved in CH4 metabolism in these high Arctic cryosols. Sequencing of 13C-labeled pmoA genes demonstrated that type II methanotrophs (Methylocapsa) were overall the dominant active methane oxidizers in these mineral cryosols, while type I methanotrophs (Methylomarinovum) were only detected in the 100 ppm SIP treatment. From the SIP-13C-labeled DNA, we retrieved nine high to intermediate quality metagenome-assembled genomes (MAGs) belonging to the Proteobacteria, Gemmatimonadetes, and Chloroflexi, with three of these MAGs containing genes associated with methanotrophy. A novel Chloroflexi MAG contained a mmoX gene along with other methane oxidation pathway genes, identifying it as a potential uncultured methane oxidizer. This MAG also contained genes for copper import, synthesis of biopolymers, mercury detoxification, and ammonia uptake, indicating that this bacterium is strongly adapted to conditions in active layer permafrost and providing new insights into methane biogeochemical cycling. In addition, Betaproteobacterial MAGs were also identified as potential cross-feeders with methanotrophs in these Arctic cryosols. Overall, in situ SIP labeling combined with metagenomics and genome binning demonstrated to be a useful tool for discovering and characterizing novel organisms related to specific microbial functions or biogeochemical cycles of interest. Our findings reveal a unique and active Arctic cryosol microbial community potentially involved in CH4 cycling. [ABSTRACT FROM AUTHOR]

Published

2022

9. Assessment of Automated Nucleic Acid Extraction Systems in Combination with MinION Sequencing As Potential Tools for the Detection of Microbial Biosignatures.

Author

Raymond-Bouchard, Isabelle, Maggiori, Catherine, Brennan, Laura, Altshuler, Ianina, Manchado, Juan Manuel, Parro, Victor, and Whyte, Lyle G.

Published

2022

10. Geomicrobiological Heterogeneity of Lithic Habitats in the Extreme Environment of Antarctic Nunataks: A Potential Early Mars Analog.

Author

Fernández-Martínez, Miguel Ángel, García-Villadangos, Miriam, Moreno-Paz, Mercedes, Gangloff, Valentin, Carrizo, Daniel, Blanco, Yolanda, González, Sergi, Sánchez-García, Laura, Prieto-Ballesteros, Olga, Altshuler, Ianina, Whyte, Lyle G., Parro, Victor, and Fairén, Alberto G.

Subjects

MICROBIAL ecology, MARS (Planet), CLIMATE extremes, ANTARCTIC ice, ICE caps, EXTREME environments, NUTRIENT cycles, HABITATS

Abstract

Nunataks are permanent ice-free rocky peaks that project above ice caps in polar regions, thus being exposed to extreme climatic conditions throughout the year. They undergo extremely low temperatures and scarcity of liquid water in winter, while receiving high incident and reflected (albedo) UVA-B radiation in summer. Here, we investigate the geomicrobiology of the permanently exposed lithic substrates of nunataks from Livingston Island (South Shetlands, Antarctic Peninsula), with focus on prokaryotic community structure and their main metabolic traits. Contrarily to first hypothesis, an extensive sampling based on different gradients and multianalytical approaches demonstrated significant differences for most geomicrobiological parameters between the bedrock, soil, and loose rock substrates, which overlapped any other regional variation. Brevibacillus genus dominated on bedrock and soil substrates, while loose rocks contained a diverse microbial community, including Actinobacteria, Alphaproteobacteria and abundant Cyanobacteria inhabiting the milder and diverse microhabitats within. Archaea, a domain never described before in similar Antarctic environments, were also consistently found in the three substrates, but being more abundant and potentially more active in soils. Stable isotopic ratios of total carbon (δ 13C) and nitrogen (δ 15N), soluble anions concentrations, and the detection of proteins involved in key metabolisms via the Life Detector Chip (LDChip), suggest that microbial primary production has a pivotal role in nutrient cycling at these exposed areas with limited deposition of nutrients. Detection of stress-resistance proteins, such as molecular chaperons, suggests microbial molecular adaptation mechanisms to cope with these harsh conditions. Since early Mars may have encompassed analogous environmental conditions as the ones found in these Antarctic nunataks, our study also contributes to the understanding of the metabolic features and biomarker profiles of a potential Martian microbiota, as well as the use of LDChip in future life detection missions. [ABSTRACT FROM AUTHOR]

Published

2021

11. Thiomicrorhabdus streamers and sulfur cycling in perennial hypersaline cold springs in the Canadian high Arctic.

Author

Magnuson, Elisse, Mykytczuk, Nadia C.S., Pellerin, Andre, Goordial, Jacqueline, Twine, Susan M., Wing, Boswell, Foote, Simon J., Fulton, Kelly, and Whyte, Lyle G.

Subjects

SULFUR cycle, ATMOSPHERIC temperature, SULFUR isotopes, ISOTOPIC fractionation, ISOTOPIC analysis, METAGENOMICS, CARBON fixation, PROJECT POSSUM

Abstract

Summary: The Gypsum Hill (GH) springs on Axel Heiberg Island in the Canadian high Arctic are host to chemolithoautotrophic, sulfur‐oxidizing streamers that flourish in the high Arctic winter in water temperatures from −1.3 to 7°C with ~8% salinity in a high Arctic winter environment with air temperatures commonly less than −40°C and an average annual air temperature of −15°C. Metagenome sequencing and binning of streamer samples produced a 96% complete Thiomicrorhabdus sp. metagenome‐assembled genome representing a possible new species or subspecies. This is the most cold‐ and salt‐extreme source environment for a Thiomicrorhabdus genome yet described. Metaproteomic and metatranscriptomic analysis attributed nearly all gene expression in the streamers to the Thiomicrorhabdus sp. and suggested that it is active in CO2 fixation and oxidation of sulfide to elemental sulfur. In situ geochemical and isotopic analyses of the fractionation of multiple sulfur isotopes determined the biogeochemical transformation of sulfur from its source in Carboniferous evaporites to biotic processes occurring in the sediment and streamers. These complementary molecular tools provided a functional link between the geochemical substrates and the collective traits and activity that define the microbial community's interactions within a unique polar saline habitat where Thiomicrorhabdus‐dominated streamers form and flourish. [ABSTRACT FROM AUTHOR]

Published

2021

12. Taxonomic Characterization and Microbial Activity Determination of Cold-Adapted Microbial Communities in Lava Tube Ice Caves from Lava Beds National Monument, a High-Fidelity Mars Analogue Environment.

Author

O'Connor, Brady R.W., Fernández-Martínez, Miguel Ángel, Léveillé, Richard J., and Whyte, Lyle G.

Published

2021

13. Diversity decoupled from sulfur isotope fractionation in a sulfate‐reducing microbial community.

Author

Colangelo‐Lillis, Jesse, Pelikan, Claus, Herbold, Craig W., Altshuler, Ianina, Loy, Alexander, Whyte, Lyle G., and Wing, Boswell A.

Subjects

ISOTOPIC fractionation, SULFUR isotopes, MICROBIAL communities, ENVIRONMENTAL chemistry, MICROBIAL physiology, MICROBIAL diversity, SULFATES, HETEROTROPHIC respiration

Abstract

The extent of fractionation of sulfur isotopes by sulfate‐reducing microbes is dictated by genomic and environmental factors. A greater understanding of species‐specific fractionations may better inform interpretation of sulfur isotopes preserved in the rock record. To examine whether gene diversity influences net isotopic fractionation in situ, we assessed environmental chemistry, sulfate reduction rates, diversity of putative sulfur‐metabolizing organisms by 16S rRNA and dissimilatory sulfite reductase (dsrB) gene amplicon sequencing, and net fractionation of sulfur isotopes along a sediment transect of a hypersaline Arctic spring. In situ sulfate reduction rates yielded minimum cell‐specific sulfate reduction rates < 0.3 × 10−15 moles cell−1 day−1. Neither 16S rRNA nor dsrB diversity indices correlated with relatively constant (38‰–45‰) net isotope fractionation (ε34Ssulfide‐sulfate). Measured ε34S values could be reproduced in a mechanistic fractionation model if 1%–2% of the microbial community (10%–60% of Deltaproteobacteria) were engaged in sulfate respiration, indicating heterogeneous respiratory activity within sulfate‐reducing populations. This model indicated enzymatic kinetic diversity of Apr was more likely to correlate with sulfur fractionation than DsrB. We propose that, above a threshold Shannon diversity value of 0.8 for dsrB, the influence of the specific composition of the microbial community responsible for generating an isotope signal is overprinted by the control exerted by environmental variables on microbial physiology. [ABSTRACT FROM AUTHOR]

Published

2019

14. Species interactions and distinct microbial communities in high Arctic permafrost affected cryosols are associated with the CH4 and CO2 gas fluxes.

Author

Altshuler, Ianina, Hamel, Jérémie, Turney, Shaun, Magnuson, Elisse, Lévesque, Roger, Greer, Charles W., and Whyte, Lyle G.

Subjects

MICROBIAL communities, PERMAFROST ecosystems, PERMAFROST, MICROBIAL metabolism, SPECIES, PHOSPHORUS cycle (Biogeochemistry), FLUX (Energy)

Abstract

Summary: Microbial metabolism of the thawing organic carbon stores in permafrost results in a positive feedback loop of greenhouse gas emissions. CO2 and CH4 fluxes and the associated microbial communities in Arctic cryosols are important in predicting future warming potential of the Arctic. We demonstrate that topography had an impact on CH4 and CO2 flux at a high Arctic ice‐wedge polygon terrain site, with higher CO2 emissions and lower CH4 uptake at troughs compared to polygon interior soils. The pmoA sequencing suggested that USCα cluster of uncultured methanotrophs is likely responsible for observed methane sink. Community profiling revealed distinct assemblages across the terrain at different depths. Deeper soils contained higher abundances of Verrucomicrobia and Gemmatimonadetes, whereas the polygon interior had higher Acidobacteria and lower Betaproteobacteria and Deltaproteobacteria abundances. Genome sequencing of isolates from the terrain revealed presence of carbon cycling genes including ones involved in serine and ribulose monophosphate pathways. A novel hybrid network analysis identified key members that had positive and negative impacts on other species. Operational Taxonomic Units (OTUs) with numerous positive interactions corresponded to Proteobacteria, Candidatus Rokubacteria and Actinobacteria phyla, while Verrucomicrobia and Acidobacteria members had negative impacts on other species. Results indicate that topography and microbial interactions impact community composition. [ABSTRACT FROM AUTHOR]

Published

2019

15. Microbial Activity and Habitability of an Antarctic Dry Valley Water Track.

Author

Chan-Yam, Kelly, Goordial, Jacqueline, Greer, Charles, Davila, Alfonso, McKay, Christopher P., and Whyte, Lyle G.

Published

2019

16. Microbiology and Nitrogen Cycle in the Benthic Sediments of a Glacial Oligotrophic Deep Andean Lake as Analog of Ancient Martian Lake-Beds.

Author

Parro, Victor, Puente-Sánchez, Fernando, Cabrol, Nathalie A., Gallardo-Carreño, Ignacio, Moreno-Paz, Mercedes, Blanco, Yolanda, García-Villadangos, Miriam, Tambley, Cristian, Tilot, Virginie C., Thompson, Cody, Smith, Eric, Sobrón, Pablo, Demergasso, Cecilia S., Echeverría-Vega, Alex, Fernández-Martínez, Miguel Ángel, Whyte, Lyle G., and Fairén, Alberto G.

Subjects

NITROGEN cycle, LAKE sediments, MICROBIAL exopolysaccharides, MICROBIOLOGY, OXIDATION of ammonia, ANAEROBIC metabolism

Abstract

Potential benthic habitats of early Mars lakes, probably oligotrophic, could range from hydrothermal to cold sediments. Dynamic processes in the water column (such as turbidity or UV penetration) as well as in the benthic bed (temperature gradients, turbation, or sedimentation rate) contribute to supply nutrients to a potential microbial ecosystem. High altitude, oligotrophic, and deep Andean lakes with active deglaciation processes and recent or past volcanic activity are natural models to assess the feasibility of life in other planetary lake/ocean environments and to develop technology for their exploration. We sampled the benthic sediments (down to 269 m depth) of the oligotrophic lake Laguna Negra (Central Andes, Chile) to investigate its ecosystem through geochemical, biomarker profiling, and molecular ecology studies. The chemistry of the benthic water was similar to the rest of the water column, except for variable amounts of ammonium (up to 2.8 ppm) and nitrate (up to 0.13 ppm). A life detector chip with a 300-antibody microarray revealed the presence of biomass in the form of exopolysaccharides and other microbial markers associated to several phylogenetic groups and potential microaerobic and anaerobic metabolisms such as nitrate reduction. DNA analyses showed that 27% of the Archaea sequences corresponded to a group of ammonia-oxidizing archaea (AOA) similar (97%) to Nitrosopumilus spp. and Nitrosoarchaeum spp. (Thaumarchaeota), and 4% of Bacteria sequences to nitrite-oxidizing bacteria from the Nitrospira genus, suggesting a coupling between ammonia and nitrite oxidation. Mesocosm experiments with the specific AOA inhibitor 2-Phenyl-4,4,5,5-tetramethylimidazoline-1-oxyl 3-oxide (PTIO) demonstrated an AOA-associated ammonia oxidation activity with the simultaneous accumulation of nitrate and sulfate. The results showed a rich benthic microbial community dominated by microaerobic and anaerobic metabolisms thriving under aphotic, low temperature (4°C), and relatively high pressure, that might be a suitable terrestrial analog of other planetary settings. [ABSTRACT FROM AUTHOR]

Published

2019

17. Characterization of Microbial Communities Hosted in Quartzofeldspathic and Serpentinite Lithologies in Jeffrey Mine, Canada.

Author

Ronholm, Jennifer, Goordial, Jacqueline, Sapers, Haley M., Izawa, Matthew R.M., Applin, Daniel M., Pontefract, Alexandra, Omelon, Christopher R., Lamarche-Gagnon, Guillaume, Cloutis, Edward A., and Whyte, Lyle G.

Published

2018

18. Macroinvertebrate and soil prokaryote communities in the forest-tundra ecotone of the Subarctic Yukon.

Author

Turney, Shaun, Altshuler, Ianina, Whyte, Lyle G., and Buddle, Christopher M.

Subjects

INVERTEBRATES, PROKARYOTES, TUNDRA ecology, CLIMATE change, BIODIVERSITY, ANTI-infective agents, CARNIVOROUS animals

Abstract

The forest-tundra interface is the world’s largest ecotone, and is globally important due to its biodiversity, climatic sensitivity, and natural resources. The ecological communities which characterize this ecotone, and which provide local and global ecosystem services, are affected by environmental variation at multiple scales. We explored correlations between environmental variables and macroinvertebrate and soil prokaryote communities in the forest-tundra ecotone of the Yukon, Canada. We found that each tussock tundra site possessed a distinct community of macroinvertebrates and prokaryotes, and therefore represented a unique contribution to regional biodiversity. Prokaryote diversity increased with active layer depth, which could be an effect of temperature, or could be evidence of a species-area effect. Prokaryote diversity decreased with lichen cover, which could be due to antimicrobial properties of lichen. The macroinvertebrate community composition was affected by proximity to a human disturbance, the Dempster Highway. Both macroinvertebrate and prokaryote community compositions changed along the latitudinal transect, as the biome transitioned from taiga to tundra. We also found that the abundance of carnivores relative to herbivores decreased with latitude, which adds to recent evidence that predation decreases with latitude. Our survey yielded new insights about how macro- and microorganisms vary together and independently in relation to environmental variables at multiple scales in a forest-tundra ecotone. [ABSTRACT FROM AUTHOR]

Published

2018

19. Comparative Transcriptomics of Cold Growth and Adaptive Features of a Eury- and Steno-Psychrophile.

Author

Raymond-Bouchard, Isabelle, Tremblay, Julien, Altshuler, Ianina, Greer, Charles W., and Whyte, Lyle G.

Subjects

COLD adaptation, PERMAFROST, RHODOCOCCUS

Abstract

Permafrost subzero environments harbor diverse, active communities of microorganisms. However, our understanding of the subzero growth, metabolisms, and adaptive properties of these microbes remains very limited. We performed transcriptomic analyses on two subzero-growing permafrost isolates with different growth profiles in order to characterize and compare their cold temperature growth and cold-adaptive strategies. The two organisms, Rhodococcus sp. JG3 (-5 to 30°C) and Polaromonas sp. Eur3 1.2.1 (-5 to 22°C), shared several common responses during low temperature growth, including induction of translation and ribosomal processes, upregulation of nutrient transport, increased oxidative and osmotic stress responses, and stimulation of polysaccharide capsule synthesis. Recombination appeared to be an important adaptive strategy for both isolates at low temperatures, likely as a mechanism to increase genetic diversity and the potential for survival in cold systems. While Rhodococcus sp. JG3 favored upregulating iron and amino acid transport, sustaining redox potential, and modulating fatty acid synthesis and composition during growth at -5°C compared to 25°C, Polaromonas sp. Eur3 1.2.1 increased the relative abundance of transcripts involved in primary energy metabolism and the electron transport chain, in addition to signal transduction and peptidoglycan synthesis at 0°C compared to 20°C. The increase in energy metabolism may explain why Polaromonas sp. Eur3 1.2.1 is able to sustain growth rates at 0°C comparable to those at higher temperatures. For Rhodococcus sp. JG3, flexibility in use of carbon sources, iron acquisition, control of membrane fatty acid composition, and modulating redox and co-factor potential may be ways in which this organism is able to sustain growth over a wider range of temperatures. Increasing our understanding of the microbes in these habitats helps us better understand active pathways and metabolisms in extreme environments. Identifying novel, thermolabile, and cold-active enzymes from studies such as this is also of great interest to the biotechnology and food industries. [ABSTRACT FROM AUTHOR]

Published

2018

20. Conserved genomic and amino acid traits of cold adaptation in subzero-growing Arctic permafrost bacteria.

Author

Raymond-Bouchard, Isabelle, Goordial, Jacqueline, Zolotarov, Yevgen, Ronholm, Jennifer, Stromvik, Martina, Bakermans, Corien, and Whyte, Lyle G.

Subjects

PERMAFROST ecosystems, BACTERIAL physiology, COLD adaptation, CONSERVED sequences (Genetics), AMINO acids, SOIL ecology, MICROBIAL communities

Abstract

Permafrost accounts for 27% of all soil ecosystems and harbors diverse microbial communities. Our understanding of microorganisms in permafrost, their activities and adaptations, remains limited. Using five subzero-growing (cryophilic) permafrost bacteria, we examined features of cold adaptation through comparative genomic analyses with mesophilic relatives. The cryophiles possess genes associated with cold adaptation, including cold shock proteins, RNA helicases, and oxidative stress and carotenoid synthesis enzymes. Higher abundances of genes associated with compatible solutes were observed, important for osmoregulation in permafrost brine veins. Most cryophiles in our study have higher transposase copy numbers than mesophiles. We investigated amino acid (AA) modifications in the cryophiles favoring increased protein flexibility at cold temperatures. Although overall there were few differences with the mesophiles, we found evidence of cold adaptation, with significant differences in proline, serine, glycine and aromaticity, in several cryophiles. The use of cold/hot AA ratios of >1, used in previous studies to indicate cold adaptation, was found to be inadequate on its own. Comparing the average of all cryophiles to all mesophiles, we found that overall cryophiles had a higher ratio of cold adapted proteins for serine (more serine), and to a lesser extent, proline and acidic residues (fewer prolines/acidic residues). [ABSTRACT FROM AUTHOR]

Published

2018

21. Biological Characterization of Microenvironments in a Hypersaline Cold Spring Mars Analog.

Author

Sapers, Haley M., Ronholm, Jennifer, Raymond-Bouchard, Isabelle, Comrey, Raven, Osinsk, Gordon R., and Whyte, Lyle G.

Subjects

CRYOSPHERE, MARS (Planet), RIBOSOMAL RNA

Abstract

While many habitable niches on Earth are characterized by permanently cold conditions, little is known about the spatial structure of seasonal communities and the importance of substrate-cell associations in terrestrial cyroenvironments. Here we use the 16S rRNA gene as a marker for genetic diversity to compare two visually distinct but spatially integrated surface microbial mats on Axel Heiberg Island, Canadian high arctic, proximal to a perennial saline spring. This is the first study to describe the bacterial diversity in microbial mats on Axel Heiberg Island. The hypersaline springs on Axel Heiberg represent a unique analog to putative subsurface aquifers on Mars. The Martian subsurface represents the longest-lived potentially habitable environment on Mars and a better understanding of the microbial communities on Earth that thrive in analog conditions will help direct future life detection missions. The microbial mats sampled on Axel Heiberg are only visible during the summer months in seasonal flood plains formed by melt water and run-off from the proximal spring. Targeted-amplicon sequencing revealed that not only does the bacterial composition of the two mat communities differ substantially from the sediment community of the proximal cold spring, but that the mat communities are distinct from any other microbial community in proximity to the Arctic springs studied to date. All samples are dominated by Gammaproteobacteria: Thiotichales is dominant within the spring samples while Alteromonadales comprises a significant component of the mat communities. The two mat samples differ in their Thiotichales:Alteromonadales ratio and contribution of Bacteroidetes to overall diversity. The red mats have a greater proportion of Alteromonadales and Bacteroidetes reads. The distinct bacterial composition of the mat bacterial communities suggests that the spring communities are not sourced from the surface, and that seasonal melt events create ephemerally habitable niches with distinct microbial communities in the Canadian high arctic. The finding that these surficial complex microbial communities exist in close proximity to perennial springs demonstrates the existence of a transiently habitable niche in an important Mars analog site. [ABSTRACT FROM AUTHOR]

Published

2017

22. In Situ Field Sequencing and Life Detection in Remote (79°26'N) Canadian High Arctic Permafrost Ice Wedge Microbial Communities.

Author

Goordial, J., Altshuler, Ianina, Hindson, Katherine, Chan-Yam, Kelly, Marcolefas, Evangelos, and Whyte, Lyle G.

Subjects

PERMAFROST, MICROORGANISMS

Abstract

Significant progress is being made in the development of the next generation of low cost life detection instrumentation with much smaller size, mass and energy requirements. Here, we describe in situ life detection and sequencing in the field in soils over laying ice wedges in polygonal permafrost terrain on Axel Heiberg Island, located in the Canadian high Arctic (79°26'N), an analog to the polygonal permafrost terrain observed on Mars. The life detection methods used here include (1) the cryo-iPlate for culturing microorganisms using diffusion of in situ nutrients into semi-solid media (2) a Microbial Activity Microassay (MAM) plate (BIOLOG Ecoplate) for detecting viable extant microorganisms through a colourimetric assay, and (3) the Oxford Nanopore MinION for nucleic acid detection and sequencing of environmental samples and the products of MAM plate and cryo-iPlate. We obtained 39 microbial isolates using the cryo-iPlate, which included several putatively novel strains based on the 16S rRNA gene, including a Pedobacter sp. (96% closest similarity in GenBank) which we partially genome sequenced using theMinION. TheMAMplate successfully identified an active community capable of L-serine metabolism, which was used for metagenomic sequencing with the MinION to identify the active and enriched community. A metagenome on environmental ice wedge soil samples was completed, with base calling and uplink/downlink carried out via satellite internet. Validation of MinION sequencing using the Illumina MiSeq platform was consistent with the results obtained with the MinION. The instrumentation and technology utilized here is pre-existing, low cost, low mass, low volume, and offers the prospect of equipping micro-rovers and micro-penetrators with aggressive astrobiological capabilities. Since potentially habitable astrobiology targets have been identified (RSLs on Mars, near subsurface water ice on Mars, the plumes and oceans of Europa and Enceladus), future astrobiology missions will certainly target these areas and there is a need for direct life detection instrumentation. [ABSTRACT FROM AUTHOR]

Published

2017

23. Mechanisms of subzero growth in the cryophile Planococcus halocryophilus determined through proteomic analysis.

Author

Raymond ‐ Bouchard, Isabelle, Chourey, Karuna, Altshuler, Ianina, Iyer, Ramsunder, Hettich, Robert L., and Whyte, Lyle G.

Subjects

PLANOCOCCUS, COLD adaptation, BACTERIAL growth, BACTERIAL metabolism, PROTEOMICS

Abstract

The eurypsychrophilic bacterium Planococcus halocryophilus is capable of growth down to −15°C, making it ideal for studying adaptations to subzero growth. To increase our understanding of the mechanisms and pathways important for subzero growth, we performed proteomics on P. halocryophilus grown at 23°C, 23°C with 12% w/v NaCl and −10°C with 12% w/v NaCl. Many proteins with increased abundances at −10°C versus 23°C also increased at 23C-salt versus 23°C, indicating a closely tied relationship between salt and cold stress adaptation. Processes which displayed the largest changes in protein abundance were peptidoglycan and fatty acid (FA) synthesis, translation processes, methylglyoxal metabolism, DNA repair and recombination, and protein and nucleotide turnover. We identified intriguing targets for further research at −10°C, including PlsX and KASII (FA metabolism), DD-transpeptidase and MurB (peptidoglycan synthesis), glyoxalase family proteins (reactive electrophile response) and ribosome modifying enzymes (translation turnover). PemK/MazF may have a crucial role in translational reprogramming under cold conditions. At −10°C P. halocryophilus induces stress responses, uses resources efficiently, and carefully controls its growth and metabolism to maximize subzero survival. The present study identifies several mechanisms involved in subzero growth and enhances our understanding of cold adaptation. [ABSTRACT FROM AUTHOR]

Published

2017

24. Habitability on Early Mars and the Search for Biosignatures with the ExoMars Rover.

Author

Vago, Jorge L., Westall, Frances, Pasteur Instrument Teams, Landing Site Selection Working Group, and Other Contributors, Coates, Andrew J., Jaumann, Ralf, Korablev, Oleg, Ciarletti, Valérie, Mitrofanov, Igor, Josset, Jean-Luc, De Sanctis, Maria Cristina, Bibring, Jean-Pierre, Rull, Fernando, Goesmann, Fred, Steininger, Harald, Goetz, Walter, Brinckerhoff, William, Szopa, Cyril, Raulin, François, Edwards, Howell G. M., and Whyte, Lyle G.

Published

2017

25. Habitability on Early Mars and the Search for Biosignatures with the ExoMars Rover.

Author

Vago, Jorge L., Westall, Frances, Coates, Andrew J., Jaumann, Ralf, Korablev, Oleg, Ciarletti, Valérie, Mitrofanov, Igor, Josset, Jean-Luc, De Sanctis, Maria Cristina, Bibring, Jean-Pierre, Rull, Fernando, Goesmann, Fred, Steininger, Harald, Goetz, Walter, Brinckerhoff, William, Szopa, Cyril, Raulin, François, Edwards, Howell G. M., Whyte, Lyle G., and Fairén, Alberto G.

Published

2017

26. Comparative activity and functional ecology of permafrost soils and lithic niches in a hyper-arid polar desert.

Author

Goordial, Jacqueline, Davila, Alfonso, Greer, Charles W., Cannam, Rebecca, DiRuggiero, Jocelyne, McKay, Christopher P., and Whyte, Lyle G.

Subjects

PERMAFROST ecosystems, ECOLOGICAL niche, QUARRIES & quarrying, DESERT ecology, COMPARATIVE studies

Abstract

Permafrost in the high elevation McMurdo Dry Valleys of Antarctica ranks among the driest and coldest on Earth. Permafrost soils appear to be largely inhospitable to active microbial life, but sandstone lithic microhabitats contain a trophically simple but functional cryptoendolithic community. We used metagenomic sequencing and activity assays to examine the functional capacity of permafrost soils and cryptoendolithic communities in University Valley, one of the most extreme regions in the Dry Valleys. We found metagenomic evidence that cryptoendolithic microorganisms are adapted to the harsh environment and capable of metabolic activity at in situ temperatures, possessing a suite of stress response and nutrient cycling genes to fix carbon under the fluctuating conditions that the sandstone rock would experience during the summer months. We additionally identified genes involved in microbial competition and cooperation within the cryptoendolithic habitat. In contrast, permafrost soils have a lower richness of stress response genes, and instead the metagenome is enriched in genes involved with dormancy and sporulation. The permafrost soils also have a large presence of phage genes and genes involved in the recycling of cellular material. Our results underlie two different habitability conditions under extreme cold and dryness: the permafrost soil which is enriched in traits which emphasize survival and dormancy, rather than growth and activity; and the cryptoendolithic environment that selects for organisms capable of growth under extremely oligotrophic, arid and cold conditions. This study represents the first metagenomic interrogation of Antarctic permafrost and polar cryptoendolithic microbial communities. [ABSTRACT FROM AUTHOR]

Published

2017

27. Viral Induced Microbial Mortality in Arctic Hypersaline Spring Sediments.

Author

Colangelo-Lillis, Jesse, Wing, Boswell A., Raymond-Bouchard, Isabelle, and Whyte, Lyle G.

Subjects

MICROBIAL aggregation, CLASSIFICATION of viruses, SEAWATER salinity

Abstract

Viruses are a primary influence on microbial mortality in the global ocean. The impacts of viruses on their microbial hosts in low-energy environments are poorly explored and are the focus of this study. To investigate the role of viruses in mediating mortality in low-energy environments where contacts between viruses and microbes are infrequent, we conducted a set of in situ time series incubations in the outlet and channel sediments of two cold, hypersaline springs of the Canadian High Arctic. We found microbial and viral populations in dynamic equilibrium, indicating approximately equal birth and death rates for each population. In situ rates of microbial growth were low (0.5-50 x 10-3 cells cm-3 h-1) as were rates of viral decay (0.09-170 x 104 virions cm-3 h-1). A large fraction of the springs' viral communities (49-100%) were refractory to decay over the timescales of our experiments. Microcosms amended with lactate or acetate exhibited increased microbial growth rates (up to three-fold) indicating organic carbon as one limiting resource for the microbial communities in these environments. A substantial fraction (15-71%) of the microbial populations contained inducible proviruses that were released-occasionally in multiple pulses-over the eight monitored days following chemical induction. Our findings indicate that viruses in low-energy systems maintain low rates of production and activity, have a small but notable impact on microbial mortality (8-29% attenuation of growth) and that successful viral replication may primarily proceed by non-lethal strategies. In cold, low biomass marine systems of similar character (e.g., subsurface sediments), viruses may be a relatively minor driver of community mortality compared to less energy-limited environments such as the marine water column or surface sediments. [ABSTRACT FROM AUTHOR]

Published

2017

28. The Willow Microbiome Is Influenced by Soil Petroleum-Hydrocarbon Concentration with Plant Compartment-Specific Effects.

Author

Tardif, Stacie, Yergeau, Étienne, Tremblay, Julien, Legendre, Pierre, Whyte, Lyle G., and Greer, Charles W.

Subjects

HUMAN microbiota, PLANT cell compartmentation, FOSSIL fuels

Abstract

The interaction between plants and microorganisms, which is the driving force behind the decontamination of petroleum hydrocarbon (PHC) contamination in phytoremediation technology, is poorly understood. Here, we aimed at characterizing the variations between plant compartments in the microbiome of two willow cultivars growing in contaminated soils. A field experiment was set-up at a former petrochemical plant in Canada and after two growing seasons, bulk soil, rhizosphere soil, roots, and stems samples of two willow cultivars (Salix purpurea cv. FishCreek, and Salix miyabeana cv. SX67) growing at three PHC contamination concentrations were taken. DNA was extracted and bacterial 16S rRNA gene and fungal internal transcribed spacer (ITS) regions were amplified and sequenced using an Ion Torrent Personal Genome Machine (PGM). Following multivariate statistical analyses, the level of PHC-contamination appeared as the primary factor influencing the willow microbiome with compartment-specific effects, with significant differences between the responses of bacterial, and fungal communities. Increasing PHC contamination levels resulted in shifts in the microbiome composition, favoring putative hydrocarbon degraders, and microorganisms previously reported as associated with plant health. These shifts were less drastic in the rhizosphere, root, and stem tissues as compared to bulk soil, probably because the willows provided a more controlled environment, and thus, protected microbial communities against increasing contamination levels. Insights from this study will help to devise optimal plant microbiomes for increasing the efficiency of phytoremediation technology. [ABSTRACT FROM AUTHOR]

Published

2016

29. Low viral predation pressure in cold hypersaline Arctic sediments and limits on lytic replication.

Author

Colangelo‐Lillis, Jesse, Wing, Boswell A., and Whyte, Lyle G.

Subjects

MICROBIAL ecology, VIRAL replication, MARINE sediments, PREDATION, BIOGEOCHEMICAL cycles, WATER sampling, SEDIMENT sampling

Abstract

Viruses are ubiquitous drivers of microbial ecology and evolution and contribute to biogeochemical cycling. Attention to these attributes has been more substantial for marine viruses than viruses of other environments. Microscopy-based investigation of the viral communities from two cold, hypersaline Arctic springs was undertaken to explore the effects of these conditions on microbe-viral ecology. Sediments and water samples were collected along transects from each spring, from anoxic spring outlets through oxygenated downstream channels. Viral abundance, virus-microbe ratios and modelled virus-microbe contact rates were lower than comparable aqueous and sedimentary environments and most similar to deep subsurface sediments. No individual cell from either spring was visibly infected. Viruses in these springs appear to play a smaller role in controlling microbial populations through lytic activity than in marine water column or surface sedimentary environments. Relief from viral predation indicates the microbial communities are primarily controlled by nutrient limitation. The similarity of these springs to deep subsurface sediments suggests a biogeographic divide in viral replication strategy in marine sediments. [ABSTRACT FROM AUTHOR]

Published

2016

30. Actinorhizal Alder Phytostabilization Alters Microbial Community Dynamics in Gold Mine Waste Rock from Northern Quebec: A Greenhouse Study.

Author

Callender, Katrina L., Roy, Sébastien, Khasa, Damase P., Whyte, Lyle G., and Greer, Charles W.

Subjects

ACTINORHIZAL plants, ALDER, PHYTOREMEDIATION, GREENHOUSE plants, GOLD mining

Abstract

Phytotechnologies are rapidly replacing conventional ex-situ remediation techniques as they have the added benefit of restoring aesthetic value, important in the reclamation of mine sites. Alders are pioneer species that can tolerate and proliferate in nutrient-poor, contaminated environments, largely due to symbiotic root associations with the N2-fixing bacteria, Frankia and ectomycorrhizal (ECM) fungi. In this study, we investigated the growth of two Frankia-inoculated (actinorhizal) alder species, A. crispa and A. glutinosa, in gold mine waste rock from northern Quebec. Alder species had similar survival rates and positively impacted soil quality and physico-chemical properties in similar ways, restoring soil pH to neutrality and reducing extractable metals up to two-fold, while not hyperaccumulating them into above-ground plant biomass. A. glutinosa outperformed A. crispa in terms of growth, as estimated by the seedling volume index (SVI), and root length. Pyrosequencing of the bacterial 16S rRNA gene for bacteria and the ribosomal internal transcribed spacer (ITS) region for fungi provided a comprehensive, direct characterization of microbial communities in gold mine waste rock and fine tailings. Plant- and treatment-specific shifts in soil microbial community compositions were observed in planted mine residues. Shannon diversity and the abundance of microbes involved in key ecosystem processes such as contaminant degradation (Sphingomonas, Sphingobium and Pseudomonas), metal sequestration (Brevundimonas and Caulobacter) and N2-fixation (Azotobacter, Mesorhizobium, Rhizobium and Pseudomonas) increased over time, i.e., as plants established in mine waste rock. Acetate mineralization and most probable number (MPN) assays showed that revegetation positively stimulated both bulk and rhizosphere communities, increasing microbial density (biomass increase of 2 orders of magnitude) and mineralization (five-fold). Genomic techniques proved useful in investigating tripartite (plant-bacteria-fungi) interactions during phytostabilization, contributing to our knowledge in this field of study. [ABSTRACT FROM AUTHOR]

Published

2016

31. Effects of simulated spring thaw of permafrost from mineral cryosol on CO2 emissions and atmospheric CH4 uptake.

Author

Stackhouse, Brandon T., Vishnivetskaya, Tatiana A., Layton, Alice, Chauhan, Archana, Pfiffner, Susan, Mykytczuk, Nadia C., Sanders, Rebecca, Whyte, Lyle G., Hedin, Lars, Saad, Nabil, Myneni, Satish, and Onstott, Tullis C.

Published

2015

32. Toxic Cyanobacterial Bloom Triggers in Missisquoi Bay, Lake Champlain, as Determined by Next-Generation Sequencing and Quantitative PCR.

Author

Fortin, Nathalie, Munoz-Ramos, Valentina, Greer, Charles W., Bird, David, Lévesque, Benoît, and Whyte, Lyle G.

Subjects

MICROCYSTIS, CHROOCOCCACEAE, NOSTOCALES, CYANOBACTERIA, ESCHERICHIA coli

Abstract

The article focuses on the triggers behind toxic cyanobacterial blooms in Missisquoi Bay on Lake Champlain using quantitative polymerase chain reaction and next-generation sequencing. It states that non-point sources are responsible for high concentrations of nitrogen and phosphorus in the bay, with nutrient concentrations and total phosphorus:total nitrogen ratios approaching 1:11, along with warmer temperatures, promote the blooms. It correlates total and dissolved phosphorus with rainfall.

Published

2015

33. Chapter 14: LIFE IN ICE ON OTHER WORLDS.

Author

McKay, Christopher P., Mykytczuk, Nadia C. S., and Whyte, Lyle G.

Published

2012

34. Chapter 13: CLIMATE CHANGE, OZONE DEPLETION, AND LIFE AT THE POLES.

Author

Vrionis, Helen A., Warner, Karen, Whyte, Lyle G., and Miller, Robert V.

Published

2012

35. Atmospheric methane oxidizers are present and active in Canadian high Arctic soils.

Author

Martineau, Christine, Pan, Yao, Bodrossy, Levente, Yergeau, Etienne, Whyte, Lyle G., and Greer, Charles W.

Subjects

ATMOSPHERIC methane, OXIDIZING agents, SOIL microbiology, PERMAFROST, GLOBAL warming

Abstract

The melting of permafrost and the associated potential for methane emissions to the atmosphere are major concerns in the context of global warming. However, soils can also represent a significant sink for methane through the activity of methane-oxidizing bacteria (MOB). In this study, we looked at the activity, diversity, and community structure of MOB at two sampling depths within the active layer in three soils from the Canadian high Arctic. These soils had the capacity to oxidize methane at low (15 ppm) and high (1000 ppm) methane concentrations, but rates differed greatly depending on the sampling date, depth, and site. The pmoA gene sequences related to two genotypes of uncultured MOB involved in atmospheric methane oxidation, the 'upland soil cluster gamma' and the 'upland soil cluster alpha', were detected in soils with near neutral and acidic pH, respectively. Other groups of MOB, including Type I methanotrophs and the 'Cluster 1' genotype, were also detected, indicating a broader diversity of MOB than previously reported for Arctic soils. Overall, the results reported here showed that methane oxidation at both low and high methane concentrations occurs in high Arctic soils and revealed that different groups of atmospheric MOB inhabit these soils. [ABSTRACT FROM AUTHOR]

Published

2014

36. Predictable bacterial composition and hydrocarbon degradation in Arctic soils following diesel and nutrient disturbance.

Author

Bell, Terrence H, Yergeau, Etienne, Maynard, Christine, Juck, David, Whyte, Lyle G, and Greer, Charles W

Subjects

COMPOSITION of bacteria, BIODEGRADATION of hydrocarbons, RESOURCE exploitation, OIL pollution of soils, MICROORGANISM populations, BIOREMEDIATION

Abstract

Increased exploration and exploitation of resources in the Arctic is leading to a higher risk of petroleum contamination. A number of Arctic microorganisms can use petroleum for growth-supporting carbon and energy, but traditional approaches for stimulating these microorganisms (for example, nutrient addition) have varied in effectiveness between sites. Consistent environmental controls on microbial community response to disturbance from petroleum contaminants and nutrient amendments across Arctic soils have not been identified, nor is it known whether specific taxa are universally associated with efficient bioremediation. In this study, we contaminated 18 Arctic soils with diesel and treated subsamples of each with monoammonium phosphate (MAP), which has successfully stimulated degradation in some contaminated Arctic soils. Bacterial community composition of uncontaminated, diesel-contaminated and diesel+MAP soils was assessed through multiplexed 16S (ribosomal RNA) rRNA gene sequencing on an Ion Torrent Personal Genome Machine, while hydrocarbon degradation was measured by gas chromatography analysis. Diversity of 16S rRNA gene sequences was reduced by diesel, and more so by the combination of diesel and MAP. Actinobacteria dominated uncontaminated soils with <10% organic matter, while Proteobacteria dominated higher-organic matter soils, and this pattern was exaggerated following disturbance. Degradation with and without MAP was predictable by initial bacterial diversity and the abundance of specific assemblages of Betaproteobacteria, respectively. High Betaproteobacteria abundance was positively correlated with high diesel degradation in MAP-treated soils, suggesting this may be an important group to stimulate. The predictability with which bacterial communities respond to these disturbances suggests that costly and time-consuming contaminated site assessments may not be necessary in the future. [ABSTRACT FROM AUTHOR]

Published

2013

37. Bacterial growth at −15 °C; molecular insights from the permafrost bacterium Planococcus halocryophilus Or1.

Author

Mykytczuk, Nadia C S, Foote, Simon J, Omelon, Chris R, Southam, Gordon, Greer, Charles W, and Whyte, Lyle G

Subjects

BACTERIAL growth, PERMAFROST microbiology, PLANOCOCCUS, HABITATS, CELL physiology, CELL envelope (Biology), CELL membranes, FATTY acids

Abstract

Planococcus halocryophilus strain Or1, isolated from high Arctic permafrost, grows and divides at −15 °C, the lowest temperature demonstrated to date, and is metabolically active at −25 °C in frozen permafrost microcosms. To understand how P. halocryophilus Or1 remains active under the subzero and osmotically dynamic conditions that characterize its native permafrost habitat, we investigated the genome, cell physiology and transcriptomes of growth at −15 °C and 18% NaCl compared with optimal (25 °C) temperatures. Subzero growth coincides with unusual cell envelope features of encrustations surrounding cells, while the cytoplasmic membrane is significantly remodeled favouring a higher ratio of saturated to branched fatty acids. Analyses of the 3.4 Mbp genome revealed that a suite of cold and osmotic-specific adaptive mechanisms are present as well as an amino acid distribution favouring increased flexibility of proteins. Genomic redundancy within 17% of the genome could enable P. halocryophilus Or1 to exploit isozyme exchange to maintain growth under stress, including multiple copies of osmolyte uptake genes (Opu and Pro genes). Isozyme exchange was observed between the transcriptome data sets, with selective upregulation of multi-copy genes involved in cell division, fatty acid synthesis, solute binding, oxidative stress response and transcriptional regulation. The combination of protein flexibility, resource efficiency, genomic plasticity and synergistic adaptation likely compensate against osmotic and cold stresses. These results suggest that non-spore forming P. halocryophilus Or1 is specifically suited for active growth in its Arctic permafrost habitat (ambient temp. ∼−16 °C), indicating that such cryoenvironments harbor a more active microbial ecosystem than previously thought. [ABSTRACT FROM AUTHOR]

Published

2013

38. Microbial Competition in Polar Soils: A Review of an Understudied but Potentially Important Control on Productivity.

Author

Bell, Terrence H., Callender, Katrina L., Whyte, Lyle G., and Greer, Charles W.

Subjects

MICROORGANISMS, TUNDRA soils, MICROBIAL aggregation, BIODEGRADATION, BIOGEOCHEMISTRY, BEHAVIOR

Abstract

Intermicrobial competition is known to occur in many natural environments, and can result from direct conflict between organisms, or from differential rates of growth, colonization, and/or nutrient acquisition. It has been difficult to extensively examine intermicrobial competition in situ, but these interactions may play an important role in the regulation of the many biogeochemical processes that are tied to microbial communities in polar soils. A greater understanding of how competition influences productivity will improve projections of gas and nutrient flux as the poles warm, may provide biotechnological opportunities for increasing the degradation of contaminants in polar soil, and will help to predict changes in communities of higher organisms, such as plants. [ABSTRACT FROM AUTHOR]

Published

2013

39. Microbes in thawing permafrost: the unknown variable in the climate change equation.

Author

Graham, David E, Wallenstein, Matthew D, Vishnivetskaya, Tatiana A, Waldrop, Mark P, Phelps, Tommy J, Pfiffner, Susan M, Onstott, Tullis C, Whyte, Lyle G, Rivkina, Elizaveta M, Gilichinsky, David A, Elias, Dwayne A, Mackelprang, Rachel, VerBerkmoes, Nathan C, Hettich, Robert L, Wagner, Dirk, Wullschleger, Stan D, and Jansson, Janet K

Subjects

PERMAFROST microbiology, CLIMATE change, METHANOBACTERIACEAE, HUMUS, MICROBIOLOGICAL synthesis, THERMOKARST, HYDROLOGY

Published

2012

40. Life at the Wedge: the Activity and Diversity of Arctic Ice Wedge Microbial Communities.

Author

Wilhelm, Roland C., Radtke, Kristin J., Mykytczuk, Nadia C.S., Greer, Charles W., and Whyte, Lyle G.

Published

2012

41. Microbial diversity of active layer and permafrost in an acidic wetland from the Canadian High Arctic.

Author

Wilhelm, Roland C., Niederberger, Thomas D., Greer, Charles, and Whyte, Lyle G.

Subjects

MICROBIAL viability counts, MICROBIAL diversity, PERMAFROST, WETLANDS, NUCLEOTIDE sequence, MICROBIAL genetics, GENE libraries

Abstract

Copyright of Canadian Journal of Microbiology is the property of Canadian Science Publishing and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2011

42. Microbial characterization of a subzero, hypersaline methane seep in the Canadian High Arctic.

Author

Niederberger, Thomas D., Perreault, Nancy N., Tille, Stephanie, Lollar, Barbara Sherwood, Lacrampe-Couloume, Georges, Andersen, Dale, Greer, Charles W., Pollard, Wayne, and Whyte, Lyle G.

Subjects

MICROBIOLOGY, METHANE, MICROORGANISMS, PROTOZOOLOGY, BACTERIOLOGY

Abstract

We report the first microbiological characterization of a terrestrial methane seep in a cryo-environment in the form of an Arctic hypersaline (∼24% salinity), subzero (−5 °C), perennial spring, arising through thick permafrost in an area with an average annual air temperature of −15 °C. Bacterial and archaeal 16S rRNA gene clone libraries indicated a relatively low diversity of phylotypes within the spring sediment (Shannon index values of 1.65 and 1.39, respectively). Bacterial phylotypes were related to microorganisms such as Loktanella, Gillisia, Halomonas and Marinobacter spp. previously recovered from cold, saline habitats. A proportion of the bacterial phylotypes were cultured, including Marinobacter and Halomonas, with all isolates capable of growth at the in situ temperature (−5 °C). Archaeal phylotypes were related to signatures from hypersaline deep-sea methane-seep sediments and were dominated by the anaerobic methane group 1a (ANME-1a) clade of anaerobic methane oxidizing archaea. CARD-FISH analyses indicated that cells within the spring sediment consisted of ∼84.0% bacterial and 3.8% archaeal cells with ANME-1 cells accounting for most of the archaeal cells. The major gas discharging from the spring was methane (∼50%) with the low CH4/C2+ ratio and hydrogen and carbon isotope signatures consistent with a thermogenic origin of the methane. Overall, this hypersaline, subzero environment supports a viable microbial community capable of activity at in situ temperature and where methane may behave as an energy and carbon source for sustaining anaerobic oxidation of methane-based microbial metabolism. This site also provides a model of how a methane seep can form in a cryo-environment as well as a mechanism for the hypothesized Martian methane plumes. [ABSTRACT FROM AUTHOR]

Published

2010

43. The functional potential of high Arctic permafrost revealed by metagenomic sequencing, qPCR and microarray analyses.

Author

Yergeau, Etienne, Hogues, Hervé, Whyte, Lyle G., and Greer, Charles W.

Subjects

PERMAFROST, GLOBAL warming, GREENHOUSE gases, MICROBIAL ecology, METHANE, ACTINOBACTERIA, POLYMERASE chain reaction

Abstract

The fate of the carbon stocked in permafrost following global warming and permafrost thaw is of major concern in view of the potential for increased CH4 and CO2 emissions from these soils. Complex carbon compound degradation and greenhouse gas emissions are due to soil microbial communities, but no comprehensive study has yet addressed their composition and functional potential in permafrost. Here, a 2-m deep permafrost sample and its overlying active layer soil were subjected to metagenomic sequencing, quantitative PCR (qPCR) and microarray analyses. The active layer soil and the 2-m permafrost microbial community structures were very similar, with Actinobacteria being the dominant phylum. The two samples also possessed a highly similar spectrum of functional genes, especially when compared with other already published metagenomes. Key genes related to methane generation, methane oxidation and organic matter degradation were highly diverse for both samples in the metagenomic libraries and some (for example, pmoA) showed relatively high abundance in qPCR assays. Genes related to nitrogen fixation and ammonia oxidation, which could have important roles following climatic change in these nitrogen-limited environments, showed low diversity but high abundance. The 2-m permafrost showed lower abundance and diversity for all the assessed genes and taxa. Experimental biases were also evaluated using qPCR and showed that the whole-community genome amplification technique used caused representational biases in the metagenomic libraries by increasing the abundance of Bacteroidetes and decreasing the abundance of Actinobacteria. This study describes for the first time the detailed functional potential of permafrost-affected soils. [ABSTRACT FROM AUTHOR]

Published

2010

44. Microbial community characterization of the Gully: a marine protected area.

Author

Yeung, C. William, Lee, Kenneth, Whyte, Lyle G., and Greer, Charles W.

Subjects

PROTECTED areas, MICROBIAL ecology, ELECTROPHORESIS, DENATURING gradient gel electrophoresis, NUCLEOTIDE sequence, CLUSTER analysis (Statistics)

Abstract

The Gully is the first Fisheries and Oceans Canada marine protected area off the eastern coast of Canada. To ensure success of conservation efforts in this area, it is essential to develop a better understanding of microbial community composition from the euphotic zone to the deep sea in this previously unsurveyed environment. Denaturing gradient gel electrophoresis (DGGE) and nucleotide sequencing were used to characterize microbial community structure. DGGE results showed a clear difference in the microbial community structure between the euphotic zone and the deep sea water. Cluster analysis showed high similarity (>85%) for all the samples taken from below 500 m, but lower similarity (49%-72%) when comparing samples from above and below 500 m. Changes in microbial community structure with depth corresponded well with changes in oceanographic physical parameters. Furthermore, 16S rRNA gene analysis showed that the bacterioplankton sequences generally clustered into 1 of 9 major lineages commonly found in marine systems. However, not all the major lineages were detected at all the different depths. The SAR11 and SAR116 sequences were only present in the surface water, and the SAR324 and Actinobacteria sequences were only present in deep sea water. These findings provide a preliminary characterization of the microbial communities of this unique ecosystem. Le Goulet est la première aire marine protégée de Pêches et Océans Canada située au large de la côte Est canadienne. Afin d’assurer le succès des efforts de conservation dans cette aire, il est essentiel de mieux comprendre la composition de la communauté microbienne qui s’échelonne de la zone euphotique vers les eaux profondes dans cet environnement encore non étudié. L’électrophorèse en gradient de gel dénaturant (DGGE) et le séquençage de nucléotides ont été utilisés pour caractériser la structure de la communauté microbienne. Les résultats de la DGGE ont montré une différence marquée entre la structure de la communauté de la zone euphotique et celle trouvée en eau profonde. Une analyse de grappe a montré un haut degré de similarité (>85 %) entre tous les échantillons prélevés à des profondeurs sous les 500 m, mais un degré moins élevé (49 % - 72 %) lorsque les échantillons prélevés au dessus et en dessous de 500 m étaient comparés. Les changements dans la structure de la communauté microbienne en fonction de la profondeur correspondaient bien avec les paramètres physiques océanographiques. De plus, l’analyse du gène de l’ARNr 16S a montré que les séquences des bactérioplanctons se groupaient généralement dans 1 des 9 lignages principaux communément trouvés dans les systèmes marins. Cependant, les lignages n’étaient pas tous détectés à toutes les profondeurs. Les séquences de SAR11 et de SAR116 n’étaient présentes que dans les eaux de surfaces alors que les séquences de SAR324 et d’Actinobacteria n’étaient présentes qu’en eaux profondes. Ces résultats fournissent une caractérisation préliminaire des communautés microbiennes de cet écosystème unique. [ABSTRACT FROM AUTHOR]

Published

2010

45. Novel sulfur-oxidizing streamers thriving in perennial cold saline springs of the Canadian high Arctic.

Author

Niederberger, Thomas D., Perreault, Nancy N., Lawrence, John R., Nadeau, Jay L., Mielke, Randall E., Greer, Charles W., Andersen, Dale T., and Whyte, Lyle G.

Subjects

WATER springs, SALINE waters, PHOTOSYNTHETIC oxygen evolution, HYDROGEOLOGY, METEOROLOGICAL precipitation, FROZEN ground, SNOW

Abstract

The perennial springs at Gypsum Hill (GH) and Colour Peak (CP), situated at nearly 80°N on Axel Heiberg Island in the Canadian high Arctic, are one of the few known examples of cold springs in thick permafrost on Earth. The springs emanate from deep saline aquifers and discharge cold anoxic brines rich in both sulfide and sulfate. Grey-coloured microbial streamers form during the winter months in snow-covered regions of the GH spring run-off channels (−1.3°C to 6.9°C, ∼7.5% NaCl, 0–20 p.p.m. dissolved sulfide, 1 p.p.m. dissolved oxygen) but disappear during the Arctic summer. Culture- and molecular-based analyses of the 16S rRNA gene (FISH, DGGE and clone libraries) indicated that the streamers were uniquely dominated by chemolithoautotrophic sulfur-oxidizing Thiomicrospira species . The streamers oxidized both sulfide and thiosulfate and fixed CO2 under in situ conditions and a Thiomicrospira strain isolated from the streamers also actively oxidized sulfide and thiosulfate and fixed CO2 under cold, saline conditions. Overall, the snow-covered spring channels appear to represent a unique polar saline microhabitat that protects and allows Thiomicrospira streamers to form and flourish via chemolithoautrophic, phototrophic-independent metabolism in a high Arctic winter environment characterized by air temperatures commonly below −40°C and with an annual average air temperature of −15°C. These results broaden our knowledge of the physical and chemical boundaries that define life on Earth and have astrobiological implications for the possibility of life existing under similar Martian conditions. [ABSTRACT FROM AUTHOR]

Published

2009

46. Microbial diversity and activity through a permafrost/ground ice core profile from the Canadian high Arctic.

Author

Steven, Blaire, Pollard, Wayne H., Greer, Charles W., and Whyte, Lyle G.

Subjects

MICROBIAL diversity, PERMAFROST, ARCHAEBACTERIA, BACTERIA, ACTINOBACTERIA, MICROBIAL ecology

Abstract

Culture-dependent and culture-independent methods were used in an investigation of the microbial diversity in a permafrost/massive ground ice core from the Canadian high Arctic. Denaturing gradient gel electrophoresis as well as Bacteria and Archaea 16S rRNA gene clone libraries showed differences in the composition of the microbial communities in the distinct core horizons. Microbial diversity was similar in the active layer (surface) soil, permafrost table and permafrost horizons while the ground ice microbial community showed low diversity. Bacteria and Archaea sequences related to the Actinobacteria (54%) and Crenarchaeota (100%) respectively were predominant in the active layer while the majority of sequences in the permafrost were related to the Proteobacteria (57%) and Euryarchaeota (76%) . The most abundant phyla in the ground ice clone libraries were the Firmicutes (59%) and Crenarchaeota (82%). Isolates from the permafrost were both less abundant and diverse than in the active layer soil, while no culturable cells were recovered from the ground ice. Mineralization of [1-14C] acetic acid and [2-14C] glucose was used to detect microbial activity in the different horizons in the core. Mineralization was detected at near ambient permafrost temperatures (−15°C), indicating that permafrost may harbour an active microbial population, while the low microbial diversity, abundance and activity in ground ice suggests a less hospitable microbial habitat. [ABSTRACT FROM AUTHOR]

Published

2008

47. Prokaryotic diversity of arctic ice shelf microbial mats.

Author

Bottos, Eric M., Vincent, Warwick F., Greer, Charles W., and Whyte, Lyle G.

Subjects

PROKARYOTES, MICROBIAL diversity, MICROBIAL mats, MICROORGANISM populations, HETEROTROPHIC bacteria, MOLECULAR cloning, GENE libraries, MICROBIAL genetics, BACTERIAL metabolism

Abstract

The prokaryotic diversity and respiratory activity of microbial mat communities on the Markham Ice Shelf and Ward Hunt Ice Shelf in the Canadian high Arctic were analysed. All heterotrophic isolates and > 95% of bacterial 16S rRNA gene clone library sequences from both ice shelves grouped within the phyla Bacteroidetes, Proteobacteria and Actinobacteria. Clone library analyses showed that the bacterial communities were diverse and varied significantly between the two ice shelves, with the Markham library having a higher estimated diversity (Chao1 = 243; 105 operational taxonomic units observed in 189 clones) than the Ward Hunt library (Chao1 = 106; 52 operational taxonomic units observed in 128 clones). Archaeal 16S rRNA gene clone libraries from both ice shelves were dominated by a single Euryarchaeota sequence, which appears to represent a novel phylotype. Analyses of community activity by radiorespiration assays detected metabolism in mat samples from both ice shelves at temperatures as low as −10°C. These findings provide the first insight into the prokaryotic biodiversity of Arctic ice shelf communities and underscore the importance of these cryo-ecosystems as a rich source of microbiota that are adapted to extreme cold. [ABSTRACT FROM AUTHOR]

Published

2008

48. Comparative phylogenetic analysis of microbial communities in pristine and hydrocarbon-contaminated Alpine soils.

Author

Labbé, Diane, Margesin, Rosa, Schinner, Franz, Whyte, Lyle G., and Greer, Charles W.

Subjects

MOUNTAIN soils, SOIL microbial ecology, SOIL pollution, HYDROCARBONS, PHYLOGENY, ACTINOBACILLUS, DENATURING gradient gel electrophoresis

Abstract

A molecular characterization of pristine and petroleum hydrocarbon-contaminated Alpine soils sampled in Tyrol (Austria) was performed. To identify predominant bacteria, PCR-amplified 16S rRNA gene fragments from five pristine and nine contaminated soils were analysed using denaturing gradient gel electrophoresis (DGGE). Sequencing and phylogenetic analyses demonstrated that the majority of the DGGE bands represented bacteria in the Actinobacteria and Proteobacteria phyla: 18 and 73%, respectively, in pristine soils, compared with 20 and 76%, respectively, in contaminated soils. A different distribution pattern of bacterial classes in the Proteobacteria was observed between pristine and contaminated soils. The relative proportion of microorganisms belonging to the Alphaproteobacteria was larger in pristine (46%) than in contaminated (24%) soils, while Betaproteobacteria and Gammaproteobacteria were detected only in the hydrocarbon-contaminated soils. This result compared favourably with earlier work in which hydrocarbon-degradation genotypes, largely pseudomonads and Acinetobacter, belonging to the Gammaproteobacteria, were enriched following oil hydrocarbon contamination. In contrast, members of the Actinobacteria phylum, represented by Rhodococcus and Mycobacterium, were found in pristine soils where contamination events had not occurred. The results demonstrate a significant shift in the microbial community structure in Alpine soils following contamination. Furthermore, more potentially novel phylotypes were found in the pristine soils than in the contaminated soils. [ABSTRACT FROM AUTHOR]

Published

2007

49. Characterization of the microbial diversity in a permafrost sample from the Canadian high Arctic using culture-dependent and culture-independent methods.

Author

Steven, Blaire, Briggs, Geoffrey, McKay, Chris P., Pollard, Wayne H., Greer, Charles W., and Whyte, Lyle G.

Subjects

PERMAFROST, MICROBIAL diversity, MOLECULAR cloning, CYTOPHAGA, ARCHAEBACTERIA, PHYLOGENY

Abstract

A combination of culture-dependent and culture-independent methodologies ( Bacteria and Archaea 16S rRNA gene clone library analyses) was used to determine the microbial diversity present within a geographically distinct high Arctic permafrost sample. Culturable Bacteria isolates, identified by 16S rRNA gene sequencing, belonged to the phyla Firmicutes, Actinobacteria and Proteobacteria with spore-forming Firmicutes being the most abundant; the majority of the isolates (19/23) were psychrotolerant, some (11/23) were halotolerant, and three isolates grew at −5°C. A Bacteria 16S rRNA gene library containing 101 clones was composed of 42 phylotypes related to diverse phylogenetic groups including the Actinobacteria, Proteobacteria, Firmicutes, Cytophaga – Flavobacteria – Bacteroides, Planctomyces and Gemmatimonadetes; the bacterial 16S rRNA gene phylotypes were dominated by Actinobacteria- and Proteobacteria-related sequences. An Archaea 16S rRNA gene clone library containing 56 clones was made up of 11 phylotypes and contained sequences related to both of the major Archaea domains ( Euryarchaeota and Crenarchaeota); the majority of sequences in the Archaea library were related to halophilic Archaea. Characterization of the microbial diversity existing within permafrost environments is important as it will lead to a better understanding of how microorganisms function and survive in such extreme cryoenvironments. [ABSTRACT FROM AUTHOR]

Published

2007

50. Alkane hydroxylase homologues in Gram-positive strains.

Author

van Beilen, Jan B., Smits, Theo H. M., Whyte, Lyle G., Schorcht, Susanne, Röthlisberger, Martina, Plaggemeier, Thorsten, Engesser, Karl-Heinrich, and Witholt, Bernard

Subjects

ALKANES, GRAM-positive bacteria, POLYMERASE chain reaction, HYDROXYLATION

Abstract

Summary We isolated Gram-positive alkane-degraders from soil and a tricking-bed reactor, and show using polymerase chain reaction (PCR) with degenerate alkane hydroxylase primers and Southern blots that most Rhodococcus isolates contain three to five quite divergent homologues of the Pseudomonas putida GPo1 alkB gene. Two Mycobacterium isolates each contain one homologue, however there is no evidence for the presence of alkB homologues in the remaining strains. [ABSTRACT FROM AUTHOR]

Published

2002