Your search keyword '"Rebecca A. Daly"' showing total 65 results

1. Methane-Oxidizing Activity Enhances Sulfamethoxazole Biotransformation in a Benthic Constructed Wetland Biomat

Author

Michael A. P. Vega, Rachel C. Scholes, Adam R. Brady, Rebecca A. Daly, Adrienne B. Narrowe, Gary F. Vanzin, Kelly C. Wrighton, David L. Sedlak, and Jonathan O. Sharp

Subjects

Environmental Chemistry, General Chemistry

Published

2023

2. Pharmaceutical Biotransformation is Influenced by Photosynthesis and Microbial Nitrogen Cycling in a Benthic Wetland Biomat

Author

Michael A. P. Vega, Rachel C. Scholes, Adam R. Brady, Rebecca A. Daly, Adrienne B. Narrowe, Lily B. Bosworth, Kelly C. Wrighton, David L. Sedlak, and Jonathan O. Sharp

Subjects

Nitrogen, Nitrous Oxide, Water, General Chemistry, Nitrification, Trimethoprim, Oxygen, Atenolol, Pharmaceutical Preparations, Nitrate Reductases, Wetlands, Ammonium Compounds, Denitrification, Emtricitabine, Environmental Chemistry, Photosynthesis, Biotransformation, Metoprolol

Abstract

In shallow, open-water engineered wetlands, design parameters select for a photosynthetic microbial biomat capable of robust pharmaceutical biotransformation, yet the contributions of specific microbial processes remain unclear. Here, we combined genome-resolved metatranscriptomics and oxygen profiling of a field-scale biomat to inform laboratory inhibition microcosms amended with a suite of pharmaceuticals. Our analyses revealed a dynamic surficial layer harboring oxic-anoxic cycling and simultaneous photosynthetic, nitrifying, and denitrifying microbial transcription spanning nine bacterial phyla, with unbinned eukaryotic scaffolds suggesting a dominance of diatoms. In the laboratory, photosynthesis, nitrification, and denitrification were broadly decoupled by incubating oxic and anoxic microcosms in the presence and absence of light and nitrogen cycling enzyme inhibitors. Through combining microcosm inhibition data with field-scale metagenomics, we inferred microbial clades responsible for biotransformation associated with membrane-bound nitrate reductase activity (emtricitabine, trimethoprim, and atenolol), nitrous oxide reduction (trimethoprim), ammonium oxidation (trimethoprim and emtricitabine), and photosynthesis (metoprolol). Monitoring of transformation products of atenolol and emtricitabine confirmed that inhibition was specific to biotransformation and highlighted the value of oscillating redox environments for the further transformation of atenolol acid. Our findings shed light on microbial processes contributing to pharmaceutical biotransformation in open-water wetlands with implications for similar nature-based treatment systems.

Published

2022

3. Human-Gut Phages Harbor Sporulation Genes

Author

Daniel A. Schwartz, Josué A. Rodríguez-Ramos, Michael Shaffer, Rory M. Flynn, Rebecca A. Daly, Kelly C. Wrighton, and Jay T. Lennon

Subjects

Virology, Microbiology

Abstract

Spore-forming bacteria are prevalent in mammalian guts and have implications for host health and nutrition. The production of dormant spores is thought to play an important role in the colonization, persistence, and transmission of these bacteria. Spore formation also modifies interactions among microorganisms such as infection by phages. Recent studies suggest that phages may counter dormancy-mediated defense through the expression of phage-encoded sporulation genes during infection, which can alter the transitions between active and inactive states. By mining genomes and gut-derived metagenomes, we identified sporulation genes that are preferentially encoded by phages that infect spore-forming bacteria. These included genes involved in chromosome partitioning, DNA damage repair, and cell wall-associated functions. In addition, phages contained homologs of sporulation-specific transcription factors, notablyspo0A, the master regulator of sporulation, which could allow phages to control the complex genetic network responsible for spore development. Our findings suggest that phages could influence the formation of bacterial spores with implications for the health of the human gut microbiome, as well as bacterial communities in other environments.SIGNIFICANCEPhages acquire bacterial genes and use them to alter host metabolism in ways that enhance their fitness. To date, most auxiliary genes replace or modulate enzymes that are used by the host for nutrition or energy production. However, phage fitness is affected by all aspects of host physiology, including decisions that reduce metabolic activity of the cell. Here we focus on endosporulation, a complex and ancient form of dormancy found among the Bacillota that involves hundreds of genes. By coupling homology searches with host classification, we identify 31 phage-encoded homologs of sporulation genes that are mostly limited to phages infecting spore-forming bacteria. Nearly one-third the homologs recovered were regulatory genes suggesting that phages may manipulate host genetic networks by tapping into their control elements. Our findings also suggest a mechanism by which phages can overcome the defensive strategy of dormancy, which may be involved in coevolutionary dynamics of spore-forming bacteria.

Published

2023

4. Spatial and temporal metagenomics of river compartments reveals viral community dynamics in an urban impacted stream

Author

Josué Rodríguez-Ramos, Angela Oliverio, Mikayla A. Borton, Robert Danczak, Birgit M. Mueller, Hanna Schulz, Jared Ellenbogen, Rory M. Flynn, Rebecca A. Daly, LeAundra Schopflin, Michael Shaffer, Amy Goldman, Joerg Lewandowski, James C. Stegen, and Kelly C. Wrighton

Subjects

Article

Abstract

Although river ecosystems comprise less than 1% of Earth’s total non-glaciated area, they are critical modulators of microbially and virally orchestrated global biogeochemical cycles. However, most studies either use data that is not spatially resolved or is collected at timepoints that do not reflect the short life cycles of microorganisms. As a result, the relevance of microbiome interactions and the impacts they have over time on biogeochemical cycles are poorly understood. To assess how viral and microbial communities change over time, we sampled surface water and pore water compartments of the wastewater-impacted River Erpe in Germany every 3 hours over a 48-hour period resulting in 32 metagenomes paired to geochemical and metabolite measurements. We reconstructed 6,500 viral and 1,033 microbial genomes and found distinct communities associated with each river compartment. We show that 17% of our vMAGs clustered to viruses from other ecosystems like wastewater treatment plants and rivers. Our results also indicated that 70% of the viral community was persistent in surface waters, whereas only 13% were persistent in the pore waters taken from the hyporheic zone. Finally, we predicted linkages between 73 viral genomes and 38 microbial genomes. These putatively linked hosts included members of theCompetibacteraceae,which we suggest are potential contributors to carbon and nitrogen cycling. Together, these findings demonstrate that microbial and viral communities in surface waters of this urban river can exist as stable communities along a flowing river; and raise important considerations for ecosystem models attempting to constrain dynamics of river biogeochemical cycles.

Published

2023

5. Improving Healthy Living in Residential Care Facilities: Feasibility, Acceptability, and Appropriateness of Implementing a Multicomponent Intervention for Diabetes Risk Reduction in Adults with Serious Mental Illnesses

Author

David H. Sommerfeld, Amy M. Brunner, Danielle Glorioso, Ellen E. Lee, Cynthia Ibarra, Elizabeth Zunshine, Rebecca E. Daly, Christine Zoumas, and Dilip V. Jeste

Subjects

Psychiatry and Mental health, Health Policy, Public Health, Environmental and Occupational Health, Pshychiatric Mental Health

Abstract

Persons with serious mental illnesses experience high rates of medical comorbidity, especially diabetes. This study examined initial implementation feasibility, acceptability, and appropriateness of a new 6-month Multicomponent Intervention for Diabetes risk reduction in Adults with Serious mental illnesses (MIDAS) among persons in residential care facilities (RCFs). We conducted a mixed-methods study using four types of quantitative and qualitative data sources (administrative data; structured facility-level observations; resident assessments including blood-based biomarkers, 24-h dietary recalls, and self-report physical activity; and focus groups/interviews with staff and participants), to assess evidence of and factors affecting intervention feasibility, acceptability, and appropriateness. It was feasible to provide a high percentage of MIDAS class sessions (mean 50 of 52 intended sessions delivered) and make nutrition-related RCF changes (substitutions for healthier food items and reduced portion sizes). Class attendance rates and positive feedback from residents and staff provided evidence of MIDAS acceptability and appropriateness for addressing identified health needs. The residents who attended ≥ 85% of the sessions had greater improvement in several desired outcomes compared to others. Implementing a fully integrated MIDAS model with more extensive changes to facilities and more fundamental health changes among residents was more challenging. While the study found evidence to support feasibility, acceptability, and appropriateness of individual MIDAS components, some challenges for full implementation and success in obtaining immediate health benefits were also apparent. The study results highlight the need for improving health among RCF populations and will inform MIDAS adaptations designed to improve intervention fit and effectiveness outcomes.

Published

2022

6. Microbial colonization and persistence in deep fractured shales is guided by metabolic exchanges and viral predation

Author

Kaela K. Amundson, Mikayla A. Borton, Rebecca A. Daly, David W. Hoyt, Allison Wong, Elizabeth Eder, Joseph Moore, Kenneth Wunch, Kelly C. Wrighton, and Michael J. Wilkins

Subjects

Microbiology (medical), Canada, Bacteria, Hydraulic Fracking, Microbiota, Research, QR100-130, Shale, Microbiology, Thermotoga, Microbial ecology, Predatory Behavior, Viruses, Animals, Metabolomics, Subsurface, Metagenomics

Abstract

Background Microbial colonization of subsurface shales following hydraulic fracturing offers the opportunity to study coupled biotic and abiotic factors that impact microbial persistence in engineered deep subsurface ecosystems. Shale formations underly much of the continental USA and display geographically distinct gradients in temperature and salinity. Complementing studies performed in eastern USA shales that contain brine-like fluids, here we coupled metagenomic and metabolomic approaches to develop the first genome-level insights into ecosystem colonization and microbial community interactions in a lower-salinity, but high-temperature western USA shale formation. Results We collected materials used during the hydraulic fracturing process (i.e., chemicals, drill muds) paired with temporal sampling of water produced from three different hydraulically fractured wells in the STACK (Sooner Trend Anadarko Basin, Canadian and Kingfisher) shale play in OK, USA. Relative to other shale formations, our metagenomic and metabolomic analyses revealed an expanded taxonomic and metabolic diversity of microorganisms that colonize and persist in fractured shales. Importantly, temporal sampling across all three hydraulic fracturing wells traced the degradation of complex polymers from the hydraulic fracturing process to the production and consumption of organic acids that support sulfate- and thiosulfate-reducing bacteria. Furthermore, we identified 5587 viral genomes and linked many of these to the dominant, colonizing microorganisms, demonstrating the key role that viral predation plays in community dynamics within this closed, engineered system. Lastly, top-side audit sampling of different source materials enabled genome-resolved source tracking, revealing the likely sources of many key colonizing and persisting taxa in these ecosystems. Conclusions These findings highlight the importance of resource utilization and resistance to viral predation as key traits that enable specific microbial taxa to persist across fractured shale ecosystems. We also demonstrate the importance of materials used in the hydraulic fracturing process as both a source of persisting shale microorganisms and organic substrates that likely aid in sustaining the microbial community. Moreover, we showed that different physicochemical conditions (i.e., salinity, temperature) can influence the composition and functional potential of persisting microbial communities in shale ecosystems. Together, these results expand our knowledge of microbial life in deep subsurface shales and have important ramifications for management and treatment of microbial biomass in hydraulically fractured wells.

Published

2022

7. Draft Metagenome-Assembled Genome Sequence of a Novel Citricoccus Species from Agricultural Soil in Western Colorado

Author

Paul O’Toole, Rebecca A. Daly, Reza Keshavarz Afshar, Michael Shaffer, Kelly C. Wrighton, and Bridget B. McGivern

Subjects

Immunology and Microbiology (miscellaneous), Genetics, Molecular Biology

Abstract

Members of the genus Citricoccus are recognized as salt-tolerant soil microorganisms. Here, we report the metagenome-assembled genome sequence of a novel Citricoccus species recovered from untilled, surface agricultural soils in western Colorado.

Published

2023

8. Draft Metagenome-Assembled Genome Sequence of a Novel

Author

Paul, O'Toole, Rebecca A, Daly, Reza, Keshavarz Afshar, Michael, Shaffer, Kelly C, Wrighton, and Bridget B, McGivern

Abstract

Members of the genus

Published

2023

9. Exposing New Taxonomic Variation with Inflammation – A Murine Model-Specific Genome Database for Gut Microbiome Researchers

Author

Ikaia Leleiwi, Josue Rodriguez-Ramos, Michael Shaffer, Anice Sabag-Daigle, Katherine Kokkinias, Rory M Flynn, Rebecca A Daly, Linnea FM Kop, Lindsey M Solden, Brian M. M. Ahmer, Mikayla A Borton, and Kelly C Wrighton

Subjects

Microbiology (medical), Microbiology

Abstract

Background The murine CBA/J mouse model widely supports immunology and enteric pathogen research. This model has illuminated Salmonella interactions with the gut microbiome since pathogen proliferation does not require disruptive pretreatment of the native microbiota, nor does it become systemic, thereby representing an analog to gastroenteritis disease progression in humans. Despite the value to broad research communities, microbiota in CBA/J mice are not represented in current murine microbiome genome catalogs. Results Here we present the first microbial and viral genomic catalog of the CBA/J murine gut microbiome. Using fecal microbial communities from untreated and Salmonella-infected, highly inflamed mice, we performed genomic reconstruction to determine the impacts on gut microbiome membership and functional potential. From high depth whole community sequencing (~ 42.4 Gbps/sample), we reconstructed 2281 bacterial and 4516 viral draft genomes. Salmonella challenge significantly altered gut membership in CBA/J mice, revealing 30 genera and 98 species that were conditionally rare and unsampled in non-inflamed mice. Additionally, inflamed communities were depleted in microbial genes that modulate host anti-inflammatory pathways and enriched in genes for respiratory energy generation. Our findings suggest decreases in butyrate concentrations during Salmonella infection corresponded to reductions in the relative abundance in members of the Alistipes. Strain-level comparison of CBA/J microbial genomes to prominent murine gut microbiome databases identified newly sampled lineages in this resource, while comparisons to human gut microbiomes extended the host relevance of dominant CBA/J inflammation-resistant strains. Conclusions This CBA/J microbiome database provides the first genomic sampling of relevant, uncultivated microorganisms within the gut from this widely used laboratory model. Using this resource, we curated a functional, strain-resolved view on how Salmonella remodels intact murine gut communities, advancing pathobiome understanding beyond inferences from prior amplicon-based approaches. Salmonella-induced inflammation suppressed Alistipes and other dominant members, while rarer commensals like Lactobacillus and Enterococcus endure. The rare and novel species sampled across this inflammation gradient advance the utility of this microbiome resource to benefit the broad research needs of the CBA/J scientific community, and those using murine models for understanding the impact of inflammation on the gut microbiome more generally.

Published

2022

10. Draft Metagenome-Assembled Genome Sequences of Three Novel Ammonia-Oxidizing Nitrososphaera Strains Recovered from Agricultural Soils in Western Colorado

Author

Arsen Yerlan, Rebecca A. Daly, Reza Keshavarz Afshar, Michael Shaffer, Kelly C. Wrighton, and Bridget B. McGivern

Subjects

Immunology and Microbiology (miscellaneous), Genetics, Molecular Biology

Abstract

Microbial nitrification is critical to nitrogen loss from agricultural soils. Here, we report three thaumarchaeotal metagenome-assembled genomes (MAGs) representing a new species of Nitrososphaera . These genomes expand the representation of archaeal nitrifiers recovered from arid, agricultural soils.

Published

2022

11. Wildfire-dependent changes in soil microbiome diversity and function

Author

Amelia R. Nelson, Adrienne B. Narrowe, Charles C. Rhoades, Timothy S. Fegel, Rebecca A. Daly, Holly K. Roth, Rosalie K. Chu, Kaela K. Amundson, Robert B. Young, Andrei S. Steindorff, Stephen J. Mondo, Igor V. Grigoriev, Asaf Salamov, Thomas Borch, and Michael J. Wilkins

Subjects

Microbiology (medical), Soil, Medical Microbiology, Microbiota, Immunology, Human Genome, Genetics, Cell Biology, Forests, Applied Microbiology and Biotechnology, Microbiology, Carbon, Wildfires

Abstract

Forest soil microbiomes have crucial roles in carbon storage, biogeochemical cycling and rhizosphere processes. Wildfire season length, and the frequency and size of severe fires have increased owing to climate change. Fires affect ecosystem recovery and modify soil microbiomes and microbially mediated biogeochemical processes. To study wildfire-dependent changes in soil microbiomes, we characterized functional shifts in the soil microbiota (bacteria, fungi and viruses) across burn severity gradients (low, moderate and high severity) 1 yr post fire in coniferous forests in Colorado and Wyoming, USA. We found severity-dependent increases of Actinobacteria encoding genes for heat resistance, fast growth, and pyrogenic carbon utilization that might enhance post-fire survival. We report that increased burn severity led to the loss of ectomycorrhizal fungi and less tolerant microbial taxa. Viruses remained active in post-fire soils and probably influenced carbon cycling and biogeochemistry via turnover of biomass and ecosystem-relevant auxiliary metabolic genes. Our genome-resolved analyses link post-fire soil microbial taxonomy to functions and reveal the complexity of post-fire soil microbiome activity.

Published

2022

12. Genome-Resolved Metaproteomics Decodes the Microbial and Viral Contributions to Coupled Carbon and Nitrogen Cycling in River Sediments

Author

Josué A. Rodríguez-Ramos, Mikayla A. Borton, Bridget B. McGivern, Garrett J. Smith, Lindsey M. Solden, Michael Shaffer, Rebecca A. Daly, Samuel O. Purvine, Carrie D. Nicora, Elizabeth K. Eder, Mary Lipton, David W. Hoyt, James C. Stegen, and Kelly C. Wrighton

Subjects

Physiology, Modeling and Simulation, Genetics, Molecular Biology, Biochemistry, Microbiology, Ecology, Evolution, Behavior and Systematics, Computer Science Applications

Abstract

Rivers have a significant role in global carbon and nitrogen cycles, serving as a nexus for nutrient transport between terrestrial and marine ecosystems. Although rivers have a small global surface area, they contribute substantially to global greenhouse gas emissions through microbially mediated processes within the river hyporheic zone. Despite this importance, microbial roles in these climatically relevant systems are mostly inferred from 16S rRNA amplicon surveys, which are not sufficiently resolved to inform biogeochemical models. To survey the metabolic potential and gene expression underpinning carbon and nitrogen biogeochemical cycling in river sediments, we collected an integrated dataset of over 30 metagenomes, metaproteomes, and paired metabolomes. We reconstructed over 500 microbial metagenome assembled genomes (MAGs), which we dereplicated into 55 unique genomes spanning 12 bacterial and archaeal phyla. We also reconstructed 2482 viral genomic contigs, which were dereplicated into 111 viral MAGs >10kb in size. As a result of integrating gene expression data with geochemical and metabolite data, we created a conceptual model that uncovers new roles for microorganisms in organic matter decomposition, carbon sequestration, nitrogen mineralization, nitrification, and denitrification. Integrated through shared resource pools of ammonium, carbon dioxide, and inorganic nitrogen we show how these metabolic pathways could ultimately contribute to carbon dioxide and nitrous oxide fluxes from hyporheic sediments. Further, by linking viral genomes to these active microbial hosts, we provide some of the first insights into viral modulation of river sediment carbon and nitrogen cycling.ImportanceHere we created HUM-V (Hyporheic Uncultured Microbial and Viral), an annotated microbial and viral genome catalog that captures the strain and functional diversity encoded in river sediments. Demonstrating its utility, this genomic inventory encompasses multiple representatives of the most dominant microbial and archaeal phyla reported in river sediments and provides novel viral genomes that can putatively infect these. Furthermore, we used HUM-V to recruit gene expression data to decipher the functional activities of these genomes and reconstruct their active roles in river sediment biogeochemical cycling. We show the power of genome resolved, multi-omics to uncover the organismal interactions and chemical handoffs shaping an intertwined carbon and nitrogen metabolic network and create a framework that can be extended to other river sediments. The accessible microbial and viral genomes in HUM-V will serve as a community resource to further advance more untargeted, activity-based measurements in these and related freshwater terrestrial-aquatic ecosystems.

Published

2022

13. Draft Metagenome-Assembled Genome Sequences of Three Novel Ammonia-Oxidizing

Author

Arsen, Yerlan, Rebecca A, Daly, Reza, Keshavarz Afshar, Michael, Shaffer, Kelly C, Wrighton, and Bridget B, McGivern

Abstract

Microbial nitrification is critical to nitrogen loss from agricultural soils. Here, we report three thaumarchaeotal metagenome-assembled genomes (MAGs) representing a new species of

Published

2022

14. Remotely Administered Resilience- and Wisdom-Focused Intervention to Reduce Perceived Stress and Loneliness: Pilot Controlled Clinical Trial in Older Adults

Author

Dilip V. Jeste, Danielle K. Glorioso, Colin A. Depp, Ellen E. Lee, Rebecca E. Daly, Dylan J. Jester, Barton W. Palmer, and Brent T Mausbach

Subjects

Psychiatry and Mental health, Aging, Loneliness, Humans, COVID-19, Geriatrics and Gerontology, Pandemics, Stress, Psychological, Aged

Abstract

Older adults are vulnerable to perceived stress and loneliness, exacerbated by the COVID-19 pandemic. We previously reported inverse relationships between loneliness/perceived stress and wisdom/resilience. There are few evidence-based tele-health interventions for older adults. We tested a new remotely-administered manualized resilience- and wisdom-focused behavioral intervention to reduce perceived stress and loneliness in older adults.This pilot controlled clinical trial used a multiple-phase-change single-case experimental design, with three successive 6-week phases: control, intervention, and follow-up periods. The intervention included six once-a-week one-hour sessions. Participants were 20 adults65 years, without dementia.All 20 participants completed every session. The study indicated feasibility and acceptability of the intervention. While the sample was too small for demonstrating efficacy, there was a reduction (small-to-medium effect size) in perceived stress and loneliness, and increase in resilience, happiness, and components of wisdom and positive perceptions of aging.These preliminary data support feasibility, acceptability, and possible efficacy of a remotely-administered resilience- and wisdom-focused intervention in older adults to reduce stress and loneliness.

Published

2022

15. Variation in Root Exudate Composition Influences Soil Microbiome Membership and Function

Author

Bridget B. McGivern, Mikayla A. Borton, Lindsay Shields, Jessica E. Prenni, Meagan E. Schipanski, Amy M. Sheflin, Stephen Kresovich, Valerie A Seitz, Rebecca A. Daly, Kelly C. Wrighton, and Jacqueline M. Chaparro

Subjects

Exudate, Microorganism, Applied Microbiology and Biotechnology, Plant Roots, Soil, Plant Growth Regulators, RNA, Ribosomal, 16S, Botany, medicine, Environmental Microbiology, Microbiome, Sugar, Soil Microbiology, biology, Ecology, Microbiota, Exudates and Transudates, Plants, 16S ribosomal RNA, Sorghum, biology.organism_classification, Rhizosphere, Composition (visual arts), Alpha diversity, medicine.symptom, Food Science, Biotechnology

Abstract

Root exudation is one of the primary processes that mediate interactions between plant roots, microorganisms, and the soil matrix. Previous research has shown that plant root exudate profiles vary between species and genotypes which can likely support different microbial associations. Here, utilizing distinct sorghum genotypes as a model system, we characterized the chemical heterogeneity between root exudates and the effects of that variability on soil microbial membership and metabolisms. Distinct exudate chemical profiles were quantified and used to formulate synthetic root exudate treatments, a High Organic acid Treatment (HOT) and a High Sugar Treatment (HST). Root exudate treatments were added to laboratory soil reactors and 16S rRNA gene profiling illustrated distinct microbial membership in response to HST or HOT amendments. Alpha and beta diversity metrics were significantly different between treatments, (Shannon’s, p < 0.0001, mrpp = 0.01, respectively). Exometabolite production was highest in the HST, with increased production of key organic acids, non-proteinogenic amino acids, and three plant growth-promoting phytohormones (benzoic acid, salicylic acid, indole-3-acetic acid), suggesting plant-derived sugars fuel microbial carbon metabolism and contribute to phytohormone production. Linking the metabolic capacity of metagenome-assembled genomes in the HST to the exometabolite patterns, we identified potential plant growth-promoting microorganisms that could produce these phytohormones. Our findings emphasize the tractability of high-resolution multi-omics tools to investigate soil microbiomes, opening the possibility of manipulating native microbial communities to improve specific soil microbial functions and enhance crop production.ImportanceUnderstanding interactions between plant root exudates and the soil microbiome provides an avenue for a more comprehensive appreciation for how plant roots modulate their microbial counterparts to promote an environment favorable to plant fitness. Although these dynamics are appreciated as indispensable, mechanisms controlling specific rhizobiome membership and complexity are not fully understood. In this study, we investigate how variability in root exudation, modeled after differences observed between distinct sorghum genotypes, contributes to altered microbial membership and metabolisms. The results demonstrate how microbial diversity is influenced by root exudates of differing chemical composition and how changes in microbial membership correspond to modifications in carbon utilization and enhance production of plant-relevant metabolites. Our findings suggest carbon substrate preferences among bacteria in semi-arid climate soils and mechanisms for root exudate utilization. These findings provide new information on plant-soil environments useful for the development of efficient and precise microbiota management strategies in agricultural systems.

Published

2022

16. Correction to: Microbial colonization and persistence in deep fractured shales is guided by metabolic exchanges and viral predation

Author

Kaela K. Amundson, Mikayla A. Borton, Rebecca A. Daly, David W. Hoyt, Allison Wong, Elizabeth Eder, Joseph Moore, Kenneth Wunch, Kelly C. Wrighton, and Michael J. Wilkins

Subjects

Microbial ecology, Microbiology (medical), QR100-130, Microbiology

Published

2022

17. Optimization of proteomics sample preparation for identification of host and bacterial proteins in mouse feces

Author

Maryam Baniasad, Yongseok Kim, Michael Shaffer, Anice Sabag-Daigle, Ikaia Leleiwi, Rebecca A. Daly, Brian M. M. Ahmer, Kelly C. Wrighton, and Vicki H. Wysocki

Subjects

Proteomics, Feces, Mice, Bacterial Proteins, Animals, Reproducibility of Results, Biochemistry, Article, Analytical Chemistry, Gastrointestinal Microbiome

Abstract

Bottom-up proteomics is a powerful method for the functional characterization of mouse gut microbiota. To date, most of the bottom-up proteomics studies of the mouse gut rely on limited amounts of fecal samples. With mass-limited samples, the performance of such analyses is highly dependent on the protein extraction protocols and contaminant removal strategies. Here, protein extraction protocols (using different lysis buffers) and contaminant removal strategies (using different types of filters and beads) were systematically evaluated to maximize quantitative reproducibility and the number of identified proteins. Overall, our results recommend a protein extraction method using a combination of sodium dodecyl sulfate (SDS) and urea in Tris-HCl to yield the greatest number of protein identifications. These conditions led to an increase in the number of proteins identified from gram-positive bacteria, such as Firmicutes and Actinobacteria, which is a challenging task. Our analysis further confirmed these conditions led to the extraction of non-abundant bacterial phyla such as Proteobacteria. In addition, we found that, when coupled to our optimized extraction method, suspension trap (S-Trap) outperforms other contaminant removal methods by providing the most reproducible method while producing the greatest number of protein identifications. Overall, our optimized sample preparation workflow is straightforward and fast, and requires minimal sample handling. Furthermore, our approach does not require high amounts of fecal samples, a vital consideration in proteomics studies where mice produce smaller amounts of feces due to a particular physiological condition. Our final method provides efficient digestion of mouse fecal material, is reproducible, and leads to high proteomic coverage for both host and microbiome proteins.

Published

2022

18. Improving Healthy Living in Residential Care Facilities: Feasibility, Acceptability, and Appropriateness of Implementing a Multicomponent Intervention for Diabetes Risk Reduction in Adults with Serious Mental Illnesses

Author

David H, Sommerfeld, Amy M, Brunner, Danielle, Glorioso, Ellen E, Lee, Cynthia, Ibarra, Elizabeth, Zunshine, Rebecca E, Daly, Christine, Zoumas, and Dilip V, Jeste

Subjects

Adult, Mental Disorders, Diabetes Mellitus, Feasibility Studies, Humans, Healthy Lifestyle, Risk Reduction Behavior

Abstract

Persons with serious mental illnesses experience high rates of medical comorbidity, especially diabetes. This study examined initial implementation feasibility, acceptability, and appropriateness of a new 6-month Multicomponent Intervention for Diabetes risk reduction in Adults with Serious mental illnesses (MIDAS) among persons in residential care facilities (RCFs). We conducted a mixed-methods study using four types of quantitative and qualitative data sources (administrative data; structured facility-level observations; resident assessments including blood-based biomarkers, 24-h dietary recalls, and self-report physical activity; and focus groups/interviews with staff and participants), to assess evidence of and factors affecting intervention feasibility, acceptability, and appropriateness. It was feasible to provide a high percentage of MIDAS class sessions (mean 50 of 52 intended sessions delivered) and make nutrition-related RCF changes (substitutions for healthier food items and reduced portion sizes). Class attendance rates and positive feedback from residents and staff provided evidence of MIDAS acceptability and appropriateness for addressing identified health needs. The residents who attended ≥ 85% of the sessions had greater improvement in several desired outcomes compared to others. Implementing a fully integrated MIDAS model with more extensive changes to facilities and more fundamental health changes among residents was more challenging. While the study found evidence to support feasibility, acceptability, and appropriateness of individual MIDAS components, some challenges for full implementation and success in obtaining immediate health benefits were also apparent. The study results highlight the need for improving health among RCF populations and will inform MIDAS adaptations designed to improve intervention fit and effectiveness outcomes.

Published

2022

19. Wildfire-dependent changes in soil microbiome diversity and function

Author

Amelia R, Nelson, Adrienne B, Narrowe, Charles C, Rhoades, Timothy S, Fegel, Rebecca A, Daly, Holly K, Roth, Rosalie K, Chu, Kaela K, Amundson, Robert B, Young, Andrei S, Steindorff, Stephen J, Mondo, Igor V, Grigoriev, Asaf, Salamov, Thomas, Borch, and Michael J, Wilkins

Subjects

Soil, Microbiota, Forests, Carbon, Wildfires

Abstract

Forest soil microbiomes have crucial roles in carbon storage, biogeochemical cycling and rhizosphere processes. Wildfire season length, and the frequency and size of severe fires have increased owing to climate change. Fires affect ecosystem recovery and modify soil microbiomes and microbially mediated biogeochemical processes. To study wildfire-dependent changes in soil microbiomes, we characterized functional shifts in the soil microbiota (bacteria, fungi and viruses) across burn severity gradients (low, moderate and high severity) 1 yr post fire in coniferous forests in Colorado and Wyoming, USA. We found severity-dependent increases of Actinobacteria encoding genes for heat resistance, fast growth, and pyrogenic carbon utilization that might enhance post-fire survival. We report that increased burn severity led to the loss of ectomycorrhizal fungi and less tolerant microbial taxa. Viruses remained active in post-fire soils and probably influenced carbon cycling and biogeochemistry via turnover of biomass and ecosystem-relevant auxiliary metabolic genes. Our genome-resolved analyses link post-fire soil microbial taxonomy to functions and reveal the complexity of post-fire soil microbiome activity.

Published

2021

20. Playing with FiRE: A genome resolved view of the soil microbiome responses to high severity forest wildfire

Author

H. K. Roth, Thomas Borch, Fegel Ts, Rebecca A. Daly, Asaf Salamov, K. K. Amundson, Michael J. Wilkins, Adrienne B. Narrowe, Joanne B. Emerson, Stephen J Mondo, Grigoriev, Nelson Ar, Steindorff As, Charles C. Rhoades, Young Rb, Geonczy Se, and Rosalie K. Chu

Subjects

Ecology, Soil water, Forest ecology, Ecosystem, Bacterial genome size, Microbiome, Biology, biology.organism_classification, Actinobacteria, Carbon cycle, Trophic level

Abstract

Warming climate has increased the frequency and size of high severity wildfires in the western United States, with deleterious impacts on forest ecosystem resilience. Although forest soil microbiomes provide a myriad of ecosystem functions, little is known regarding the impact of high severity fire on microbially-mediated processes. Here, we characterized functional shifts in the soil microbiome (bacterial, fungal, and viral) across wildfire burn severity gradients one year post-fire in coniferous forests (Colorado and Wyoming, USA). We generated the Fire Responding Ecogenomic database (FiRE-db), consisting of 637 metagenome-assembled bacterial genomes, 2490 viral populations, and 2 fungal genomes complemented by 12 metatranscriptomes from soils affected by low and high-severity, and complementary marker gene sequencing and metabolomics data. Actinobacteria dominated the fraction of enriched and active taxa across burned soils. Taxa within surficial soils impacted by high severity wildfire exhibited traits including heat resistance, sporulation and fast growth that enhanced post-fire survival. Carbon cycling within this system was predicted to be influenced by microbial processing of pyrogenic compounds and turnover of dominant bacterial community members by abundant viruses. These genome-resolved analyses across trophic levels reveal the complexity of post-fire soil microbiome activity and offer opportunities for restoration strategies that specifically target these communities.

Published

2021

21. Microbial Genome-Resolved Metaproteomic Analyses Frame Intertwined Carbon and Nitrogen Cycles in River Hyporheic Sediments

Author

Kelly C. Wrighton, Samuel O. Purvine, David W. Hoyt, Mikayla A. Borton, Rebecca A. Daly, Michael Shaffer, Elizabeth K. Eder, Mary S. Lipton, Carrie D. Nicora, Josué Rodríguez-Ramos, Bridget B. McGivern, Garrett J. Smith, Lindsey M. Solden, and James C. Stegen

Subjects

chemistry, Environmental chemistry, Frame (networking), Environmental science, chemistry.chemical_element, Microbial genome, Nitrogen cycle, Carbon

Abstract

Background:Rivers serve as a nexus for nutrient transfer between terrestrial and marine ecosystems and as such, have a significant impact on global carbon and nitrogen cycles. In river ecosystems, the sediments found within the hyporheic zone are microbial hotspots that can account for a significant portion of ecosystem respiration and have profound impacts on system biogeochemistry. Despite this, studies using genome-resolved analyses linking microbial and viral communities to nitrogen and carbon biogeochemistry are limited.Results:Here, we characterized the microbial and viral communities of Columbia River hyporheic zone sediments to reveal the metabolisms that actively cycle carbon and nitrogen. Using genome-resolved metagenomics, we created the Hyporheic Uncultured Microbial and Viral (HUM-V) database, containing a dereplicated database of 55 microbial Metagenome-Assembled Genomes (MAGs), representing 12 distinct phyla. We also sampled 111 viral Metagenome Assembled Genomes (vMAGs) from 26 distinct and novel genera. The HUM-V recruited metaproteomes from these same samples, providing the first inventory of microbial gene expression in hyporheic zone sediments. Combining this data with metabolite data, we generated a conceptual model where heterotrophic and autotrophic metabolisms co-occur to drive an integrated carbon and nitrogen cycle, revealing microbial sources and sinks for carbon dioxide and ammonium in these sediments. We uncovered the metabolic handoffs underpinning these processes including mutualistic nitrification by Thermoproteota (formerly Thaumarchaeota) and Nitrospirota, as well as identified possible cooperative and cheating behavior impacting nitrogen mineralization. Finally, by linking vMAGs to microbial genome hosts, we reveal possible viral controls on microbial nitrification and organic carbon degradation.Conclusions:Our multi-omics analyses provide new mechanistic insight into coupled carbon-nitrogen cycling in the hyporheic zone. This is a key step in developing predictive hydrobiogeochemical models that account for microbial cross-feeding and viral influences over potential and expressed microbial metabolisms. Furthermore, the publicly available HUM-V genome resource can be queried and expanded by researchers working in other ecosystems to assess the transferability of our results to other parts of the globe.

Published

2021

22. Hydraulically Fractured Natural-Gas Well Microbial Communities Contain Genomic Halogenation and Dehalogenation Potential

Author

Rebecca A. Daly, Morgan V. Evans, Paula J. Mouser, Jenna L. Luek, Kelly C. Wrighton, Desiree L. Plata, and Andrew J. Sumner

Subjects

010504 meteorology & atmospheric sciences, Ecology, business.industry, Chemistry, Health, Toxicology and Mutagenesis, Halogenation, 010501 environmental sciences, 01 natural sciences, Pollution, Natural gas, Environmental chemistry, Environmental Chemistry, business, Waste Management and Disposal, 0105 earth and related environmental sciences, Water Science and Technology

Abstract

Organohalides are routinely detected in fluid produced from hydraulically fractured oil and natural-gas wells, yet the origin and fate of these compounds remain largely unknown. Because few organoh...

Published

2019

23. Decrypting bacterial polyphenol metabolism in an anoxic wetland soil

Author

Allison R. Wong, Trent R. Northen, Ann E. Hagerman, Suzanne M. Kosina, Carrie D. Nicora, Malak M. Tfaily, Mikayla A. Borton, Kelly C. Wrighton, Samuel O. Purvine, Mary S. Lipton, Bridget B. McGivern, David W. Hoyt, and Rebecca A. Daly

Subjects

0301 basic medicine, Science, 030106 microbiology, Microbial metabolism, General Physics and Astronomy, complex mixtures, General Biochemistry, Genetics and Molecular Biology, Article, Environmental, 03 medical and health sciences, Soil, Bioreactors, Soil Pollutants, Organic matter, Anaerobiosis, Microbial biodegradation, Organic Chemicals, Soil Microbiology, 2. Zero hunger, chemistry.chemical_classification, Multidisciplinary, Bacteria, Chemistry, Microbiota, Soil chemistry, food and beverages, Polyphenols, General Chemistry, Carbon cycle, 15. Life on land, Soil type, Anoxic waters, 030104 developmental biology, Soil microbiology, Biodegradation, Environmental, 13. Climate action, Polyphenol, Environmental chemistry, Wetlands, Biodegradation

Abstract

Microorganisms play vital roles in modulating organic matter decomposition and nutrient cycling in soil ecosystems. The enzyme latch paradigm posits microbial degradation of polyphenols is hindered in anoxic peat leading to polyphenol accumulation, and consequently diminished microbial activity. This model assumes that polyphenols are microbially unavailable under anoxia, a supposition that has not been thoroughly investigated in any soil type. Here, we use anoxic soil reactors amended with and without a chemically defined polyphenol to test this hypothesis, employing metabolomics and genome-resolved metaproteomics to interrogate soil microbial polyphenol metabolism. Challenging the idea that polyphenols are not bioavailable under anoxia, we provide metabolite evidence that polyphenols are depolymerized, resulting in monomer accumulation, followed by the generation of small phenolic degradation products. Further, we show that soil microbiome function is maintained, and possibly enhanced, with polyphenol addition. In summary, this study provides chemical and enzymatic evidence that some soil microbiota can degrade polyphenols under anoxia and subvert the assumed polyphenol lock on soil microbial metabolism., It is thought that polyphenols inhibit organic matter decomposition in soils devoid of oxygen. Here the authors use metabolomics and genome-resolved metaproteomics to provide experimental evidence of polyphenol biodegradation and maintained soil microbial community metabolism despite anoxia.

Published

2021

24. DRAM for distilling microbial metabolism to automate the curation of microbiome function

Author

Kelly C. Wrighton, Benjamin Bolduc, Rebecca A. Daly, Simon Roux, Michael Shaffer, Pengfei Liu, M. Consuelo Gazitúa, Garrett J. Smith, Sabina Leanti La Rosa, Josué Rodríguez-Ramos, Matthew B. Sullivan, Bridget B. McGivern, Ahmed A. Zayed, Phillip B. Pope, Lindsey M. Solden, Adrienne B. Narrowe, Mikayla A. Borton, and Dean R. Vik

Subjects

AcademicSubjects/SCI00010, In silico, Microbial metabolism, Computational biology, Biology, Genome, 03 medical and health sciences, Human gut, Information and Computing Sciences, Genetics, Humans, Metabolomics, Microbiome, Soil Microbiology, 030304 developmental biology, 0303 health sciences, Bacteria, 030306 microbiology, Gastrointestinal Microbiome, Computational Biology, Molecular Sequence Annotation, Genomics, Biological Sciences, Narese/24, ComputingMethodologies_PATTERNRECOGNITION, Metagenomics, Viruses, Metagenome, Genomic information, Software, Environmental Sciences, Dram, Human Microbiome Project, Developmental Biology

Abstract

Microbial and viral communities transform the chemistry of Earth’s ecosystems, yet the specific reactions catalyzed by these biological engines are hard to decode due to the absence of a scalable, metabolically resolved, annotation software. Here, we present DRAM (Distilled and Refined Annotation of Metabolism), a framework to translate the deluge of microbiome-based genomic information into a catalog of microbial traits. To demonstrate the applicability of DRAM across metabolically diverse genomes, we evaluated DRAM performance on a defined, in silico soil community and previously published human gut metagenomes. We show that DRAM accurately assigned microbial contributions to geochemical cycles, and automated the partitioning of gut microbial carbohydrate metabolism at substrate levels. DRAM-v, the viral mode of DRAM, established rules to identify virally-encoded auxiliary metabolic genes (AMGs), resulting in the metabolic categorization of thousands of putative AMGs from soils and guts. Together DRAM and DRAM-v provide critical metabolic profiling capabilities that decipher mechanisms underpinning microbiome function.

Published

2020

25. Ecological Assembly Processes Are Coordinated between Bacterial and Viral Communities in Fractured Shale Ecosystems

Author

Kelly C. Wrighton, Rebecca A. Daly, Robert E. Danczak, Simon Roux, James C. Stegen, Mikayla A. Borton, Michael J. Wilkins, and Lloyd, Karen G

Subjects

Metacommunity, viral ecology, Physiology, Range (biology), lcsh:QR1-502, Ecological and Evolutionary Science, microbial ecology, hydraulic fracturing, Biochemistry, Microbiology, lcsh:Microbiology, shale, 03 medical and health sciences, Microbial ecology, Genetics, 2.2 Factors relating to the physical environment, Ecosystem, Aetiology, Community development, Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Trophic level, 0303 health sciences, 030306 microbiology, Ecology, QR1-502, Computer Science Applications, null modeling, Microbial population biology, Metagenomics, Modeling and Simulation, Environmental science, Research Article

Abstract

Interactions between viral communities and their microbial hosts have been the subject of many recent studies in a wide range of ecosystems. The degree of coordination between ecological assembly processes influencing viral and microbial communities, however, has been explored to a much lesser degree. By using a combined null modeling approach, this study investigated the ecological assembly processes influencing both viral and microbial community structure within hydraulically fractured shale environments. Among other results, significant relationships between the structuring processes affecting both the viral and microbial community were observed, indicating that ecological assembly might be coordinated between these communities despite differing selective pressures. Within this deep subsurface ecosystem, these results reveal a potentially important balance of ecological dynamics that must be maintained to enable long-term microbial community persistence. More broadly, this relationship begins to provide insight into the development of communities across trophic levels., The ecological drivers that concurrently act upon both a virus and its host and that drive community assembly are poorly understood despite known interactions between viral populations and their microbial hosts. Hydraulically fractured shale environments provide access to a closed ecosystem in the deep subsurface where constrained microbial and viral community assembly processes can be examined. Here, we used metagenomic analyses of time-resolved-produced fluid samples from two wells in the Appalachian Basin to track viral and host dynamics and to investigate community assembly processes. Hypersaline conditions within these ecosystems should drive microbial community structure to a similar configuration through time in response to common osmotic stress. However, viral predation appears to counterbalance this potentially strong homogeneous selection and pushes the microbial community toward undominated assembly. In comparison, while the viral community was also influenced by substantial undominated processes, it assembled, in part, due to homogeneous selection. When the overall assembly processes acting upon both these communities were directly compared with each other, a significant relationship was revealed, suggesting an association between microbial and viral community development despite differing selective pressures. These results reveal a potentially important balance of ecological dynamics that must be in maintained within this deep subsurface ecosystem in order for the microbial community to persist over extended time periods. More broadly, this relationship begins to provide knowledge underlying metacommunity development across trophic levels. IMPORTANCE Interactions between viral communities and their microbial hosts have been the subject of many recent studies in a wide range of ecosystems. The degree of coordination between ecological assembly processes influencing viral and microbial communities, however, has been explored to a much lesser degree. By using a combined null modeling approach, this study investigated the ecological assembly processes influencing both viral and microbial community structure within hydraulically fractured shale environments. Among other results, significant relationships between the structuring processes affecting both the viral and microbial community were observed, indicating that ecological assembly might be coordinated between these communities despite differing selective pressures. Within this deep subsurface ecosystem, these results reveal a potentially important balance of ecological dynamics that must be maintained to enable long-term microbial community persistence. More broadly, this relationship begins to provide insight into the development of communities across trophic levels.

Published

2020

26. Author Correction: Cryptic inoviruses revealed as pervasive in bacteria and archaea across Earth's biomes

Author

Nikos C. Kyrpides, Kelly C. Wrighton, Frederik Schulz, Natalia Ivanova, Axel Visel, Emiley A. Eloe-Fadrosh, Simon Roux, Stephen Nayfach, Mart Krupovic, Allison Sharrar, Rebecca A. Daly, Tanja Woyke, Paula B. Matheus Carnevali, Adair L. Borges, Joseph Bondy-Denomy, and Jan Fang Cheng

Subjects

Archaeal Viruses, Microbiology (medical), Immunology, Biome, Phage biology, Genome, Viral, Applied Microbiology and Biotechnology, Microbiology, Machine Learning, Genetics, Bacteriophages, Author Correction, Phylogeny, Environmental microbiology, Bacteria, biology, Ecology, Inoviridae, Computational Biology, Cell Biology, biology.organism_classification, Archaea, Geography, Medical Microbiology, Earth (chemistry), Metagenomics

Abstract

Bacteriophages from the Inoviridae family (inoviruses) are characterized by their unique morphology, genome content and infection cycle. One of the most striking features of inoviruses is their ability to establish a chronic infection whereby the viral genome resides within the cell in either an exclusively episomal state or integrated into the host chromosome and virions are continuously released without killing the host. To date, a relatively small number of inovirus isolates have been extensively studied, either for biotechnological applications, such as phage display, or because of their effect on the toxicity of known bacterial pathogens including Vibrio cholerae and Neisseria meningitidis. Here, we show that the current 56 members of the Inoviridae family represent a minute fraction of a highly diverse group of inoviruses. Using a machine learning approach leveraging a combination of marker gene and genome features, we identified 10,295 inovirus-like sequences from microbial genomes and metagenomes. Collectively, our results call for reclassification of the current Inoviridae family into a viral order including six distinct proposed families associated with nearly all bacterial phyla across virtually every ecosystem. Putative inoviruses were also detected in several archaeal genomes, suggesting that, collectively, members of this supergroup infect hosts across the domains Bacteria and Archaea. Finally, we identified an expansive diversity of inovirus-encoded toxin-antitoxin and gene expression modulation systems, alongside evidence of both synergistic (CRISPR evasion) and antagonistic (superinfection exclusion) interactions with co-infecting viruses, which we experimentally validated in a Pseudomonas model. Capturing this previously obscured component of the global virosphere may spark new avenues for microbial manipulation approaches and innovative biotechnological applications.

Published

2020

27. Identification of Persistent Sulfidogenic Bacteria in Shale Gas Produced Waters

Author

Christopher Boothman, Jonathan R. Lloyd, Lisa Cliffe, Bob Eden, Rebecca A. Daly, Sophie L. Nixon, Kevin G. Taylor, Kelly C. Wrighton, and Michael J. Wilkins

Subjects

Microbiology (medical), Sulfide, biogenic sulfide, Hydrogen sulfide, non-conventional gas, lcsh:QR1-502, Souring, lcsh:Microbiology, 03 medical and health sciences, chemistry.chemical_compound, Microbial ecology, Most probable number, thiosulfate-reducing bacteria, 030304 developmental biology, Original Research, chemistry.chemical_classification, 0303 health sciences, 030306 microbiology, microbiology, Produced water, 6. Clean water, Halanaerobium, chemistry, 13. Climate action, Environmental chemistry, Sour gas, Environmental science, Oil shale

Abstract

Produced waters from hydraulically fractured shale formations give insight into the microbial ecology and biogeochemical conditions down-well. This study explores the potential for sulfide production by persistent microorganisms recovered from produced water samples collected from the Marcellus shale formation. Hydrogen sulfide is highly toxic and corrosive, and can lead to the formation of "sour gas" which is costly to refine. Furthermore, microbial colonization of hydraulically fractured shale could result in formation plugging and a reduction in well productivity. It is vital to assess the potential for sulfide production in persistent microbial taxa, especially when considering the trend of reusing produced waters as input fluids, potentially enriching for problematic microorganisms. Using most probable number (MPN) counts and 16S rRNA gene sequencing, multiple viable strains of bacteria were identified from stored produced waters, mostly belonging to the Genus Halanaerobium, that were capable of growth via fermentation, and produced sulfide when supplied with thiosulfate. No sulfate-reducing bacteria (SRB) were detected through culturing, despite the detection of relatively low numbers of sulfate-reducing lineages by high-throughput 16S rRNA gene sequencing. These results demonstrate that sulfidogenic produced water populations remain viable for years post production and, if left unchecked, have the potential to lead to natural gas souring during shale gas extraction.

Published

2020

28. Minimum Information about an Uncultivated Virus Genome (MIUViG)

Author

Seth R. Bordenstein, Frederik Schulz, Pelin Yilmaz, Rebecca Vega Thurber, Natalia Ivanova, Christelle Desnues, Shinichi Sunagawa, Karyna Rosario, Simon Roux, Steven W. Wilhelm, Nicole S. Webster, Mart Krupovic, Lisa Zeigler Allen, Catherine Putonti, K. Eric Wommack, Tanja Woyke, Eugene V. Koonin, Joanne B. Emerson, Jed A. Fuhrman, Hiroyuki Ogata, Ramy K. Aziz, Arvind Varsani, Marie-Agnès Petit, Bonnie L. Hurwitz, Evelien M. Adriaenssens, Andrew M. Kropinski, Katrine Whiteson, Thomas Rattei, Kyung Bum Lee, Peer Bork, David Paez-Espino, Mark J. Young, Jens H. Kuhn, Ben Temperton, Rebecca A. Daly, Natalya Yutin, Emiley A. Eloe-Fadrosh, Manuel Martinez-Garcia, Curtis A. Suttle, Susannah G. Tringe, Alejandro Reyes, Bas E. Dutilh, Nikos C. Kyrpides, Rex R. Malmstrom, Ilene Karsch Mizrachi, Kelly C. Wrighton, Rob Lavigne, Mya Breitbart, Lynn M. Schriml, Philip Hugenholtz, Melissa B. Duhaime, François Enault, Pascal Hingamp, Francisco Rodriguez-Valera, Clara Amid, Matthew B. Sullivan, Jessica M. Labonté, Grieg F. Steward, J. Rodney Brister, Takashi Yoshida, Guy Cochrane, DOE Joint Genome Institute [Walnut Creek], University of Liverpool, Theoretical Biology & Bioinformatics [Utrecht], University Medical Center [Utrecht], Radboud University Medical Center [Nijmegen], National Center for Biotechnology Information (NCBI), University of Guelph, Biologie Moléculaire du Gène chez les Extrêmophiles (BMGE), Institut Pasteur [Paris] (IP), National Institute of Allergy and Infectious Diseases [Bethesda] (NIAID-NIH), National Institutes of Health [Bethesda] (NIH), Catholic University of Leuven - Katholieke Universiteit Leuven (KU Leuven), Arizona State University [Tempe] (ASU), University of Cape Town, European Bioinformatics Institute [Hinxton] (EMBL-EBI), EMBL Heidelberg, Cairo University, Vanderbilt University [Nashville], European Molecular Biology Laboratory [Heidelberg] (EMBL), University of South Florida [Tampa] (USF), Colorado State University [Fort Collins] (CSU), Microbes évolution phylogénie et infections (MEPHI), Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS), University of Michigan [Ann Arbor], University of Michigan System, University of California [Davis] (UC Davis), University of California (UC), Laboratoire Microorganismes : Génome et Environnement (LMGE), Université Clermont Auvergne [2017-2020] (UCA [2017-2020])-Centre National de la Recherche Scientifique (CNRS), University of Southern California (USC), Institut méditerranéen d'océanologie (MIO), Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Toulon (UTLN)-Centre National de la Recherche Scientifique (CNRS), University of Queensland [Brisbane], University of Arizona, Texas A&M University [Galveston], National Institute of Genetics (NIG), Universidad de Alicante, Kyoto University, MICrobiologie de l'ALImentation au Service de la Santé (MICALIS), Institut National de la Recherche Agronomique (INRA)-AgroParisTech, University of Chicago, Department of Microbiology and Ecosystem Science [Vienna], University of Vienna [Vienna], Universidad de los Andes [Bogota] (UNIANDES), Universidad Miguel Hernández [Elche] (UMH), University of Maryland School of Medicine, University of Maryland System, University of Hawai‘i [Mānoa] (UHM), Ohio State University [Columbus] (OSU), Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich), University of British Columbia (UBC), University of Exeter, Oregon State University (OSU), Australian Institute of Marine Science [Townsville] (AIMS Townsville), Australian Institute of Marine Science (AIMS), University of California [Irvine] (UC Irvine), The University of Tennessee [Knoxville], University of Delaware [Newark], Max Planck Institute for Marine Microbiology, Max-Planck-Gesellschaft, Montana State University (MSU), J. Craig Venter Institute, University of California [San Diego] (UC San Diego), This work was supported by the Laboratory Directed Research and Development Program of Lawrence Berkeley National Laboratory under US Department of Energy Contract No. DE-AC02-05CH11231 for S.R., the Netherlands Organization for Scientific Research (NWO) Vidi grant 864.14.004 for B.E.D., the Intramural Research Program of the National Library of Medicine, National Institutes of Health for E.V.K., I.K.M., J.R.B. and N.Y., the Virus-X project (EU Horizon 2020, No. 685778) for F.E. and M.K., Battelle Memorial Institute's prime contract with the US National Institute of Allergy and Infectious Diseases (NIAID) under Contract No. HHSN272200700016I for J.H.K., the GOA grant 'Bacteriophage Biosystems' from KU Leuven for R.L., the European Molecular Biology Laboratory for C.A. and G.R.C., Cairo University Grant 2016-57 for R.K.A., National Science Foundation award 1456778, National Institutes of Health awards R01 AI132581 and R21 HD086833, and The Vanderbilt Microbiome Initiative award for S.R.B., National Science Foundation awards DEB-1239976 for M.B. and K.R. and DEB-1555854 for M.B., the NSF Early Career award DEB-1555854 and NSF Dimensions of Biodiversity #1342701 for K.C.W. and R.A.D., the Agence Nationale de la Recherche JCJC grant ANR-13-JSV6-0004 and Investissements d'Avenir Méditerranée Infection 10-IAHU-03 for C.D., the Gordon and Betty Moore Foundation Marine Microbiology Initiative No. 3779 and the Simons Foundation for J.A.F., the French government 'Investissements d'Avenir' program OCEANOMICS ANR-11-BTBR-0008 and European FEDER Fund 1166-39417 for P. Hingamp, Australian Research Council Laureate Fellowship FL150100038 to P. Hugenholtz the National Science Foundation award 1801367 and C-DEBI Research Grant for J.M.L., the Gordon and Betty Moore Foundation grant 5334 and Ministry of Economy and Competitivity refs. CGL2013-40564-R and SAF2013-49267-EXP for M.M.-G., the Grant-in-Aid for Scientific Research on Innovative Areas from the Ministry of Education, Culture, Science, Sports, and Technology (MEXT) of Japan No. 16H06429, 16K21723, and 16H06437 for H.O. and T.Y., National Science Foundation award DBI-1661357 to C.P., the Ministry of Economy and Competitivity ref CGL2016-76273-P (cofunded with FEDER funds) for F.R.-V., the Gordon and Betty Moore Foundation awards 3305 and 3790 and NSF Biological Oceanography OCE 1536989 for M.B.S., the ETH Zurich and Helmut Horten Foundation and the Novartis Foundation for Medical-Biological Research (17B077) for S.S., a BIOS-SCOPE award from Simons Foundation International and NERC award NE/P008534/1 to B.T., NSF Biological Oceanography Grant 1635913 for R.V.T., the Australian Research Council Future Fellowship FT120100480 for N.S.W., a Gilead Sciences Cystic Fibrosis Research Scholarship for K.L.W., Gordon and Better Moore Foundation Grant 4971 for S.W.W., the NSF EPSCoR grant 1736030 for K.E.W., the National Science Foundation award DEB-4W4596 and National Institutes of Health award R01 GM117361 for M.J.Y., the Gordon and Betty Moore Foundation No. 7000 and the National Oceanic and Atmospheric Administration (NOAA) under award NA15OAR4320071 for L.Z.A. DDBJ is supported by ROIS and MEXT. The work conducted by the US Department of Energy Joint Genome Institute is supported by the Office of Science of the US Department of Energy under contract no. DE-AC02-05CH11231. The views and conclusions contained in this document are those of the authors and should not be interpreted as necessarily representing the official policies, either expressed or implied, of the US Department of Health and Human Services or of the institutions and companies affiliated with the authors. B.E.D., A.K., M.K., J.H.K., R.L. and A.V. are members of the ICTV Executive Committee, but the views and opinions expressed are those of the authors and not those of the ICTV., Universidad de Alicante. Departamento de Fisiología, Genética y Microbiología, Ecología Microbiana Molecular, Institut Pasteur [Paris], University of South Florida (USF), University of California, Laboratoire Microorganismes : Génome et Environnement - Clermont Auvergne (LMGE), Université Clermont Auvergne (UCA)-Centre National de la Recherche Scientifique (CNRS), Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Université de Toulon (UTLN)-Centre National de la Recherche Scientifique (CNRS), Kyoto University [Kyoto], Universidad de los Andes [Bogota], Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology in Zürich [Zürich] (ETH Zürich), University of California [Irvine] (UCI), J Craig Venter Institute, Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université de Toulon (UTLN), Centre National de la Recherche Scientifique (CNRS)-Université Clermont Auvergne [2017-2020] (UCA [2017-2020]), Sub Bioinformatics, and Theoretical Biology and Bioinformatics

Subjects

[SDV]Life Sciences [q-bio], Microbiología, 2.2 Factors relating to physical environment, Applied Microbiology and Biotechnology, Genome, 0302 clinical medicine, Databases, Genetic, Tumours of the digestive tract Radboud Institute for Molecular Life Sciences [Radboudumc 14], phage, Viral, 0303 health sciences, Genetic Databases, Environmental microbiology, pipeline, Genome project, dynamics, Genomics, annotation, Viruses, Molecular Medicine, tacomony, Infection, Genetic databases, Biotechnology, Virus Cultivation, In silico, Biomedical Engineering, Phage biology, Bioengineering, Computational biology, Genome, Viral, Biology, Virus, dna viruses, Article, Uncultivated virus genomes, Databases, 03 medical and health sciences, Annotation, Genetic, Virology, MD Multidisciplinary, Genetics, 030304 developmental biology, Human Genome, Biological classification, commitee, prediction, Metagenomics, Minimum Information about any (x) Sequence (MIxS), 030217 neurology & neurosurgery, discovery

Abstract

We present an extension of the Minimum Information about any (x) Sequence (MIxS) standard for reporting sequences of uncultivated virus genomes. Minimum Information about an Uncultivated Virus Genome (MIUViG) standards were developed within the Genomic Standards Consortium framework and include virus origin, genome quality, genome annotation, taxonomic classification, biogeographic distribution and in silico host prediction. Community-wide adoption of MIUViG standards, which complement the Minimum Information about a Single Amplified Genome (MISAG) and Metagenome-Assembled Genome (MIMAG) standards for uncultivated bacteria and archaea, will improve the reporting of uncultivated virus genomes in public databases. In turn, this should enable more robust comparative studies and a systematic exploration of the global virosphere., Nature Biotechnology, 37 (1), ISSN:1546-1696, ISSN:1087-0156

Published

2018

29. Comparative genomics and physiology of the genus Methanohalophilus , a prevalent methanogen in hydraulically fractured shale

Author

Kelly C. Wrighton, Susan A. Welch, Tea Meulia, Joseph D. Moore, David W. Hoyt, Sybille S. Hastings, Mikayla A. Borton, Kenneth Wunch, David R. Cole, Michael J. Wilkins, Thomas H. Darrah, Anne E. Booker, Richard A. Wolfe, Rebecca A. Daly, Bridget S. O’Banion, Daniel N. Marcus, and Shikha Sharma

Subjects

0301 basic medicine, Comparative genomics, education.field_of_study, biology, Hydraulic Fracking, Population, Niche differentiation, Methanosarcinaceae, Natural Gas, Methanohalophilus, biology.organism_classification, Microbiology, Methanogen, Genome, 03 medical and health sciences, 030104 developmental biology, Evolutionary biology, Metagenomics, Metagenome, Oil and Gas Fields, education, Ecosystem, Genome, Bacterial, Ecology, Evolution, Behavior and Systematics, Archaea

Abstract

About 60% of natural gas production in the United States comes from hydraulic fracturing of unconventional reservoirs, such as shales or organic-rich micrites. This process inoculates and enriches for halotolerant microorganisms in these reservoirs over time, resulting in a saline ecosystem that includes methane producing archaea. Here, we survey the biogeography of methanogens across unconventional reservoirs, and report that members of genus Methanohalophilus are recovered from every hydraulically fractured unconventional reservoir sampled by metagenomics. We provide the first genomic sequencing of three isolate genomes, as well as two metagenome assembled genomes (MAGs). Utilizing six other previously sequenced isolate genomes and MAGs, we perform comparative analysis of the 11 genomes representing this genus. This genomic investigation revealed distinctions between surface and subsurface derived genomes that are consistent with constraints encountered in each environment. Genotypic differences were also uncovered between isolate genomes recovered from the same well, suggesting niche partitioning among closely related strains. These genomic substrate utilization predictions were then confirmed by physiological investigation. Fine-scale microdiversity was observed in CRISPR-Cas systems of Methanohalophilus, with genomes from geographically distinct unconventional reservoirs sharing spacers targeting the same viral population. These findings have implications for augmentation strategies resulting in enhanced biogenic methane production in hydraulically fractured unconventional reservoirs.

Published

2018

30. Interspecies cross-feeding orchestrates carbon degradation in the rumen ecosystem

Author

Simon Roux, William B. Collins, Julia Schückel, Rebecca A. Daly, Bodil Jørgensen, Mary S. Lipton, Kelly C. Wrighton, William G.T. Willats, Matthew B. Sullivan, Phillip B. Pope, Jeffrey L. Firkins, Carrie D. Nicora, Samuel O. Purvine, Lindsey M. Solden, David W. Hoyt, Donald E. Spalinger, and Adrian E. Naas

Subjects

Proteomics, 0301 basic medicine, Microbiology (medical), Rumen, Microorganism, Microbial Consortia, Immunology, Computational biology, Biology, Applied Microbiology and Biotechnology, Microbiology, Genome, Article, 03 medical and health sciences, Nutrient, Genetics, Animals, Ecosystem, Phylogeny, Trophic level, 2. Zero hunger, Microbial food web, Bacteria, Host Microbial Interactions, Ruminants, Cell Biology, 15. Life on land, Wood, Carbon, 030104 developmental biology, Viruses, Microbiome, Metagenomics, DNA microarray, Metabolic Networks and Pathways

Abstract

Because of their agricultural value, there is a great body of research dedicated to understanding the microorganisms responsible for rumen carbon degradation. However, we lack a holistic view of the microbial food web responsible for carbon processing in this ecosystem. Here, we sampled rumen-fistulated moose, allowing access to rumen microbial communities actively degrading woody plant biomass in real time. We resolved 1,193 viral contigs and 77 unique, near-complete microbial metagenome-assembled genomes, many of which lacked previous metabolic insights. Plant-derived metabolites were measured with NMR and carbohydrate microarrays to quantify the carbon nutrient landscape. Network analyses directly linked measured metabolites to expressed proteins from these unique metagenome-assembled genomes, revealing a genome-resolved three-tiered carbohydrate-fuelled trophic system. This provided a glimpse into microbial specialization into functional guilds defined by specific metabolites. To validate our proteomic inferences, the catalytic activity of a polysaccharide utilization locus from a highly connected metabolic hub genome was confirmed using heterologous gene expression. Viral detected proteins and linkages to microbial hosts demonstrated that phage are active controllers of rumen ecosystem function. Our findings elucidate the microbial and viral members, as well as their metabolic interdependencies, that support in situ carbon degradation in the rumen ecosystem., A combination of proteomics, metagenome-assembled genomes and heterologous gene expression experiments reveals a trophic system for carbon utilization in the moose rumen microbiome and provides insights into phage dynamics in this ecosystem.

Published

2018

31. Methanogenesis in oxygenated soils is a substantial fraction of wetland methane emissions

Author

Mikayla A. Borton, Rebecca A. Daly, Jordan C. Angle, Garrett J. Smith, Golnazalsdat Mirfenderesgi, Kelly C. Wrighton, Adrienne B. Narrowe, Camilo Rey-Sanchez, Lindsey M. Solden, Gil Bohrer, William J. Riley, Christopher S. Miller, T. H. Morin, and David W. Hoyt

Subjects

0301 basic medicine, Biogeochemical cycle, 010504 meteorology & atmospheric sciences, Methanogenesis, Science, General Physics and Astronomy, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Methane, Article, 03 medical and health sciences, chemistry.chemical_compound, lcsh:Science, Life Below Water, 0105 earth and related environmental sciences, Multidisciplinary, biology, Ecology, Soil classification, General Chemistry, biology.organism_classification, Anoxic waters, Methanogen, 030104 developmental biology, chemistry, Soil water, Environmental science, lcsh:Q, Wetland methane emissions

Abstract

The current paradigm, widely incorporated in soil biogeochemical models, is that microbial methanogenesis can only occur in anoxic habitats. In contrast, here we show clear geochemical and biological evidence for methane production in well-oxygenated soils of a freshwater wetland. A comparison of oxic to anoxic soils reveal up to ten times greater methane production and nine times more methanogenesis activity in oxygenated soils. Metagenomic and metatranscriptomic sequencing recover the first near-complete genomes for a novel methanogen species, and show acetoclastic production from this organism was the dominant methanogenesis pathway in oxygenated soils. This organism, Candidatus Methanothrix paradoxum, is prevalent across methane emitting ecosystems, suggesting a global significance. Moreover, in this wetland, we estimate that up to 80% of methane fluxes could be attributed to methanogenesis in oxygenated soils. Together, our findings challenge a widely held assumption about methanogenesis, with significant ramifications for global methane estimates and Earth system modeling., Methane production is traditionally not found in oxygenated soils, a paradigm incorporated in global greenhouse gas modelling efforts. Here the authors show geochemical and biological evidence of active methanogenesis in bulk-oxic wetland soils, attributing up to 80% of the total methane budget for the site.

Published

2017

32. Chemical and pathogen-induced inflammation disrupt the murine intestinal microbiome

Author

Mikayla A. Borton, Lindsey M. Solden, Jikang Wu, Rebecca A. Daly, Richard A. Wolfe, Brian M. M. Ahmer, Bridget S. O’Banion, Kelly C. Wrighton, Vicki H. Wysocki, Juan F. González, and Anice Sabag-Daigle

Subjects

DNA, Bacterial, 0301 basic medicine, Microbiology (medical), Beta diversity, Salmonella, 030106 microbiology, Inflammation, Salmonella infection, Butyrate, Biology, medicine.disease_cause, DNA, Ribosomal, Microbiology, lcsh:Microbial ecology, Feces, Mice, 03 medical and health sciences, Short-chain fatty acids, Lipocalin-2, RNA, Ribosomal, 16S, medicine, Animals, Alistipes, Cecum, 2. Zero hunger, Salmonella Infections, Animal, Bacteria, Research, Dextran Sulfate, Lachnospiraceae, LEfSe, Akkermansia, CBA/J, Sequence Analysis, DNA, biology.organism_classification, medicine.disease, Enterobacteriaceae, Gastrointestinal Microbiome, 3. Good health, 030104 developmental biology, Immunology, lcsh:QR100-130, medicine.symptom

Abstract

Background Salmonella is one of the most significant food-borne pathogens to affect humans and agriculture. While it is well documented that Salmonella infection triggers host inflammation, the impacts on the gut environment are largely unknown. A CBA/J mouse model was used to evaluate intestinal responses to Salmonella-induced inflammation. In parallel, we evaluated chemically induced inflammation by dextran sodium sulfate (DSS) and a non-inflammation control. We profiled gut microbial diversity by sequencing 16S ribosomal ribonucleic acid (rRNA) genes from fecal and cecal samples. These data were correlated to the inflammation marker lipocalin-2 and short-chain fatty acid concentrations. Results We demonstrated that inflammation, chemically or biologically induced, restructures the chemical and microbial environment of the gut over a 16-day period. We observed that the ten mice within the Salmonella treatment group had a variable Salmonella relative abundance, with three high responding mice dominated by >46% Salmonella at later time points and the remaining seven mice denoted as low responders. These low- and high-responding Salmonella groups, along with the chemical DSS treatment, established an inflammation gradient with chemical and low levels of Salmonella having at least 3 log-fold lower lipocalin-2 concentration than the high-responding Salmonella mice. Total short-chain fatty acid and individual butyrate concentrations each negatively correlated with inflammation levels. Microbial communities were also structured along this inflammation gradient. Low levels of inflammation, regardless of chemical or biological induction, enriched for Akkermansia spp. in the Verrucomicrobiaceae and members of the Bacteroidetes family S24-7. Relative to the control or low inflammation groups, high levels of Salmonella drastically decreased the overall microbial diversity, specifically driven by the reduction of Alistipes and Lachnospiraceae in the Bacteroidetes and Firmicutes phyla, respectively. Conversely, members of the Enterobacteriaceae and Lactobacillus were positively correlated to high levels of Salmonella-induced inflammation. Conclusions Our results show that enteropathogenic infection and intestinal inflammation are interrelated factors modulating gut homeostasis. These findings may prove informative with regard to prophylactic or therapeutic strategies to prevent disruption of microbial communities, or promote their restoration. Electronic supplementary material The online version of this article (doi:10.1186/s40168-017-0264-8) contains supplementary material, which is available to authorized users.

Published

2017

33. High-resolution sequencing reveals unexplored archaeal diversity in freshwater wetland soils

Author

Adrienne B. Narrowe, Rebecca A. Daly, Kelly C. Wrighton, K. C. Stefanik, Christopher S. Miller, and Jordan C. Angle

Subjects

0301 basic medicine, Biogeochemical cycle, geography, geography.geographical_feature_category, Community, Ecology, 030106 microbiology, Biogeochemistry, Wetland, Biology, biology.organism_classification, Microbiology, 03 medical and health sciences, 030104 developmental biology, Microbial population biology, Hydric soil, Soil microbiology, Ecology, Evolution, Behavior and Systematics, Archaea

Abstract

Despite being key contributors to biogeochemical processes, archaea are frequently outnumbered by bacteria, and consequently are underrepresented in combined molecular surveys. Here, we demonstrate an approach to concurrently survey the archaea alongside the bacteria with high-resolution 16S rRNA gene sequencing, linking these community data to geochemical parameters. We applied this integrated analysis to hydric soils sampled across a model methane-emitting freshwater wetland. Geochemical profiles, archaeal communities, and bacterial communities were independently correlated with soil depth and water cover. Centimeters of soil depth and corresponding geochemical shifts consistently affected microbial community structure more than hundreds of meters of lateral distance. Methanogens with diverse metabolisms were detected across the wetland, but displayed surprising OTU-level partitioning by depth. Candidatus Methanoperedens spp. archaea thought to perform anaerobic oxidation of methane linked to iron reduction were abundant. Domain-specific sequencing also revealed unexpectedly diverse non-methane-cycling archaeal members. OTUs within the underexplored Woesearchaeota and Bathyarchaeota were prevalent across the wetland, with subgroups and individual OTUs exhibiting distinct occupancy and abundance distributions aligned with environmental gradients. This study adds to our understanding of ecological range for key archaeal taxa in a model freshwater wetland, and links these taxa and individual OTUs to hypotheses about processes governing biogeochemical cycling.

Published

2017

34. Genome-Resolved Metagenomics Extends the Environmental Distribution of the Verrucomicrobia Phylum to the Deep Terrestrial Subsurface

Author

David R. Cole, Mikayla A. Borton, Michael J. Wilkins, Kelly C. Wrighton, Susan A. Welch, Rebecca A. Daly, Lindsey M. Solden, Paula J. Mouser, and Sophie L. Nixon

Subjects

lcsh:QR1-502, hydraulic fracturing, Microbiology, Genome, lcsh:Microbiology, shale, 03 medical and health sciences, Verrucomicrobia, viruses, Ecosystem, Molecular Biology, Soil Microbiology, Organism, 030304 developmental biology, 0303 health sciences, biology, Applied and Environmental Science, 030306 microbiology, Ecology, Phylum, Computational Biology, Genomics, 15. Life on land, hypersaline, biology.organism_classification, QR1-502, Genes, Bacterial, 13. Climate action, Metagenomics, glycoside hydrolases, Cosmopolitan distribution, Adaptation, Genome, Bacterial, Metabolic Networks and Pathways, Research Article

Abstract

The Verrucomicrobia phylum of bacteria is widespread in many different ecosystems; however, its role in microbial communities remains poorly understood. Verrucomicrobia are often low-abundance community members, yet previous research suggests they play a major role in organic carbon degradation. While Verrucomicrobia remain poorly represented in culture collections, numerous genomes have been reconstructed from metagenomic data sets in recent years. The study of genomes from across the phylum allows for an extensive assessment of their potential ecosystem roles. The significance of this work is (i) the recovery of a novel genus of Verrucomicrobia from 2.3 km in the subsurface with the ability to withstand the extreme conditions that characterize this environment, and (ii) the most extensive assessment of ecophysiological traits encoded by Verrucomicrobia genomes to date. We show that members of this phylum are specialist organic polymer degraders that can withstand a wider range of environmental conditions than previously thought., Bacteria of the phylum Verrucomicrobia are prevalent and are particularly common in soil and freshwater environments. Their cosmopolitan distribution and reported capacity for polysaccharide degradation suggests members of Verrucomicrobia are important contributors to carbon cycling across Earth’s ecosystems. Despite their prevalence, the Verrucomicrobia are underrepresented in isolate collections and genome databases; consequently, their ecophysiological roles may not be fully realized. Here, we expand genomic sampling of the Verrucomicrobia phylum by describing a novel genus, “Candidatus Marcellius,” belonging to the order Opitutales. “Ca. Marcellius” was recovered from a shale-derived produced fluid metagenome collected 313 days after hydraulic fracturing, the deepest environment from which a member of the Verrucomicrobia has been recovered to date. We uncover genomic attributes that may explain the capacity of this organism to inhabit a shale gas well, including the potential for utilization of organic polymers common in hydraulic fracturing fluids, nitrogen fixation, adaptation to high salinities, and adaptive immunity via CRISPR-Cas. To illuminate the phylogenetic and environmental distribution of these metabolic and adaptive traits across the Verrucomicrobia phylum, we performed a comparative genomic analysis of 31 publicly available, nearly complete Verrucomicrobia genomes. Our genomic findings extend the environmental distribution of the Verrucomicrobia 2.3 kilometers into the terrestrial subsurface. Moreover, we reveal traits widely encoded across members of the Verrucomicrobia, including the capacity to degrade hemicellulose and to adapt to physical and biological environmental perturbations, thereby contributing to the expansive habitat range reported for this phylum. IMPORTANCE The Verrucomicrobia phylum of bacteria is widespread in many different ecosystems; however, its role in microbial communities remains poorly understood. Verrucomicrobia are often low-abundance community members, yet previous research suggests they play a major role in organic carbon degradation. While Verrucomicrobia remain poorly represented in culture collections, numerous genomes have been reconstructed from metagenomic data sets in recent years. The study of genomes from across the phylum allows for an extensive assessment of their potential ecosystem roles. The significance of this work is (i) the recovery of a novel genus of Verrucomicrobia from 2.3 km in the subsurface with the ability to withstand the extreme conditions that characterize this environment, and (ii) the most extensive assessment of ecophysiological traits encoded by Verrucomicrobia genomes to date. We show that members of this phylum are specialist organic polymer degraders that can withstand a wider range of environmental conditions than previously thought.

Published

2019

35. Uncovering the Diversity and Activity of Methylotrophic Methanogens in Freshwater Wetland Soils

Author

Gil Bohrer, Rebecca A. Daly, Adrienne B. Narrowe, Allison R. Wong, Garrett J. Smith, Kelly C. Wrighton, David W. Hoyt, Christopher S. Miller, Jordan C. Angle, Elizabeth K. Eder, Alexandra Pappas, Richard A. Wolfe, and Mikayla A. Borton

Subjects

Biogeochemical cycle, Physiology, Methanogenesis, lcsh:QR1-502, Wetland, Biochemistry, Microbiology, lcsh:Microbiology, Methane, wetlands, 03 medical and health sciences, chemistry.chemical_compound, Genetics, Molecular Biology, Ecology, Evolution, Behavior and Systematics, methanol, 030304 developmental biology, 2. Zero hunger, metagenomics, 0303 health sciences, geography, metatranscriptomics, geography.geographical_feature_category, Applied and Environmental Science, 030306 microbiology, 15. Life on land, Substrate (marine biology), QR1-502, 6. Clean water, Computer Science Applications, chemistry, 13. Climate action, Metagenomics, Modeling and Simulation, Environmental chemistry, Soil water, trimethylamine, Environmental science, Microcosm, methanomassiliicoccales, Research Article

Abstract

Understanding the sources and controls on microbial methane production from wetland soils is critical to global methane emission predictions, particularly in light of changing climatic conditions. Current biogeochemical models of methanogenesis consider only acetoclastic and hydrogenotrophic sources and exclude methylotrophic methanogenesis, potentially underestimating microbial contributions to methane flux. Our multi-omic results demonstrated that methylotrophic methanogens of the family Methanomassiliicoccaceae were present and active in a freshwater wetland, with metatranscripts indicating that methanol, not methylamines, was the likely substrate under the conditions measured here. However, laboratory experiments indicated the potential for other methanogens to become enriched in response to trimethylamine, revealing the reservoir of methylotrophic methanogenesis potential residing in these soils. Collectively, our approach used coupled field and laboratory investigations to illuminate metabolisms influencing the terrestrial microbial methane cycle, thereby offering direction for increased realism in predictive process-oriented models of methane flux in wetland soils., Wetland soils are one of the largest natural contributors to the emission of methane, a potent greenhouse gas. Currently, microbial contributions to methane emissions from these systems emphasize the roles of acetoclastic and hydrogenotrophic methanogens, while less frequently considering methyl-group substrates (e.g., methanol and methylamines). Here, we integrated laboratory and field experiments to explore the potential for methylotrophic methanogenesis in Old Woman Creek (OWC), a temperate freshwater wetland located in Ohio, USA. We first demonstrated the capacity for methylotrophic methanogenesis in these soils using laboratory soil microcosms amended with trimethylamine. However, subsequent field porewater nuclear magnetic resonance (NMR) analyses to identify methanogenic substrates failed to detect evidence for methylamine compounds in soil porewaters, instead noting the presence of the methylotrophic substrate methanol. Accordingly, our wetland soil-derived metatranscriptomic data indicated that methanol utilization by the Methanomassiliicoccaceae was the likely source of methylotrophic methanogenesis. Methanomassiliicoccaceae relative contributions to mcrA transcripts nearly doubled with depth, accounting for up to 8% of the mcrA transcripts in 25-cm-deep soils. Longitudinal 16S rRNA amplicon and mcrA gene surveys demonstrated that Methanomassiliicoccaceae were stably present over 2 years across lateral and depth gradients in this wetland. Meta-analysis of 16S rRNA sequences similar (>99%) to OWC Methanomassiliicoccaceae in public databases revealed a global distribution, with a high representation in terrestrial soils and sediments. Together, our results demonstrate that methylotrophic methanogenesis likely contributes to methane flux from climatically relevant wetland soils. IMPORTANCE Understanding the sources and controls on microbial methane production from wetland soils is critical to global methane emission predictions, particularly in light of changing climatic conditions. Current biogeochemical models of methanogenesis consider only acetoclastic and hydrogenotrophic sources and exclude methylotrophic methanogenesis, potentially underestimating microbial contributions to methane flux. Our multi-omic results demonstrated that methylotrophic methanogens of the family Methanomassiliicoccaceae were present and active in a freshwater wetland, with metatranscripts indicating that methanol, not methylamines, was the likely substrate under the conditions measured here. However, laboratory experiments indicated the potential for other methanogens to become enriched in response to trimethylamine, revealing the reservoir of methylotrophic methanogenesis potential residing in these soils. Collectively, our approach used coupled field and laboratory investigations to illuminate metabolisms influencing the terrestrial microbial methane cycle, thereby offering direction for increased realism in predictive process-oriented models of methane flux in wetland soils.

Published

2019

36. Deep-Subsurface Pressure Stimulates Metabolic Plasticity in Shale-Colonizing Halanaerobium spp

Author

Susan M. Pfiffner, Rebecca A. Daly, Paula J. Mouser, David W. Hoyt, Samuel O. Purvine, Kelly C. Wrighton, Tea Meulia, Elizabeth K. Eder, Carrie D. Nicora, Mary S. Lipton, Kenneth Wunch, Anne E. Booker, Michael J. Wilkins, and Joseph D. Moore

Subjects

0303 health sciences, Ecology, 030306 microbiology, business.industry, Biofilm, Biomass, 15. Life on land, Applied Microbiology and Biotechnology, Corrosion, Clogging, 03 medical and health sciences, Hydraulic fracturing, 13. Climate action, Natural gas, Environmental chemistry, Environmental science, Ecosystem, business, Oil shale, 030304 developmental biology, Food Science, Biotechnology

Abstract

The hydraulic fracturing of deep-shale formations for hydrocarbon recovery accounts for approximately 60% of U.S. natural gas production. Microbial activity associated with this process is generally considered deleterious due to issues associated with sulfide production, microbially induced corrosion, and bioclogging in the subsurface. Here we demonstrate that a representative Halanaerobium species, frequently the dominant microbial taxon in hydraulically fractured shales, responds to pressures characteristic of the deep subsurface by shifting its metabolism to generate more corrosive organic acids and produce more polymeric substances that cause “clumping” of biomass. While the potential for increased corrosion of steel infrastructure and clogging of pores and fractures in the subsurface may significantly impact hydrocarbon recovery, these data also offer new insights for microbial control in these ecosystems.

Published

2019

37. Cryptic inoviruses are pervasive in bacteria and archaea across Earth’s biomes

Author

Mart Krupovic, Simon Roux, Stephen Nayfach, Jan Fang Cheng, Emiley A. Eloe-Fadrosh, Adair L. Borges, Joseph Bondy-Denomy, Frederik Schulz, Natalia Ivanova, Kelly C. Wrighton, Rebecca A. Daly, Tanja Woyke, Nikos C. Kyrpides, and Axel Visel

Subjects

Inovirus, Phage display, Superinfection exclusion, Genome, Vaccine Related, 03 medical and health sciences, Rare Diseases, Biodefense, Genetics, 2.2 Factors relating to the physical environment, CRISPR, Aetiology, Bacterial phyla, 030304 developmental biology, 0303 health sciences, biology, 030306 microbiology, Prevention, biology.organism_classification, Good Health and Well Being, Infectious Diseases, Emerging Infectious Diseases, Evolutionary biology, Inoviridae, Infection, Biotechnology, Archaea

Abstract

Author(s): Roux, Simon; Krupovic, Mart; Daly, Rebecca; Borges, Adair; Nayfach, Stephen; Schulz, Frederik; Cheng, Jan-Fang; Ivanova, Natalia; Bondy-Denomy, Joseph; Wrighton, Kelly; Woyke, Tanja; Visel, Axel; Kyrpides, Nikos; Eloe-Fadrosh, Emiley | Abstract: Bacteriophages from the Inoviridae family (inoviruses) are characterized by their unique morphology, genome content, and infection cycle. To date, a relatively small number of inovirus isolates have been extensively studied, either for biotechnological applications such as phage display, or because of their impact on the toxicity of known bacterial pathogens including Vibrio cholerae and Neisseria meningitidis . Here we show that the current 56 members of the Inoviridae family represent a minute fraction of a highly diverse group of inoviruses. Using a new machine learning approach leveraging a combination of marker gene and genome features, we identified 10,295 inovirus-like genomes from microbial genomes and metagenomes. Collectively, these represent six distinct proposed inovirus families infecting nearly all bacterial phyla across virtually every ecosystem. Putative inoviruses were also detected in several archaeal genomes, suggesting that these viruses may have occasionally transferred from bacterial to archaeal hosts. Finally, we identified an expansive diversity of inovirus-encoded toxin-antitoxin and gene expression modulation systems, alongside evidence of both synergistic (CRISPR evasion) and antagonistic (superinfection exclusion) interactions with co-infecting viruses which we experimentally validated in a Pseudomonas model. Capturing this previously obscured component of the global virosphere sparks new avenues for microbial manipulation approaches and innovative biotechnological applications.

Published

2019

38. Deep-Subsurface Pressure Stimulates Metabolic Plasticity in Shale-Colonizing

Author

Anne E, Booker, David W, Hoyt, Tea, Meulia, Elizabeth, Eder, Carrie D, Nicora, Samuel O, Purvine, Rebecca A, Daly, Joseph D, Moore, Kenneth, Wunch, Susan M, Pfiffner, Mary S, Lipton, Paula J, Mouser, Kelly C, Wrighton, and Michael J, Wilkins

Subjects

high pressure, Extracellular Polymeric Substance Matrix, Hydraulic Fracking, Pressure, Environmental Microbiology, Firmicutes, Spotlight, biofilms, hydraulic fracturing, metabolomics, Halanaerobium, shale

Abstract

The hydraulic fracturing of deep-shale formations for hydrocarbon recovery accounts for approximately 60% of U.S. natural gas production. Microbial activity associated with this process is generally considered deleterious due to issues associated with sulfide production, microbially induced corrosion, and bioclogging in the subsurface. Here we demonstrate that a representative Halanaerobium species, frequently the dominant microbial taxon in hydraulically fractured shales, responds to pressures characteristic of the deep subsurface by shifting its metabolism to generate more corrosive organic acids and produce more polymeric substances that cause “clumping” of biomass. While the potential for increased corrosion of steel infrastructure and clogging of pores and fractures in the subsurface may significantly impact hydrocarbon recovery, these data also offer new insights for microbial control in these ecosystems., Bacterial Halanaerobium strains become the dominant persisting microbial community member in produced fluids across geographically distinct hydraulically fractured shales. Halanaerobium is believed to be inadvertently introduced into this environment during the drilling and fracturing process and must therefore tolerate large changes in pressure, temperature, and salinity. Here, we used a Halanaerobium strain isolated from a natural gas well in the Utica Point Pleasant formation to investigate metabolic and physiological responses to growth under high-pressure subsurface conditions. Laboratory incubations confirmed the ability of Halanaerobium congolense strain WG8 to grow under pressures representative of deep shale formations (21 to 48 MPa). Under these conditions, broad metabolic and physiological shifts were identified, including higher abundances of proteins associated with the production of extracellular polymeric substances. Confocal laser scanning microscopy indicated that extracellular polymeric substance (EPS) production was associated with greater cell aggregation when biomass was cultured at high pressure. Changes in Halanaerobium central carbon metabolism under the same conditions were inferred from nuclear magnetic resonance (NMR) and gas chromatography measurements, revealing large per-cell increases in production of ethanol, acetate, and propanol and cessation of hydrogen production. These metabolic shifts were associated with carbon flux through 1,2-propanediol in response to slower fluxes of carbon through stage 3 of glycolysis. Together, these results reveal the potential for bioclogging and corrosion (via organic acid fermentation products) associated with persistent Halanaerobium growth in deep, hydraulically fractured shale ecosystems, and offer new insights into cellular mechanisms that enable these strains to dominate deep-shale microbiomes. IMPORTANCE The hydraulic fracturing of deep-shale formations for hydrocarbon recovery accounts for approximately 60% of U.S. natural gas production. Microbial activity associated with this process is generally considered deleterious due to issues associated with sulfide production, microbially induced corrosion, and bioclogging in the subsurface. Here we demonstrate that a representative Halanaerobium species, frequently the dominant microbial taxon in hydraulically fractured shales, responds to pressures characteristic of the deep subsurface by shifting its metabolism to generate more corrosive organic acids and produce more polymeric substances that cause “clumping” of biomass. While the potential for increased corrosion of steel infrastructure and clogging of pores and fractures in the subsurface may significantly impact hydrocarbon recovery, these data also offer new insights for microbial control in these ecosystems.

Published

2019

39. Clinical Correlates of Insulin Resistance in Chronic Schizophrenia: Relationship to Negative Symptoms

Author

Virawudh Soontornniyomkij, Ellen E. Lee, Hua Jin, Averria Sirkin Martin, Rebecca E. Daly, Jinyuan Liu, Xin M. Tu, Lisa Todd Eyler, and Dilip V. Jeste

Subjects

medicine.medical_specialty, Psychosis, congenital, hereditary, and neonatal diseases and abnormalities, lcsh:RC435-571, Clinical Sciences, body mass index, 03 medical and health sciences, 0302 clinical medicine, Insulin resistance, Clinical Research, Internal medicine, lcsh:Psychiatry, medicine, Psychology, Obesity, psychosis, hemoglobin A1c, Depression (differential diagnoses), Metabolic and endocrine, cognitive function, Original Research, Nutrition, 2. Zero hunger, Psychiatry, business.industry, Prevention, Diabetes, nutritional and metabolic diseases, medicine.disease, Comorbidity, 030227 psychiatry, 3. Good health, Brain Disorders, Psychiatry and Mental health, antipsychotics, Mental Health, Good Health and Well Being, Schizophrenia, depression, Homeostatic model assessment, Public Health and Health Services, business, Body mass index, 030217 neurology & neurosurgery

Abstract

Higher prevalence of physical comorbidity and premature mortality in persons with schizophrenia (PwS) results primarily from heightened cardiovascular and metabolic risks. The literature suggests that insulin resistance precedes the development of obesity, smoking, and use of antipsychotic medications, although these likely play a compounding role later in the course of the disorder. It is thus important to discover the clinical characteristics of PwS with high insulin resistance, as these individuals may represent an etiopathologically distinct subgroup with a distinct course and treatment needs. We conducted a cross-sectional study and compared insulin resistance between 145 PwS and 140 nonpsychiatric comparison (NC) participants, similar in age, sex, and race distribution. In addition, we examined correlates of insulin resistance in PwS. As expected, PwS had higher levels of insulin resistance [Homeostatic Model Assessment of Insulin Resistance (HOMA-IR)] and body mass index (BMI) compared to the NC participants. HOMA-IR in the PwS was most associated with negative symptoms, BMI, and non-White race/ethnicity. The mechanistic relationships between insulin resistance and negative symptoms in schizophrenia patients warrant further investigation, and future studies should examine outcomes of PwS with this cluster of physical and mental symptoms and determine how management of insulin resistance might improve health of these individuals.

Published

2019

40. Comparative geochemistry of flowback chemistry from the Utica/Point Pleasant and Marcellus formations

Author

Paula J. Mouser, Julia M. Sheets, Rebecca A. Daly, Michael J. Wilkins, Shikha Sharma, Anthony Lutton, Andrea J. Hanson, David R. Cole, John W. Olesik, Thomas H. Darrah, Timothy R. Carr, Kelly C. Wrighton, and Susan A. Welch

Subjects

010504 meteorology & atmospheric sciences, Geochemistry, chemistry.chemical_element, Geology, Barium, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Diagenesis, chemistry.chemical_compound, chemistry, Brining, Geochemistry and Petrology, engineering, Halite, Carbonate, Seawater, Clay minerals, Dissolution, 0105 earth and related environmental sciences

Abstract

Flowback/Produced fluid samples were collected from several wells from two Utica/Point Pleasant (UPP) sites (UPPW and UPPS) in Ohio, and one Marcellus (Marcellus Shale Energy and Environment Laboratory (MSEEL)) site in West Virginia over a period of approximately two years. Although these formations have different ages, depositional environments, diagenetic histories, and geochemical and mineralogical compositions (i.e. the UPP is significantly more carbonate rich than the Marcellus which is more siliceous), analysis of trends in fluid species over time shows that, overall, the TDS and major solubilized elements (Na, Ca, Cl) in the UPP and Marcellus brines are remarkably similar. Total dissolved solutes (TDS) in these brines ranged from approximately 40 to 250 g/L salt, and in general, concentrations increased with time elapsed since natural gas well completion and stimulation. The behavior of Na, Br, and Cl suggests that the produced water signatures from these formations are largely derived from the native formational brines which display evidence of originating from evaporated seawater. There is a strong correlation between Cl and Br, indicating that both species behave conservatively, and the similarity among each of these brines suggests no appreciable contribution of salt from halite dissolution because Br is excluded from the halite structure. Cl/Br ratios in the brines range from ~80 to 120 (mg/L/mg/L). Other elements, such as K, which readily reacts between fluids and ion exchange sites on clays, generally exhibit conservative behavior for an individual site, but show significant variations among each of the different well pads. The concentrations of Sr and Ba vary dramatically among well sites, and increase with respect to Cl− over time, suggesting increasing solubilization, presumably from desorption from clay minerals or dissolution of carbonates or sulfates from the source formation(s). The UPPW well site has very low Ba due to high-sulfate input fluid, which resulted in precipitation of barite/celestite in the brines. In contrast the UPPS well site had elevated Sr (~ 3500 mg/L), presumably due to the use of Sr-rich recycled brine used in hydraulic fracturing. The Marcellus site had the highest Ba concentrations (up to 10 g/L) and highest Ba/Sr ratios in the fluids, due to the high concentration of barium in the Marcellus target (~ 1000 ppm, as compared to ~200 ppm in the UPP). These observations suggest that solutes in the FP fluids are derived from native brines, water-rock interactions that have occurred over geologic time scales, as well as some contribution from contemporaneous reactions in the subsurface. The results also show that the composition of the injected fluid can influence flowback fluid chemistry and possibly production efficiency.

Published

2021

41. Members of the Genus Methylobacter Are Inferred To Account for the Majority of Aerobic Methane Oxidation in Oxic Soils from a Freshwater Wetland

Author

T. H. Morin, Rebecca A. Daly, Jordan C. Angle, K. C. Stefanik, Michael D. Johnston, Garrett J. Smith, Bohrer Gil, Kelly C. Wrighton, Richard A. Wolfe, Lindsey M. Solden, and Mikayla A. Borton

Subjects

DNA, Bacterial, 0301 basic medicine, Biogeochemical cycle, Methanotroph, Methanogenesis, 030106 microbiology, Fresh Water, Microbiology, Methane, 12. Responsible consumption, Soil, 03 medical and health sciences, chemistry.chemical_compound, methanotrophs, RNA, Ribosomal, 16S, Virology, Ecosystem, Phylogeny, Ohio, metagenomics, denitrification, metatranscriptomics, Applied and Environmental Science, Ecology, Gene Expression Profiling, methane, Atmospheric methane, Sequence Analysis, DNA, 15. Life on land, soil microbiology, QR1-502, chemistry, 13. Climate action, Wetlands, Anaerobic oxidation of methane, Environmental science, Methylobacteriaceae, Oxidation-Reduction, Soil microbiology, Genome, Bacterial, Research Article

Abstract

Here we used soil metagenomics and metatranscriptomics to uncover novel members within the genus Methylobacter. We denote these closely related genomes as members of the lineage OWC Methylobacter. Despite the incredibly high microbial diversity in soils, here we present findings that unexpectedly showed that methane cycling was primarily mediated by a single genus for both methane production (“Candidatus Methanothrix paradoxum”) and methane consumption (OWC Methylobacter). Metatranscriptomic analyses revealed that decreased methanotrophic activity rather than increased methanogenic activity possibly contributed to the greater methane emissions that we had previously observed in summer months, findings important for biogeochemical methane models. Although members of this Methylococcales order have been cultivated for decades, multi-omic approaches continue to illuminate the methanotroph phylogenetic and metabolic diversity harbored in terrestrial and marine ecosystems., Microbial carbon degradation and methanogenesis in wetland soils generate a large proportion of atmospheric methane, a highly potent greenhouse gas. Despite their potential to mitigate greenhouse gas emissions, knowledge about methane-consuming methanotrophs is often limited to lower-resolution single-gene surveys that fail to capture the taxonomic and metabolic diversity of these microorganisms in soils. Here our objective was to use genome-enabled approaches to investigate methanotroph membership, distribution, and in situ activity across spatial and seasonal gradients in a freshwater wetland near Lake Erie. 16S rRNA gene analyses demonstrated that members of the methanotrophic Methylococcales were dominant, with the dominance largely driven by the relative abundance of four taxa, and enriched in oxic surface soils. Three methanotroph genomes from assembled soil metagenomes were assigned to the genus Methylobacter and represented the most abundant methanotrophs across the wetland. Paired metatranscriptomes confirmed that these Old Woman Creek (OWC) Methylobacter members accounted for nearly all the aerobic methanotrophic activity across two seasons. In addition to having the capacity to couple methane oxidation to aerobic respiration, these new genomes encoded denitrification potential that may sustain energy generation in soils with lower dissolved oxygen concentrations. We further show that Methylobacter members that were closely related to the OWC members were present in many other high-methane-emitting freshwater and soil sites, suggesting that this lineage could participate in methane consumption in analogous ecosystems. This work contributes to the growing body of research suggesting that Methylobacter may represent critical mediators of methane fluxes in freshwater saturated sediments and soils worldwide.

Published

2018

42. Members of Marinobacter and Arcobacter Influence System Biogeochemistry During Early Production of Hydraulically Fractured Natural Gas Wells in the Appalachian Basin

Author

Morgan V. Evans, Jenny Panescu, Andrea J. Hanson, Susan A. Welch, Julia M. Sheets, Nicholas Nastasi, Rebecca A. Daly, David R. Cole, Thomas H. Darrah, Michael J. Wilkins, Kelly C. Wrighton, and Paula J. Mouser

Subjects

dark biosphere, 0301 basic medicine, Microbiology (medical), Biogeochemical cycle, Denitrification, 030106 microbiology, lcsh:QR1-502, hydraulic fracturing, Microbiology, lcsh:Microbiology, deep subsurface, 03 medical and health sciences, characterization, Nitrogen cycle, Chemosynthesis, biology, Chemistry, Biogeochemistry, 15. Life on land, Marinobacter, biology.organism_classification, 6. Clean water, natural gas, cultivation, 13. Climate action, Arcobacter, Environmental chemistry, Archaea

Abstract

Hydraulic fracturing is the prevailing method for enhancing recovery of hydrocarbon resources from unconventional shale formations, yet little is understood regarding the microbial impact on biogeochemical cycling in natural-gas wells. Although the metabolisms of certain fermentative bacteria and methanogenic archaea that dominate in later produced fluids have been well studied, few details have been reported on microorganisms prevelant during the early flowback period, when oxygen and other surface-derived oxyanions and nutrients become depleted. Here, we report the isolation, genomic and phenotypic characterization of Marinobacter and Arcobacter bacterial species from natural-gas wells in the Utica-Point Pleasant and Marcellus Formations coupled to supporting geochemical and metagenomic analyses of produced fluid samples. These unconventional hydrocarbon system-derived Marinobacter sp. are capable of utilizing a diversity of organic carbon sources including aliphatic and aromatic hydrocarbons, amino acids, and carboxylic acids. Marinobacter and Arcobacter can metabolize organic nitrogen sources and have the capacity for denitrification and dissimilatory nitrate reduction to ammonia (DNRA) respectively; with DNRA and ammonification processes partially explaining high concentrations of ammonia measured in produced fluids. Arcobacter is capable of chemosynthetic sulfur oxidation, which could fuel metabolic processes for other heterotrophic, fermentative, or sulfate-reducing community members. Our analysis revealed mechanisms for growth of these taxa across a broad range of salinities (up to 15% salt), which explains their enrichment during early natural-gas production. These results demonstrate the prevalence of Marinobacter and Arcobacter during a key maturation phase of hydraulically fractured natural-gas wells, and highlight the significant role these genera play in biogeochemical cycling for this economically important energy system.

Published

2018

43. Characterizing the Deep Terrestrial Subsurface Microbiome

Author

Rebecca A, Daly, Kelly C, Wrighton, and Michael J, Wilkins

Subjects

DNA, Bacterial, Geologic Sediments, Bacteria, Microbiota, Biomass, Metagenomics, Water Microbiology, Soil Microbiology, Gene Library

Abstract

A large portion of the earth's biomass resides in the subsurface and recent studies have expanded our knowledge of indigenous microbial life. Advances in the field of metagenomics now allow analysis of microbial communities from low-biomass samples such as deep (2.5 km) shale core samples. Here we present protocols for the best practices in contamination control, handling core material, extraction of nucleic acids, and low-input library preparation for subsequent metagenomic sequencing.

Published

2018

44. Members of

Author

Morgan V, Evans, Jenny, Panescu, Andrea J, Hanson, Susan A, Welch, Julia M, Sheets, Nicholas, Nastasi, Rebecca A, Daly, David R, Cole, Thomas H, Darrah, Michael J, Wilkins, Kelly C, Wrighton, and Paula J, Mouser

Subjects

natural gas, dark biosphere, deep subsurface, cultivation, characterization, Microbiology, hydraulic fracturing, genome, Original Research, shale

Abstract

Hydraulic fracturing is the prevailing method for enhancing recovery of hydrocarbon resources from unconventional shale formations, yet little is understood regarding the microbial impact on biogeochemical cycling in natural-gas wells. Although the metabolisms of certain fermentative bacteria and methanogenic archaea that dominate in later produced fluids have been well studied, few details have been reported on microorganisms prevelant during the early flowback period, when oxygen and other surface-derived oxyanions and nutrients become depleted. Here, we report the isolation, genomic and phenotypic characterization of Marinobacter and Arcobacter bacterial species from natural-gas wells in the Utica-Point Pleasant and Marcellus Formations coupled to supporting geochemical and metagenomic analyses of produced fluid samples. These unconventional hydrocarbon system-derived Marinobacter sp. are capable of utilizing a diversity of organic carbon sources including aliphatic and aromatic hydrocarbons, amino acids, and carboxylic acids. Marinobacter and Arcobacter can metabolize organic nitrogen sources and have the capacity for denitrification and dissimilatory nitrate reduction to ammonia (DNRA) respectively; with DNRA and ammonification processes partially explaining high concentrations of ammonia measured in produced fluids. Arcobacter is capable of chemosynthetic sulfur oxidation, which could fuel metabolic processes for other heterotrophic, fermentative, or sulfate-reducing community members. Our analysis revealed mechanisms for growth of these taxa across a broad range of salinities (up to 15% salt), which explains their enrichment during early natural-gas production. These results demonstrate the prevalence of Marinobacter and Arcobacter during a key maturation phase of hydraulically fractured natural-gas wells, and highlight the significant role these genera play in biogeochemical cycling for this economically important energy system.

Published

2018

45. Coupled laboratory and field investigations resolve microbial interactions that underpin persistence in hydraulically fractured shales

Author

Kelly C. Wrighton, David W. Hoyt, Shikha Sharma, Susan A. Welch, J. Sheets, David M. Morgan, Timothy R. Carr, Mikayla A. Borton, Michael J. Wilkins, Paula J. Mouser, Samuel O. Purvine, Simon Roux, Carrie D. Nicora, Elizabeth K. Eder, David R. Cole, Mary S. Lipton, Andrea J. Hanson, Rebecca A. Daly, and Richard A. Wolfe

Subjects

0301 basic medicine, Biogeochemical cycle, Earth science, Microbial Consortia, Natural Gas, Microbiology, hydraulic fracturing, 03 medical and health sciences, Hydraulic fracturing, Stickland reaction, Natural gas, Management practices, metagenomics, Multidisciplinary, Bacteria, business.industry, Hydraulic Fracking, methanogenesis, Biological Sciences, United States, 030104 developmental biology, PNAS Plus, Metagenomics, Metaproteomics, Environmental science, metaproteomics, business, Oil shale, Halanaerobium

Abstract

Significance Microorganisms persisting in hydraulically fractured shales must maintain osmotic balance in hypersaline fluids, gain energy in the absence of electron acceptors, and acquire carbon and nitrogen to synthesize cell building blocks. We provide evidence that that cofermentation of amino acids (Stickland reaction) meets all of these organismal needs, thus functioning as a keystone metabolism in enriched and natural microbial communities from hydraulically fractured shales. This amino acid-based metabolic network can be rationally designed to optimize biogenic methane yields and minimize undesirable chemistries in this engineered ecosystem. Our proposed ecological framework extends to the human gut and other protein-rich ecosystems, where the role of Stickland fermentations and their derived syntrophies play unrecognized roles in carbon and nitrogen turnover., Hydraulic fracturing is one of the industrial processes behind the surging natural gas output in the United States. This technology inadvertently creates an engineered microbial ecosystem thousands of meters below Earth’s surface. Here, we used laboratory reactors to perform manipulations of persisting shale microbial communities that are currently not feasible in field scenarios. Metaproteomic and metabolite findings from the laboratory were then corroborated using regression-based modeling performed on metagenomic and metabolite data from more than 40 produced fluids from five hydraulically fractured shale wells. Collectively, our findings show that Halanaerobium, Geotoga, and Methanohalophilus strain abundances predict a significant fraction of nitrogen and carbon metabolites in the field. Our laboratory findings also exposed cryptic predatory, cooperative, and competitive interactions that impact microorganisms across fractured shales. Scaling these results from the laboratory to the field identified mechanisms underpinning biogeochemical reactions, yielding knowledge that can be harnessed to potentially increase energy yields and inform management practices in hydraulically fractured shales.

Published

2018

46. Draft Genome Sequences of Two Chemosynthetic Arcobacter Strains Isolated from Hydraulically Fractured Wells in Marcellus and Utica Shales

Author

Kelly C. Wrighton, Paula J. Mouser, Rebecca A. Daly, and Jenny Panescu

Subjects

0301 basic medicine, Chemosynthesis, biology, Shale gas, Geochemistry, biology.organism_classification, Genome, 03 medical and health sciences, 030104 developmental biology, Arcobacter, Genetics, Genus Arcobacter, Prokaryotes, Molecular Biology, Oil shale

Abstract

Genome sequences were obtained for two isolates of the genus Arcobacter from saline fluids produced from hydraulically fractured shale gas wells in the Marcellus and Utica formations. These genomes provide insight into microbial sulfur cycles occurring in a high-salt deep terrestrial shale environment.

Published

2018

47. Viruses control dominant bacteria colonizing the terrestrial deep biosphere after hydraulic fracturing

Author

David M. Morgan, Joseph D. Moore, Paula J. Mouser, Rebecca A. Daly, Matthew B. Sullivan, Kelly C. Wrighton, Kenneth Wunch, Mikayla A. Borton, Richard A. Wolfe, Tea Meulia, Michael D. Johnston, Andrea J. Hanson, Simon Roux, Michael J. Wilkins, Anne E. Booker, and David W. Hoyt

Subjects

Microbiology (medical), Microorganism, Immunology, Microbial Consortia, Biodiversity, Firmicutes, Biology, Applied Microbiology and Biotechnology, Microbiology, 03 medical and health sciences, Microbial ecology, Genetics, Ecosystem, Bacteriophages, Clustered Regularly Interspaced Short Palindromic Repeats, Oil and Gas Fields, 030304 developmental biology, 0303 health sciences, Biomass (ecology), 030306 microbiology, Ecology, Hydraulic Fracking, Biosphere, Cell Biology, biology.organism_classification, Microbial population biology, Metagenome, Virus Activation, Archaea

Abstract

The deep terrestrial biosphere harbours a substantial fraction of Earth's biomass and remains understudied compared with other ecosystems. Deep biosphere life primarily consists of bacteria and archaea, yet knowledge of their co-occurring viruses is poor. Here, we temporally catalogued viral diversity from five deep terrestrial subsurface locations (hydraulically fractured wells), examined virus-host interaction dynamics and experimentally assessed metabolites from cell lysis to better understand viral roles in this ecosystem. We uncovered high viral diversity, rivalling that of peatland soil ecosystems, despite low host diversity. Many viral operational taxonomic units were predicted to infect Halanaerobium, the dominant microorganism in these ecosystems. Examination of clustered regularly interspaced short palindromic repeats-CRISPR-associated proteins (CRISPR-Cas) spacers elucidated lineage-specific virus-host dynamics suggesting active in situ viral predation of Halanaerobium. These dynamics indicate repeated viral encounters and changing viral host range across temporally and geographically distinct shale formations. Laboratory experiments showed that prophage-induced Halanaerobium lysis releases intracellular metabolites that can sustain key fermentative metabolisms, supporting the persistence of microorganisms in this ecosystem. Together, these findings suggest that diverse and active viral populations play critical roles in driving strain-level microbial community development and resource turnover within this deep terrestrial subsurface ecosystem.

Published

2018

48. Draft Genome Sequences of Marinobacter Strains Recovered from Utica Shale-Produced Fluids

Author

Kelly C. Wrighton, Jenny Panescu, Rebecca A. Daly, Paula J. Mouser, and Shantal S. Tummings

Subjects

0301 basic medicine, biology, 030106 microbiology, Virulence, 010501 environmental sciences, Marinobacter, biology.organism_classification, complex mixtures, 01 natural sciences, Genome, Microbiology, 03 medical and health sciences, Genetics, Microaerophile, Prokaryotes, Molecular Biology, Oil shale, 0105 earth and related environmental sciences

Abstract

The genomes of three Marinobacter strains, isolated from saline fluids produced from a Utica-Point Pleasant shale well, have been sequenced. These genomes provide novel information on the degradation of petroleum distillates and virulence mechanisms under microaerophilic conditions in fractured shale.

Published

2018

49. Characterizing the Deep Terrestrial Subsurface Microbiome

Author

Michael J. Wilkins, Rebecca A. Daly, and Kelly C. Wrighton

Subjects

0301 basic medicine, 03 medical and health sciences, 030104 developmental biology, Metagenomics, Earth science, Library preparation, 030106 microbiology, Environmental science, Microbiome, Oil shale

Abstract

A large portion of the earth's biomass resides in the subsurface and recent studies have expanded our knowledge of indigenous microbial life. Advances in the field of metagenomics now allow analysis of microbial communities from low-biomass samples such as deep (>2.5 km) shale core samples. Here we present protocols for the best practices in contamination control, handling core material, extraction of nucleic acids, and low-input library preparation for subsequent metagenomic sequencing.

Published

2018

50. Sulfide Generation by Dominant Halanaerobium Microorganisms in Hydraulically Fractured Shales

Author

Anne E. Booker, Mikayla A. Borton, Rebecca A. Daly, Susan A. Welch, Carrie D. Nicora, David W. Hoyt, Travis Wilson, Samuel O. Purvine, Richard A. Wolfe, Shikha Sharma, Paula J. Mouser, David R. Cole, Mary S. Lipton, Kelly C. Wrighton, Michael J. Wilkins, Katherine McMahon, Gregory Dick, and Theodore Flynn

Subjects

0301 basic medicine, Sulfide, Microorganism, lcsh:QR1-502, Microbial metabolism, Mineralogy, Souring, 010501 environmental sciences, 01 natural sciences, Microbiology, lcsh:Microbiology, Sulfite reductase, shale, 03 medical and health sciences, chemistry.chemical_compound, Molecular Biology, 0105 earth and related environmental sciences, Thiosulfate, chemistry.chemical_classification, thiosulfate, Halanaerobium, QR1-502, 6. Clean water, 030104 developmental biology, chemistry, Microbial population biology, 13. Climate action, Environmental chemistry, Oil shale

Abstract

Hydraulic fracturing of black shale formations has greatly increased United States oil and natural gas recovery. However, the accumulation of biomass in subsurface reservoirs and pipelines is detrimental because of possible well souring, microbially induced corrosion, and pore clogging. Temporal sampling of produced fluids from a well in the Utica Shale revealed the dominance of Halanaerobium strains within the in situ microbial community and the potential for these microorganisms to catalyze thiosulfate-dependent sulfidogenesis. From these field data, we investigated biogenic sulfide production catalyzed by a Halanaerobium strain isolated from the produced fluids using proteogenomics and laboratory growth experiments. Analysis of Halanaerobium isolate genomes and reconstructed genomes from metagenomic data sets revealed the conserved presence of rhodanese-like proteins and anaerobic sulfite reductase complexes capable of converting thiosulfate to sulfide. Shotgun proteomics measurements using a Halanaerobium isolate verified that these proteins were more abundant when thiosulfate was present in the growth medium, and culture-based assays identified thiosulfate-dependent sulfide production by the same isolate. Increased production of sulfide and organic acids during the stationary growth phase suggests that fermentative Halanaerobium uses thiosulfate to remove excess reductant. These findings emphasize the potential detrimental effects that could arise from thiosulfate-reducing microorganisms in hydraulically fractured shales, which are undetected by current industry-wide corrosion diagnostics. IMPORTANCE Although thousands of wells in deep shale formations across the United States have been hydraulically fractured for oil and gas recovery, the impact of microbial metabolism within these environments is poorly understood. Our research demonstrates that dominant microbial populations in these subsurface ecosystems contain the conserved capacity for the reduction of thiosulfate to sulfide and that this process is likely occurring in the environment. Sulfide generation (also known as “souring”) is considered deleterious in the oil and gas industry because of both toxicity issues and impacts on corrosion of the subsurface infrastructure. Critically, the capacity for sulfide generation via reduction of sulfate was not detected in our data sets. Given that current industry wellhead tests for sulfidogenesis target canonical sulfate-reducing microorganisms, these data suggest that new approaches to the detection of sulfide-producing microorganisms may be necessary.

Published

2017