Your search keyword '"Oliver J. Burns"' showing total 7 results

1. Communal metabolism by Methylococcaceae and Methylophilaceae is driving rapid aerobic methane oxidation in sediments of a shallow seep near Elba, Italy

Author

Martin Taubert, Oliver J. Burns, Martin von Bergen, John Colin Murrell, Carolina Grob, Christian Lott, Nico Jehmlich, Alexandra M. Howat, Anne-Kristin Kaster, Yin Chen, John Vollmers, Andrew T. Crombie, and Miriam Weber

Subjects

Geologic Sediments, Geologic Sediments/microbiology, Stable-isotope probing, Methylophilaceae, Biology, Microbiology, Methylococcaceae, Methane, 03 medical and health sciences, chemistry.chemical_compound, QH301, Ecology, Evolution, Behavior and Systematics, Phylogeny, 030304 developmental biology, 0303 health sciences, 030306 microbiology, Microbiota, biology.organism_classification, Methane/metabolism, chemistry, Microbial population biology, Italy, Greenhouse gas, Environmental chemistry, Methylococcaceae/metabolism, Anaerobic oxidation of methane, Methylophilaceae/metabolism, Microbiota/physiology, Metagenomics, Energy source, Oxidation-Reduction

Abstract

The release of abiotic methane from marine seeps into the atmosphere is a major source of this potent greenhouse gas. Methanotrophic microorganisms in methane seeps use methane as carbon and energy source, thus significantly mitigating global methane emissions. Here, we investigated microbial methane oxidation at the sediment-water interface of a shallow marine methane seep. Metagenomics and metaproteomics, combined with 13 C-methane stable isotope probing, demonstrated that various members of the gammaproteobacterial family Methylococcaceae were the key players for methane oxidation, catalysing the first reaction step to methanol. We observed a transfer of carbon to methanol-oxidizing methylotrophs of the betaproteobacterial family Methylophilaceae, suggesting an interaction between methanotrophic and methylotrophic microorganisms that allowed for rapid methane oxidation. From our microcosms, we estimated methane oxidation rates of up to 871 nmol of methane per gram sediment per day. This implies that more than 50% of methane at the seep is removed by microbial oxidation at the sediment-water interface, based on previously reported in situ methane fluxes. The organic carbon produced was further assimilated by different heterotrophic microbes, demonstrating that the methane-oxidizing community supported a complex trophic network. Our results provide valuable eco-physiological insights into this specialized microbial community performing an ecosystem function of global relevance.

Published

2019

2. Combining metagenomics with metaproteomics and stable isotope probing reveals metabolic pathways used by a naturally occurring marine methylotroph

Author

J. Colin Murrell, Hans H. Richnow, Martin von Bergen, Nico Jehmlich, Alexandra M. Howat, Oliver J. Burns, Yin Chen, Carolina Grob, Martin Taubert, and Joanna L. Dixon

Subjects

biology, Ecology, Stable-isotope probing, Computational biology, biology.organism_classification, Microbiology, Genome, Metabolic pathway, Metagenomics, Proteome, Metaproteomics, Methylotroph, Gene, Ecology, Evolution, Behavior and Systematics

Abstract

A variety of culture-independent techniques have been developed that can be used in conjunction with culture-dependent physiological and metabolic studies of key microbial organisms in order to better understand how the activity of natural populations influences and regulates all major biogeochemical cycles. In this study, we combined deoxyribonucleic acid-stable isotope probing (DNA-SIP) with metagenomics and metaproteomics to characterize an uncultivated marine methylotroph that actively incorporated carbon from (13) C-labeled methanol into biomass. By metagenomic sequencing of the heavy DNA, we retrieved virtually the whole genome of this bacterium and determined its metabolic potential. Through protein-stable isotope probing, the RuMP cycle was established as the main carbon assimilation pathway, and the classical methanol dehydrogenase-encoding gene mxaF, as well as three out of four identified xoxF homologues were found to be expressed. This proof-of-concept study is the first in which the culture-independent techniques of DNA-SIP and protein-SIP have been used to characterize the metabolism of a naturally occurring Methylophaga-like bacterium in the marine environment (i.e. Methylophaga thiooxydans L4) and thus provides a powerful approach to access the genome and proteome of uncultivated microbes involved in key processes in the environment.

Published

2015

3. Methylamine as a nitrogen source for microorganisms from a coastal marine environment

Author

Martin, Taubert, Carolina, Grob, Alexandra M, Howat, Oliver J, Burns, Jennifer, Pratscher, Nico, Jehmlich, Martin, von Bergen, Hans H, Richnow, Yin, Chen, and J Colin, Murrell

Subjects

Carbon Isotopes, Methylamines, Nitrogen, Metagenomics, Carbon, Ecosystem, Gammaproteobacteria, Alphaproteobacteria

Abstract

Nitrogen is a key limiting resource for biomass production in the marine environment. Methylated amines, released from the degradation of osmolytes, could provide a nitrogen source for marine microbes. Thus far, studies in aquatic habitats on the utilization of methylamine, the simplest methylated amine, have mainly focussed on the fate of the carbon from this compound. Various groups of methylotrophs, microorganisms that can grow on one-carbon compounds, use methylamine as a carbon source. Non-methylotrophic microorganisms may also utilize methylamine as a nitrogen source, but little is known about their diversity, especially in the marine environment. In this proof-of-concept study, stable isotope probing (SIP) was used to identify microorganisms from a coastal environment that assimilate nitrogen from methylamine. SIP experiments using

Published

2016

4. Analysis of Active Methylotrophic Communities: When DNA-SIP Meets High-Throughput Technologies

Author

Martin, Taubert, Carolina, Grob, Alexandra M, Howat, Oliver J, Burns, Yin, Chen, Josh D, Neufeld, and J Colin, Murrell

Subjects

DNA, Bacterial, Carbon Isotopes, Carbon Compounds, Inorganic, Isotope Labeling, Environmental Microbiology, Metagenomics, Sequence Analysis, DNA, DNA Probes, Ecosystem

Abstract

Methylotrophs are microorganisms ubiquitous in the environment that can metabolize one-carbon (C1) compounds as carbon and/or energy sources. The activity of these prokaryotes impacts biogeochemical cycles within their respective habitats and can determine whether these habitats act as sources or sinks of C1 compounds. Due to the high importance of C1 compounds, not only in biogeochemical cycles, but also for climatic processes, it is vital to understand the contributions of these microorganisms to carbon cycling in different environments. One of the most challenging questions when investigating methylotrophs, but also in environmental microbiology in general, is which species contribute to the environmental processes of interest, or "who does what, where and when?" Metabolic labeling with C1 compounds substituted with (13)C, a technique called stable isotope probing, is a key method to trace carbon fluxes within methylotrophic communities. The incorporation of (13)C into the biomass of active methylotrophs leads to an increase in the molecular mass of their biomolecules. For DNA-based stable isotope probing (DNA-SIP), labeled and unlabeled DNA is separated by isopycnic ultracentrifugation. The ability to specifically analyze DNA of active methylotrophs from a complex background community by high-throughput sequencing techniques, i.e. targeted metagenomics, is the hallmark strength of DNA-SIP for elucidating ecosystem functioning, and a protocol is detailed in this chapter.

Published

2016

5. Analysis of Active Methylotrophic Communities: When DNA-SIP Meets High-Throughput Technologies

Author

Oliver J. Burns, J. Colin Murrell, Carolina Grob, Martin Taubert, Yin Chen, Alexandra M. Howat, and Josh D. Neufeld

Subjects

0301 basic medicine, 03 medical and health sciences, Biogeochemical cycle, 030104 developmental biology, Microbial ecology, Chemistry, Metagenomics, Isotopes of carbon, Stable-isotope probing, Computational biology, Energy source, DNA sequencing, Carbon cycle

Abstract

Methylotrophs are microorganisms ubiquitous in the environment that can metabolize one-carbon (C1) compounds as carbon and/or energy sources. The activity of these prokaryotes impacts biogeochemical cycles within their respective habitats and can determine whether these habitats act as sources or sinks of C1 compounds. Due to the high importance of C1 compounds, not only in biogeochemical cycles, but also for climatic processes, it is vital to understand the contributions of these microorganisms to carbon cycling in different environments. One of the most challenging questions when investigating methylotrophs, but also in environmental microbiology in general, is which species contribute to the environmental processes of interest, or "who does what, where and when?" Metabolic labeling with C1 compounds substituted with (13)C, a technique called stable isotope probing, is a key method to trace carbon fluxes within methylotrophic communities. The incorporation of (13)C into the biomass of active methylotrophs leads to an increase in the molecular mass of their biomolecules. For DNA-based stable isotope probing (DNA-SIP), labeled and unlabeled DNA is separated by isopycnic ultracentrifugation. The ability to specifically analyze DNA of active methylotrophs from a complex background community by high-throughput sequencing techniques, i.e. targeted metagenomics, is the hallmark strength of DNA-SIP for elucidating ecosystem functioning, and a protocol is detailed in this chapter.

Published

2016

6. Combining metagenomics with metaproteomics and stable isotope probing reveals metabolic pathways used by a naturally occurring marine methylotroph

Author

Carolina, Grob, Martin, Taubert, Alexandra M, Howat, Oliver J, Burns, Joanna L, Dixon, Hans H, Richnow, Nico, Jehmlich, Martin, von Bergen, Yin, Chen, and J Colin, Murrell

Subjects

DNA, Bacterial, Proteomics, Base Sequence, Proteome, Methanol, Molecular Sequence Data, Sequence Analysis, DNA, Carbon, Alcohol Oxidoreductases, Isotope Labeling, RNA, Ribosomal, 16S, Seawater, Biomass, Metagenomics, Piscirickettsiaceae, Genome, Bacterial, Metabolic Networks and Pathways

Abstract

A variety of culture-independent techniques have been developed that can be used in conjunction with culture-dependent physiological and metabolic studies of key microbial organisms in order to better understand how the activity of natural populations influences and regulates all major biogeochemical cycles. In this study, we combined deoxyribonucleic acid-stable isotope probing (DNA-SIP) with metagenomics and metaproteomics to characterize an uncultivated marine methylotroph that actively incorporated carbon from (13) C-labeled methanol into biomass. By metagenomic sequencing of the heavy DNA, we retrieved virtually the whole genome of this bacterium and determined its metabolic potential. Through protein-stable isotope probing, the RuMP cycle was established as the main carbon assimilation pathway, and the classical methanol dehydrogenase-encoding gene mxaF, as well as three out of four identified xoxF homologues were found to be expressed. This proof-of-concept study is the first in which the culture-independent techniques of DNA-SIP and protein-SIP have been used to characterize the metabolism of a naturally occurring Methylophaga-like bacterium in the marine environment (i.e. Methylophaga thiooxydans L4) and thus provides a powerful approach to access the genome and proteome of uncultivated microbes involved in key processes in the environment.

Published

2015

7. Screening of metagenomic and genomic libraries reveals three classes of bacterial enzymes that overcome the toxicity of acrylate

Author

Rolf Daniel, Andrew W. B. Johnston, Margaret Wexler, Andrew R. J. Curson, Oliver J. Burns, Kathryn McInnis, Jonathan D. Todd, Sonja Voget, and Tyagi, Anil Kumar

Subjects

Novosphingobium, Mutant, Gene Identification and Analysis, lcsh:Medicine, Bacillus, Reductase, medicine.disease_cause, Biochemistry, Microbial Physiology, Genomic library, Screening, Bacterial Enzymes, Toxicity, Acrylate, Cloning, Molecular, Amino Acids, lcsh:Science, Genetics, 0303 health sciences, Genomic Library, Multidisciplinary, biology, Ecology, Intracellular Signaling Peptides and Proteins, Genomics, Bacterial Pathogens, Bacillus Subtilis, Chemistry, Organic Acids, Acrylates, Medical Microbiology, Physical Sciences, Prokaryotic Models, Oxidoreductases, Research Article, Research and Analysis Methods, Microbiology, Bacterial genetics, Microbial Ecology, Molecular Genetics, 03 medical and health sciences, Model Organisms, Bacterial Proteins, Drug Resistance, Bacterial, medicine, Escherichia coli, Gene, Microbial Pathogens, 030304 developmental biology, Microbial Metabolism, 030306 microbiology, lcsh:R, Organic Chemistry, Chemical Compounds, Biology and Life Sciences, Proteins, biology.organism_classification, Mutation, Sinorhizobium fredii, lcsh:Q, Metagenomics, Gene Function, Carrier Proteins, Acids, Bacteria

Abstract

Acrylate is produced in significant quantities through the microbial cleavage of the highly abundant marine osmoprotectant dimethylsulfoniopropionate, an important process in the marine sulfur cycle. Acrylate can inhibit bacterial growth, likely through its conversion to the highly toxic molecule acrylyl-CoA. Previous work identified an acrylyl-CoA reductase, encoded by the gene acuI, as being important for conferring on bacteria the ability to grow in the presence of acrylate. However, some bacteria lack acuI, and, conversely, many bacteria that may not encounter acrylate in their regular environments do contain this gene. We therefore sought to identify new genes that might confer tolerance to acrylate. To do this, we used functional screening of metagenomic and genomic libraries to identify novel genes that corrected an E. coli mutant that was defective in acuI, and was therefore hyper-sensitive to acrylate. The metagenomic libraries yielded two types of genes that overcame this toxicity. The majority encoded enzymes resembling AcuI, but with significant sequence divergence among each other and previously ratified AcuI enzymes. One other metagenomic gene, arkA, had very close relatives in Bacillus and related bacteria, and is predicted to encode an enoyl-acyl carrier protein reductase, in the same family as FabK, which catalyses the final step in fatty-acid biosynthesis in some pathogenic Firmicute bacteria. A genomic library of Novosphingobium, a metabolically versatile alphaproteobacterium that lacks both acuI and arkA, yielded vutD and vutE, two genes that, together, conferred acrylate resistance. These encode sequential steps in the oxidative catabolism of valine in a pathway in which, significantly, methacrylyl-CoA is a toxic intermediate. These findings expand the range of bacteria for which the acuI gene encodes a functional acrylyl-CoA reductase, and also identify novel enzymes that can similarly function in conferring acrylate resistance, likely, again, through the removal of the toxic product acrylyl-CoA. peerReviewed

Published

2014