Your search keyword '"Deltaproteobacteria metabolism"' showing total 16 results

1. Anaerobic oxidation of ethane by archaea from a marine hydrocarbon seep.

Author

Chen SC, Musat N, Lechtenfeld OJ, Paschke H, Schmidt M, Said N, Popp D, Calabrese F, Stryhanyuk H, Jaekel U, Zhu YG, Joye SB, Richnow HH, Widdel F, and Musat F

Subjects

Anaerobiosis, Archaea classification, Archaea enzymology, Archaea genetics, Deltaproteobacteria metabolism, Ethane chemistry, Gases chemistry, Gases metabolism, Gulf of Mexico, Methane biosynthesis, Oxidation-Reduction, Oxidoreductases genetics, Oxidoreductases isolation & purification, Oxidoreductases metabolism, Phylogeny, RNA, Ribosomal, 16S genetics, Sulfates metabolism, Sulfides metabolism, Aquatic Organisms metabolism, Archaea metabolism, Ethane metabolism

Abstract

Ethane is the second most abundant component of natural gas in addition to methane, and-similar to methane-is chemically unreactive. The biological consumption of ethane under anoxic conditions was suggested by geochemical profiles at marine hydrocarbon seeps 1-3 , and through ethane-dependent sulfate reduction in slurries 4-7 . Nevertheless, the microorganisms and reactions that catalyse this process have to date remained unknown 8 . Here we describe ethane-oxidizing archaea that were obtained by specific enrichment over ten years, and analyse these archaea using phylogeny-based fluorescence analyses, proteogenomics and metabolite studies. The co-culture, which oxidized ethane completely while reducing sulfate to sulfide, was dominated by an archaeon that we name 'Candidatus Argoarchaeum ethanivorans'; other members were sulfate-reducing Deltaproteobacteria. The genome of Ca. Argoarchaeum contains all of the genes that are necessary for a functional methyl-coenzyme M reductase, and all subunits were detected in protein extracts. Accordingly, ethyl-coenzyme M (ethyl-CoM) was identified as an intermediate by liquid chromatography-tandem mass spectrometry. This indicated that Ca. Argoarchaeum initiates ethane oxidation by ethyl-CoM formation, analogous to the recently described butane activation by 'Candidatus Syntrophoarchaeum' 9 . Proteogenomics further suggests that oxidation of intermediary acetyl-CoA to CO 2 occurs through the oxidative Wood-Ljungdahl pathway. The identification of an archaeon that uses ethane (C 2 H 6 ) fills a gap in our knowledge of microorganisms that specifically oxidize members of the homologous alkane series (C n H 2n+2 ) without oxygen. Detection of phylogenetic and functional gene markers related to those of Ca. Argoarchaeum at deep-sea gas seeps 10-12 suggests that archaea that are able to oxidize ethane through ethyl-CoM are widespread members of the local communities fostered by venting gaseous alkanes around these seeps.

Published

2019

2. Microbiology: Conductive consortia.

Author

Wagner M

Subjects

Archaea metabolism, Bacteria metabolism, Deltaproteobacteria metabolism, Methane metabolism, Single-Cell Analysis, Symbiosis

Published

2015

3. Single cell activity reveals direct electron transfer in methanotrophic consortia.

Author

McGlynn SE, Chadwick GL, Kempes CP, and Orphan VJ

Subjects

Anaerobiosis, Archaea cytology, Cytochromes genetics, Cytochromes metabolism, Cytochromes ultrastructure, Deltaproteobacteria cytology, Diffusion, Electron Transport, Genome, Archaeal genetics, Genome, Bacterial genetics, Heme metabolism, Microbiota physiology, Models, Biological, Molecular Sequence Data, Sulfates metabolism, Archaea metabolism, Deltaproteobacteria metabolism, Methane metabolism, Single-Cell Analysis, Symbiosis

Abstract

Multicellular assemblages of microorganisms are ubiquitous in nature, and the proximity afforded by aggregation is thought to permit intercellular metabolic coupling that can accommodate otherwise unfavourable reactions. Consortia of methane-oxidizing archaea and sulphate-reducing bacteria are a well-known environmental example of microbial co-aggregation; however, the coupling mechanisms between these paired organisms is not well understood, despite the attention given them because of the global significance of anaerobic methane oxidation. Here we examined the influence of interspecies spatial positioning as it relates to biosynthetic activity within structurally diverse uncultured methane-oxidizing consortia by measuring stable isotope incorporation for individual archaeal and bacterial cells to constrain their potential metabolic interactions. In contrast to conventional models of syntrophy based on the passage of molecular intermediates, cellular activities were found to be independent of both species intermixing and distance between syntrophic partners within consortia. A generalized model of electric conductivity between co-associated archaea and bacteria best fit the empirical data. Combined with the detection of large multi-haem cytochromes in the genomes of methanotrophic archaea and the demonstration of redox-dependent staining of the matrix between cells in consortia, these results provide evidence for syntrophic coupling through direct electron transfer.

Published

2015

4. An environmental bacterial taxon with a large and distinct metabolic repertoire.

Author

Wilson MC, Mori T, Rückert C, Uria AR, Helf MJ, Takada K, Gernert C, Steffens UA, Heycke N, Schmitt S, Rinke C, Helfrich EJ, Brachmann AO, Gurgui C, Wakimoto T, Kracht M, Crüsemann M, Hentschel U, Abe I, Matsunaga S, Kalinowski J, Takeyama H, and Piel J

Subjects

Animals, Biosynthetic Pathways genetics, Deltaproteobacteria genetics, Deltaproteobacteria physiology, Environmental Microbiology, Genes, Bacterial genetics, Genome, Bacterial genetics, Metagenomics, Molecular Sequence Data, Multigene Family genetics, Peptides metabolism, Polyketides metabolism, Porifera metabolism, Porifera microbiology, Single-Cell Analysis, Symbiosis, Deltaproteobacteria classification, Deltaproteobacteria metabolism, Drug Discovery

Abstract

Cultivated bacteria such as actinomycetes are a highly useful source of biomedically important natural products. However, such 'talented' producers represent only a minute fraction of the entire, mostly uncultivated, prokaryotic diversity. The uncultured majority is generally perceived as a large, untapped resource of new drug candidates, but so far it is unknown whether taxa containing talented bacteria indeed exist. Here we report the single-cell- and metagenomics-based discovery of such producers. Two phylotypes of the candidate genus 'Entotheonella' with genomes of greater than 9 megabases and multiple, distinct biosynthetic gene clusters co-inhabit the chemically and microbially rich marine sponge Theonella swinhoei. Almost all bioactive polyketides and peptides known from this animal were attributed to a single phylotype. 'Entotheonella' spp. are widely distributed in sponges and belong to an environmental taxon proposed here as candidate phylum 'Tectomicrobia'. The pronounced bioactivities and chemical uniqueness of 'Entotheonella' compounds provide significant opportunities for ecological studies and drug discovery.

Published

2014

5. Microbiology: a talented genus.

Author

Jaspars M and Challis G

Subjects

Animals, Deltaproteobacteria classification, Deltaproteobacteria metabolism, Drug Discovery

Published

2014

6. Microbiology: A piece of the methane puzzle.

Author

Joye SB

Subjects

Aquatic Organisms metabolism, Archaea metabolism, Deltaproteobacteria metabolism, Methane metabolism, Sulfur chemistry, Sulfur metabolism

Published

2012

7. Zero-valent sulphur is a key intermediate in marine methane oxidation.

Author

Milucka J, Ferdelman TG, Polerecky L, Franzke D, Wegener G, Schmid M, Lieberwirth I, Wagner M, Widdel F, and Kuypers MM

Subjects

Anaerobiosis, Carbon Cycle, Carbon Dioxide metabolism, Disulfides metabolism, Geologic Sediments chemistry, Models, Biological, Oxidation-Reduction, Sulfates metabolism, Aquatic Organisms metabolism, Archaea metabolism, Deltaproteobacteria metabolism, Methane metabolism, Sulfur chemistry, Sulfur metabolism

Abstract

Emissions of methane, a potent greenhouse gas, from marine sediments are controlled by anaerobic oxidation of methane coupled primarily to sulphate reduction (AOM). Sulphate-coupled AOM is believed to be mediated by a consortium of methanotrophic archaea (ANME) and sulphate-reducing Deltaproteobacteria but the underlying mechanism has not yet been resolved. Here we show that zero-valent sulphur compounds (S(0)) are formed during AOM through a new pathway for dissimilatory sulphate reduction performed by the methanotrophic archaea. Hence, AOM might not be an obligate syntrophic process but may be carried out by the ANME alone. Furthermore, we show that the produced S(0)--in the form of disulphide--is disproportionated by the Deltaproteobacteria associated with the ANME. Our observations expand the diversity of known microbially mediated sulphur transformations and have significant implications for our understanding of the biogeochemical carbon and sulphur cycles.

Published

2012

8. Microbiology: Bacterial power cords.

Author

Reguera G

Subjects

Deltaproteobacteria metabolism, Electric Conductivity

Published

2012

9. Filamentous bacteria transport electrons over centimetre distances.

Author

Pfeffer C, Larsen S, Song J, Dong M, Besenbacher F, Meyer RL, Kjeldsen KU, Schreiber L, Gorby YA, El-Naggar MY, Leung KM, Schramm A, Risgaard-Petersen N, and Nielsen LP

Subjects

Aquatic Organisms cytology, Aquatic Organisms metabolism, Aquatic Organisms ultrastructure, Deltaproteobacteria cytology, Deltaproteobacteria ultrastructure, Denmark, Electron Transport, Geologic Sediments microbiology, Glass, Microspheres, Molecular Sequence Data, Molecular Typing, Oceans and Seas, Oxygen metabolism, Porosity, RNA, Ribosomal, 16S analysis, RNA, Ribosomal, 16S genetics, Sulfides metabolism, Deltaproteobacteria metabolism, Electric Conductivity

Abstract

Oxygen consumption in marine sediments is often coupled to the oxidation of sulphide generated by degradation of organic matter in deeper, oxygen-free layers. Geochemical observations have shown that this coupling can be mediated by electric currents carried by unidentified electron transporters across centimetre-wide zones. Here we present evidence that the native conductors are long, filamentous bacteria. They abounded in sediment zones with electric currents and along their length they contained strings with distinct properties in accordance with a function as electron transporters. Living, electrical cables add a new dimension to the understanding of interactions in nature and may find use in technology development.

Published

2012

10. A conspicuous nickel protein in microbial mats that oxidize methane anaerobically.

Author

Krüger M, Meyerdierks A, Glöckner FO, Amann R, Widdel F, Kube M, Reinhardt R, Kahnt J, Böcher R, Thauer RK, and Shima S

Subjects

Amino Acid Sequence, Anaerobiosis, Archaeal Proteins chemistry, Bacterial Proteins chemistry, Deltaproteobacteria metabolism, Geologic Sediments chemistry, Methanosarcinales metabolism, Molecular Sequence Data, Oceans and Seas, Phylogeny, Protein Subunits chemistry, Protein Subunits metabolism, Archaeal Proteins metabolism, Bacterial Proteins metabolism, Geologic Sediments microbiology, Metalloproteins chemistry, Metalloproteins metabolism, Methane metabolism, Nickel analysis

Abstract

Anaerobic oxidation of methane (AOM) in marine sediments is an important microbial process in the global carbon cycle and in control of greenhouse gas emission. The responsible organisms supposedly reverse the reactions of methanogenesis, but cultures providing biochemical proof of this have not been isolated. Here we searched for AOM-associated cell components in microbial mats from anoxic methane seeps in the Black Sea. These mats catalyse AOM rather than carry out methanogenesis. We extracted a prominent nickel compound displaying the same absorption spectrum as the nickel cofactor F430 of methyl-coenzyme M reductase, the terminal enzyme of methanogenesis; however, the nickel compound exhibited a higher molecular mass than F430. The apparent variant of F(430) was part of an abundant protein that was purified from the mat and that consists of three different subunits. Determined amino-terminal amino acid sequences matched a gene locus cloned from the mat. Sequence analyses revealed similarities to methyl-coenzyme M reductase from methanogenic archaea. The abundance of the nickel protein (7% of extracted proteins) in the mat suggests an important role in AOM.

Published

2003

11. Geobacter metallireducens accesses insoluble Fe(III) oxide by chemotaxis.

Author

Childers SE, Ciufo S, and Lovley DR

Subjects

Bacterial Proteins genetics, DNA-Binding Proteins genetics, Deltaproteobacteria genetics, Deltaproteobacteria physiology, Ferrous Compounds metabolism, Fimbriae, Bacterial genetics, Fimbriae, Bacterial physiology, Flagella physiology, Manganese Compounds metabolism, Movement, Oxidation-Reduction, Oxides metabolism, Solubility, Chemotaxis, Deltaproteobacteria cytology, Deltaproteobacteria metabolism, Ferric Compounds chemistry, Ferric Compounds metabolism, Fimbriae Proteins

Abstract

Microorganisms that use insoluble Fe(III) oxide as an electron acceptor can have an important function in the carbon and nutrient cycles of aquatic sediments and in the bioremediation of organic and metal contaminants in groundwater. Although Fe(III) oxides are often abundant, Fe(III)-reducing microbes are faced with the problem of how to access effectively an electron acceptor that can not diffuse to the cell. Fe(III)-reducing microorganisms in the genus Shewanella have resolved this problem by releasing soluble quinones that can carry electrons from the cell surface to Fe(III) oxide that is at a distance from the cell. Here we report that another Fe(III)-reducer, Geobacter metallireducens, has an alternative strategy for accessing Fe(III) oxides. Geobacter metallireducens specifically expresses flagella and pili only when grown on insoluble Fe(III) or Mn(IV) oxide, and is chemotactic towards Fe(II) and Mn(II) under these conditions. These results suggest that G. metallireducens senses when soluble electron acceptors are depleted and then synthesizes the appropriate appendages to permit it to search for, and establish contact with, insoluble Fe(III) or Mn(IV) oxide. This approach to the use of an insoluble electron acceptor may explain why Geobacter species predominate over other Fe(III) oxide-reducing microorganisms in a wide variety of sedimentary environments.

Published

2002

12. Anaerobic microbial metabolism can proceed close to thermodynamic limits.

Author

Jackson BE and McInerney MJ

Subjects

Archaea metabolism, Deltaproteobacteria metabolism, Ecosystem, Energy Metabolism, Thermodynamics, Bacteria, Anaerobic metabolism

Abstract

Many fermentative bacteria obtain energy for growth by reactions in which the change in free energy (DeltaG') is less than that needed to synthesize ATP. These bacteria couple substrate metabolism directly to ATP synthesis, however, by classical phosphoryl transfer reactions. An explanation for the energy economy of these organisms is that biological systems conserve energy in discrete amounts, with a minimum, biochemically convertible energy value of about -20 kJ mol-1 (refs 1, 2, 3). This concept predicts that anaerobic substrate decay ceases before the minimum free energy value is reached, and several studies support this prediction. Here we show that metabolism by syntrophic associations, in which the degradation of a substrate by one species is thermodynamically possible only through removal of the end product by another species, can occur at values close to thermodynamic equilibrium (DeltaG' approximately 0 kJ mol-1). The free energy remaining when substrate metabolism halts is not constant; it depends on the terminal electron-accepting reaction and the amount of energy required for substrate activation. Syntrophic associations metabolize near thermodynamic equilibrium, indicating that bacteria operate extremely efficient catabolic systems.

Published

2002

13. Endosymbiotic sulphate-reducing and sulphide-oxidizing bacteria in an oligochaete worm.

Author

Dubilier N, Mülders C, Ferdelman T, de Beer D, Pernthaler A, Klein M, Wagner M, Erséus C, Thiermann F, Krieger J, Giere O, and Amann R

Subjects

Aerobiosis, Agar, Animals, Carbon Dioxide metabolism, Deltaproteobacteria genetics, Deltaproteobacteria ultrastructure, Gammaproteobacteria genetics, Gammaproteobacteria ultrastructure, In Situ Hybridization, Fluorescence, Kinetics, Likelihood Functions, Microscopy, Electron, Models, Biological, Molecular Sequence Data, Oligochaeta ultrastructure, Oxidation-Reduction, Phylogeny, RNA, Bacterial genetics, RNA, Ribosomal, 16S genetics, Silicon Dioxide, Sulfur metabolism, Deltaproteobacteria metabolism, Gammaproteobacteria metabolism, Oligochaeta microbiology, Sulfates metabolism, Sulfides metabolism, Symbiosis

Abstract

Stable associations of more than one species of symbiont within a single host cell or tissue are assumed to be rare in metazoans because competition for space and resources between symbionts can be detrimental to the host. In animals with multiple endosymbionts, such as mussels from deep-sea hydrothermal vents and reef-building corals, the costs of competition between the symbionts are outweighed by the ecological and physiological flexibility gained by the hosts. A further option for the coexistence of multiple symbionts within a host is if these benefit directly from one another, but such symbioses have not been previously described. Here we show that in the gutless marine oligochaete Olavius algarvensis, endosymbiotic sulphate-reducing bacteria produce sulphide that can serve as an energy source for sulphide-oxidizing symbionts of the host. Thus, these symbionts do not compete for resources but rather share a mutalistic relationship with each other in an endosymbiotic sulphur cycle, in addition to their symbiotic relationship with the oligochaete host.

Published

2001

14. A marine microbial consortium apparently mediating anaerobic oxidation of methane.

Author

Boetius A, Ravenschlag K, Schubert CJ, Rickert D, Widdel F, Gieseke A, Amann R, Jørgensen BB, Witte U, and Pfannkuche O

Subjects

Anaerobiosis, Geologic Sediments, Oceans and Seas, Oregon, Oxidation-Reduction, Sulfates metabolism, Thiotrichaceae metabolism, Archaea metabolism, Deltaproteobacteria metabolism, Methane metabolism, Water Microbiology

Abstract

A large fraction of globally produced methane is converted to CO2 by anaerobic oxidation in marine sediments. Strong geochemical evidence for net methane consumption in anoxic sediments is based on methane profiles, radiotracer experiments and stable carbon isotope data. But the elusive microorganisms mediating this reaction have not yet been isolated, and the pathway of anaerobic oxidation of methane is insufficiently understood. Recent data suggest that certain archaea reverse the process of methanogenesis by interaction with sulphate-reducing bacteria. Here we provide microscopic evidence for a structured consortium of archaea and sulphate-reducing bacteria, which we identified by fluorescence in situ hybridization using specific 16S rRNA-targeted oligonucleotide probes. In this example of a structured archaeal-bacterial symbiosis, the archaea grow in dense aggregates of about 100 cells and are surrounded by sulphate-reducing bacteria. These aggregates were abundant in gas-hydrate-rich sediments with extremely high rates of methane-based sulphate reduction, and apparently mediate anaerobic oxidation of methane.

Published

2000

15. Resolving a methane mystery.

Author

DeLong EF

Subjects

Anaerobiosis, Atmosphere, Geologic Sediments, Oceans and Seas, Archaea metabolism, Deltaproteobacteria metabolism, Methane metabolism, Water Microbiology

Published

2000

16. Phosphite oxidation by sulphate reduction.

Author

Schink B and Friedrich M

Subjects

Anaerobiosis, Bacteria, Anaerobic classification, Deltaproteobacteria classification, Deltaproteobacteria genetics, Energy Metabolism, Oxidation-Reduction, Phylogeny, RNA, Bacterial genetics, RNA, Ribosomal, 16S genetics, Bacteria, Anaerobic metabolism, Deltaproteobacteria metabolism, Phosphites metabolism, Sulfates metabolism

Published

2000