Genomic Insights into Methanotrophy: The Complete Genome Sequence of Methylococcus capsulatus (Bath)

Ward, Naomi; Larsen, Øivind; Sakwa, James; Bruseth, Live J.; Khouri, Hoda; Durkin, A. Scott; Dimitrov, George; Jiang, Lingxia; Scanlan, David J.; Kang, Katherine H.; Lewis, Matt; Nelson, Karen E.; Methé, Barbara A.; Wu, Martin; Heidelberg, John F.; Paulsen, Ian T.; Fouts, Derrick E.; Ravel, Jacques; Tettelin, Hervé; Ren, Qinghu; Read, Timothy D.; DeBoy, Robert T.; Seshadri, Rekha; Salzberg, Steven L.; Jensen, Harald B.; Birkeland, Nils Kåre; Nelson, William; Dodson, Robert J.; Grindhaug, Svenn Helge; Holt, Ingeborg; Eidhammer, Ingvar; Jonasen, Inge; Vanaken, Susan E.; Utterback, Terry; Feldblyum, Tamara; Fraser, Claire M.; Lillehaug, Johan R.; Eisen, Jonathan A.

doi:10.1371/journal.pbio.0020303

Cited by 300 publications

(301 citation statements)

References 113 publications

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“…(Supplementary Tables S2-S6). Although several genome sequences of MOB (Methylomonas methanica MC09 (Boden et al, 2011), Methylomicrobium album strain BG8, Methylococcus capsulatus strain Bath and Texas (Ward et al, 2004;Kleiveland et al, 2012), Methylocystis strain Rockwell (Stein et al, 2011), Methylocystis strain SC2 (Dam et al, 2012), Methylocystis parvus OBBP (del Cerro et al, 2012), Methylosinus trichosporium OB3b (Stein et al, 2010)) were deposited in the consulted NCBI nr database, almost no other labeled peptide sequences affiliated to MOB were identified besides peptides of Methylobacter tundripaludum SV96. In addition, most of the identified peptide sequences had to be excluded according to the stringent Mascot scoring parameters, which may be related to the soil matrix.…”

Section: Resultsmentioning

confidence: 99%

Microbial minorities modulate methane consumption through niche partitioning

et al. 2013

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Microbes catalyze all major geochemical cycles on earth. However, the role of microbial traits and community composition in biogeochemical cycles is still poorly understood mainly due to the inability to assess the community members that are actually performing biogeochemical conversions in complex environmental samples. Here we applied a polyphasic approach to assess the role of microbial community composition in modulating methane emission from a riparian floodplain. We show that the dynamics and intensity of methane consumption in riparian wetlands coincide with relative abundance and activity of specific subgroups of methane-oxidizing bacteria (MOB), which can be considered as a minor component of the microbial community in this ecosystem. Microarray-based community composition analyses demonstrated linear relationships of MOB diversity parameters and in vitro methane consumption. Incubations using intact cores in combination with stable isotope labeling of lipids and proteins corroborated the correlative evidence from in vitro incubations demonstrating c-proteobacterial MOB subgroups to be responsible for methane oxidation. The results obtained within the riparian flooding gradient collectively demonstrate that niche partitioning of MOB within a community comprised of a very limited amount of active species modulates methane consumption and emission from this wetland. The implications of the results obtained for biodiversity-ecosystem functioning are discussed with special reference to the role of spatial and temporal heterogeneity and functional redundancy.

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Section: Resultsmentioning

confidence: 99%

Microbial minorities modulate methane consumption through niche partitioning

et al. 2013

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“…Indeed, such lesions have been confirmed through the genomic analysis of some obligate methylotrophs, such as Methylobacillus flagellatus (Chistoserdova et al, 2007). However, genomes of other obligate methylotrophs, such as Methylococcus capsulatus, were found to encode all the functions necessary for growth on multicarbon compounds (Ward et al, 2004;Kelly et al, 2005). This points to the fact that growth and behavior of such microbes as observed in the laboratory may not fully reflect their physiological potential encoded in the genome and that some of the genomic features must be only expressed under specific environmental conditions.…”

Section: Introductionmentioning

confidence: 99%

Functioning in situ: gene expression in Methylotenera mobilis in its native environment as assessed through transcriptomics

et al. 2009

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Methylotrophs, organisms able to gain energy and carbon from compounds containing no carboncarbon bonds, such as methane, methanol and methylated amines, are widespread in nature. However, knowledge of their nutrient preference and their metabolism is mostly based on experiments with cultures grown in defined laboratory conditions. Here, we use transcriptomics to explore the activity of one methylotroph, Methyotenera mobilis in its natural environment, lake sediment from which it has been previously isolated. Cells encapsulated in incubation cassettes were exposed to sediment conditions, with or without supplementation with a carbon/energy source (methylamine), and gene-expression patterns were compared for those cells to patterns for cells incubated in a defined medium supplemented with methylamine. A few specific trends in gene expression were observed at in situ conditions that may be of environmental significance, as follows. Expression of genes for the linear formaldehyde oxidation pathway linked to tetrahydromethanopterin increased, suggesting an important role for this pathway in situ, in contrast to laboratory condition culture, in which the cyclic ribulose monophosphate pathway seemed to be the major route for formaldehyde oxidation. Along with the ribulose monophosphate cycle that is also a major pathway for assimilating C 1 units, the methylcitric acid cycle seemd to be important in situ, suggesting that multicarbon compounds may be the natural carbon and/or energy substrates for M. mobilis, challenging the notion of an obligately methylotrophic lifestyle for this bacterium. We also detected a major switch in expression of genes responsible for the mode of motility between different conditions: from flagellum-enabled motility in defined medium to in situ expression of pili known to be involved in twitching motility and adherence. Overall, this study offers a novel approach for gaining insights into the lifestyle of individual microbes in their native environments.

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“…Copper also increases the synthesis of an extensive network of intracytoplasmic membranes [10] and is the active center metal of pMMO [11] Little is known about copper homeostasis in M. capsulatus although copper has a significant physiological role in this methanotroph. The genome sequencing of M. capsulatus led to the identification of four copper transport homologues [12]. Among them, three copper translocating P-type ATPase homologues; MCA0705, MCA0805 and MCA2072 were identified.…”

Section: Introductionmentioning

confidence: 99%

Mutagenesis of a Copper P-Type ATPase Encoding Genein Methylococcus capsulatus (Bath) Results inCopper-Resistance

Khalifa¹

2013

IJBBB

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Abstract-Copper is an essential micronutrient for all living cells, however, it is extremely toxic at high concentrations and thus copper homeostasis is required to be tightly regulated. copA encodes for a copper-translocating P-type ATPase (CopA) and plays a vital role in copper homeostasis and is involved in copper transport across membranes of many organisms. Little is known about copper homeostasis in Methylococcus capsulatus although copper has a significant physiological role in this methanotroph. In this study we investigated the disruption of a CopA1 homologue (MCA2072; copA1) in M. capsulatus (Bath) by insertional inactivation mutagenesis. The resulting mutant, M. capsulatus ΔcopA1, was copper resistant to elevated copper concentrations (100 µM) than the wild-type strain (80 µM). Furthermore, the intracellular copper measurements revealed that ΔcopA1 accumulated half the amount of copper when compared with the wild-type. No observed phenotypic difference between the mutant strain and wild-type related to growth at different silver concentrations. These observations suggest that M. capsulatus CopA1 has a key role in copper homeostasis.

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Genomic Insights into Methanotrophy: The Complete Genome Sequence of Methylococcus capsulatus (Bath)

Cited by 300 publications

References 113 publications

Microbial minorities modulate methane consumption through niche partitioning

Microbial minorities modulate methane consumption through niche partitioning

Functioning in situ: gene expression in Methylotenera mobilis in its native environment as assessed through transcriptomics

Mutagenesis of a Copper P-Type ATPase Encoding Genein Methylococcus capsulatus (Bath) Results inCopper-Resistance

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