Genomic Insights Into the Acid Adaptation of Novel Methanotrophs Enriched From Acidic Forest Soils

Nguyen, Ngoc-Loi; Yu, Woon-Jong; Gwak, Joo-Han; Kim, So-Jeong; Park, Soo-Je; Herbold, Craig W.; Kim, Jong-Geol; Jung, Man‐Young; Rhee, Sung‐Keun

doi:10.3389/fmicb.2018.01982

Cited by 24 publications

(23 citation statements)

References 126 publications

(156 reference statements)

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“…This was supported by the consumption of methane in the headspace, measured using gas chromatograph (GC-2010 Plus, Shimadzu). The gas chromatograph was equipped with an Rtx1 capillary column (30 m×0.25 mm×0.25 µm, Restek) coupled to a flame ionization detector and operated as described previously [22]. To obtain a pure culture, the enriched culture was repeatedly diluted to extinction until a culture with uniform cell morphology was observed under the light microscope (Eclipse 80i, Nikon) [23].…”

Section: Isolation and Cultivationmentioning

confidence: 99%

Methylococcus geothermalis sp. nov., a methanotroph isolated from a geothermal field in the Republic of Korea

Awala

Bellosillo

Gwak

et al. 2020

International Journal of Systematic and Evolutionary Microbiology

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A Gram-stain-negative, aerobic, non-motile and coccoid methanotroph, strain IM1T, was isolated from hot spring soil. Cells of strain IM1T were catalase-negative, oxidase-positive and displayed a characteristic intracytoplasmic membrane arrangement of type I methanotrophs. The strain possessed genes encoding both membrane-bound and soluble methane monooxygenases and grew only on methane or methanol. The strain was capable of growth at temperatures between 15 and 48 °C (optimum, 30–45 °C) and pH values between pH 4.8 and 8.2 (optimum, pH 6.2–7.0). Based on phylogenetic analysis of 16S rRNA gene and PmoA sequences, strain IM1T was demonstrated to be affiliated to the genus Methylococcus . The 16S rRNA gene sequence of this strain was most closely related to the sequences of an uncultured bacterium clone FD09 (100 %) and a partially described cultured Methylococcus sp. GDS2.4 (99.78 %). The most closely related taxonomically described strains were Methylococcus capsulatus TexasT (97.92 %), Methylococcus capsulatus Bath (97.86 %) and Methyloterricola oryzae 73aT (94.21 %). Strain IM1T shared average nucleotide identity values of 85.93 and 85.62 % with Methylococcus capsulatus strains TexasT and Bath, respectively. The digital DNA–DNA hybridization value with the closest type strain was 29.90 %. The DNA G+C content of strain IM1T was 63.3 mol% and the major cellular fatty acids were C16 : 0 (39.0 %), C16 : 1 ω7c (24.0 %), C16 : 1 ω6c (13.6 %) and C16 : 1 ω5c (12.0 %). The major ubiquinone was methylene-ubiquinone-8. On the basis of phenotypic, genetic and phylogenetic data, strain IM1T represents a novel species of the genus Methylococcus for which the name Methylococcus geothermalis sp. nov. is proposed, with strain IM1T (=JCM 33941T=KCTC 72677T) as the type strain.

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Section: Isolation and Cultivationmentioning

confidence: 99%

Methylococcus geothermalis sp. nov., a methanotroph isolated from a geothermal field in the Republic of Korea

Awala

Bellosillo

Gwak

et al. 2020

International Journal of Systematic and Evolutionary Microbiology

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“…KS41 of the Methylobacter clade 2 (see Fig. 3) but the phylogeny is not well supported (58% bootstrap support) similarly to what was observed previously by Nguyen et al (2018). OTU LL-pmoA-1 is not identical to the pmoA gene coding sequence retrieved from the MAG bin-63, but as this OTU represented 97% of the total pmoA gene sequences in the sample from which the metagenome was obtained, it is likely that both the pmoA of MAG bin-63 and the OTU LL-pmoA-1 are the same.…”

Section: Methylobacter Species Metagenomic Analysissupporting

confidence: 81%

Microorganisms and electron acceptors affecting methane oxidation in freshwater and marine systems

Grinsven¹

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Water column stratification is one of the main factors determining electron acceptor availability. In a well-mixed water column, water masses, particulate and dissolved matter and gasses can move freely through the water column, resulting in homogeneous temperature, nutrient, oxygen and other gas concentration profiles, as is illustrated in Fig. 3. Stratified systems, by contrast, consist of two or more layers separated by a steep gradient in temperature or dissolved substances, which limits vertical transport of water, particles and gasses (Fig. 3). The diffusion of atmospheric gasses such as oxygen is limited to the upper water layer, whilst gasses that diffuse from the sediment, such as methane, get trapped in the bottom water layer. The bottom water layer can become oxygen depleted, creating an oxygen gradient within the water column with distinct niches for aerobic and anaerobic microorganisms, including methane producers and oxidizers. Stratification can occur seasonally, as is observed in many lakes, or be permanent, like in the Black Sea. The microbial community within the anoxic zone of the Black Sea is highly adapted to the permanently anoxic conditions (Deuser, 1971). In seasonally stratified systems, however, microorganisms that are able to adapt to the changing conditions may have a competitive advantage, e.g. facultative anaerobes and fast-growing microorganisms. tion of a seasonally stratified aquatic system. In the mixed situation (left side), the water column is homogeneous and well-mixed. The oxic-anoxic interface is located in the sediment. In the stratified situation (right side), two or more water masses exist, separated by an area that is characterized by a steep oxygen gradient, called the oxycline, which forms the oxic-anoxic interface. Methane is produced by methanogenic microorganisms (i.e. archaea) in the anoxic sediments (1), where it may partly already be oxidized. The remaining methane diffuses into the water column, both in the mixed and stratified situation. In the stratified situation, methane may also be produced in the anoxic water column. In the mixed situation, the dissolved, diffused methane that escaped sedimentary methane oxidation can be transported through the whole water column (2), and will reach the surface waters, from where it can be emitted to the atmosphere (3). Water column methane oxidation in the oxic, mixed situation is generally considered to be inhibited by high oxygen concentrations. In the stratified water column, the oxycline acts as a barrier for the dissolved methane, limiting diffusion and trapping methane in the bottom water layer, resulting in an increase in methane concentration over time (4). Methane may be oxidized in the anoxic water column or at the oxycline, or can be released when mixing of the water layers occurs, ending stratification. Microorganisms involved in methane consumption Methane oxidizing bacteria Methane oxidizing organisms were first detected in 1906 by N.L. Söhngen (Söhngen, 1906). In 1970, Whittenbury, Phillips, and Wilkinson c...

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“…The remaining imbalanced reactions were stoichiometrically inaccurate and required the atoms on both sides of the reaction equation to be balanced. The metabolites consumed and produced by models were established by referring to literature and known transporter information (Boden et al, 2011;Caspi et al, 2016;Elbourne et al, 2017;Henry et al, 2010;Kanehisa, 2008;Nguyen et al, 2018;Orata, Kits & Stein, 2018;Svenning et al, 2011;Szklarczyk et al, 2017;UniProt Consortium, 2018;Wartiainen et al, 2006).…”

Section: Metabolic Model Curationmentioning

confidence: 99%

“…Metabolic pathways and individual reactions that are fundamental to the growth of these organisms such as the ribulose monophosphate pathway, pentose phosphate pathway, methane metabolism, amino acid synthesis and utilization, serine cycle, and Coenzyme B12 biosynthesis were manually scrutinized and then integrated into the models. The metabolites exchanged by the two species models were established by referring to literature and known transporter information (Boden et al, 2011;Caspi et al, 2016;Elbourne et al, 2017;Henry et al, 2010;Kanehisa, 2008;Nguyen et al, 2018;Orata, Kits & Stein, 2018;Svenning et al, 2011;Szklarczyk et al, 2017;UniProt Consortium, 2018;Wartiainen et al, 2006). The curated models of Methylobacter (704 genes, 1,329 metabolites, and 1,404 reactions) and Methylomonas (658 genes, 1,378 metabolites, and 1,391 reactions) were then utilized to develop a community model using a multi-level optimization framework, which was used to estimate biologically feasible metabolite secretion profiles and community compositions (Zomorrodi & Maranas, 2012;Zomorrodi, Islam & Maranas, 2014;Islam et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Investigation of microbial community interactions between Lake Washington methanotrophs using genome-scale metabolic modeling

Islam

Daggumati

et al. 2020

PeerJ

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Background The role of methane in global warming has become paramount to the environment and the human society, especially in the past few decades. Methane cycling microbial communities play an important role in the global methane cycle, which is why the characterization of these communities is critical to understand and manipulate their behavior. Methanotrophs are a major player in these communities and are able to oxidize methane as their primary carbon source. Results Lake Washington is a freshwater lake characterized by a methane-oxygen countergradient that contains a methane cycling microbial community. Methanotrophs are a major part of this community involved in assimilating methane from lake water. Two significant methanotrophic species in this community are Methylobacter and Methylomonas. In this work, these methanotrophs are computationally studied via developing highly curated genome-scale metabolic models. Each model was then integrated to form a community model with a multi-level optimization framework. The competitive and mutualistic metabolic interactions among Methylobacter and Methylomonas were also characterized. The community model was next tested under carbon, oxygen, and nitrogen limited conditions in addition to a nutrient-rich condition to observe the systematic shifts in the internal metabolic pathways and extracellular metabolite exchanges. Each condition showed variations in the methane oxidation pathway, pyruvate metabolism, and the TCA cycle as well as the excretion of formaldehyde and carbon di-oxide in the community. Finally, the community model was simulated under fixed ratios of these two members to reflect the opposing behavior in the two-member synthetic community and in sediment-incubated communities. The community simulations predicted a noticeable switch in intracellular carbon metabolism and formaldehyde transfer between community members in sediment-incubated vs. synthetic condition. Conclusion In this work, we attempted to predict the response of a simplified methane cycling microbial community from Lake Washington to varying environments and also provide an insight into the difference of dynamics in sediment-incubated microcosm community and synthetic co-cultures. Overall, this study lays the ground for in silico systems-level studies of freshwater lake ecosystems, which can drive future efforts of understanding, engineering, and modifying these communities for dealing with global warming issues.

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Genomic Insights Into the Acid Adaptation of Novel Methanotrophs Enriched From Acidic Forest Soils

Cited by 24 publications

References 126 publications

Methylococcus geothermalis sp. nov., a methanotroph isolated from a geothermal field in the Republic of Korea

Methylococcus geothermalis sp. nov., a methanotroph isolated from a geothermal field in the Republic of Korea

Microorganisms and electron acceptors affecting methane oxidation in freshwater and marine systems

Investigation of microbial community interactions between Lake Washington methanotrophs using genome-scale metabolic modeling

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Genomic Insights Into the Acid Adaptation of Novel Methanotrophs Enriched From Acidic Forest Soils

Cited by 24 publications

References 126 publications

Methylococcus geothermalis sp. nov., a methanotroph isolated from a geothermal field in the Republic of Korea

Methylococcus geothermalis sp. nov., a methanotroph isolated from a geothermal field in the Republic of Korea

Microorganisms and electron acceptors affecting methane oxidation in freshwater and marine systems

Investigation of microbial community interactions between Lake Washington methanotrophs using ­­­­­­­genome-scale metabolic modeling

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Investigation of microbial community interactions between Lake Washington methanotrophs using genome-scale metabolic modeling