Your search keyword '"Chemoautotrophic Growth"' showing total 847 results

1. The diversity and evolution of microbial dissimilatory phosphite oxidation

Author

Ewens, Sophia D, Gomberg, Alexa FS, Barnum, Tyler P, Borton, Mikayla A, Carlson, Hans K, Wrighton, Kelly C, and Coates, John D

Subjects

Microbiology, Biological Sciences, Anaerobiosis, Bacteria, Bacterial Proteins, Biodiversity, Carbon Dioxide, Chemoautotrophic Growth, Energy Metabolism, Evolution, Molecular, Genetic Variation, Genome, Bacterial, Microbiota, Oxidation-Reduction, Phosphites, Phylogeny, Wastewater, CO2 fixation, phosphite, glycine reductive pathway, Desulfotignum, Phosphitivorax

Abstract

Phosphite is the most energetically favorable chemotrophic electron donor known, with a half-cell potential (Eo') of -650 mV for the PO43-/PO33- couple. Since the discovery of microbial dissimilatory phosphite oxidation (DPO) in 2000, the environmental distribution, evolution, and diversity of DPO microorganisms (DPOMs) have remained enigmatic, as only two species have been identified. Here, metagenomic sequencing of phosphite-enriched microbial communities enabled the genome reconstruction and metabolic characterization of 21 additional DPOMs. These DPOMs spanned six classes of bacteria, including the Negativicutes, Desulfotomaculia, Synergistia, Syntrophia, Desulfobacteria, and Desulfomonilia_A Comparing the DPO genes from the genomes of enriched organisms with over 17,000 publicly available metagenomes revealed the global existence of this metabolism in diverse anoxic environments, including wastewaters, sediments, and subsurface aquifers. Despite their newfound environmental and taxonomic diversity, metagenomic analyses suggested that the typical DPOM is a chemolithoautotroph that occupies low-oxygen environments and specializes in phosphite oxidation coupled to CO2 reduction. Phylogenetic analyses indicated that the DPO genes form a highly conserved cluster that likely has ancient origins predating the split of monoderm and diderm bacteria. By coupling microbial cultivation strategies with metagenomics, these studies highlighted the unsampled metabolic versatility latent in microbial communities. We have uncovered the unexpected prevalence, diversity, biochemical specialization, and ancient origins of a unique metabolism central to the redox cycling of phosphorus, a primary nutrient on Earth.

Published

2021

2. Metabolic dependencies govern microbial syntrophies during methanogenesis in an anaerobic digestion ecosystem.

Author

Zhu, Xinyu, Campanaro, Stefano, Treu, Laura, Seshadri, Rekha, Ivanova, Natalia, Kougias, Panagiotis G, Kyrpides, Nikos, and Angelidaki, Irini

Subjects

Bacteria, Methanosarcina, Hydrogen, Acetates, Methane, Gene Expression Profiling, Bioreactors, Ecosystem, Anaerobiosis, Chemoautotrophic Growth, Metabolic Networks and Pathways, Metagenomics, Microbiota, Anaerobic digestion, Auxotrophies, Glycine cleavage, Metatranscriptomics, Methanogenic pathways, Microbial community, Syntrophic acetate oxidation, Ecology, Microbiology, Medical Microbiology

Abstract

Methanogenesis, a biological process mediated by complex microbial communities, has attracted great attention due to its contribution to global warming and potential in biotechnological applications. The current study unveiled the core microbial methanogenic metabolisms in anaerobic vessel ecosystems by applying combined genome-centric metagenomics and metatranscriptomics. Here, we demonstrate that an enriched natural system, fueled only with acetate, could support a bacteria-dominated microbiota employing a multi-trophic methanogenic process. Moreover, significant changes, in terms of microbial structure and function, were recorded after the system was supplemented with additional H2. Methanosarcina thermophila, the predominant methanogen prior to H2 addition, simultaneously performed acetoclastic, hydrogenotrophic, and methylotrophic methanogenesis. The methanogenic pattern changed after the addition of H2, which immediately stimulated Methanomicrobia-activity and was followed by a slow enrichment of Methanobacteria members. Interestingly, the essential genes involved in the Wood-Ljungdahl pathway were not expressed in bacterial members. The high expression of a glycine cleavage system indicated the activation of alternative metabolic pathways for acetate metabolism, which were reconstructed in the most abundant bacterial genomes. Moreover, as evidenced by predicted auxotrophies, we propose that specific microbes of the community were forming symbiotic relationships, thus reducing the biosynthetic burden of individual members. These results provide new information that will facilitate future microbial ecology studies of interspecies competition and symbiosis in methanogenic niches. Video abstract.

Published

2020

3. Genomic inference of the metabolism and evolution of the archaeal phylum Aigarchaeota.

Author

Hua, Zheng-Shuang, Qu, Yan-Ni, Zhu, Qiyun, Zhou, En-Min, Qi, Yan-Ling, Yin, Yi-Rui, Rao, Yang-Zhi, Tian, Ye, Li, Yu-Xian, Liu, Lan, Castelle, Cindy J, Hedlund, Brian P, Shu, Wen-Sheng, Knight, Rob, and Li, Wen-Jun

Subjects

Archaea, Carbon Monoxide, Sulfides, Bayes Theorem, Genomics, Hot Springs, Phylogeny, Gene Transfer, Horizontal, Anaerobiosis, Oxidation-Reduction, Genome, Archaeal, China, Chemoautotrophic Growth, Metabolic Networks and Pathways, Hot Temperature, Biological Evolution

Abstract

Microbes of the phylum Aigarchaeota are widely distributed in geothermal environments, but their physiological and ecological roles are poorly understood. Here we analyze six Aigarchaeota metagenomic bins from two circumneutral hot springs in Tengchong, China, to reveal that they are either strict or facultative anaerobes, and most are chemolithotrophs that can perform sulfide oxidation. Applying comparative genomics to the Thaumarchaeota and Aigarchaeota, we find that they both originated from thermal habitats, sharing 1154 genes with their common ancestor. Horizontal gene transfer played a crucial role in shaping genetic diversity of Aigarchaeota and led to functional partitioning and ecological divergence among sympatric microbes, as several key functional innovations were endowed by Bacteria, including dissimilatory sulfite reduction and possibly carbon monoxide oxidation. Our study expands our knowledge of the possible ecological roles of the Aigarchaeota and clarifies their evolutionary relationship to their sister lineage Thaumarchaeota.

Published

2018

4. Metagenomics-guided analysis of microbial chemolithoautotrophic phosphite oxidation yields evidence of a seventh natural CO2 fixation pathway

Author

Figueroa, Israel A, Barnum, Tyler P, Somasekhar, Pranav Y, Carlström, Charlotte I, Engelbrektson, Anna L, and Coates, John D

Subjects

Genetics, Carbon Dioxide, Chemoautotrophic Growth, Deltaproteobacteria, Metagenomics, Oxidation-Reduction, Phosphites, Sewage, Wastewater, Water Microbiology, Water Purification, phosphite oxidation, carbon fixation, metagenomics, formatotrophic, reductive glycine pathway

Abstract

Dissimilatory phosphite oxidation (DPO), a microbial metabolism by which phosphite (HPO32-) is oxidized to phosphate (PO43-), is the most energetically favorable chemotrophic electron-donating process known. Only one DPO organism has been described to date, and little is known about the environmental relevance of this metabolism. In this study, we used 16S rRNA gene community analysis and genome-resolved metagenomics to characterize anaerobic wastewater treatment sludge enrichments performing DPO coupled to CO2 reduction. We identified an uncultivated DPO bacterium, Candidatus Phosphitivorax (Ca. P.) anaerolimi strain Phox-21, that belongs to candidate order GW-28 within the Deltaproteobacteria, which has no known cultured isolates. Genes for phosphite oxidation and for CO2 reduction to formate were found in the genome of Ca. P. anaerolimi, but it appears to lack any of the known natural carbon fixation pathways. These observations led us to propose a metabolic model for autotrophic growth by Ca. P. anaerolimi whereby DPO drives CO2 reduction to formate, which is then assimilated into biomass via the reductive glycine pathway.

Published

2018

5. Hydrogenimonas leucolamina sp. nov., a hydrogen- and sulphur-oxidizing mesophilic chemolithoautotroph isolated from a deep-sea hydrothermal vent chimney at the Suiyo Seamount in the Western Pacific Ocean.

Author

Hatakeyama S, Mino S, Mizobata M, Takada M, Tsuchiya J, Yamaki S, Ando Y, Sawabe T, and Takai K

Subjects

Pacific Ocean, Base Composition, Oxidation-Reduction, Chemoautotrophic Growth, Fatty Acids chemistry, Phylogeny, RNA, Ribosomal, 16S genetics, Hydrothermal Vents microbiology, Sulfur metabolism, DNA, Bacterial genetics, Hydrogen metabolism, Seawater microbiology, Sequence Analysis, DNA, Bacterial Typing Techniques

Abstract

A novel mesophilic bacterium, strain SS33 T , was isolated from a deep-sea hydrothermal vent chimney at Suiyo Seamount, Izu-Bonin Arc, Western Pacific Ocean. The cells of strain SS33 T were motile short rods with a single polar flagellum. The growth of strain SS33 T was observed at the temperature range between 33 and 55 °C (optimum growth at 45 °C), at the pH range between 5.0 and 7.1 (optimum growth at pH 6.0) and in the presence of between 2.0 and 4.5% (w/v) NaCl [optimum growth at 3.5% (w/v)]. Strain SS33 T was a facultative anaerobic chemolithoautotroph using molecular hydrogen and elemental sulphur as the sole electron donor. Nitrate, nitrous oxide, sulphate, elemental sulphur and molecular oxygen were capable of serving as the sole electron acceptor. Phylogenetic analysis based on 16S rRNA gene sequences placed strain SS33 T in the genus Hydrogenimonas belonging to the class Epsilonproteobacteria . The closely related species of strain SS33 T were Hydrogenimonas urashimensis SSM-Sur55 T (95.96%), Hydrogenimonas thermophila EP1-55-1% T (95.75%) and Hydrogenimonas cancrithermarum ISO32 T (95.24%). According to the taxonomic and physiological characteristics, it is proposed that strain SS33 T was classified into a novel species of genus Hydrogenimonas , Hydrogenimonas leucolamina sp. nov., with SS33 T (=JCM 39184 T =KCTC 25253 T ) as the type strain. Furthermore, the genome comparison of Epsilonproteobacteria revealed that their [NiFe] hydrogenase genes belonging to Group 1b could be divided into two phylogenetic lineages and suggested that the reverse gyrase gene has been lost after division to the genus Hydrogenimonas .

Published

2024

6. Thiobacillus sedimenti sp. nov., a chemolithoautotrophic sulphur-oxidizing bacterium isolated from freshwater sediment.

Author

Dai C, Zhang G, Lin W, and Luo J

Subjects

China, Fatty Acids, Genome, Bacterial, Bacterial Typing Techniques, Chemoautotrophic Growth, Sequence Analysis, DNA, Geologic Sediments microbiology, Phylogeny, Sulfur metabolism, RNA, Ribosomal, 16S genetics, Oxidation-Reduction, Thiobacillus genetics, Thiobacillus metabolism, Thiobacillus classification, Fresh Water microbiology, DNA, Bacterial genetics, Base Composition

Abstract

A sulphur-oxidizing bacterium, designated strain SCUT-2 T , was isolated from freshwater sediment collected from the Pearl River in Guangzhou, PR China. This strain was an obligate chemolithoautotroph, utilizing reduced sulphur compounds (elemental sulphur, thiosulphate, tetrathionate and sulphite) as the electron donor. Growth of strain SCUT-2 T was observed at 20-40 ℃ (optimum at 30 °C), pH 5.0-9.0 (optimum at 6.0), and NaCl concentration range of 0-9 g L -1 (optimum at 1 g L -1 ). The major cellular fatty acids were C 16:0 ω7c and cyclo-C 17:0 . The DNA G + C content of the complete genome sequence was 66.8 mol%. Phylogenetic analysis based on the 16S rRNA gene sequence showed that strain SCUT-2 T formed a lineage within the genus Thiobacillus, showing gene sequence identity of 98.0% with its closest relative Thiobacillus thioparus THI 115. The genome of strain SCUT-2 T contains multiple genes encoding sulphur-oxidizing enzymes that catalyse the oxidation of reduced sulphur compounds, partial genes that are necessary for denitrification, and the genes encoding cbb 3 -type cytochrome c oxidase, aa 3 -type cytochrome c oxidase and bd-type quinol oxidase. Facultative anaerobic growth occurs when using nitrate as the electron acceptor and thiosulphate as the electron donor. On the basis of phenotypic, chemotaxonomic, genotypic and phylogenetic analysis, strain SCUT-2 T (= GDMCC 1.4108 T  = JCM 39443 T ) is deemed to represent a novel Thiobacillus species, for which we propose the name Thiobacillus sedimenti sp. nov., (© 2024. The Author(s), under exclusive licence to Springer Nature Switzerland AG.)

Published

2024

7. A new type of carboxysomal carbonic anhydrase in sulfur chemolithoautotrophs from alkaline environments.

Author

Wieschollek J, Fuller D, Gahramanova A, Millen T, Mislay AJ, Payne RR, Walsh DP, Zhao Y, Carney M, Cross J, Kashem J, Korde R, Lacy C, Lyons N, Mason T, Torres-Betancourt K, Trapnell T, Dennison CL, Chaput D, and Scott KM

Subjects

Hydrogen-Ion Concentration, Sulfur metabolism, Chemoautotrophic Growth, Phylogeny, Carbonic Anhydrases metabolism, Carbonic Anhydrases genetics, Carbon Dioxide metabolism, Bacterial Proteins metabolism, Bacterial Proteins genetics

Abstract

Autotrophic bacteria are able to fix CO 2 in a great diversity of habitats, even though this dissolved gas is relatively scarce at neutral pH and above. As many of these bacteria rely on CO 2 fixation by ribulose 1,5-bisphospate carboxylase/oxygenase (RubisCO) for biomass generation, they must compensate for the catalytical constraints of this enzyme with CO 2 -concentrating mechanisms (CCMs). CCMs consist of CO 2 and HCO 3 - transporters and carboxysomes. Carboxysomes encapsulate RubisCO and carbonic anhydrase (CA) within a protein shell and are essential for the operation of a CCM in autotrophic Bacteria that use the Calvin-Benson-Basham cycle. Members of the genus Thiomicrospira lack genes homologous to those encoding previously described CA, and prior to this work, the mechanism of function for their carboxysomes was unclear. In this paper, we provide evidence that a member of the recently discovered iota family of carbonic anhydrase enzymes (ιCA) plays a role in CO 2 fixation by carboxysomes from members of Thiomicrospira and potentially other Bacteria . Carboxysome enrichments from Thiomicrospira pelophila and Thiomicrospira aerophila were found to have CA activity and contain ιCA, which is encoded in their carboxysome loci. When the gene encoding ιCA was interrupted in T. pelophila , cells could no longer grow under low-CO 2 conditions, and CA activity was no longer detectable in their carboxysomes. When T. pelophila ιCA was expressed in a strain of Escherichia coli lacking native CA activity, this strain recovered an ability to grow under low CO 2 conditions, and CA activity was present in crude cell extracts prepared from this strain., Importance: Here, we provide evidence that iota carbonic anhydrase (ιCA) plays a role in CO 2 fixation by some organisms with CO 2 -concentrating mechanisms; this is the first time that ιCA has been detected in carboxysomes. While ιCA genes have been previously described in other members of bacteria, this is the first description of a physiological role for this type of carbonic anhydrase in this domain. Given its distribution in alkaliphilic autotrophic bacteria, ιCA may provide an advantage to organisms growing at high pH values and could be helpful for engineering autotrophic organisms to synthesize compounds of industrial interest under alkaline conditions., Competing Interests: The authors declare no conflict of interest.

Published

2024

8. Novel isolates of hydrogen-oxidizing chemolithoautotrophic Sulfurospirillum provide insight to the functions and adaptation mechanisms of Campylobacteria in shallow-water hydrothermal vents.

Author

Wang L, Cheng X, Guo Y, Cao J, Sun M, Hwang J-S, Liu R, and Fang J

Subjects

Genome, Bacterial genetics, Phylogeny, Adaptation, Physiological, Chemoautotrophic Growth, Hydrothermal Vents microbiology, Oxidation-Reduction, Hydrogen metabolism, Epsilonproteobacteria genetics, Epsilonproteobacteria isolation & purification, Epsilonproteobacteria metabolism, Epsilonproteobacteria classification

Abstract

Enhancing the availability of representative isolates from hydrothermal vents (HTVs) is imperative for comprehending the microbial processes that propel the vent ecosystem. In recent years, Campylobacteria have emerged as the predominant and ubiquitous taxon across both shallow and deep-sea vent systems. Nevertheless, only a few isolates have been cultured, primarily originating from deep-sea HTVs. Presently, no cultivable isolates of Campylobacteria are accessible in shallow water vent systems (<200 m), which exhibit markedly distinct environmental conditions from their deep-sea counterparts. In this study, we enriched a novel isolate (genus Sulfurospirillum , Campylobacteria) from shallow-water HTVs of Kueishan Island. Genomic and physiological analysis revealed that this novel Campylobacteria species grows on a variety of substrate and carbon/energy sources. The pan-genome and phenotypic comparisons with 12 previously isolated Sulfurospirillum species from different environments supported the identification of functional features in Sulfurospirillum genomes crucial for adaptation to vent environments, such as sulfur oxidation, carbon fixation, biofilm formation, and benzoate/toluene degradation, as well as diverse genes related with signal transportation. To conclude, the metabolic characteristics of this novel Campylobacteria augment our understanding of Campylobacteria spanning from deep-sea to shallow-water vent systems.IMPORTANCECampylobacteria emerge as the dominant and ubiquitous taxa within vent systems, playing important roles in the vent ecosystems. However, isolated representatives of Campylobacteria have been mainly from the deep-sea hydrothermal fields, leaving a significant knowledge gap regarding the functions, activities, and adaptation strategies of the vent microorganisms in shallow-water hydrothermal vents (HTVs). This study bridges this gap by providing insights into the phenomics and genomic diversity of genus Sulfurospirillum (order Campylobacterales, class Campylobacteria) based on data derived from a novel isolate obtained from shallow-water HTVs. Our mesophilic isolate of Sulfurospirillum not only augments the genus diversity of Campylobacteria pure cultures derived from vent systems but also serves as the inaugural reference isolate for Campylobacteria in shallow-water environments., Competing Interests: The authors declare no conflict of interest.

Published

2024

9. Nitrosotalea devaniterrae gen. nov., sp. nov. and Nitrosotalea sinensis sp. nov., two acidophilic ammonia oxidising archaea isolated from acidic soil, and proposal of the new order Nitrosotaleales ord. nov. within the class Nitrososphaeria of the phylum Nitrososphaerota .

Author

Lehtovirta-Morley LE, Ge C, Ross J, Yao H, Hazard C, Gubry-Rangin C, Prosser JI, and Nicol GW

Subjects

China, Archaea classification, Archaea genetics, Archaea isolation & purification, Hydrogen-Ion Concentration, Nitrites metabolism, Chemoautotrophic Growth, Soil Microbiology, Phylogeny, Base Composition, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Ammonia metabolism, DNA, Archaeal genetics, Oxidation-Reduction

Abstract

Two obligately acidophilic, mesophilic and aerobic soil ammonia-oxidising archaea were isolated from a pH 4.5 arable sandy loam (UK) and pH 4.7 acidic sulphate paddy soil (PR China) and designated strains Nd1 T and Nd2 T , respectively. The strains shared more than 99 % 16S rRNA gene sequence identity and their genomes were both less than 2 Mb in length, sharing 79 % average nucleotide identity, 81 % average amino acid identity and a DNA G+C content of approximately 37 mol%. Both strains were chemolithotrophs that fixed carbon dioxide and gained energy by oxidising ammonia to nitrite, with no evidence of mixotrophic growth. Neither strain was capable of using urea as a source of ammonia. Both strains were non-motile in culture, although Nd1 T does possess genes encoding flagella components and therefore may be motile under certain conditions. Cells of Nd1 T were small angular rods 0.5-1 µm in length and grew at pH 4.2-5.6 and at 20-30 °C. Cells of Nd1 T were small angular rods 0.5-1 µm in length and grew at pH 4.0-6.1 and at 20-42 °C. Nd1 T and Nd2 T are distinct with respect to genomic and physiological features and are assigned as the type strains for the species Nitrosotalea devaniterrae sp. nov. (type strain, Nd1 T =NCIMB 15248 T =DSM 110862 T ) and Nitrosotalea sinensis sp. nov. (type strain, Nd2 T =NCIMB 15249 T =DSM 110863 T ), respectively, within the genus Nitrosotalea gen. nov. The family Nitrosotaleaceae fam. nov. and order Nitrosotaleales ord. nov. are also proposed officially.

Published

2024

10. Contribution of ammonia oxidation to chemoautotrophy in Antarctic coastal waters

Author

Tolar, Bradley B, Ross, Meredith J, Wallsgrove, Natalie J, Liu, Qian, Aluwihare, Lihini I, Popp, Brian N, and Hollibaugh, James T

Subjects

Microbiology, Biological Sciences, Ecology, Ammonia, Antarctic Regions, Archaea, Chemoautotrophic Growth, Genes, Archaeal, Nitrification, Oceans and Seas, Oxidation-Reduction, Oxidoreductases, Phylogeny, Seasons, Seawater, Environmental Sciences, Technology, Biological sciences, Environmental sciences

Abstract

There are few measurements of nitrification in polar regions, yet geochemical evidence suggests that it is significant, and chemoautotrophy supported by nitrification has been suggested as an important contribution to prokaryotic production during the polar winter. This study reports seasonal ammonia oxidation (AO) rates, gene and transcript abundance in continental shelf waters west of the Antarctic Peninsula, where Thaumarchaeota strongly dominate populations of ammonia-oxidizing organisms. Higher AO rates were observed in the late winter surface mixed layer compared with the same water mass sampled during summer (mean±s.e.: 62±16 versus 13±2.8 nm per day, t-test P

Published

2016

11. Metatranscriptomic evidence of pervasive and diverse chemolithoautotrophy relevant to C, S, N and Fe cycling in a shallow alluvial aquifer.

Author

Jewell, Talia NM, Karaoz, Ulas, Brodie, Eoin L, Williams, Kenneth H, and Beller, Harry R

Subjects

Gallionellaceae, Epsilonproteobacteria, Nitrates, Carbon, Sulfur, Iron, Nitrogen, Oxidation-Reduction, Chemoautotrophic Growth, Metagenome, Groundwater, Transcriptome, Microbiology, Biological Sciences, Technology, Environmental Sciences

Abstract

Groundwater ecosystems are conventionally thought to be fueled by surface-derived allochthonous organic matter and dominated by heterotrophic microbes living under often-oligotrophic conditions. However, in a 2-month study of nitrate amendment to a perennially suboxic aquifer in Rifle (CO), strain-resolved metatranscriptomic analysis revealed pervasive and diverse chemolithoautotrophic bacterial activity relevant to C, S, N and Fe cycling. Before nitrate injection, anaerobic ammonia-oxidizing (anammox) bacteria accounted for 16% of overall microbial community gene expression, whereas during the nitrate injection, two other groups of chemolithoautotrophic bacteria collectively accounted for 80% of the metatranscriptome: (1) members of the Fe(II)-oxidizing Gallionellaceae family and (2) strains of the S-oxidizing species, Sulfurimonas denitrificans. Notably, the proportion of the metatranscriptome accounted for by these three groups was considerably greater than the proportion of the metagenome coverage that they represented. Transcriptional analysis revealed some unexpected metabolic couplings, in particular, putative nitrate-dependent Fe(II) and S oxidation among nominally microaerophilic Gallionellaceae strains, including expression of periplasmic (NapAB) and membrane-bound (NarGHI) nitrate reductases. The three most active groups of chemolithoautotrophic bacteria in this study had overlapping metabolisms that allowed them to occupy different yet related metabolic niches throughout the study. Overall, these results highlight the important role that chemolithoautotrophy can have in aquifer biogeochemical cycling, a finding that has broad implications for understanding terrestrial carbon cycling and is supported by recent studies of geochemically diverse aquifers.

Published

2016

12. Metagenomic analysis of a high carbon dioxide subsurface microbial community populated by chemolithoautotrophs and bacteria and archaea from candidate phyla.

Author

Emerson, Joanne B, Thomas, Brian C, Alvarez, Walter, and Banfield, Jillian F

Subjects

Bacteria, Archaea, Carbon Dioxide, Sulfur, Biodiversity, Phylogeny, Chemoautotrophic Growth, Metagenome, Metagenomics, Carbon Cycle, Microbiology, Evolutionary Biology

Abstract

Research on geologic carbon sequestration raises questions about potential impacts of subsurface microbiota on carbon cycling and biogeochemistry. Subsurface, high-CO2 systems are poorly biologically characterized, partly because of difficulty accessing high-volume, uncontaminated samples. CO2 -driven Crystal Geyser (CG, Utah, USA), an established geologic carbon sequestration analogue, provides high volumes of deep (∼ 200-500 m) subsurface fluids. We explored microbial diversity and metabolic potential in this high-CO2 environment by assembly and analysis of metagenomes recovered from geyser water filtrate. The system is dominated by neutrophilic, iron-oxidizing bacteria, including 'marine' Mariprofundus (Zetaproteobacteria) and 'freshwater' Gallionellales, sulfur-oxidizing Thiomicrospira crunogena and Thiobacillus-like Hydrogenophilales. Near-complete genomes were reconstructed for these bacteria. CG is notably populated by a wide diversity of bacteria and archaea from phyla lacking isolated representatives (candidate phyla) and from as-yet undefined lineages. Many bacteria affiliate with OD1, OP3, OP9, PER, ACD58, WWE3, BD1-5, OP11, TM7 and ZB2. The recovery of nearly 100 genes encoding ribulose-1,5 bisphosphate carboxylase-oxygenase subunit proteins of the Calvin cycle and AMP salvage pathways suggests a strong biological role in high-CO2 subsurface carbon cycling. Overall, we predict microbial impacts on subsurface biogeochemistry via iron, sulfur, and complex carbon oxidation, carbon and nitrogen fixation, fermentation, hydrogen metabolism, and aerobic and anaerobic respiration.

Published

2016

13. Non-thermodynamic factors affect competition between thermophilic chemolithoautotrophs from deep-sea hydrothermal vents.

Author

Kubik BC and Holden JF

Subjects

Seawater microbiology, Deltaproteobacteria metabolism, Deltaproteobacteria growth & development, Methanocaldococcus metabolism, Methanocaldococcus growth & development, Methanobacteriaceae metabolism, Methanobacteriaceae growth & development, Hot Temperature, Hydrothermal Vents microbiology, Chemoautotrophic Growth, Hydrogen metabolism

Abstract

Various environmental factors, including H 2 availability, metabolic tradeoffs, optimal growth temperature, stochasticity, and hydrology, were examined to determine if they affect microbial competition between three autotrophic thermophiles. The thiosulfate reducer Desulfurobacterium thermolithotrophum ( T opt 72°C) was grown in mono- and coculture separately with the methanogens Methanocaldococcus jannaschii ( T opt 82°C) at 72°C and Methanothermococcus thermolithotrophicu s ( T opt 65°C) at 65°C at high and low H 2 concentrations. Both methanogens showed a metabolic tradeoff shifting from high growth rate-low cell yield at high H 2 concentrations to low growth rate-high cell yield at low H 2 concentrations and when grown in coculture with the thiosulfate reducer. In 1:1 initial ratios, D. thermolithotrophum outcompeted both methanogens at high and low H 2 , no H 2 S was detected on low H 2 , and it grew with only CO 2 as the electron acceptor indicating a similar metabolic tradeoff with low H 2 . When the initial methanogen-to-thiosulfate reducer ratio varied from 1:1 to 10 4 :1 with high H 2 , D. thermolithotrophum always outcompeted M. jannaschii at 72°C. However, M. thermolithotrophicus outcompeted D. thermolithotrophum at 65°C when the ratio was 10 3 :1. A reactive transport model that mixed pure hydrothermal fluid with cold seawater showed that hyperthermophilic methanogens dominated in systems where the residence time of the mixed fluid above 72°C was sufficiently high. With shorter residence times, thermophilic thiosulfate reducers dominated. If residence times increased with decreasing fluid temperature along the flow path, then thermophilic methanogens could dominate. Thermophilic methanogen dominance spread to previously thiosulfate-reducer-dominated conditions if the initial ratio of thermophilic methanogen-to-thiosulfate reducer increased., Importance: The deep subsurface is the largest reservoir of microbial biomass on Earth and serves as an analog for life on the early Earth and extraterrestrial environments. Methanogenesis and sulfur reduction are among the more common chemolithoautotrophic metabolisms found in hot anoxic hydrothermal vent environments. Competition between H2-oxidizing sulfur reducers and methanogens is primarily driven by the thermodynamic favorability of redox reactions with the former outcompeting methanogens. This study demonstrated that competition between the hydrothermal vent chemolithoautotrophs Methanocaldococcus jannaschii , Methanothermococcus thermolithotrophicus , and Desulfurobacterium thermolithotrophum is also influenced by other overlapping factors such as staggered optimal growth temperatures, stochasticity, and hydrology. By modeling all aspects of microbial competition coupled with field data, a better understanding is gained on how methanogens can outcompete thiosulfate reducers in hot anoxic environments and how the deep subsurface contributes to biogeochemical cycling., Competing Interests: The authors declare no conflict of interest.

Published

2024

14. Sealing solid agar in serum bottles for rapid isolation and long-term preservation of chemoautotrophic ammonia-oxidizing bacteria.

Author

Wu J, Zhan M, Yuan L, Zhu Y, Lin W, and Luo J

Subjects

Oxygen metabolism, Culture Media, Chemoautotrophic Growth, Agar, Ammonia metabolism, Bacteria metabolism, Oxidation-Reduction

Abstract

Ammonia-oxidizing bacteria (AOB) are ubiquitous on the earth and have broad applications in bioremediation. However, the number of their species with standing in nomenclature and deposited in Microbial Culture Collections still remains low. Moreover, only a few novel species have been reported over the last decades. In this study, we sealed agar in serum bottles to develop a kind of solid agar plate with the oxygen concentration in the headspace maintained at low levels. By using these plates, eight AOB isolates including two novel species were obtained. When AOB cells were grown on the sealed solid agar plates, the time to form visible colonies was largely reduced and the maximum diameter of colonies reached 2 mm, which makes the process of AOB isolation rapid and efficient. Based on five AOB isolates, the headspace oxygen concentration had a significant influence on AOB growth either on solid plate or in liquid culture. Especially, when grown under 21 % O 2 , the number of colonies formed on solid agar plates was very low and sometimes no visible colony formed. Besides the application on AOB isolation, the sealed solid agar plate was also effective for the enumeration and preservation of AOB cells. When preserved under room temperature for more than ten months, the AOB colonies on the plate could still be recovered. This method provides a feasible way to isolate more novel AOB species from the environment and deposit more species in Microbial Culture Collections., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Ltd. All rights reserved.)

Published

2024

15. Co-expression analysis reveals distinct alliances around two carbon fixation pathways in hydrothermal vent symbionts.

Author

Mitchell JH, Freedman AH, Delaney JA, and Girguis PR

Subjects

Animals, Oxidation-Reduction, Citric Acid Cycle, Sulfides metabolism, Gene Expression Regulation, Bacterial, Hydrogenase metabolism, Hydrogenase genetics, Chemoautotrophic Growth, Gene Expression Profiling, Nitrates metabolism, Photosynthesis, Bacteria metabolism, Bacteria genetics, Hydrothermal Vents microbiology, Carbon Cycle, Symbiosis, Polychaeta metabolism

Abstract

Most autotrophic organisms possess a single carbon fixation pathway. The chemoautotrophic symbionts of the hydrothermal vent tubeworm Riftia pachyptila, however, possess two functional pathways: the Calvin-Benson-Bassham (CBB) and the reductive tricarboxylic acid (rTCA) cycles. How these two pathways are coordinated is unknown. Here we measured net carbon fixation rates, transcriptional/metabolic responses and transcriptional co-expression patterns of Riftia pachyptila endosymbionts by incubating tubeworms collected from the East Pacific Rise at environmental pressures, temperature and geochemistry. Results showed that rTCA and CBB transcriptional patterns varied in response to different geochemical regimes and that each pathway is allied to specific metabolic processes; the rTCA is allied to hydrogenases and dissimilatory nitrate reduction, whereas the CBB is allied to sulfide oxidation and assimilatory nitrate reduction, suggesting distinctive yet complementary roles in metabolic function. Furthermore, our network analysis implicates the rTCA and a group 1e hydrogenase as key players in the physiological response to limitation of sulfide and oxygen. Net carbon fixation rates were also exemplary, and accordingly, we propose that co-activity of CBB and rTCA may be an adaptation for maintaining high carbon fixation rates, conferring a fitness advantage in dynamic vent environments., (© 2024. The Author(s).)

Published

2024

16. Rhodoferax lithotrophicus sp. nov., a neutrophilic iron-oxidizing and -reducing bacterium isolated from iron-rich freshwater sediments.

Author

Kato S, Itoh T, Iino T, Sakamoto M, and Ohkuma M

Subjects

Japan, Fresh Water microbiology, Base Composition, Wetlands, Chemoautotrophic Growth, Phylogeny, RNA, Ribosomal, 16S genetics, Fatty Acids, Iron metabolism, Geologic Sediments microbiology, DNA, Bacterial genetics, Sequence Analysis, DNA, Bacterial Typing Techniques, Oxidation-Reduction

Abstract

A neutrophilic iron-oxidizing and -reducing bacterium, strain MIZ03 T , was previously isolated from a wetland in Ibaraki, Japan. Here, we report the detailed characteristics of this strain. It was motile with a single polar flagellum, and Gram-stain-negative. It could grow not only chemolithoautotrophically but also chemoorganotrophically by aerobic respiration and fermentation. Major cellular fatty acids were C 16 : 1  ω 7 c /C 16 : 1  ω 6 c , and C 16 : 0 . Phylogenetic analyses indicated that strain MIZ03 T belonged to the genus Rhodoferax . This strain was closely related to Rhodoferax ferrireducens with 98.5 % of 16S rRNA gene sequence similarity. Based on its phenotypic and genomic based characteristics, we conclude that strain MIZ03 T represents a new species in the genus Rhodoferax . We propose the name Rhodoferax lithotrophicus sp. nov. to accommodate this strain. The type strain is MIZ03 T (=JCM 34246 T =DSM 113266 T ). We also propose the name Rhodoferax koreensis sp. nov., of which the type strain is DCY110 T (=KCTC 52288 T =JCM 31441 T ), for the effectively, but not yet validly, published name ' Rhodoferax koreense '.

Published

2024

17. Comparative proteomics of a versatile, marine, iron-oxidizing chemolithoautotroph.

Author

Barco RA, Merino N, Lam B, Budnik B, Kaplan M, Wu F, Amend JP, Nealson KH, and Emerson D

Subjects

Chemoautotrophic Growth, Multigene Family, Gene Expression Regulation, Bacterial, Seawater microbiology, Oxidation-Reduction, Iron metabolism, Proteomics, Bacterial Proteins genetics, Bacterial Proteins metabolism

Abstract

This study conducted a comparative proteomic analysis to identify potential genetic markers for the biological function of chemolithoautotrophic iron oxidation in the marine bacterium Ghiorsea bivora. To date, this is the only characterized species in the class Zetaproteobacteria that is not an obligate iron-oxidizer, providing a unique opportunity to investigate differential protein expression to identify key genes involved in iron-oxidation at circumneutral pH. Over 1000 proteins were identified under both iron- and hydrogen-oxidizing conditions, with differentially expressed proteins found in both treatments. Notably, a gene cluster upregulated during iron oxidation was identified. This cluster contains genes encoding for cytochromes that share sequence similarity with the known iron-oxidase, Cyc2. Interestingly, these cytochromes, conserved in both Bacteria and Archaea, do not exhibit the typical β-barrel structure of Cyc2. This cluster potentially encodes a biological nanowire-like transmembrane complex containing multiple redox proteins spanning the inner membrane, periplasm, outer membrane, and extracellular space. The upregulation of key genes associated with this complex during iron-oxidizing conditions was confirmed by quantitative reverse transcription-PCR. These findings were further supported by electromicrobiological methods, which demonstrated negative current production by G. bivora in a three-electrode system poised at a cathodic potential. This research provides significant insights into the biological function of chemolithoautotrophic iron oxidation., (© 2024 The Authors. Environmental Microbiology published by John Wiley & Sons Ltd.)

Published

2024

18. A comprehensive review of flue gas bio-mitigation: chemolithotrophic interactions with flue gas in bio-reactors as a sustainable possibility for technological advancements.

Author

Barla RJ, Raghuvanshi S, and Gupta S

Subjects

Air Pollutants, Chemoautotrophic Growth, Gases, Bioreactors, Air Pollution

Abstract

Flue gas mitigation technologies aim to reduce the environmental impact of flue gas emissions, particularly from industrial processes and power plants. One approach to mitigate flue gas emissions involves bio-mitigation, which utilizes microorganisms to convert harmful gases into less harmful or inert substances. The review thus explores the bio-mitigation efficiency of chemolithotrophic interactions with flue gas and their potential application in bio-reactors. Chemolithotrophs are microorganisms that can derive energy from inorganic compounds, such as carbon dioxide (CO 2 ), nitrogen oxides (NO x ), and sulfur dioxide (SO 2 ), present in the flue gas. These microorganisms utilize specialized enzymatic pathways to oxidize these compounds and produce energy. By harnessing the metabolic capabilities of chemolithotrophs, flue gas emissions can be transformed into value-added products. Bio-reactors provide controlled environments for the growth and activity of chemolithotrophic microorganisms. Depending on the specific application, these can be designed as suspended or immobilized reactor systems. The choice of bio-reactor configuration depends on process efficiency, scalability, and ease of operation. Factors influencing the bio-mitigation efficiency of chemolithotrophic interactions include the concentration and composition of the flue gas, operating conditions (such as temperature, pH, and nutrient availability), and reactor design. Chemolithotrophic interactions with flue gas in bio-reactors offer a potentially efficient approach to mitigating flue gas emissions. Continued research and development in this field are necessary to optimize reactor design, microbial consortia, and operating conditions. Advances in understanding the metabolism and physiology of chemolithotrophic microorganisms will contribute to developing robust and scalable bio-mitigation technologies for flue gas emissions., (© 2024. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2024

19. Acidithiobacillus acidisediminis sp. nov., an acidophilic sulphur-oxidizing chemolithotroph isolated from acid mine drainage sediment.

Author

Li XT, Liang ZL, Huang Y, Jiang Z, Yang ZN, Zhou N, Liu Y, Liu SJ, and Jiang CY

Subjects

China, Oxidation-Reduction, Chemoautotrophic Growth, Ubiquinone, Copper metabolism, RNA, Ribosomal, 16S genetics, Phylogeny, Mining, Base Composition, Sulfur metabolism, DNA, Bacterial genetics, Fatty Acids analysis, Geologic Sediments microbiology, Bacterial Typing Techniques, Acidithiobacillus classification, Acidithiobacillus genetics, Acidithiobacillus isolation & purification, Nucleic Acid Hybridization, Sequence Analysis, DNA

Abstract

Strain S30A2 T , isolated from the acid mine drainage sediment of Mengzi Copper Mine, Yunnan, is proposed to represent a novel species of the sulphur-oxidizing genus Acidithiobacillus . Cells were Gram-stain-negative, non-endospore forming, highly motile with one or two monopolar flagella and rod-shaped. The strain was mesophilic, growing at 30-50 °C (optimum, 38 °C), acidophilic, growing at pH 2.0-4.5 (optimum, pH 2.5), and tolerant of 0-4 % (w/v; 684 mol l -1 ) NaCl. The 16S rRNA gene-based sequence analysis showed that strain S30A2 T belongs to the genus Acidithiobacillus and shows the largest similarity of 96.6 % to the type strain Acidithiobacillus caldus KU T . The genomic DNA G+C content of strain S30A2 T was 59.25 mol%. The average nucleotide identity ANIb and ANIm values between strain S30A2 T and A. caldus KU T were 70.95 and 89.78 %, respectively and the digital DNA-DNA hybridization value was 24.9 %. Strain S30A2 T was strictly aerobic and could utilize elementary sulphur and tetrathionate to support chemolithotrophic growth. The major cellular fatty acid of S30A2 T was C 19 : 1 ω7 c . The respiratory quinones were ubiquinone-8 and ubiquinone-7. Based upon its phylogenetic, genetic, phenotypic, physiologic and chemotaxonomic characteristics, strain S30A2 T is considered to represent a novel species of the genus Acidithiobacillus , for which the name Acidithiobacillus acidisediminis sp. nov. is proposed. The type strain is S30A2 T (=CGMCC 1.17059 T =KCTC 72580 T ).

Published

2024

20. Quantifying genome-specific carbon fixation in a 750-meter deep subsurface hydrothermal microbial community.

Author

Coskun ÖK, Gomez-Saez GV, Beren M, Özcan D, Günay SD, Elkin V, Hoşgörmez H, Einsiedl F, Eisenreich W, and Orsi WD

Subjects

Bacteria genetics, Bacteria metabolism, Bacteria classification, Carbon metabolism, Hydrothermal Vents microbiology, Groundwater microbiology, Chemoautotrophic Growth, Archaea genetics, Archaea metabolism, Carbon Cycle, Bicarbonates metabolism, Microbiota, Carbon Isotopes metabolism, Metagenome

Abstract

Dissolved inorganic carbon has been hypothesized to stimulate microbial chemoautotrophic activity as a biological sink in the carbon cycle of deep subsurface environments. Here, we tested this hypothesis using quantitative DNA stable isotope probing of metagenome-assembled genomes (MAGs) at multiple 13C-labeled bicarbonate concentrations in hydrothermal fluids from a 750-m deep subsurface aquifer in the Biga Peninsula (Turkey). The diversity of microbial populations assimilating 13C-labeled bicarbonate was significantly different at higher bicarbonate concentrations, and could be linked to four separate carbon-fixation pathways encoded within 13C-labeled MAGs. Microbial populations encoding the Calvin-Benson-Bassham cycle had the highest contribution to carbon fixation across all bicarbonate concentrations tested, spanning 1-10 mM. However, out of all the active carbon-fixation pathways detected, MAGs affiliated with the phylum Aquificae encoding the reverse tricarboxylic acid (rTCA) pathway were the only microbial populations that exhibited an increased 13C-bicarbonate assimilation under increasing bicarbonate concentrations. Our study provides the first experimental data supporting predictions that increased bicarbonate concentrations may promote chemoautotrophy via the rTCA cycle and its biological sink for deep subsurface inorganic carbon., (© The Author(s) 2024. Published by Oxford University Press on behalf of FEMS.)

Published

2024

21. Metagenome of a Versatile Chemolithoautotroph from Expanding Oceanic Dead Zones

Author

Walsh, David A.

Subjects

Basic biological sciences, Biomass, British Columbia, Carbon/metabolism, Chemoautotrophic Growth, Ecosystem, Energy Metabolism, Gammaproteobacteria/genetics, Gammaproteobacteria/metabolism, Gammaproteobacteria/physiology, Genes, rRNA, Genome, Bacterial, Metagenome, Molecular Sequence Data, Nitrates/metabolism, Oxidation-Reduction, Oxygen/analysis, Pacific Ocean, Phylogeny, Seasons, Seawater/chemistry, Seawater/microbiology, Sulfur/metabolism, Symbiosis

Abstract

Oxygen minimum zones (OMZs), also known as oceanic "dead zones", are widespread oceanographic features currently expanding due to global warming and coastal eutrophication. Although inhospitable to metazoan life, OMZs support a thriving but cryptic microbiota whose combined metabolic activity is intimately connected to nutrient and trace gas cycling within the global ocean. Here we report time-resolved metagenomic analyses of a ubiquitous and abundant but uncultivated OMZ microbe (SUP05) closely related to chemoautotrophic gill symbionts of deep-sea clams and mussels. The SUP05 metagenome harbors a versatile repertoire of genes mediating autotrophic carbon assimilation, sulfur-oxidation and nitrate respiration responsive to a wide range of water column redox states. Thus, SUP05 plays integral roles in shaping nutrient and energy flow within oxygen-deficient oceanic waters via carbon sequestration, sulfide detoxification and biological nitrogen loss with important implications for marine productivity and atmospheric greenhouse control.

Published

2009

22. Oxidation of sulfur, hydrogen, and iron by metabolically versatile Hydrogenovibrio from deep sea hydrothermal vents.

Author

Laufer-Meiser K, Alawi M, Böhnke S, Solterbeck CH, Schloesser J, Schippers A, Dirksen P, Brüser T, Henkel S, Fuss J, and Perner M

Subjects

Carbon Dioxide metabolism, Seawater microbiology, Piscirickettsiaceae genetics, Piscirickettsiaceae metabolism, Chemoautotrophic Growth, Oxidation-Reduction, Hydrogen metabolism, Iron metabolism, Hydrothermal Vents microbiology, Sulfur metabolism

Abstract

Chemolithoautotrophic Hydrogenovibrio are ubiquitous and abundant at hydrothermal vents. They can oxidize sulfur, hydrogen, or iron, but none are known to use all three energy sources. This ability though would be advantageous in vents hallmarked by highly dynamic environmental conditions. We isolated three Hydrogenovibrio strains from vents along the Indian Ridge, which grow on all three electron donors. We present transcriptomic data from strains grown on iron, hydrogen, or thiosulfate with respective oxidation and autotrophic carbon dioxide (CO2) fixation rates, RubisCO activity, SEM, and EDX. Maximum estimates of one strain's oxidation potential were 10, 24, and 952 mmol for iron, hydrogen, and thiosulfate oxidation and 0.3, 1, and 84 mmol CO2 fixation, respectively, per vent per hour indicating their relevance for element cycling in-situ. Several genes were up- or downregulated depending on the inorganic electron donor provided. Although no known genes of iron-oxidation were detected, upregulated transcripts suggested iron-acquisition and so far unknown iron-oxidation-pathways., (© The Author(s) 2024. Published by Oxford University Press on behalf of the International Society for Microbial Ecology.)

Published

2024

23. Bacterial chemolithoautotrophy in ultramafic plumes along the Mid-Atlantic Ridge.

Author

Dede B, Reeves EP, Walter M, Bach W, Amann R, and Meyerdierks A

Subjects

Atlantic Ocean, Microbiota, Hydrogen metabolism, Phylogeny, Sulfur metabolism, Oxidation-Reduction, In Situ Hybridization, Fluorescence, Carbon Dioxide metabolism, Hydrothermal Vents microbiology, RNA, Ribosomal, 16S genetics, Bacteria genetics, Bacteria classification, Bacteria isolation & purification, Chemoautotrophic Growth, Seawater microbiology

Abstract

Hydrothermal vent systems release reduced chemical compounds that act as an important energy source in the deep sea. Chemolithoautotrophic microbes inhabiting hydrothermal plumes oxidize these compounds, in particular, hydrogen and reduced sulfur, to obtain the energy required for CO2 fixation. Here, we analysed the planktonic communities of four hydrothermal systems located along the Mid-Atlantic Ridge: Irinovskoe, Semenov-2, Logatchev-1, and Ashadze-2, by combining long-read 16S rRNA gene analysis, fluorescence in situ hybridization, meta-omics, and thermodynamic calculations. Sulfurimonas and SUP05 dominated the microbial communities in these hydrothermal plumes. Investigation of Sulfurimonas and SUP05 MAGs, and their gene transcription in plumes indicated a niche partitioning driven by hydrogen and sulfur. In addition to sulfur and hydrogen oxidation, a novel SAR202 clade inhabiting the plume, here referred to as genus Carboxydicoccus, harbours the capability for CO oxidation and CO2 fixation via reverse TCA cycle. Both pathways were also highly transcribed in other hydrogen-rich plumes, including the Von Damm vent field. Carboxydicoccus profundi reached up to 4% relative abundance (1.0 x 103 cell ml- 1) in Irinovskoe non-buoyant plume and was also abundant in non-hydrothermally influenced deep-sea metagenomes (up to 5 RPKM). Therefore, CO, which is probably not sourced from the hydrothermal fluids (1.9-5.8 μM), but rather from biological activities within the rising fluid, may serve as a significant energy source in hydrothermal plumes. Taken together, this study sheds light on the chemolithoautotrophic potential of the bacterial community in Mid-Atlantic Ridge plumes., (© The Author(s) 2024. Published by Oxford University Press on behalf of the International Society for Microbial Ecology.)

Published

2024

24. Chemolithoautotrophic diazotrophs dominate dark nitrogen fixation in mangrove sediments.

Author

Wang S, Jiang L, Zhao Z, Chen Z, Wang J, Alain K, Cui L, Zhong Y, Peng Y, Lai Q, Dong X, and Shao Z

Subjects

Chemoautotrophic Growth, Nitrogenase metabolism, Nitrogenase genetics, Wetlands, Nitrogen metabolism, Sulfur metabolism, Metagenomics, Bacteria classification, Bacteria metabolism, Bacteria genetics, Bacteria isolation & purification, Nitrogen-Fixing Bacteria metabolism, Nitrogen-Fixing Bacteria genetics, Nitrogen-Fixing Bacteria classification, Nitrogen-Fixing Bacteria isolation & purification, Ecosystem, Oxidation-Reduction, Nitrogen Fixation, Geologic Sediments microbiology, Phylogeny

Abstract

Diazotrophic microorganisms regulate marine productivity by alleviating nitrogen limitation. So far chemolithoautotrophic bacteria are widely recognized as the principal diazotrophs in oligotrophic marine and terrestrial ecosystems. However, the contribution of chemolithoautotrophs to nitrogen fixation in organic-rich habitats remains unclear. Here, we utilized metagenomic and metatranscriptomic approaches integrated with cultivation assays to investigate the diversity, distribution, and activity of diazotrophs residing in Zhangzhou mangrove sediments. Physicochemical assays show that the studied mangrove sediments are typical carbon-rich, sulfur-rich, nitrogen-limited, and low-redox marine ecosystems. These sediments host a wide phylogenetic variety of nitrogenase genes, including groups I-III and VII-VIII. Unexpectedly diverse chemolithoautotrophic taxa including Campylobacteria, Gammaproteobacteria, Zetaproteobacteria, and Thermodesulfovibrionia are the predominant and active nitrogen fixers in the 0-18 cm sediment layer. In contrast, the 18-20 cm layer is dominated by active diazotrophs from the chemolithoautotrophic taxa Desulfobacterota and Halobacteriota. Further analysis of MAGs shows that the main chemolithoautotrophs can fix nitrogen by coupling the oxidation of hydrogen, reduced sulfur, and iron, with the reduction of oxygen, nitrate, and sulfur. Culture experiments further demonstrate that members of chemolithoautotrophic Campylobacteria have the nitrogen-fixing capacity driven by hydrogen and sulfur oxidation. Activity measurements confirm that the diazotrophs inhabiting mangrove sediments preferentially drain energy from diverse reduced inorganic compounds other than from organics. Overall, our results suggest that chemolithoautotrophs rather than heterotrophs are dominant nitrogen fixers in mangrove sediments. This study underscores the significance of chemolithoautotrophs in carbon-dominant ecosystems., (© The Author(s) 2024. Published by Oxford University Press on behalf of the International Society for Microbial Ecology.)

Published

2024

25. Microbially promoted calcite precipitation in the pelagic redoxcline: Elucidating the formation of the turbid layer

Author

Leberecht, Kerstin M., Ritter, Simon M., Lapp, Christian J., Klose, Lukas, Eschenröder, Julian, Scholz, Christian, Kühnel, Sebastian, Stinnesbeck, Wolfgang, Kletzin, Arnulf, Isenbeck‐Schröter, Margot, Gescher, Johannes, 1 Institute of Technical Microbiology Hamburg University of Technology Hamburg Germany, 2 Institute of Earth Sciences Heidelberg University Heidelberg Germany, 3 Department of Physics & Earth Sciences Jacobs University Bremen Bremen Germany, 5 Department of Biology, Microbiology, and Sulfur Biochemistry and Microbial Bioenergetics Technical University of Darmstadt Darmstadt Germany

Subjects

microbially induced calcite precipitation, Chemoautotrophic Growth, redoxcline, Biowissenschaften, Biologie [570], Sulfides, sulfide oxidation, chemolithoautotrophy, Calcium Carbonate, biogeochemistry, ddc:570, ddc:551.9, General Earth and Planetary Sciences, ddc:600, Technik [600], Oxidation-Reduction, Sulfur, Ecology, Evolution, Behavior and Systematics, General Environmental Science

Abstract

Large bell‐shaped calcite formations called “Hells Bells” were discovered underwater in the stratified cenote El Zapote on the Yucatán Peninsula, Mexico. Together with these extraordinary speleothems, divers found a white, cloudy turbid layer into which some Hells Bells partially extend. Here, we address the central question if the formation of the turbid layer could be based on microbial activity, more specifically, on microbially induced calcite precipitation. Metagenomic and metatranscriptomic profiling of the microbial community in the turbid layer, which overlaps with the pelagic redoxcline in the cenote, revealed chemolithoautotrophic Hydrogenophilales and unclassified β‐Proteobacteria as the metabolic key players. Bioinformatic and hydrogeochemical data suggest chemolithoautotrophic oxidation of sulfide to zero‐valent sulfur catalyzed by denitrifying organisms due to oxygen deficiency. Incomplete sulfide oxidation via nitrate reduction and chemolithoautotrophy are both proton‐consuming processes, which increase the pH in the redoxcline favoring authigenic calcite precipitation and may contribute to Hells Bells growth. The observed mechanism of microbially induced calcite precipitation is potentially applicable to many other stagnant sulfate‐rich water bodies., Deutsche Forschungsgemeinschaft http://dx.doi.org/10.13039/501100001659, CONACYT‐FONCICYT‐DADC, https://doi.org/10.11588/data/TMYLWS, https://doi.org/10.11588/data/GYLDH5

Published

2022

26. Chemoautotrophy, symbiosis and sedimented diatoms support high biomass of benthic molluscs in the Namibian shelf

Author

Amorim, K., Loick-Wilde, N., Yuen, B., Osvatic, J. T., Wäge-Recchioni, J., Hausmann, B., Petersen, J. M., Fabian, J., Wodarg, D., and Zettler, M. L.

Subjects

Diatoms, Chemoautotrophic Growth, Stable isotope analysis, Nitrates, Multidisciplinary, Nitrogen, Ecosystem ecology, Food webs, Water, Bivalvia, Element cycles, RNA, Ribosomal, 16S, Ammonium Compounds, Animals, Biomass, Molecular ecology, Symbiosis, Microbial biooceanography, Ecosystem, Gammaproteobacteria

Abstract

The molluscs Lucinoma capensis, Lembulus bicuspidatus and Nassarius vinctus are highly abundant in Namibian oxygen minimum zone sediments. To understand which nutritional strategies allow them to reach such impressive abundances in this extreme habitat we investigated their trophic diversity, including a chemosymbiosis in L. capensis, focussing on nitrogen biochemical pathways of the symbionts. We combined results of bulk nitrogen and carbon (δ13C and δ15N) and of compound-specific isotope analyses of amino acid nitrogen (AAs—δ15NPhe and δ15NGlu), with 16S rRNA gene sequencing of L. capensis tissues and also with exploratory results of ammonium, nitrate and nitrite turnover. The trophic position (TP) of the bivalve L. capensis is placed between autotrophy and mixotrophy, consistent with its proposed symbiosis with sulfur-oxidizing Candidatus Thiodiazotropha sp. symbionts. The symbionts are here revealed to perform nitrate reduction and ammonium uptake, with clear indications of ammonium host-symbionts recycling, but surprisingly unable to fix nitrogen. The TP of the bivalve L. bicuspidatus is placed in between mixotrophy and herbivory. The TP of the gastropod N. vinctus reflected omnivory. Multiple lines of evidences in combination with current ecosystem knowledge point to sedimented diatoms as important components of L. bicuspidatus and N. vinctus’ diet, likely supplemented at times with chemoautotrophic bacteria. This study highlights the importance of benthic-pelagic coupling that fosters the dietary base for macrozoobenthos in the OMZ. It further unveils that, in contrast to all shallow water lucinid symbionts, deeper water lucinid symbionts rely on ammonium assimilation rather than dinitrogen fixation to obtain nitrogen for growth.

Published

2022

27. Short- and long-term effects of copper on anammox under gradually increased copper concentrations

Author

Cigdem Kalkan Aktan, Kozet Yapsakli, and Bulent Mertoglu

Subjects

Chemoautotrophic Growth, Environmental Engineering, Nitrogen, chemistry.chemical_element, Bioengineering, 010501 environmental sciences, 01 natural sciences, Microbiology, 03 medical and health sciences, Bioreactors, Environmental Chemistry, Anaerobiosis, IC50, 0105 earth and related environmental sciences, High copper, 0303 health sciences, 030306 microbiology, Pollution, Copper, Bioavailability, Biodegradation, Environmental, chemistry, Anammox, Increased copper, Oxidation-Reduction, Intracellular, Nuclear chemistry

Abstract

This study aims to determine both short- and long-term response of enriched anammox culture to Cu. Assessment of short-term inhibition is based both on total applied Cu concentration and potential bioavailable fractions like intracellular, surface-bound, soluble and free Cu ion. The half maximal inhibitory concentration (IC50) values for total applied, soluble, intracellular and cell-associated concentrations were determined as 4.57 mg/L, 1.97 mg/L, 0.71 mg/L, 1.11 mg/L, respectively. Correlation between the surface-bound fraction of Cu and inhibition response was weak, suggesting that Cu sorbed to biomass was not directly responsible for the effects on anammox activity. There was a disparity between the results of short- and long-term experiments in terms of inhibition threshold concentration (i.e. short-term IC50 = 4.57 mg/L vs long-term IC50 = 6.74 mg/L). Candidatus Kuenenia (59.8%) and Candidatus Brocadia (40.2%) were the two main anammox genera within the initial biomass sample. One of the most interesting finding of the study is the demonstration that a complete wash-out of C. Brocadia genus at an applied Cu concentration of 6.5 mg/L. This strongly indicates that C. Brocadia were not able to tolerate high copper concentrations and all nitrogen conversion was carried out by C. Kuenenia during the Cu exposure period.

Published

2021

28. Engineering nonphotosynthetic carbon fixation for production of bioplastics by methanogenic archaea

Author

Kershanthen Thevasundaram, Joseph J. Gallagher, Freeman Cherng, and Michelle C. Y. Chang

Subjects

Chemoautotrophic Growth, Multidisciplinary, Carbon Dioxide, Euryarchaeota, Archaea, Carbon Cycle

Abstract

The conversion of CO2 to value-added products allows both capture and recycling of greenhouse gas emissions. While plants and other photosynthetic organisms play a key role in closing the global carbon cycle, their dependence on light to drive carbon fixation can be limiting for industrial chemical synthesis. Methanogenic archaea provide an alternative platform as an autotrophic microbial species capable of non-photosynthetic CO2 fixation, providing a potential route to engineered microbial fermentation to synthesize chemicals from CO2 without the need for light irradiation. One major challenge in this goal is to connect upstream carbon-fixation pathways with downstream biosynthetic pathways, given the distinct differences in metabolism between archaea and typical heterotrophs. We engineered the model methanogen, Methanococcus maripaludis, to divert acetyl-coenzyme A toward biosynthesis of value-added chemicals, including the bioplastic polyhydroxybutyrate (PHB). A number of studies implicated limitations in the redox pool, with NAD(P)(H) pools in M. maripaludis measured to be15% of that of Escherichia coli, likely since methanogenic archaea utilize F420 and ferredoxins instead. Multiple engineering strategies were used to precisely target and increase the cofactor pool, including heterologous expression of a synthetic nicotinamide salvage pathway as well as an NAD+-dependent formate dehydrogenase from Candida boidinii. Engineered strains of M. maripaludis with improved NADH pools produced up to 171 ± 4 mg/L PHB and 24.0 ± 1.9% of dry cell weight. The metabolic engineering strategies presented in this study broaden the utility of M. maripaludis for sustainable chemical synthesis using CO2 and may be transferable to related archaeal species.

Published

2022

29. Comparative Genomics on Cultivated and Uncultivated Freshwater and Marine '

Author

Hang, Yu, Grayson L, Chadwick, Usha F, Lingappa, and Jared R, Leadbetter

Subjects

Chemoautotrophic Growth, Manganese, Bacteria, Fresh Water, Genomics

Abstract

Chemolithoautotrophic manganese oxidation has long been theorized but only recently demonstrated in a bacterial coculture. The majority member of the coculture, "

Published

2022

30. Comparative proteomics of Geobacter sulfurreducens PCA T in response to acetate, formate and/or hydrogen as electron donor

Author

Monir Mollaei, Maria Suarez-Diez, Alfons J. M. Stams, Caroline M. Plugge, Antonie H. van Gelder, Peer H. A. Timmers, Sjef Boeren, and Universidade do Minho

Subjects

Proteomics, Chemoautotrophic Growth, Hydrogenase, Formates, Citric Acid Cycle, Inorganic chemistry, Biochemie, Electrons, Electron donor, Acetates, Formate dehydrogenase, Biochemistry, Ferric Compounds, Microbiology, Electron Transport, 03 medical and health sciences, chemistry.chemical_compound, Microbiologie, Life Science, Systems and Synthetic Biology, Formate, Organic Chemicals, Geobacter sulfurreducens, Research Articles, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, chemistry.chemical_classification, Systeem en Synthetische Biologie, 0303 health sciences, WIMEK, Science & Technology, biology, 030306 microbiology, Carbon fixation, MicPhys, Gluconeogenesis, Electron acceptor, biology.organism_classification, Formate Dehydrogenases, Electron transport chain, 6. Clean water, 3. Good health, chemistry, 13. Climate action, Geobacter, Oxidation-Reduction, Research Article, Hydrogen

Abstract

Geobacter sulfurreducens is a model bacterium to study the degradation of organic compounds coupled to the reduction of Fe(III). The response of G. sulfurreducens to the electron donors acetate, formate, hydrogen and a mixture of all three with Fe(III) citrate as electron acceptor was studied using comparative physiological and proteomic approaches. Variations in the supplied electron donors resulted in differential abundance of proteins involved in the citric acid cycle (CAC), gluconeogenesis, electron transport, and hydrogenases and formate dehydrogenase. Our results provided new insights into the electron donor metabolism of G. sulfurreducens. Remarkably, formate was the preferred electron donor compared to acetate, hydrogen, or acetate plus hydrogen. When hydrogen was the electron donor, formate was formed, which was associated with a high abundance of formate dehydrogenase. Notably, abundant proteins of two CO2 fixation pathways (acetyl-CoA pathway and the reversed oxidative CAC) corroborated chemolithoautotrophic growth of G. sulfurreducens with formate or hydrogen and CO2, and provided novel insight into chemolithoautotrophic growth of G. sulfurreducens. This article is protected by copyright. All rights reserved., This work was performed in the TTIW-cooperation framework of Wetsus, European Centre of Excellence for Sustain able Water Technology (www.wetsus.nl). Wetsus is funded by the Dutch Ministry of Economic Affairs, the European Union Regional Development Fund, the Province of Fryslân, the City of Leeuwarden and the EZ/Kompas program of the “Samenwerkingsverband Noord-Nederland”. The authors like to thank the participants of the research theme ‘Resource Recovery’ for fruitful discussions and their financial support. Research of AJMS is financed by an advanced grant of the European Research Council under the European Union’s Seventh Framework Programme (FP/2007e2013)/ERC Grant Agreement (project 323009). Research of AJMS and PHAT is supported by a Gravitation grant (project 024.002.002) of the Netherlands Ministry of Education, Culture and Science., info:eu-repo/semantics/publishedVersion

Published

2020

31. Sulfurimicrobium lacus gen. nov., sp. nov., a sulfur oxidizer isolated from lake water, and review of the family Sulfuricellaceae to show that it is not a later synonym of Gallionellaceae

Author

Kazuhiro Umezawa, Mamoru Kanda, Hisaya Kojima, and Manabu Fukui

Subjects

Chemoautotrophic Growth, Biochemistry, Microbiology, 03 medical and health sciences, chemistry.chemical_compound, Species Specificity, Genus, RNA, Ribosomal, 16S, Botany, Genetics, Molecular Biology, Phylogeny, 030304 developmental biology, Tetrathionate, Thiosulfate, 0303 health sciences, biology, Strain (chemistry), 030306 microbiology, Gallionellaceae, Fatty Acids, Betaproteobacteria, General Medicine, biology.organism_classification, 16S ribosomal RNA, Anoxic waters, Lakes, chemistry, Synonym (taxonomy), Oxidation-Reduction, Genome, Bacterial, Sulfur, Bacteria

Abstract

A facultatively anaerobic sulfur-oxidizing bacterium, strain skT11T, was isolated from anoxic lake water of a stratified freshwater lake. As electron donor for chemolithoautotrophic growth, strain skT11T oxidized thiosulfate, tetrathionate, and elemental sulfur under nitrate-reducing conditions. Oxygen-dependent growth was observed under microoxic conditions, but not under fully oxygenated conditions. Growth was observed at a temperature range of 5–37 °C, with optimum growth at 28 °C. Strain skT11T grew at a pH range of 5.1–7.5, with optimum growth at pH 6.5–6.9. Heterotrophic growth was not observed. Major components in the cellular fatty acid profile were C16:1 and C16:0. The complete genome of strain skT11T consisted of a circular chromosome with a size of 3.8 Mbp and G + C content of 60.2 mol%. Phylogenetic analysis based on the 16S rRNA gene sequences indicated that the strain skT11T is related to sulfur-oxidizing bacteria of the genera Sulfuricella, Sulfurirhabdus, and Sulfuriferula, with sequence identities of 95.4% or lower. The analysis also indicated that these three genera should be excluded from the family Gallionellaceae, as members of another family. On the basis of its genomic and phenotypic properties, strain skT11T (= DSM 110711 T = NBRC 114323 T) is proposed as the type strain of a new species in a new genus, Sulfurimicrobium lacus gen. nov., sp. nov. In addition, emended descriptions of the families Gallionellaceae and Sulfuricellaceae are proposed to declare that Sulfuricellaceae is not a later synonym of Gallionellaceae.

Published

2020

32. Phosphoglycolate salvage in a chemolithoautotroph using the Calvin cycle

Author

Axel Fischer, Giovanni Scarinci, Avi I. Flamholz, Oliver Lenz, Arren Bar-Even, Nico J. Claassens, William Newell, and Stefan Frielingsdorf

Subjects

Cyanobacteria, Chemoautotrophic Growth, Cupriavidus necator, Glyoxylate cycle, Malates, Microbiology, glycolate secretion, Carbon Cycle, Bacterial Proteins, Acetyl Coenzyme A, Malate synthase, Life Science, Photosynthesis, CO2 fixation, Multidisciplinary, biology, Chemistry, Carbon fixation, RuBisCO, Malate Synthase, Metabolism, Biological Sciences, glycolate oxidation, biology.organism_classification, Glycolates, hydrogen-oxidizing bacteria, Biochemistry, biology.protein, Photorespiration, Oxidation-Reduction

Abstract

Significance The Calvin cycle is the most important carbon fixation pathway in the biosphere. However, its carboxylating enzyme Rubisco also accepts oxygen, thus producing 2-phosphoglycolate. Phosphoglycolate salvage pathways were extensively studied in photoautotrophs but remain uncharacterized in chemolithoautotrophs using the Calvin cycle. Here, we study phosphoglycolate salvage in the chemolithoautotrophic model bacterium Cupriavidus necator H16. We demonstrate that this bacterium mainly reassimilates 2-phosphoglycolate via the glycerate pathway. Upon disruption of this pathway, a secondary route, which we term the malate cycle, supports photorespiration by completely oxidizing 2-phosphoglycolate to CO2. While the malate cycle was not previously known to metabolize 2-phosphoglycolate in nature, a bioinformatic analysis suggests that it may support phosphoglycolate salvage in diverse chemoautotrophic bacteria., Carbon fixation via the Calvin cycle is constrained by the side activity of Rubisco with dioxygen, generating 2-phosphoglycolate. The metabolic recycling of phosphoglycolate was extensively studied in photoautotrophic organisms, including plants, algae, and cyanobacteria, where it is referred to as photorespiration. While receiving little attention so far, aerobic chemolithoautotrophic bacteria that operate the Calvin cycle independent of light must also recycle phosphoglycolate. As the term photorespiration is inappropriate for describing phosphoglycolate recycling in these nonphotosynthetic autotrophs, we suggest the more general term “phosphoglycolate salvage.” Here, we study phosphoglycolate salvage in the model chemolithoautotroph Cupriavidus necator H16 (Ralstonia eutropha H16) by characterizing the proxy process of glycolate metabolism, performing comparative transcriptomics of autotrophic growth under low and high CO2 concentrations, and testing autotrophic growth phenotypes of gene deletion strains at ambient CO2. We find that the canonical plant-like C2 cycle does not operate in this bacterium, and instead, the bacterial-like glycerate pathway is the main route for phosphoglycolate salvage. Upon disruption of the glycerate pathway, we find that an oxidative pathway, which we term the malate cycle, supports phosphoglycolate salvage. In this cycle, glyoxylate is condensed with acetyl coenzyme A (acetyl-CoA) to give malate, which undergoes two oxidative decarboxylation steps to regenerate acetyl-CoA. When both pathways are disrupted, autotrophic growth is abolished at ambient CO2. We present bioinformatic data suggesting that the malate cycle may support phosphoglycolate salvage in diverse chemolithoautotrophic bacteria. This study thus demonstrates a so far unknown phosphoglycolate salvage pathway, highlighting important diversity in microbial carbon fixation metabolism.

Published

2020

33. Alternative strategies of nutrient acquisition and energy conservation map to the biogeography of marine ammonia-oxidizing archaea

Author

Tong Zhang, Mari K.H. Winkler, Yue Zheng, Annette Bollmann, Yulin Wang, Xiaowu Huang, Shady A. Amin, Reiji Takahashi, Baozhan Wang, David A. Stahl, Chuanlun Zhang, Edward F. DeLong, Daniel R. Mende, Tatsunori Nakagawa, Feng Zhao, Jizhong Zhou, Anitra E. Ingalls, Jeppe Lund Nielsen, Xinxu Zhang, Meng Li, Yao Zhang, Willm Martens-Habbena, Hidetoshi Urakawa, Po Heng Lee, Wei Qin, Koji Mori, E. Virginia Armbrust, and Haodong Liu

Subjects

Water microbiology, Technology, Biogeography, Hydrostatic pressure, Biology, Deep sea, Microbiology, Article, Microbial ecology, Ammonia, Chemoautotrophic Growth, Life Below Water, Ecology, Evolution, Behavior and Systematics, Phylogeny, Ecology, Nutrients, Biological Sciences, biology.organism_classification, Archaea, Nitrification, Metagenomics, Oxidation-Reduction, Environmental Sciences

Abstract

Ammonia-oxidizing archaea (AOA) are among the most abundant and ubiquitous microorganisms in the ocean, exerting primary control on nitrification and nitrogen oxides emission. Although united by a common physiology of chemoautotrophic growth on ammonia, a corresponding high genomic and habitat variability suggests tremendous adaptive capacity. Here, we compared 44 diverse AOA genomes, 37 from species cultivated from samples collected across diverse geographic locations and seven assembled from metagenomic sequences from the mesopelagic to hadopelagic zones of the deep ocean. Comparative analysis identified seven major marine AOA genotypic groups having gene content correlated with their distinctive biogeographies. Phosphorus and ammonia availabilities as well as hydrostatic pressure were identified as selective forces driving marine AOA genotypic and gene content variability in different oceanic regions. Notably, AOA methylphosphonate biosynthetic genes span diverse oceanic provinces, reinforcing their importance for methane production in the ocean. Together, our combined comparative physiological, genomic, and metagenomic analyses provide a comprehensive view of the biogeography of globally abundant AOA and their adaptive radiation into a vast range of marine and terrestrial habitats.

Published

2020

34. Catabolism and interactions of uncultured organisms shaped by eco-thermodynamics in methanogenic bioprocesses

Author

Michael J. McInerney, Po Heng Lee, Ran Mei, Takashi Narihiro, Yoichi Kamagata, Wen Tso Liu, Patrick K. H. Lee, and Masaru K. Nobu

Subjects

Microbiology (medical), Chemoautotrophic Growth, Formates, Uncultured organisms, Methanogenesis, Microorganism, Interactions, Acetates, Biology, Microbiology, lcsh:Microbial ecology, 03 medical and health sciences, chemistry.chemical_compound, Eco-thermodynamics, Microbial ecology, Formate, Methanogenic bioprocesses, Anaerobiosis, Ecosystem, 030304 developmental biology, 0303 health sciences, 030306 microbiology, Catabolism, Research, Organotroph, Metabolism, Archaea, chemistry, Biochemistry, Metagenomics, Thermodynamics, lcsh:QR100-130, Methane

Abstract

Background Current understanding of the carbon cycle in methanogenic environments involves trophic interactions such as interspecies H2 transfer between organotrophs and methanogens. However, many metabolic processes are thermodynamically sensitive to H2 accumulation and can be inhibited by H2 produced from co-occurring metabolisms. Strategies for driving thermodynamically competing metabolisms in methanogenic environments remain unexplored. Results To uncover how anaerobes combat this H2 conflict in situ, we employ metagenomics and metatranscriptomics to revisit a model ecosystem that has inspired many foundational discoveries in anaerobic ecology—methanogenic bioreactors. Through analysis of 17 anaerobic digesters, we recovered 1343 high-quality metagenome-assembled genomes and corresponding gene expression profiles for uncultured lineages spanning 66 phyla and reconstructed their metabolic capacities. We discovered that diverse uncultured populations can drive H2-sensitive metabolisms through (i) metabolic coupling with concurrent H2-tolerant catabolism, (ii) forgoing H2 generation in favor of interspecies transfer of formate and electrons (cytochrome- and pili-mediated) to avoid thermodynamic conflict, and (iii) integration of low-concentration O2 metabolism as an ancillary thermodynamics-enhancing electron sink. Archaeal populations support these processes through unique methanogenic metabolisms—highly favorable H2 oxidation driven by methyl-reducing methanogenesis and tripartite uptake of formate, electrons, and acetate. Conclusion Integration of omics and eco-thermodynamics revealed overlooked behavior and interactions of uncultured organisms, including coupling favorable and unfavorable metabolisms, shifting from H2 to formate transfer, respiring low-concentration O2, performing direct interspecies electron transfer, and interacting with high H2-affinity methanogenesis. These findings shed light on how microorganisms overcome a critical obstacle in methanogenic carbon cycles we had hitherto disregarded and provide foundational insight into anaerobic microbial ecology.

Published

2020

35. Genome diversification in globally distributed novel marine Proteobacteria is linked to environmental adaptation

Author

Zhichao Zhou, Patricia Q. Tran, Karthik Anantharaman, and Kristopher Kieft

Subjects

Chemoautotrophic Growth, Ecosystem ecology, Niche, Diversification (marketing strategy), Biology, Microbiology, Genome, Article, Microbial ecology, 03 medical and health sciences, Hydrothermal Vents, Proteobacteria, Seawater, Autotroph, Microbiome, Atlantic Ocean, Phylogeny, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Comparative genomics, 0303 health sciences, 030306 microbiology, Ecology, biology.organism_classification, bacteria, Hydrothermal vent

Abstract

Proteobacteria constitute one of the most diverse and abundant groups of microbes on Earth. In productive marine environments like deep-sea hydrothermal systems, Proteobacteria are implicated in autotrophy coupled to sulfur, methane, and hydrogen oxidation, sulfate reduction, and denitrification. Beyond chemoautotrophy, little is known about the ecological significance of poorly studied Proteobacteria lineages that are globally distributed and active in hydrothermal systems. Here we apply multi-omics to characterize 51 metagenome-assembled genomes from three hydrothermal vent plumes in the Pacific and Atlantic Oceans that are affiliated with nine Proteobacteria lineages. Metabolic analyses revealed these organisms to contain a diverse functional repertoire including chemolithotrophic ability to utilize sulfur and C1compounds, and chemoorganotrophic ability to utilize environment-derived fatty acids, aromatics, carbohydrates, and peptides. Comparative genomics with marine and terrestrial microbiomes suggests that lineage-associated functional traits could explain niche specificity. Our results shed light on the ecological functions and metabolic strategies of novel Proteobacteria in hydrothermal systems and beyond, and highlight the relationship between genome diversification and environmental adaptation.

Published

2020

36. Autotrophic carbon fixation pathways along the redox gradient in <scp>oxygen‐depleted</scp> oceanic waters

Author

Salvador Ramírez-Flandes, Osvaldo Ulloa, Paula Ruiz-Fernández, and Edwin Rodríguez-León

Subjects

Chemoautotrophic Growth, Biogeochemical cycle, Proteome, Nitrogen, Citric Acid Cycle, Reductive tricarboxylic acid cycle, Carbon Cycle, Carbon cycle, 03 medical and health sciences, Seawater, Photosynthesis, Nitrogen cycle, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Autotrophic Processes, 0303 health sciences, Bacteria, biology, 030306 microbiology, Chemistry, Brief Report, Carbon fixation, biology.organism_classification, Archaea, Agricultural and Biological Sciences (miscellaneous), Anoxic waters, Carbon, Oxygen, Redox gradient, Genes, Bacterial, Environmental chemistry, Metagenome, Scalindua, Brief Reports, Metagenomics, Energy Metabolism, Gammaproteobacteria, Sulfur

Abstract

Summary Anoxic marine zones (AMZs), also known as ‘oxygen‐deficient zones’, contribute to the loss of fixed nitrogen from the ocean by anaerobic microbial processes. While these microbial processes associated with the nitrogen cycle have been extensively studied, those linked to the carbon cycle in AMZs have received much less attention, particularly the autotrophic carbon fixation — a crucial component of the carbon cycle. Using metagenomic and metatranscriptomic data from major AMZs, we report an explicit partitioning of the marker genes associated with different autotrophic carbon fixation pathways along the redox gradient (from oxic to anoxic conditions) present in the water column of AMZs. Sequences related to the Calvin‐Benson‐Bassham cycle were found along the entire gradient, while those related to the reductive Acetyl‐CoA pathway were restricted to suboxic and anoxic waters. Sequences putatively associated with the 3‐hydroxypropionate/4‐hydroxybutyrate cycle dominated in the upper and lower oxyclines. Genes related to the reductive tricarboxylic acid cycle were represented from dysoxic to anoxic waters. The taxonomic affiliation of the sequences is consistent with the presence of microorganisms involved in crucial steps of biogeochemical cycles in AMZs, such as the gamma‐proteobacteria sulfur oxidisers, the anammox bacteria Candidatus Scalindua and the thaumarcheota ammonia oxidisers of the Marine Group I.

Published

2020

37. Another chemolithotrophic metabolism missing in nature: sulfur comproportionation

Author

Heidi S. Aronson, Jan P. Amend, Jennifer L. Macalady, and Douglas E. LaRowe

Subjects

Chemoautotrophic Growth, Sulfide, Inorganic chemistry, chemistry.chemical_element, Biology, Microbiology, Redox, 03 medical and health sciences, chemistry.chemical_compound, symbols.namesake, Hydrothermal Vents, Sulfite, Correspondence, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Thiosulfate, chemistry.chemical_classification, Exergonic reaction, 0303 health sciences, Bacteria, Sulfates, 030306 microbiology, Temperature, Comproportionation, Sulfur, Gibbs free energy, chemistry, symbols, Thermodynamics, Energy Metabolism, Oxidation-Reduction

Abstract

Chemotrophic microorganisms gain energy for cellular functions by catalyzing oxidation-reduction (redox) reactions that are out of equilibrium. Calculations of the Gibbs energy ( ΔG r ) can identify whether a reaction is thermodynamically favourable and quantify the accompanying energy yield at the temperature, pressure and chemical composition in the system of interest. Based on carefully calculated values of ΔG r , we predict a novel microbial metabolism - sulfur comproportionation (3H2 S + SO42- + 2H+ ⇌ 4S0 + 4H2 O). We show that at elevated concentrations of sulfide and sulfate in acidic environments over a broad temperature range, this putative metabolism can be exergonic ( ΔG r

Published

2020

38. Culture of Methanogenic Archaea from Human Colostrum and Milk

Author

Marion S. Bonnet, Aurelia Caputo, Véronique Brevaut, Matthieu Million, Amadou Hamidou Togo, Saber Khelaifia, Didier Raoult, Michel Drancourt, Anthony Levasseur, Ghiles Grine, Emeline Baptiste, Clotilde des Robert, Microbes évolution phylogénie et infections (MEPHI), and Institut de Recherche pour le Développement (IRD)-Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS)

Subjects

0301 basic medicine, Chemoautotrophic Growth, Microbiological culture, Microorganism, ved/biology.organism_classification_rank.species, lcsh:Medicine, Genome, Body Mass Index, Feces, fluids and secretions, [SDV.MHEP.MI]Life Sciences [q-bio]/Human health and pathology/Infectious diseases, Pregnancy, lcsh:Science, ComputingMilieux_MISCELLANEOUS, 2. Zero hunger, [SDV.MHEP.ME]Life Sciences [q-bio]/Human health and pathology/Emerging diseases, Multidisciplinary, biology, Archaeal genomics, Microbiota, Methanobrevibacter smithii, food and beverages, 3. Good health, Breast Feeding, DNA, Archaeal, [SDV.MP.VIR]Life Sciences [q-bio]/Microbiology and Parasitology/Virology, Female, 030106 microbiology, Mothers, Euryarchaeota, Methanobrevibacter, Article, Microbiology, 03 medical and health sciences, [SDV.MHEP.CSC]Life Sciences [q-bio]/Human health and pathology/Cardiology and cardiovascular system, Animals, Humans, [SDV.MP.PAR]Life Sciences [q-bio]/Microbiology and Parasitology/Parasitology, Archaeal physiology, Milk, Human, ved/biology, Colostrum, lcsh:R, Infant, biology.organism_classification, Commensalism, [SDV.MP.BAC]Life Sciences [q-bio]/Microbiology and Parasitology/Bacteriology, 030104 developmental biology, lcsh:Q, Methanobrevibacter oralis, Archaea

Abstract

Archaeal sequences have been detected in human colostrum and milk, but no studies have determined whether living archaea are present in either of these fluids. Methanogenic archaea are neglected since they are not detected by usual molecular and culture methods. By using improved DNA detection protocols and microbial culture techniques associated with antioxidants previously developed in our center, we investigated the presence of methanogenic archaea using culture and specific Methanobrevibacter smithii and Methanobrevibacter oralis real-time PCR in human colostrum and milk. M. smithii was isolated from 3 colostrum and 5 milk (day 10) samples. M. oralis was isolated from 1 milk sample. For 2 strains, the genome was sequenced, and the rhizome was similar to that of strains previously isolated from the human mouth and gut. M. smithii was detected in the colostrum or milk of 5/13 (38%) and 37/127 (29%) mothers by culture and qPCR, respectively. The different distribution of maternal body mass index according to the detection of M. smithii suggested an association with maternal metabolic phenotype. M. oralis was not detected by molecular methods. Our results suggest that breastfeeding may contribute to the vertical transmission of these microorganisms and may be essential to seed the infant’s microbiota with these neglected critical commensals from the first hour of life.

Published

2019

39. Molecular characterization of methanogenic microbial communities for degrading various types of polycyclic aromatic hydrocarbon

Author

Xunwen Chen, Tingting Fang, Yun Wang, Chengyue Liang, Hui Wang, and Quanhui Ye

Subjects

0301 basic medicine, Methanobacterium, Chemoautotrophic Growth, Environmental Engineering, Thauera, ved/biology.organism_classification_rank.species, Polycyclic aromatic hydrocarbon, Euryarchaeota, 010501 environmental sciences, 01 natural sciences, Thiobacillus, 03 medical and health sciences, chemistry.chemical_compound, Bioremediation, Soil Pollutants, Environmental Chemistry, Polycyclic Aromatic Hydrocarbons, 0105 earth and related environmental sciences, General Environmental Science, chemistry.chemical_classification, Bacteria, biology, Chemistry, ved/biology, Microbiota, fungi, General Medicine, Phenanthrene, biology.organism_classification, Archaea, Methanomethylovorans, Biodegradation, Environmental, 030104 developmental biology, Microbial population biology, Environmental chemistry

Abstract

Knowledge on methanogenic microbial communities associated with the degradation of polycyclic aromatic hydrocarbons (PAHs) is crucial to developing strategies for PAHs bioremediation. In this study, the linkage between the type of PAHs and microbial community structure was fully investigated through 16S rRNA gene sequencing on four PAH-degrading cultures. Putative degradation products were also detected. Our results indicated that naphthalene (Nap)/2-methylnaphthalene (2-Nap), phenanthrene (Phe) and anthracene (Ant) sculpted different microbial communities. Among them, Nap and 2-Nap selected for similar degrading bacteria (i.e., Alicycliphilus and Thauera) and methanogens (Methanomethylovorans and Methanobacterium). Nap and 2-Nap were probably activated via carboxylation, producing 2-naphthoic acid. In contrast, Phe and Ant shaped different bacterial and archaeal communities, with Arcobacter and Acinetobacter being Phe-degraders and Thiobacillus Ant-degrader. Methanogenic archaea Methanobacterium and Methanomethylovorans predominated Phe-degrading and Ant-degrading culture, respectively. These findings can improve our understanding of natural PAHs attenuation and provide some guidance for PAHs bioremediation in methanogenic environment.

Published

2019

40. Metagenomics of Antarctic Marine Sediment Reveals Potential for Diverse Chemolithoautotrophy

Author

Michael W. Henson, Deric R. Learman, Andrew R. Mahon, Jessica R. Zehnpfennig, Arkadiy I. Garber, Kenneth M Halanych, Cody S. Sheik, and Gustavo A. Ramírez

Subjects

Chemoautotrophic Growth, Geologic Sediments, Biogeochemical cycle, Nitrogen, Climate Change, Antarctic Regions, marine microbiology, Microbiology, Carbon Cycle, 03 medical and health sciences, Benthos, Ecosystem, 14. Life underwater, Molecular Biology, Phylogeny, chemolithotrophy, 030304 developmental biology, metagenomics, 0303 health sciences, 030306 microbiology, Ecology, Microbiota, fungi, Sediment, Biogeochemistry, marine sediment, Pelagic zone, 15. Life on land, QR1-502, Carbon, 13. Climate action, Benthic zone, Antarctica, Metagenome, Environmental science, Nitrification, Sulfur, Research Article

Abstract

The microbial biogeochemical processes occurring in marine sediment in Antarctica remain underexplored due to limited access. Further, these polar habitats are unique, as they are being exposed to significant changes in their climate. To explore how microbes drive biogeochemistry in these sediments, we performed a shotgun metagenomic survey of marine surficial sediment (0 to 3 cm of the seafloor) collected from 13 locations in western Antarctica and assembled 16 high-quality metagenome assembled genomes for focused interrogation of the lifestyles of some abundant lineages. We observe an abundance of genes from pathways for the utilization of reduced carbon, sulfur, and nitrogen sources. Although organotrophy is pervasive, nitrification and sulfide oxidation are the dominant lithotrophic pathways and likely fuel carbon fixation via the reverse tricarboxylic acid and Calvin cycles. Oxygen-dependent terminal oxidases are common, and genes for reduction of oxidized nitrogen are sporadically present in our samples. Our results suggest that the underlying benthic communities are well primed for the utilization of settling organic matter, which is consistent with findings from highly productive surface water. Despite the genetic potential for nitrate reduction, the net catabolic pathway in our samples remains aerobic respiration, likely coupled to the oxidation of sulfur and nitrogen imported from the highly productive Antarctic water column above. IMPORTANCE The impacts of climate change in polar regions, like Antarctica, have the potential to alter numerous ecosystems and biogeochemical cycles. Increasing temperature and freshwater runoff from melting ice can have profound impacts on the cycling of organic and inorganic nutrients between the pelagic and benthic ecosystems. Within the benthos, sediment microbial communities play a critical role in carbon mineralization and the cycles of essential nutrients like nitrogen and sulfur. Metagenomic data collected from sediment samples from the continental shelf of western Antarctica help to examine this unique system and document the metagenomic potential for lithotrophic metabolisms and the cycles of both nitrogen and sulfur, which support not only benthic microbes but also life in the pelagic zone.

Published

2021

41. Hydrothermal plumes as hotspots for deep-ocean heterotrophic microbial biomass production

Author

Cathalot, Cécile, Roussel, Erwan G., Perhirin, Antoine, Creff, Vanessa, Donval, Jean-Pierre, Guyader, Vivien, Roullet, Guillaume, Gula, Jonathan, Tamburini, Christian, Garel, Marc, Godfroy, Anne, Sarradin, Pierre-Marie, Institut Français de Recherche pour l'Exploitation de la Mer (IFREMER), Laboratoire d'Océanographie Physique et Spatiale (LOPS), Institut de Recherche pour le Développement (IRD)-Institut Français de Recherche pour l'Exploitation de la Mer (IFREMER)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Brest (UBO)-Centre National de la Recherche Scientifique (CNRS), 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), ANR-10-LABX-0019,LabexMER,LabexMER Marine Excellence Research: a changing ocean(2010), and Institut de Recherche pour le Développement (IRD)-Institut Français de Recherche pour l'Exploitation de la Mer (IFREMER)-Université de Brest (UBO)-Centre National de la Recherche Scientifique (CNRS)

Subjects

[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, Chemoautotrophic Growth, Microbiota, Oceans and Seas, Science, [SDE.MCG]Environmental Sciences/Global Changes, Heterotrophic Processes, Carbon cycle, Models, Theoretical, Article, Hydrothermal Vents, Marine chemistry, Prokaryotic Cells, Seawater, Biomass, [SDE.BE]Environmental Sciences/Biodiversity and Ecology, [SDU.STU.OC]Sciences of the Universe [physics]/Earth Sciences/Oceanography

Abstract

Carbon budgets of hydrothermal plumes result from the balance between carbon sinks through plume chemoautotrophic processes and carbon release via microbial respiration. However, the lack of comprehensive analysis of the metabolic processes and biomass production rates hinders an accurate estimate of their contribution to the deep ocean carbon cycle. Here, we use a biogeochemical model to estimate the autotrophic and heterotrophic production rates of microbial communities in hydrothermal plumes and validate it with in situ data. We show how substrate limitation might prevent net chemolithoautotrophic production in hydrothermal plumes. Elevated prokaryotic heterotrophic production rates (up to 0.9 gCm−2y−1) compared to the surrounding seawater could lead to 0.05 GtCy−1 of C-biomass produced through chemoorganotrophy within hydrothermal plumes, similar to the Particulate Organic Carbon (POC) export fluxes reported in the deep ocean. We conclude that hydrothermal plumes must be accounted for as significant deep sources of POC in ocean carbon budgets., Hydrothermal vents are biogeochemically important, but their contribution to the carbon cycle is poorly constrained. Here the authors build a biogeochemical model that estimates autotrophic and heterotrophic production rates of microbial communities within hydrothermal plumes along mid-ocean ridges.

Published

2021

42. Thermochronologic perspectives on the deep-time evolution of the deep biosphere

Author

Henrik, Drake and Peter W, Reiners

Subjects

Canada, Chemoautotrophic Growth, Extremophiles, Geologic Sediments, Origin of Life, Physical Sciences, Environmental Microbiology, Temperature, Scandinavian and Nordic Countries, Biological Evolution, Evolution, Planetary, Extreme Environments, Time

Abstract

The Earth’s deep biosphere hosts some of its most ancient chemolithotrophic lineages. The history of habitation in this environment is thus of interest for understanding the origin and evolution of life. The oldest rocks on Earth, formed about 4 billion years ago, are in continental cratons that have experienced complex histories due to burial and exhumation. Isolated fracture-hosted fluids in these cratons may have residence times older than a billion years, but understanding the history of their microbial communities requires assessing the evolution of habitable conditions. Here, we present a thermochronological perspective on the habitability of Precambrian cratons through time. We show that rocks now in the upper few kilometers of cratons have been uninhabitable (>∼122 °C) for most of their lifetime or have experienced high-temperature episodes, such that the longest record of habitability does not stretch much beyond a billion years. In several cratons, habitable conditions date back only 50 to 300 million years, in agreement with dated biosignatures. The thermochronologic approach outlined here provides context for prospecting and interpreting the little-explored geologic record of the deep biosphere of Earth’s cratons, when and where microbial communities may have thrived, and candidate areas for the oldest records of chemolithotrophic microbes.

Published

2021

43. Microbes mediating the sulfur cycle in the Atlantic Ocean and their link to chemolithoautotrophy

Author

Simone Muck, Daniele De Corte, Gerhard J. Herndl, Eva Sintes, Catalina Mena, and Johanna Tiroch

Subjects

Chemoautotrophic Growth, animal structures, Mesopelagic zone, Microorganisms, Microbiology, Centro Oceanográfico de Baleares, 03 medical and health sciences, Water column, Sulphur, Total inorganic carbon, Botany, Seawater, 14. Life underwater, Medio Marino, Atlantic Ocean, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Pelagibacterales, 0303 health sciences, biology, 030306 microbiology, RuBisCO, Sulfur cycle, biology.organism_classification, 13. Climate action, biology.protein, Energy source, Mixotroph, Gammaproteobacteria, Sulfur

Abstract

Only about 10%–30% of the organic matter produced in the epipelagic layers reaches the dark ocean. Under these limiting conditions, reduced inorganic substrates might be used as an energy source to fuel prokaryotic chemoautotrophic and/or mixotrophic activity. The aprA gene encodes the alpha subunit of the adenosine-5′-phosphosulfate (APS) reductase, present in sulfate-reducing (SRP) and sulfur-oxidizing prokaryotes (SOP). The sulfur-oxidizing pathway can be coupled to inorganic carbon fixation via the Calvin–Benson–Bassham cycle. The abundances of aprA and cbbM, encoding RuBisCO form II (the key CO2 fixing enzyme), were determined over the entire water column along a latitudinal transect in the Atlantic from 64°N to 50°S covering six oceanic provinces. The abundance of aprA and cbbM genes significantly increased with depth reaching the highest abundances in meso- and upper bathypelagic layers. The contribution of cells containing these genes also increased from mesotrophic towards oligotrophic provinces, suggesting that under nutrient limiting conditions alternative energy sources are advantageous. However, the aprA/cbbM ratios indicated that only a fraction of the SOP is associated with inorganic carbon fixation. The aprA harbouring prokaryotic community was dominated by Pelagibacterales in surface and mesopelagic waters, while Candidatus Thioglobus, Chromatiales and the Deltaproteobacterium_SCGC dominated the bathypelagic realm. Noticeably, the contribution of the SRP to the prokaryotic community harbouring aprA gene was low, suggesting a major utilization of inorganic sulfur compounds either as an energy source (occasionally coupled with inorganic carbon fixation) or in biosynthesis pathways., SI

Published

2021

44. A Single Bacterium Capable of Oxidation and Reduction of Iron at Circumneutral pH

Author

Moriya Ohkuma and Shingo Kato

Subjects

Microbiology (medical), Biogeochemical cycle, Chemoautotrophic Growth, iron cycling, Physiology, Inorganic chemistry, iron reduction, Electron donor, Observation, Microbiology, Redox, Ferric Compounds, Comamonadaceae, chemistry.chemical_compound, Japan, Rhodoferax, Genetics, Ferrous Compounds, Phylogeny, chemolithotrophy, chemistry.chemical_classification, Thiosulfate, General Immunology and Microbiology, Ecology, biology, Chemistry, Carbon fixation, Cell Biology, Electron acceptor, Hydrogen-Ion Concentration, iron oxidizers, biology.organism_classification, Anoxic waters, QR1-502, Aerobiosis, Infectious Diseases, Wetlands, Oxidation-Reduction, Genome, Bacterial, Hydrogen

Abstract

Fe(II)-oxidizing microorganisms and Fe(III)-reducing microorganisms, which drive the biogeochemical Fe cycle on the Earth’s surface, are phylogenetically and ecologically diverse. However, no single organism capable of aerobic Fe(II) oxidation and anaerobic Fe(III) reduction at circumneutral pH have been reported so far. Here, we report a novel neutrophilic Fe(II)-oxidizing Rhodoferax bacterium, strain MIZ03, isolated from an iron-rich wetland in Japan. Our cultivation experiments demonstrate that MIZ03 represents a much more versatile metabolism for energy acquisition than previously recognized in the genus Rhodoferax. MIZ03 can grow chemolithoautotrophically at circumneutral pH by oxidation of Fe(II), H2, or thiosulfate as the sole electron donor under (micro)aerobic conditions (i.e., using O2 as the sole electron acceptor). In addition, it can reduce Fe(III) or nitrate under anaerobic conditions. Thus, this is the first report demonstrating the presence of a single bacterium capable of both Fe(II) oxidation and Fe(III) reduction at circumneutral pH. The observed physiology was consistent with its 4.9-Mbp complete genome encoding key genes for iron oxidation/reduction (foxEY and mtrABC), for nitrate reduction (narGHI), for thiosulfate oxidation (soxABCDXYZ), and for carbon fixation via the Calvin cycle. Our metagenomic survey suggests that there are more Rhodoferax members capable of Fe(II) oxidation and Fe(III) reduction. Such bifunctional Rhodoferax may have an ecological advantage in suboxic/anoxic environments at circumneutral pH by recycling of Fe as the electron donor and acceptor. IMPORTANCE The biogeochemical cycle of iron (Fe) via reactions of oxidation, reduction, precipitation, and dissolution is involved in the cycle of other ecologically relevant elements, such as C, N, P, S, As, Co, Ni, and Pb. The Fe cycle on the Earth’s surface is driven by a variety of Fe(II)-oxidizing microorganisms and Fe(III)-reducing microorganisms. Here, we discovered a novel bacterium, Rhodoferax sp. strain MIZ03, capable of both Fe(II) oxidation and Fe(III) reduction at circumneutral pH, and we report its physiological characteristics and complete genome sequence. The unexpected capability of this bacterium provides novel insights into the Fe cycle in the environment. Moreover, this bacterium will help to better understand the molecular mechanisms of microbial Fe redox cycling as a model organism.

Published

2021

45. Active microbial ecosystem in glacier basal ice fuelled by iron and silicate comminution‐derived hydrogen

Author

Sanja Potgieter-Vermaak, Edda Sigurdís Oddsdóttir, David Elliott, Mario Toubes-Rodrigo, Robin Sen, and Simon J. Cook

Subjects

Chemoautotrophic Growth, Geologic Sediments, Biogeochemical cycle, Methanogenesis, Iron, Weathering, microbial ecology, Microbiology, Carbon Cycle, chemistry.chemical_compound, Microbial ecology, RNA, Ribosomal, 16S, Cryosphere, Ice Cover, Ecosystem, extremophiles, geography, geography.geographical_feature_category, Bacteria, Ecology, Chemistry, Silicates, Glacier, Original Articles, cryosphere, QR1-502, Silicate, environmental microbiology, glaciers, Original Article, Methane, Oxidation-Reduction, Hydrogen

Abstract

The basal zone of glaciers is characterized by physicochemical properties that are distinct from firnified ice due to strong interactions with underlying substrate and bedrock. Basal ice (BI) ecology and the roles that the microbiota play in biogeochemical cycling, weathering, and proglacial soil formation remain poorly described. We report on basal ice geochemistry, bacterial diversity (16S rRNA gene phylogeny), and inferred ecological roles at three temperate Icelandic glaciers. We sampled three physically distinct basal ice facies (stratified, dispersed, and debris bands) and found facies dependent on biological similarities and differences; basal ice character is therefore an important sampling consideration in future studies. Based on a high abundance of silicates and Fe‐containing minerals and, compared to earlier BI literature, total C was detected that could sustain the basal ice ecosystem. It was hypothesized that C‐fixing chemolithotrophic bacteria, especially Fe‐oxidisers and hydrogenotrophs, mutualistically support associated heterotrophic communities. Basal ice‐derived rRNA gene sequences corresponding to genera known to harbor hydrogenotrophic methanogens suggest that silicate comminution‐derived hydrogen can also be utilized for methanogenesis. PICRUSt‐predicted metabolism suggests that methane metabolism and C‐fixation pathways could be highly relevant in BI, indicating the importance of these metabolic routes. The nutrients and microbial communities release from melting basal ice may play an important role in promoting pioneering communities establishment and soil development in deglaciating forelands., The subglacial ecosystem is globally significant because glaciers and ice sheets cover ~10% of the Earth's land surface, yet it remains poorly understood. This study provides a detailed characterization of the geochemistry and bacterial community inhabiting the subglacial basal ice layer of three Icelandic glaciers. Our data show that a thriving chemolithotroph‐powered community exists within basal ice, fuelled by the oxidation of hydrogen and iron.

Published

2021

46. Niche partitioning of bacterial communities along the stratified water column in the Black Sea

Author

Elena Stoica, Jaroslav Slobodnik, Evgen Dykyi, Mariia Pavlovska, Andrii Zotov, Alina Frolova, Ievgeniia Prekrasna, and Artem Dzhulai

Subjects

DNA, Bacterial, Chemoautotrophic Growth, Stratification (vegetation), Microbiology, Water column, Dissimilatory sulfate reduction, RNA, Ribosomal, 16S, Phytoplankton, Seawater, Rhodobacteraceae, Ecosystem, Phylogeny, biology, Bacteria, Ecology, Sulfates, Microbiota, anoxic, PICRUSt, vertical distribution, Original Articles, biology.organism_classification, Anoxygenic photosynthesis, Anoxic waters, QR1-502, Oxygen, Phototrophic Processes, Microbial population biology, Black Sea, Environmental science, Original Article, 16S rRNA gene, microbial community, Water Microbiology, Oxidation-Reduction

Abstract

The Black Sea is the largest semi‐closed permanently anoxic basin on our planet with long‐term stratification. The study aimed at describing the Black Sea microbial community taxonomic and functional composition within the range of depths spanning across oxic/anoxic interface, and to uncover the factors behind both their vertical and regional differentiation. 16S rRNA gene MiSeq sequencing was applied to get the data on microbial community taxonomy, and the PICRUSt pipeline was used to infer their functional profile. The normoxic zone was mainly inhabited by primary producers and heterotrophic prokaryotes (e.g., Flavobacteriaceae, Rhodobacteraceae, Synechococcaceae) whereas the euxinic zone—by heterotrophic and chemoautotrophic taxa (e.g., MSBL2, Piscirickettsiaceae, and Desulfarculaceae). Assimilatory sulfate reduction and oxygenic photosynthesis were prevailing within the normoxic zone, while the role of nitrification, dissimilatory sulfate reduction, and anoxygenic photosynthesis increased in the oxygen‐depleted water column part. Regional differentiation of microbial communities between the Ukrainian shelf and offshore zone was detected as well, yet it was significantly less pronounced than the vertical one. It is suggested that regional differentiation within a well‐oxygenated zone is driven by the difference in phytoplankton communities providing various substrates for the prokaryotes, whereas redox stratification is the main driving force behind microbial community vertical structure., The study aimed at describing the Black Sea microbial community taxonomic and functional composition within the range of depths spanning across oxic/anoxic interface, and to uncover the factors behind both their vertical and regional differentiation. It is suggested that regional differentiation within a well‐oxygenated zone is driven by the difference in phytoplankton communities providing various substrates for the bacteria, whereas redox stratification is the main driving force behind microbial community vertical structure.

Published

2021

47. Comparative proteomics of related symbiotic mussel species reveals high variability of host–symbiont interactions

Author

Horst Felbeck, Tjorven Hinzke, Christian Hentschker, Manuel Kleiner, Rabea Schlüter, Ruby Ponnudurai, Dörte Becher, Thomas Schweder, Stefan E. Heiden, Lizbeth Sayavedra, Stefan M. Sievert, and Stephanie Markert

Subjects

Gills, Proteomics, Water microbiology, Chemoautotrophic Growth, animal structures, Methanotroph, Bathymodiolus, Microbial metabolism, Brief Communication, Bacterial physiology, Microbiology, Bacterial genetics, Microbial ecology, 03 medical and health sciences, Symbiosis, Animals, 14. Life underwater, Amino Acids, Ecology, Evolution, Behavior and Systematics, Carbonic Anhydrases, 030304 developmental biology, 0303 health sciences, Bacteria, Host Microbial Interactions, biology, 030306 microbiology, Host (biology), fungi, food and beverages, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Evolutionary biology, bacteria, Mytilidae, Genome, Bacterial

Abstract

Deep-sea Bathymodiolus mussels and their chemoautotrophic symbionts are well-studied representatives of mutualistic host–microbe associations. However, how host–symbiont interactions vary on the molecular level between related host and symbiont species remains unclear. Therefore, we compared the host and symbiont metaproteomes of Pacific B. thermophilus, hosting a thiotrophic symbiont, and Atlantic B. azoricus, containing two symbionts, a thiotroph and a methanotroph. We identified common strategies of metabolic support between hosts and symbionts, such as the oxidation of sulfide by the host, which provides a thiosulfate reservoir for the thiotrophic symbionts, and a cycling mechanism that could supply the host with symbiont-derived amino acids. However, expression levels of these processes differed substantially between both symbioses. Backed up by genomic comparisons, our results furthermore revealed an exceptionally large repertoire of attachment-related proteins in the B. thermophilus symbiont. These findings imply that host–microbe interactions can be quite variable, even between closely related systems.

Published

2019

48. Sulfobacillus thermotolerans: new insights into resistance and metabolic capacities of acidophilic chemolithotrophs

Author

Elena S. Kostryukova, Andrey V. Letarov, Maria A. Letarova, Iraida A. Tsaplina, Anastasia S. Nikitina, A. E. Panyushkina, Vladislav V. Babenko, and Oksana V. Selezneva

Subjects

0301 basic medicine, Chemoautotrophic Growth, 030106 microbiology, ved/biology.organism_classification_rank.species, Glyoxylate cycle, lcsh:Medicine, Biology, Regulon, Genome, Article, Applied microbiology, 03 medical and health sciences, Plasmid, Stress, Physiological, Phylogenetics, Rusticyanin, lcsh:Science, Gene, Phylogeny, Bacterial genomics, Genetics, Clostridiales, Sulfobacillus thermotolerans, Multidisciplinary, ved/biology, lcsh:R, Carbon, 030104 developmental biology, lcsh:Q, DNA, Circular, Energy Metabolism, Genome, Bacterial, Function (biology), Plasmids

Abstract

The first complete genome of the biotechnologically important species Sulfobacillus thermotolerans has been sequenced. Its 3 317 203-bp chromosome contains an 83 269-bp plasmid-like region, which carries heavy metal resistance determinants and the rusticyanin gene. Plasmid-mediated metal resistance is unusual for acidophilic chemolithotrophs. Moreover, most of their plasmids are cryptic and do not contribute to the phenotype of the host cells. A polyphosphate-based mechanism of metal resistance, which has been previously unknown in the genus Sulfobacillus or other Gram-positive chemolithotrophs, potentially operates in two Sulfobacillus species. The methylcitrate cycle typical for pathogens and identified in the genus Sulfobacillus for the first time can fulfill the energy and/or protective function in S. thermotolerans Kr1 and two other Sulfobacillus species, which have incomplete glyoxylate cycles. It is notable that the TCA cycle, disrupted in all Sulfobacillus isolates under optimal growth conditions, proved to be complete in the cells enduring temperature stress. An efficient antioxidant defense system gives S. thermotolerans another competitive advantage in the microbial communities inhabiting acidic metal-rich environments. The genomic comparisons revealed 80 unique genes in the strain Kr1, including those involved in lactose/galactose catabolism. The results provide new insights into metabolism and resistance mechanisms in the Sulfobacillus genus and other acidophiles.

Published

2019

49. NanoSIMS reveals unusual enrichment of acetate and propionate by an anammox consortium dominated by Jettenia asiatica

Author

Xiaoli Huang, Chun-Hong Chen, Xiaolong Wang, Mark C.M. van Loosdrecht, Yu Tao, Dawen Gao, and Hong Liang

Subjects

Chemoautotrophic Growth, Environmental Engineering, Nitrogen, Microorganism, 0208 environmental biotechnology, Heterotroph, 02 engineering and technology, Acetates, 010501 environmental sciences, 01 natural sciences, Bacteria, Anaerobic, chemistry.chemical_compound, Ammonium, Anaerobiosis, Autotroph, Nitrite, Waste Management and Disposal, Ecosystem, 0105 earth and related environmental sciences, Water Science and Technology, Civil and Structural Engineering, chemistry.chemical_classification, Bacteria, biology, Chemistry, Ecological Modeling, biology.organism_classification, Pollution, 020801 environmental engineering, Quaternary Ammonium Compounds, Anammox, Environmental chemistry, Propionate, Propionates, Oxidation-Reduction

Abstract

Anaerobic ammonium-oxidizing (anammox) bacteria convert ammonium and nitrite into N2 in a chemolithoautotrophic way, meaning that they utilize CO2/HCO3 solely as their carbon sources. Such autotrophic behavior limits their competitiveness with heterotrophic microorganisms in both natural environments and engineered systems. Recently, environmental metagenomic results have indicated the capability of anammox bacteria to metabolize short-chain fatty acids, further confirmed by limited experimental evidence based on highly enriched cultures. However, clear evidence is difficult to get because of the limits of traditional methodologies which rely on the availability of a pure anammox culture. In this study, we identified and quantified the uptake of acetate and propionate, on a single-cell level, by an anammox consortium that was dominated by Candidatus Jettenia asiatica (relative abundance of 96%). The consortium, growing in granular form with an average relative abundance of anammox bacteria of 96.0%, was firstly incubated in a13C-labelled acetate or propionate medium; then microtome sections were scanned by a nanometer-scale secondary ion mass spectrometer (NanoSIMS). The NanoSIMS scannings revealed that the consortium enriched acetate and propionate at a >10 times higher efficiency than bicarbonate incorporation. Our results also suggest that acetate or propionate was likely not assimilated by J. asiatica directly, but firstly oxidized to CO2, which then served as carbon sources for the follow-up autotrophy in J. asiatica cells. Furthermore, more [15N]ammonium was enriched by the propionate-fed consortium than the acetate-fed consortium despite that exactly the same amount of 13C atoms were supplied. Our study strongly indicates an alternative lifestyle, namely organotrophy, in addition to chemolithoautotrophy of anammox bacteria, making it more versatile than often expected. It suggests that the niche of anammox bacteria in both natural and engineered ecosystems can be much broader than usual assumed. Recognising this is important for their role in wastewater treatment and the global nitrogen turn-over rates.

Published

2019

50. Determinants of sulphur chemolithoautotrophy in the extremely thermoacidophilicSulfolobales

Author

Mashkurul Haque, Robert M. Kelly, Lisa M. Keller, Andrew J. Loder, Karl A. Widney, Benjamin M. Zeldes, James A. Counts, and Sonja-Verena Albers

Subjects

inorganic chemicals, Sulfolobus acidocaldarius, Chemoautotrophic Growth, Oxygenase, Thiosulfates, Sulfolobus tokodaii, chemistry.chemical_element, Microbiology, 03 medical and health sciences, Oxidoreductase, Autotroph, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, chemistry.chemical_classification, Autotrophic Processes, 0303 health sciences, biology, 030306 microbiology, digestive, oral, and skin physiology, biology.organism_classification, Sulfur, chemistry, Biochemistry, Heterologous expression, Oxidoreductases, Sulfolobales, Oxidation-Reduction

Abstract

Species in the archaeal order Sulfolobales thrive in hot acid and exhibit remarkable metabolic diversity. Some species are chemolithoautotrophic, obtaining energy through the oxidation of inorganic substrates, sulphur in particular, and acquiring carbon through the 3-hydroxypropionate/4-hydroxybutyrate (3-HP/4-HB) CO2 -fixation cycle. The current model for sulphur oxidation in the Sulfolobales is based on the biochemical analysis of specific proteins from Acidianus ambivalens, including sulphur oxygenase reductase (SOR) that disproportionates S° into H2 S and sulphite (SO32- ). Initial studies indicated SOR catalyses the essential first step in oxidation of elemental sulphur, but an ancillary role for SOR as a 'recycle' enzyme has also been proposed. Here, heterologous expression of both SOR and membrane-bound thiosulphate-quinone oxidoreductase (TQO) from Sulfolobus tokodaii 'restored' sulphur oxidation capacity in Sulfolobus acidocaldarius DSM639, but not autotrophy, although earlier reports indicate this strain was once capable of chemolithoautotrophy. Comparative transcriptomic analyses of Acidianus brierleyi, a chemolithoautotrophic sulphur oxidizer, and S. acidocaldarius DSM639 showed that while both share a strong transcriptional response to elemental sulphur, S. acidocaldarius DSM639 failed to upregulate key 3-HP/4-HB cycle genes used by A. brierleyi to drive chemolithoautotrophy. Thus, the inability for S. acidocaldarius DSM639 to grow chemolithoautotrophically may be rooted more in gene regulation than the biochemical capacity.

Published

2019