Your search keyword '"Michiel H. in 't Zandt"' showing total 7 results

1. Roles of Thermokarst Lakes in a Warming World

Author

Susanne Liebner, Cornelia U. Welte, and Michiel H. in 't Zandt

Subjects

Microbiology (medical), Greenhouse Effect, Geologic Sediments, Earth science, Climate Change, Climate change, chemistry.chemical_element, Biology, Permafrost, Microbiology, Global Warming, Methane, Thermokarst, Atmosphere, 03 medical and health sciences, chemistry.chemical_compound, Virology, 030304 developmental biology, 0303 health sciences, geography, geography.geographical_feature_category, Bacteria, 030306 microbiology, Arctic Regions, Temperature, Carbon Dioxide, Archaea, Lakes, Infectious Diseases, chemistry, Greenhouse gas, Ecological Microbiology, Carbon dioxide, Carbon

Abstract

Permafrost covers a quarter of the northern hemisphere land surface and contains twice the amount of carbon that is currently present in the atmosphere. Future climate change is expected to reduce its near-surface cover by over 90% by the end of the 21st century, leading to thermokarst lake formation. Thermokarst lakes are point sources of carbon dioxide and methane which release long-term carbon stocks into the atmosphere, thereby initiating a positive climate feedback potentially contributing up to a 0.39°C rise of surface air temperatures by 2300. This review describes the potential role of thermokarst lakes in a warming world and the microbial mechanisms that underlie their contributions to the global greenhouse gas budget.

Published

2020

2. Amsterdam urban canals contain novel niches for methane-cycling microorganisms

Author

Koen A J Pelsma, Michiel H. in 't Zandt, Mike S. M. Jetten, Joshua F. Dean, Cornelia U. Welte, and Huub J. M. Op den Camp

Subjects

Methanotroph, Microorganism, Euryarchaeota, 010501 environmental sciences, Biology, 01 natural sciences, Microbiology, Methylococcaceae, Carbon cycle, 03 medical and health sciences, RNA, Ribosomal, 16S, Humans, Methanosaetaceae, Ecosystem, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0105 earth and related environmental sciences, 0303 health sciences, Ecology, Aquatic ecosystem, 15. Life on land, biology.organism_classification, 13. Climate action, Ecological Microbiology, Anaerobic oxidation of methane, Microcosm, Methane, Oxidation-Reduction

Abstract

Urbanised environments have been identified as hotspots of anthropogenic methane emissions. Especially urban aquatic ecosystems are increasingly recognised as important sources of methane. However, the microbiology behind these emissions remains unexplored. Here, we applied microcosm incubations and molecular analyses to investigate the methane-cycling community of the Amsterdam canal system in the Netherlands. The sediment methanogenic communities were dominated by Methanoregulaceae and Methanosaetaceae, with co-occurring methanotrophic Methanoperedenaceae and Methylomirabilaceae indicating the potential for anaerobic methane oxidation. Methane was readily produced after substrate amendment, suggesting an active but substrate-limited methanogenic community. Bacterial 16 S rRNA gene amplicon sequencing of the sediment revealed a high relative abundance of Thermodesulfovibrionia. Canal wall biofilms showed the highest initial methanotrophic potential under oxic conditions compared to the sediment. During prolonged incubations the maximum methanotrophic rate increased to 8.08 mmol gDW-1 d-1 that was concomitant with an enrichment of Methylomonadaceae bacteria. Metagenomic analysis of the canal wall biofilm lead to the recovery of a single methanotroph metagenome-assembled genome. Taxonomic analysis showed that this methanotroph belongs to the genus Methyloglobulus Our results underline the importance of previously unidentified and specialised environmental niches at the nexus of the natural and human-impacted carbon cycle. This article is protected by copyright. All rights reserved.

Published

2022

3. The Polar Fox Lagoon in Siberia harbours a community of Bathyarchaeota possessing the potential for peptide fermentation and acetogenesis

Author

Tom Berben, Franco Forlano Bó, Michiel H. in ‘t Zandt, Sizhong Yang, Susanne Liebner, and Cornelia U. Welte

Subjects

Formates, Polymers, General Medicine, Microbiology, Archaea, Carbon, Siberia, Greenhouse Gases, Hydrogenase, Ecological Microbiology, Fermentation, Ferredoxins, Peptides, Molecular Biology, Methane, Hydrogen

Abstract

Archaea belonging to the phylum Bathyarchaeota are the predominant archaeal species in cold, anoxic marine sediments and additionally occur in a variety of habitats, both natural and man-made. Metagenomic and single-cell sequencing studies suggest that Bathyarchaeota may have a significant impact on the emissions of greenhouse gases into the atmosphere, either through direct production of methane or through the degradation of complex organic matter that can subsequently be converted into methane. This is especially relevant in permafrost regions where climate change leads to thawing of permafrost, making high amounts of stored carbon bioavailable. Here we present the analysis of nineteen draft genomes recovered from a sediment core metagenome of the Polar Fox Lagoon, a thermokarst lake located on the Bykovsky Peninsula in Siberia, Russia, which is connected to the brackish Tiksi Bay. We show that the Bathyarchaeota in this lake are predominantly peptide degraders, producing reduced ferredoxin from the fermentation of peptides, while degradation pathways for plant-derived polymers were found to be incomplete. Several genomes encoded the potential for acetogenesis through the Wood-Ljungdahl pathway, but methanogenesis was determined to be unlikely due to the lack of genes encoding the key enzyme in methanogenesis, methyl-CoM reductase. Many genomes lacked a clear pathway for recycling reduced ferredoxin. Hydrogen metabolism was also hardly found: one type 4e [NiFe] hydrogenase was annotated in a single MAG and no [FeFe] hydrogenases were detected. Little evidence was found for syntrophy through formate or direct interspecies electron transfer, leaving a significant gap in our understanding of the metabolism of these organisms.

Published

2022

4. Co-cultivation of the strictly anaerobic methanogen Methanosarcina barkeri with aerobic methanotrophs in an oxygen-limited membrane bioreactor

Author

Michiel H. in 't Zandt, Tijs J. M. van den Bosch, Cornelia U. Welte, Maartje A. H. J. van Kessel, Mike S. M. Jetten, and Ruud Rijkers

Subjects

0301 basic medicine, Methanogenesis, Methanogens, Microorganism, 030106 microbiology, ved/biology.organism_classification_rank.species, Methane cycle, Membrane bioreactor, Applied Microbiology and Biotechnology, Methane, 03 medical and health sciences, chemistry.chemical_compound, Aggregation, Bioreactors, Methanotrophs, Bioreactor, Environmental Microbiology, In Situ Hybridization, Fluorescence, biology, Chemistry, ved/biology, General Medicine, biology.organism_classification, Methanogen, 6. Clean water, Oxygen, 030104 developmental biology, Applied Microbial and Cell Physiology, 13. Climate action, Environmental chemistry, Ecological Microbiology, Methylocystaceae, Microbial Interactions, Methanosarcina barkeri, Co-culture, Biotechnology

Abstract

Wetlands contribute to 30% of global methane emissions due to an imbalance between microbial methane production and consumption. Methanogenesis and methanotrophy have mainly been studied separately, and little is known about their potential interactions in aquatic environments. To mimic the interaction between methane producers and oxidizers in the environment, we co-cultivated the methanogenic archaeon Methanosarcina barkeri with aerobic Methylocystaceae methanotrophs in an oxygen-limited bioreactor using acetate as methanogenic substrate. Methane, acetate, dissolved oxygen, available nitrogen, pH, temperature, and cell density were monitored to follow system stability and activity. Stable reactor operation was achieved for two consecutive periods of 2 months. Fluorescence in situ hybridization micrographs indicated close association between both groups of microorganisms. This association suggests that the methanotrophs profit from direct access to the methane that is produced from acetate, while methanogens are protected by the concomitant oxygen consumption of the methanotrophs. This proof of principle study can be used to set up systems to study their responses to environmental changes. Electronic supplementary material The online version of this article (10.1007/s00253-018-9038-x) contains supplementary material, which is available to authorized users.

Published

2018

5. Nutrient and acetate amendment leads to acetoclastic methane production and microbial community change in a non-producing Australian coal well

Author

Mike Manefield, Sabrina Beckmann, Mike S. M. Jetten, Ruud Rijkers, Michiel H. in 't Zandt, and Cornelia U. Welte

Subjects

0301 basic medicine, Geologic Sediments, Coalbed methane, 030106 microbiology, Amendment, Bioengineering, Acetates, complex mixtures, Applied Microbiology and Biotechnology, Biochemistry, Methane, 03 medical and health sciences, chemistry.chemical_compound, Bioenergy, Coal, Research Articles, 2. Zero hunger, Bacteria, biology, Ecology, business.industry, Microbiota, Australia, Fungi, Coal mining, biology.organism_classification, Coal Mining, Microbial population biology, chemistry, 13. Climate action, Ecological Microbiology, Environmental chemistry, Metagenome, Environmental science, business, Research Article, Biotechnology, Geobacter

Abstract

Contains fulltext : 176750.pdf (Publisher’s version ) (Open Access) Coal mining is responsible for 11% of total anthropogenic methane emission thereby contributing considerably to climate change. Attempts to harvest coalbed methane for energy production are challenged by relatively low methane concentrations. In this study, we investigated whether nutrient and acetate amendment of a non-producing sub-bituminous coal well could transform the system to a methane source. We tracked cell counts, methane production, acetate concentration and geochemical parameters for 25 months in one amended and one unamended coal well in Australia. Additionally, the microbial community was analysed with 16S rRNA gene amplicon sequencing at 17 and 25 months after amendment and complemented by metagenome sequencing at 25 months. We found that cell numbers increased rapidly from 3.0 x 104 cells ml-1 to 9.9 x 107 in the first 7 months after amendment. However, acetate depletion with concomitant methane production started only after 12-19 months. The microbial community was dominated by complex organic compound degraders (Anaerolineaceae, Rhodocyclaceae and Geobacter spp.), acetoclastic methanogens (Methanothrix spp.) and fungi (Agaricomycetes). Even though the microbial community had the functional potential to convert coal to methane, we observed no indication that coal was actually converted within the time frame of the study. Our results suggest that even though nutrient and acetate amendment stimulated relevant microbial species, it is not a sustainable way to transform non-producing coal wells into bioenergy factories.

Published

2017

6. Increases in temperature and nutrient availability positively affect methane-cycling microorganisms in Arctic thermokarst lake sediments

Author

Michiel H. in 't Zandt, Mike S. M. Jetten, Olivia Rasigraf, Cornelia U. Welte, Ove H. Meisel, Joshua F. Dean, Anniek E. E. de Jong, and Earth and Climate

Subjects

0301 basic medicine, Geologic Sediments, Climate Change, 030106 microbiology, Biology, Permafrost, Microbiology, Methane, Thermokarst, 03 medical and health sciences, chemistry.chemical_compound, Nitrate, RNA, Ribosomal, 16S, SDG 13 - Climate Action, Organic matter, SDG 14 - Life Below Water, Research Articles, Ecology, Evolution, Behavior and Systematics, chemistry.chemical_classification, geography, geography.geographical_feature_category, Arctic Regions, Microbiota, Temperature, Methanosarcinaceae, Nutrients, Carbon Dioxide, Lakes, chemistry, Arctic, Microbial population biology, 13. Climate action, Environmental chemistry, Ecological Microbiology, Methylococcaceae, Carbon dioxide, Alaska, Research Article

Abstract

Contains fulltext : 198842.pdf (Publisher’s version ) (Open Access) Arctic permafrost soils store large amounts of organic matter that is sensitive to temperature increases and subsequent microbial degradation to methane (CH 4 ) and carbon dioxide (CO 2 ). Here, we studied methanogenic and methanotrophic activity and community composition in thermokarst lake sediments from Utqiag vik (formerly Barrow), Alaska. This experiment was carried out under in situ temperature conditions (4 degrees C) and the IPCC 2013 Arctic climate change scenario (10 degrees C) after addition of methanogenic and methanotrophic substrates for nearly a year. Trimethylamine (TMA) amendment with warming showed highest maximum CH 4 production rates, being 30% higher at 10 degrees C than at 4 degrees C. Maximum methanotrophic rates increased by up to 57% at 10 degrees C compared to 4 degrees C. 16S rRNA gene sequencing indicated high relative abundance of Methanosarcinaceae in TMA amended incubations, and for methanotrophic incubations Methylococcaeae were highly enriched. Anaerobic methanotrophic activity with nitrite or nitrate as electron acceptor was not detected. This study indicates that the methane cycling microbial community can adapt to temperature increases and that their activity is highly dependent on substrate availability. 01 december 2018

Published

2018

7. The hunt for the most-wanted chemolithoautotrophic spookmicrobes

Author

Mike S. M. Jetten, Anniek E. E. de Jong, Michiel H. in 't Zandt, Caroline P. Slomp, Bio-, hydro-, and environmental geochemistry, and Geochemistry

Subjects

0301 basic medicine, Chemoautotrophic Growth, Microorganism, 030106 microbiology, Microbial metabolism, iron reduction, Applied Microbiology and Biotechnology, Microbiology, nitrogen, diversity, 03 medical and health sciences, Soil, Ammonium Compounds, Anaerobiosis, Nitrites, Nitrates, Ecology, biology, Bacteria, methane, Comammox, Methanosarcinales, Nitrogen Cycle, biology.organism_classification, Editor's Choice, 030104 developmental biology, Anammox, Environmental chemistry, Ecological Microbiology, anaerobic, Candidatus, anammox, Minireview, Nitrospira, Oxidation-Reduction, Archaea

Abstract

Microorganisms are the drivers of biogeochemical methane and nitrogen cycles. Essential roles of chemolithoautotrophic microorganisms in these cycles were predicted long before their identification. Dedicated enrichment procedures, metagenomics surveys and single-cell technologies have enabled the identification of several new groups of most-wanted spookmicrobes, including novel methoxydotrophic methanogens that produce methane from methylated coal compounds and acetoclastic ‘Candidatus Methanothrix paradoxum’, which is active in oxic soils. The resultant energy-rich methane can be oxidized via a suite of electron acceptors. Recently, ‘Candidatus Methanoperedens nitroreducens’ ANME-2d archaea and ‘Candidatus Methylomirabilis oxyfera’ bacteria were enriched on nitrate and nitrite under anoxic conditions with methane as an electron donor. Although ‘Candidatus Methanoperedens nitroreducens’ and other ANME archaea can use iron citrate as an electron acceptor in batch experiments, the quest for anaerobic methane oxidizers that grow via iron reduction continues. In recent years, the nitrogen cycle has been expanded by the discovery of various ammonium-oxidizing prokaryotes, including ammonium-oxidizing archaea, versatile anaerobic ammonium-oxidizing (anammox) bacteria and complete ammonium-oxidizing (comammox) Nitrospira bacteria. Several biogeochemical studies have indicated that ammonium conversion occurs under iron-reducing conditions, but thus far no microorganism has been identified. Ultimately, iron-reducing and sulfate-dependent ammonium-oxidizing microorganisms await discovery., In this review, we highlight the most-wanted methane- and ammonia-oxidizing spookmicrobes discovered in the past quarter century.

Published

2018