Your search keyword '"Jay, Zackary J."' showing total 2 results

1. Methyl-reducing methanogenesis by a thermophilic culture of Korarchaeia.

Author

Krukenberg, Viola, Kohtz, Anthony J., Jay, Zackary J., and Hatzenpichler, Roland

Abstract

Methanogenesis mediated by archaea is the main source of methane, a strong greenhouse gas, and thus is critical for understanding Earth’s climate dynamics. Recently, genes encoding diverse methanogenesis pathways have been discovered in metagenome-assembled genomes affiliated with several archaeal phyla1–7. However, all experimental studies on methanogens are at present restricted to cultured representatives of the Euryarchaeota. Here we show methanogenic growth by a member of the lineage Korarchaeia within the phylum Thermoproteota (TACK superphylum)5–7. Following enrichment cultivation of ‘Candidatus Methanodesulfokora washburnenis’ strain LCB3, we used measurements of metabolic activity and isotope tracer conversion to demonstrate methanol reduction to methane using hydrogen as an electron donor. Analysis of the archaeon’s circular genome and transcriptome revealed unique modifications in the energy conservation pathways linked to methanogenesis, including enzyme complexes involved in hydrogen and sulfur metabolism. The cultivation and characterization of this new group of archaea is critical for a deeper evaluation of the diversity, physiology and biochemistry of methanogens.We show methanogenic growth by a member of the lineage Korarchaeia and, following cultivation, methanol reduction to methane using hydrogen as an electron donor, which could be critical for a thorough evaluation of methanogens. [ABSTRACT FROM AUTHOR]

Published

2024

2. Cultivation and visualization of a methanogen of the phylum Thermoproteota.

Author

Kohtz, Anthony J., Petrosian, Nikolai, Krukenberg, Viola, Jay, Zackary J., Pilhofer, Martin, and Hatzenpichler, Roland

Abstract

Methane is the second most abundant climate-active gas, and understanding its sources and sinks is an important endeavour in microbiology, biogeochemistry, and climate sciences1,2. For decades, it was thought that methanogenesis, the ability to conserve energy coupled to methane production, was taxonomically restricted to a metabolically specialized group of archaea, the Euryarchaeota1. The discovery of marker genes for anaerobic alkane cycling in metagenome-assembled genomes obtained from diverse habitats has led to the hypothesis that archaeal lineages outside the Euryarchaeota are also involved in methanogenesis3–6. Here we cultured Candidatus Methanosuratincola verstraetei strain LCB70, a member of the archaeal class Methanomethylicia (formerly Verstraetearchaeota) within the phylum Thermoproteota, from a terrestrial hot spring. Growth experiments combined with activity assays, stable isotope tracing, and genomic and transcriptomic analyses demonstrated that this thermophilic archaeon grows by means of methyl-reducing hydrogenotrophic methanogenesis. Cryo-electron tomography revealed that Ca. M. verstraetei are coccoid cells with archaella and chemoreceptor arrays, and that they can form intercellular bridges connecting two to three cells with continuous cytoplasm and S-layer. The wide environmental distribution of Ca. M. verstraetei suggests that they might play important and hitherto overlooked roles in carbon cycling within diverse anoxic habitats.We demonstrate that the ability to conserve energy coupled to methane production is not restricted to the Euryarchaeota and is much more widespread than originally thought. [ABSTRACT FROM AUTHOR]

Published

2024