Evans, Paul N.


Publications
7

CitationNamesAbstract
Panguiarchaeum symbiosum, a potential hyperthermophilic symbiont in the TACK superphylum Qu et al. (2023). Cell Reports 42 (3) Panguiarchaeum Panguiarchaeaceae Panguiarchaeales Panguiarchaeum symbiosum Ts
Comparative Genomics Reveals Thermal Adaptation and a High Metabolic Diversity in “ Candidatus Bathyarchaeia” Qi et al. (2021). mSystems 6 (4) Bathyarchaeia
Recoding of stop codons expands the metabolic potential of two novel Asgardarchaeota lineages Sun et al. (2021). ISME Communications 1 (1) Ca. Borrarchaeum weybense “Jordiarchaeum” “Jordiarchaeum madagascariense” “Sifarchaeaceae” “Jordiarchaeaceae” “Sifarchaeales” “Jordiarchaeales” “Sifarchaeia” “Jordiarchaeia” “Borrarchaeaceae” Ca. Borrarchaeum “Sifarchaeum” Ca. Sifarchaeum marinoarchaea Ca. Sifarchaeum subterraneus “Sifarchaeota”
Insights into the ecological roles and evolution of methyl-coenzyme M reductase-containing hot spring Archaea Hua et al. (2019). Nature Communications 10 (1) Ca. Methanoproducendum senex
Genome-centric view of carbon processing in thawing permafrost Woodcroft et al. (2018). Nature 560 (7716) “Methanoflorentales” “Acidiflorens” “Changshengia” “Acidiflorens stordalenmirensis” “Methanoflorens crillii” “Methanoflorentaceae”
Recovery of nearly 8,000 metagenome-assembled genomes substantially expands the tree of life Parks et al. (2017). Nature Microbiology 2 (11) Binatus soli Ts Binatus
Methylotrophic methanogenesis discovered in the archaeal phylum Verstraetearchaeota Vanwonterghem et al. (2016). Nature Microbiology 1 (12) Ca. Methanomethylicia Ca. Methanomethylicus Ca. Methanomethylicus mesodigestus Ca. Methanomethylicus oleisabuli “Methanosuratincola petrocarbonis” “Methanosuratincola” Ca. Methanomethylicaceae Ca. Methanomethylicales “Methanomethylicota”