Williams, Timothy J


Publications
2

Candidatus Eremiobacterota, a metabolically and phylogenetically diverse terrestrial phylum with acid-tolerant adaptations

Citation
Ji et al. (2021). The ISME Journal 15 (9)
Names
“Eremiobacterota” “Mawsoniella” “Mawsoniella australis” “Cryoxeromicrobium” “Cryoxeromicrobium davisii” “Nyctobacter” “Nyctobacter psychrophilus” “Erabacter” “Erabacter solicola” “Hesperobacter” “Hesperobacter lustricola” “Meridianibacter” “Meridianibacter frigidus” “Aquilonibacter” “Aquilonibacter stordalenmirensis” “Tyrphobacter” “Tyrphobacter aquilonaris” “Tumulicola” “Tumulicola scandinaviensis” “Cybelea” “Cybelea septentrionalis” “Cybelea tumulisoli” “Cybelea tyrphae” “Cybelea palsarum” “Palsibacter” “Palsibacter borealis” “Hemerobacter” “Hemerobacter limicola” “Velthaea” “Velthaea versatilis” “Lustribacter” “Lustribacter caenicola” “Lustribacter telmatis” “Elarobacter” “Elarobacter winogradskyi” “Elarobacter vanleeuwenhoeki” “Elarobacter pasteuri” “Elarobacter beijerinckii” “Tityobacter” “Tityobacter terrigena” “Xenobium” “Xenobium occultum” “Bruticola” “Bruticola papionis” “Xenobium purgamenti” “Xenobiaceae” “Eremiobacterales” “Eremiobacteraceae” “Eremiobacter” “Eremiobacter antarcticus” “Eremiobacteria” “Zemelea palustris” “Zemelea” “Xenobiales” “Xenobiia”
Abstract
Abstract Candidatus phylum Eremiobacterota (formerly WPS-2) is an as-yet-uncultured bacterial clade that takes its name from Ca. Eremiobacter, an Antarctic soil aerobe proposed to be capable of a novel form of chemolithoautotrophy termed atmospheric chemosynthesis, that uses the energy derived from atmospheric H2-oxidation to fix CO2 through the Calvin-Benson-Bassham (CBB) cycle via type 1E RuBisCO. To elucidate the phylogenetic affiliation and metabolic capacities of Ca. Eremioba

Phylogeny resolved, metabolism revealed: functional radiation within a widespread and divergent clade of sponge symbionts

Citation
Taylor et al. (2021). The ISME Journal 15 (2)
Names
Perseibacter sydneyensis Ts Perseibacter Perseibacteraceae Tethybacter castelli Ts Tethybacter Tethybacteraceae Tethybacterales
Abstract
Abstract The symbiosis between bacteria and sponges has arguably the longest evolutionary history for any extant metazoan lineage, yet little is known about bacterial evolution or adaptation in this process. An example of often dominant and widespread bacterial symbionts of sponges is a clade of uncultured and uncharacterised Proteobacteria. Here we set out to characterise this group using metagenomics, in-depth phylogenetic analyses, metatranscriptomics, and fluorescence in situ