Lian, Zheng-Han

Publications
5

Genome-guided isolation of the hyperthermophilic aerobe Fervidibacter sacchari reveals conserved polysaccharide metabolism in the Armatimonadota

Citation: Nou et al. (2024). Nature Communications 15 (1)
Names: “Fervidibacter antarcticus” Thermosaccharophagus gerlachensis ^Ts Fervidibacter canadensis Thermosaccharophagus yellowstonensis Fervidibacter sacchari ^Ts Fervidibacteria Fervidibacterales Fervidibacteraceae Fervidibacter Thermosaccharophagaceae Thermosaccharophagus Caldisaccharidevorator sinensis ^Ts Fervidibacter sinensis Fervidibacter japonicus Caldisaccharidevorator Caldisaccharidevorator malaysiensis Thermosaccharophagus tengchongensis
Abstract

Insights into chemoautotrophic traits of a prevalent bacterial phylum CSP1-3, herein Sysuimicrobiota

Citation: Liu et al. (2024). National Science Review
Names: Sysuimicrobium Segetimicrobium genomatis ^Ts Segetimicrobium Geohabitans Sysuimicrobium tengchongense Fervidifonticultor quartus Fervidifonticultor secundus Humicultor Kaftiobacterium Segetimicrobiaceae Geohabitans tengchongensis ^Ts Sysuimicrobiia Sysuimicrobiota Sysuimicrobiales Sysuimicrobiaceae Kaftiobacterium secundum ^Ts Kaftiobacteriaceae Thermofontivivens Thermofontiviventaceae Thermofontivivens primus ^Ts Tepidifontimicrobium thermophilum ^Ts Tepidifontimicrobium Caldifonticola Sysuimicrobium calidum ^Ts Fervidifonticultor tertius Fervidifonticultor Humicultoraceae Calidihabitans tengchongensis ^Ts Calidihabitans Caldifonticola tengchongensis ^Ts Humicultor tengchongensis ^Ts Fervidifonticultor primus ^Ts
Abstract: Abstract Candidate bacterial phylum CSP1-3 has not been cultivated and is poorly understood. Here, we analyzed 112 CSP1-3 metagenome-assembled genomes (MAGs) and showed they are likely facultative anaerobes, with three of five families encoding autotrophy through the reductive glycine pathway (RGP), Wood–Ljungdahl pathway (WLP), or Calvin-Benson-Bassham (CBB), with hydrogen or sulfide as electron donors. Chemoautotrophic enrichments from hot spring sediments and fluorescence in si

Cultivation of novel Atribacterota from oil well provides new insight into their diversity, ecology, and evolution in anoxic, carbon-rich environments

Citation: Jiao et al. (2024). Microbiome 12 (1)
Names: “Oleincola secundus” “Atribacter hydrocarboniphilus” “Profundicultor thermophilus” “Sordicultor fermentans” “Stramentimicrobium fermentans” “Infernicultor aquiphilus” “Sediminicultor sextus” “Sediminicultor quintus” “Sediminicultor quartus” “Sediminicultor tertius” “Sediminicultor secundus” “Sediminicultor” “Immundihabitans aquiphilus” “Phoenicimicrobiales” “Atribacter allofermentans” “Atribacter alterifermentans” “Atribacter fermentans” “Caldatribacterium thermophilum” “Nitricultor siberiensis” “Nitricultor lacus” “Caldatribacterium caloriphilum” “Profundicultor aquiphilus” “Profundicultor” “Sordicultor aquaticus” “Sordicultor” “Nitricultor” “Phoenicimicrobiia” “Stramentimicrobiaceae” “Stramentimicrobium” “Oleincola” “Phoenicimicrobiaceae” “Phoenicimicrobium” “Phoenicimicrobium oleiphilum” “Immundihabitans” “Infernicultor”
Abstract: Abstract Background The Atribacterota are widely distributed in the subsurface biosphere. Recently, the first Atribacterota isolate was described and the number of Atribacterota genome sequences retrieved from environmental samples has increased significantly; however, their diversity, physiology, ecology, and evolution remain poorly understood. Results We report the isolation of the second member of Atribacterota, Th

Hyperactive nanobacteria with host-dependent traits pervade Omnitrophota

Citation: Seymour et al. (2023). Nature Microbiology 8 (4)
Names: “Zapsychrus unditaenarius” Velaminicoccus archaeovorus ^Ts Velaminicoccus Multiplicimicrobium Fredricksoniimonas aquilentivivens ^Ts “Amyimicrobium” Omnitrophia Omnitrophales Omnitrophaceae Pluralincolimonas frigidipaludosa ^Ts “Fontincolimonas calida” “Profunditerraquicola sanfordiae” Fredricksoniimonas borealis Duberdicusella sinuisediminis ^Ts Phelpsiimicrobium noxiivivens ^Ts Velesiimonas alkalicola ^Ts Aquitaenariimonas noxiae ^Ts Aquincolibacterium aerophilum ^Ts Aquincolibacterium lacustre Multiplicimicrobium inquinatum ^Ts Pegaeibacterium caenilacustre ^Ts Danuiimicrobium aquiferis ^Ts Taenariivivens baikalensis ^Ts Aquivivens invisus ^Ts Abzuiibacterium crystallinum ^Ts Makaraimicrobium Aquincolibacterium Pegaeibacterium Aquivivens Duberdicusellaceae Pluralincolimonadaceae Taenariiviventaceae Aquincolibacteriaceae Aquiviventaceae Duberdicusellales Ghiorseimicrobiales Aquitaenariimonadales Velesiimonadales Aquiviventales Undivivens Taenaricolales Undivivens industriae ^Ts Sherwoodlollariibacterium unditelluris ^Ts Sherwoodlollariibacterium “Fontincolimonas” Aquitaenariimonadaceae “Profunditerraquicola” “Profunditerraquicolaceae” “Amyimicrobium silvilacustre” Ghiorseimicrobiaceae Ghiorseimicrobium Ghiorseimicrobium undicola ^Ts Fredricksoniimonadaceae Fredricksoniimonas Phelpsiimicrobium Pluralincolimonadales Duberdicusella Velesiimonadaceae Velesiimonas Taenaricolaceae Taenaricola Taenaricola geysiri ^Ts Pluralincolimonas Aquitaenariimonas Makaraimicrobium thalassicum ^Ts Taenariivivens Danuiimicrobiaceae Danuiimicrobium Aquiviventia Abzuiibacterium Abzuiibacteriaceae Omnitrophus Omnitrophus fodinae ^Ts Omnitrophota
Abstract: AbstractCandidate bacterial phylum Omnitrophota has not been isolated and is poorly understood. We analysed 72 newly sequenced and 349 existing Omnitrophota genomes representing 6 classes and 276 species, along with Earth Microbiome Project data to evaluate habitat, metabolic traits and lifestyles. We applied fluorescence-activated cell sorting and differential size filtration, and showed that most Omnitrophota are ultra-small (~0.2 μm) cells that are found in water, sediments and soils. Omnitro

Insights into ecological role of a new deltaproteobacterial order Candidatus Acidulodesulfobacterales by metagenomics and metatranscriptomics

Citation: Tan et al. (2019). The ISME Journal 13 (8)
Names: Ca. Acidulodesulfobacterales
Abstract