Bergey's Manual of Systematics of Archaea and Bacteria

Abstract Ba.be.lo'ta. N.L. fem. n. Babela , a Candidatus genus name; L. neut. pl. n. suff. ‐ ota , ending to denote a phylum; N.L. neut. pl. n. Babelota , the Candidatus Babela phylum. Candidatus Babelota is a phylum of strictly intracellular bacteria, currently divided into two class‐level groups and at least five orders based on 16S rRNA sequence analyses. However, all known biological isolates to date belong to the same order of the Babelales, within the Babelia class. Presently, four isolates representing three families have been described and maintained in laboratory cultures through the cultivation of their hosts, which are known to be amoeboid and flagellated protists. Genomic analysis of Ca . Babelota consistently reveals a profound reduction in metabolic capabilities, suggesting a phylum‐wide, conserved parasitic lifestyle. To date, all lineages covered by genomic data indicate that parasitism is a defining trait of this phylum. Ca . Babelota exhibits a cosmopolitan environmental distribution, with sequences detected across a spectrum of habitats including soil, freshwater, and saline or hypersaline water bodies.

Abstract Na.no.pu.sil'lus. Gr. masc. n. nânos, a dwarf; L. masc. adj. pusillus, very small; N.L. masc. n. Nanopusillus, a very small member of the Nanoarchaeota . Nanoarchaeota / Nanobdellia / Nanobdellales / Nanobdellaceae / Candidatus Nanopusillus The genus Candidatus Nanopusillus is comprised of small coccoid cells (∼100–400 nm) that live epibiotically on the surface of archaeal hosts. The first described species, Candidatus Nanopusillus acidilobi, is an anaerobic, hyperthermophilic acidophile whose best growth is observed at 82°C, pH 3.6, cultivated from a hot spring in Yellowstone National Park. Ca . Nanopusillus acidilobi cells associate with the Crenarchaeota host organism Acidilobus sp. 7A. Archaeal flagella (archaella) have been predicted from the genome sequence and shown to be expressed in the proteome. A second putative species, Candidatus Nanopusillus massiliensis, was recently reported from human dental plaque and associates with the methanogen Methanobrevibacter oralis . The genome consists of a single scaffold which is highly fragmented by spans of ambiguous nucleotides, with 16S rRNA gene fragments from Bacteria . Both species have small genomes (∼0.6 Mb) encoding few biosynthetic genes and no apparent ATP synthase complex genes, suggesting that the nanoarchaeotes rely on their host for the production of major cellular precursors. DNA G + C content (mol%) : 24 (genome analysis). Type species : Candidatus Nanopusillus acidilobi Wurch et al. 2016.

Abstract Na.no.clep'ta. Gr. masc. n. nânos, a dwarf; Gr. masc. n. kleptês, a thief; N.L. masc. n. Nanoclepta, a small thief, a small organism that steals from its host. Nanoarchaeota / Nanobdellia / Nanobdellales / Nanobdellaceae / Candidatus Nanoclepta The genus Candidatus Nanoclepta currently comprises a single species, Candidatus Nanoclepta minutus Ncl‐1, an anaerobic hyperthermophile (optimal growth observed from 80 to 85°C) cultivated from a New Zealand hot spring. Cells are ultra‐small cocci (∼200 nm) with archaeal flagella and are cultivated in near‐neutral pH conditions (pH ∼6.0). Like several other Nanoarchaeota , Ca . N. minutus cells are epibionts on the surface of a host from the Crenarchaeota . Although this symbiosis is obligate for Ca . N. minutus, the relationship is not required for the host, Zestosphaera tikiterensis NZ3 T , which can survive as a free‐living organism. Ca . N. minutus has a highly reduced genome (∼0.58 Mb) with minimal biosynthetic potential and no detected ATP synthase genes, and Ca . Nanoclepta cells likely rely on their host for many metabolic precursors. DNA G + C content (mol%) : 32.2 (genome analysis). Type species : Candidatus Nanoclepta minutus St. John et al. 2019a.

Abstract Thi.o.ha.lo.rhab.dal'es N.L. fem. n. Thiohalorhabdus , the type genus of the order; L. fem. pl. n. suff. ‐ ales ending to denote an order; N.L. fem. pl. n. Thiohalorhabdales , order of the genus Thiohalorhabdus . Proteobacteria / Gammaproteobacteria / Thiohalorhabdales ord. nov. According to the phylogenomic analysis, the order Thiohalorhabdales forms a deeply branching phylogenetic lineage at the base of the Gammaproteobacteria . It consists of a single family Thiohalorhabdaceae and genus Thiohalorhabdus . The cultured members of the order are extremely halophilic, facultatively anaerobic (denitrifying), chemolithoautotrophic, sulfur‐oxidizing bacteria from hypersaline habitats with neutral pH. Type genus : Thiohalorhabdus Sorokin et al. 2008 VP .

Abstract Thi.o.ha.lo.bac.ter.a.ce'ae N.L. masc. n. Thiohalobacter , the type genus of the family, ‐ aceae ending to denote a family; N.L. fem. pl. n. Thiohalobacteraceae the Thiohalobacter family. Proteobacteria / Gammaproteobacteria / Thiohalobacterales / Thiohalobacteraceae fam. nov. The family Thiohalobacteraceae consists of aerobic, chemolithoautotrophic, sulfur‐oxidizing bacteria from hypersaline salt lakes. They are moderately halophilic aerobic, bacteria utilizing reduced sulfur compounds as the energy source and assimilating CO 2 via the Calvin–Benson–Bassham cycle. The family is a member of the order Thiohalobacterales within the Gammaproteobacteria and consists of a single genus Thiohalobacter . The family‐level status was established by phylogenomic analysis based on the Genome Taxonomy DataBase classification. DNA G + C content (%) : 64.2 (genome sequence). Type genus : Thiohalobacter Sorokin et al. 2010 VP .

Abstract Thi.o.ha.lo.bac.ter.al'es N.L. masc. n. Thiohalobacter , the type genus of the order; L. fem. pl. n. suff. ‐ ales , ending to denote an order; N.L. fem. pl. n. Thiohalobacterales , the order of the genus Thiohalobacter . Proteobacteria / Gammaproteobacteria / Thiohalobacterales ord. nov. The order Thiohalobacterales accommodates obligately chemolithoautotrophic aerobic bacteria utilizing inorganic sulfur compounds as the energy source and assimilating CO 2 via the Calvin–Benson–Bassham cycle. The order is a deeply branching member of the Gammaproteobacteria and consists of two families Thiohalobacteraceae and Thiogranaceae, both of which include one genus. The order‐level status was established by phylogenomic analysis based on the Genome Taxonomy DataBase classification. Type genus : Thiohalobacter Sorokin et al. 2010 VP .

Abstract Thi.o.ha.lo.rhab.da.ce'ae N.L. fem. n. Thiohalorhabdus , the type genus of the family; L. fem. pl. n. suff.‐ aceae , ending to denote a family; N.L. fem. pl. n. Thiohalorhabdaceae , the Thiohalorhabdus family. Proteobacteria / Gammaproteobacteria / Thiohalorhabdales / Thiohalorhabdaceae fam. nov. The family Thiohalorhabdaceae incorporates facultatively anaerobic, chemolithoautotrophic, sulfur‐oxidizing bacteria from hypersaline habitats. They are extreme halophiles utilizing reduced sulfur compounds as energy sources with either O 2 or nitrate as the electron acceptor and assimilating CO 2 via the Calvin–Benson–Bassham cycle. The family is a member of the order Thiohalorhabdales in the Gammaproteobacteria, and it consists of a single genus Thiohalorhabdus . The family‐level status was established by phylogenomic analysis based on the Genome Taxonomy DataBase classification. DNA G  +  C content (%) : 68.9 (genome of the type strain). Type genus : Thiohalorhabdus Sorokin et al. 2008 VP .

Abstract Sil.va.ni.grel'la. N.L. fem. dim. n. Silvanigrella named after Silva nigra the Latin geographic name of the Schwarzwald (Black Forest) mountains located in the south‐west of Germany. Proteobacteria / Oligoflexia / Silvanigrellales / Silvanigrellaceae / Silvanigrella The genus Silvanigrella accommodates heterotrophic freshwater bacteria isolated from the water column of circumneutral or slightly acidic (pH 5–7) lakes and ponds with low ion concentrations (conductivity < 30 μS/cm). So far, only the two species Silvanigrella aquatica and Silvanigrella paludirubra have been described. Cells of the type strains have in common red pigmentation, motility, and pleomorphic morphology. In both species, the cell morphology ranges from rod‐shaped cells to filamentous forms, the cell size is variable in length and width. The type strain of S. aquatica in addition forms, densely coiled spirals. The type strains of both species grow at temperatures above 30°C, but only the type strain of S. paludirubra grows at temperatures below 10°C. Growth occurred up to supplementary NaCl concentrations of 1.0–1.1% (w/v). Both type strains utilized various organic substrates including carbohydrates, amino acids, and short‐chain fatty acids; however, the substrate spectra of the two strains differed. The most abundant fatty acid was iso‐C 15:0 for both type strains, contributing 33% to the total fatty acid content. The major respiratory quinone of S. paludirubra is menaquinone MK‐8, while the quinones of S. aquatica remained unidentified. The type strains of S. aquatica and S. paludirubra were both characterized by medium‐sized genomes (3.5 and 3.9 Mb, respectively) with low G + C content (32.6 and 29.3 mol%, respectively). DNA G + C content (mol%) : 29–33 (genome sequencing). Type species : Silvanigrella aquatica Hahn et al. 2017 VP .