Yuki, Masahiro

Abstract Members of the phylum Deferribacterota inhabit diverse environments, but their symbiosis with protists has never been reported. We discovered an ectosymbiotic clade of Deferribacterota specifically associated with spirotrichonymphid protists in the guts of the termites Reticulitermes speratus and Hodotermopsis sjostedti and trichonymphid protists in the gut of the wood-feeding cockroach Cryptocercus punctulatus. The ectosymbiotic Deferribacterota were spiral shaped and attached to 16%–91% of the host protist cells. These formed a monophyletic cluster within an uncultured insect gut-associated family-level clade, which is sister to the vertebrate gut-associated family Mucispirillaceae. The complete genome of an ectosymbiotic Deferribacterota was obtained from a Trichonympha acuta cell in a C. punctulatus gut and analyzed together with a single-cell amplified genome of another ectosymbiotic Deferribacterota associated with Holomastigotes sp. in the gut of R. speratus. Genome analyses suggest that these Deferribacterota ferment monosaccharides and conduct fumarate and oxidative respiration with H2 as an electron donor. They thus possibly contribute to the removal of hydrogen and oxygen to protect the fermentative activity of the protist hosts. The ectosymbionts possess reduced signal transduction gene repertoires, implying that the association has provided a relatively stable environment for these bacteria. The ectosymbionts likely possess flagella with an unusually expanded number of flagellin variants up to 40, which may reflect an adaptation to their ectosymbiotic lifestyle. We propose a novel genus, Termitispirillum, for these ectosymbionts and a novel family, Termitispirillaceae, for the insect-gut clade, under SeqCode. Our findings provide new insights into the ecology and evolution of Deferribacterota.

The genus Lactococcus was proposed by Schleifer et al. by separating Lactococcus lactis from the genus Streptococcus. Although the family Streptococcaceae consists of four genera, each genus contains a relatively small number of species, with the exception of the genus Streptococcus, which contains more than 100 species. The genera Lactococcus and Lactovum currently comprise 26 species and a single species, respectively. This study evaluated the taxonomy of the genus Lactococcus based on the 16S rRNA gene phylogeny, core-genome phylogeny and (conserved) pairwise average amino acid identity. These evaluations clearly indicated that the genus Lactococcus could be divided into two genus-level clusters, and we propose to reclassify this genus into two; the authentic Lactococcus, which includes the L. lactis group, and a novel genus for which the name Pseudolactococcus is proposed. Three lactic acid bacterial strains, RyT2T, OfM1T and OfM2, were isolated from the gut of termites in Okinawa, Japan. Based on the combination of genetic and phenotypic data, we conclude that these isolates represent two novel species of the genera Pseudolactococcus and Lactovum, respectively, for which we propose the names Pseudolactococcus yaeyamensis sp. nov. (RyT2T=JCM 36015T=DSM 118067T) and Lactovum odontotermitis sp. nov. (OfM1T=JCM 34431T=DSM 118066T, OfM2=JCM 34432), respectively.

A co-culture of a novel thermoacidophilic, obligate symbiotic archaeon, designated as strain MJ1T, with its specific host archaeon Metallosphaera sedula strain MJ1HA was obtained from a terrestrial hot spring in Japan. Strain MJ1T grew in the co-culture under aerobic conditions. Coccoid cells of strain MJ1T were 200–500 nm in diameter, and attached to the MJ1HA cells in the co-culture. The ranges and optima of the growth temperature and pH of strain MJ1T in the co-culture were 60–75 °C (optimum, 65–70 °C) and pH 1.0–4.0 (optimum, pH 2.5), respectively. Core lipids of dialkyl glycerol tetraethers (GDGT)−3 and GDGT-4 were highly abundant in MJ1T cells concentrated from the co-culture. Strain MJ1T has a small genome (0.67 Mbp) lacking genes for biosynthesis of essential biomolecules, such as nucleotides, lipids and ATP. The genomic DNA G+C content was 24.9 mol%. The 16S rRNA gene sequence of strain MJ1T was most closely related to that of the cultivated species, ‘Nanopusillus acidilobi’ strain N7A (85.8 % similarity). Based on phylogenetic and physiological characteristics, we propose the name Nanobdella aerobiophila gen. nov., sp. nov. to accommodate the strain MJ1T (=JCM 33616T=DSM 111728T). In addition, we propose the names Nanobdellaceae fam. nov., Nanobdellales ord. nov., and Nanobdellia class. nov. to accommodate the novel genus.

Abstract A deep-branching clade of Thaumarchaeota, conventionally called Terrestrial hot spring creanarchaeotic group (THSCG), is a missing link between thaumarchaeotic ammonia oxidizers and the deeper-branching non-ammonia oxidizers, such as Crenarchaeota and Candidatus Korarchaeota. Here, we report isolation of the first cultivated representative from the THSCG, named as NAS-02. Physiological characterization demonstrated that the isolate was a thermoacidophilic, sulfur- and iron-reducing organoheterotroph, which was supported by gene contents encoded in its complete genome. There was no evidence for ammonia oxidation by the isolate. Members in THSCG are likely thermophiles, and may play roles in degrading cell debris as a scavenger and in biogeochemical cycling of sulfur and iron in the hot environments, as suggested by the physiological characteristics of the isolate and the geographical distribution of the 16S rRNA gene sequences of THSCG in terrestrial hot springs and marine hydrothermal fields. Phylogenetic analysis suggests that the THSCG lineage represented by NAS-02 has gained the ability of sulfur reduction via horizontal gene transfer. Based on the phylogeny and physiology, we propose the name Conexivisphaera calidus gen. nov., sp. nov. to accommodate the isolate.