Hongoh, Yuichi

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.

Termites harbor diverse symbiotic gut microorganisms, the majority of which are as yet uncultivable and their interrelationships unclear. Here, we present the complete genome sequence of the uncultured Bacteroidales endosymbiont of the cellulolytic protist Pseudotrichonympha grassii, which accounts for 70% of the bacterial cells in the gut of the termite Coptotermes formosanus . Functional annotation of the chromosome (1,114,206 base pairs) unveiled its ability to fix dinitrogen and recycle putative host nitrogen wastes for biosynthesis of diverse amino acids and cofactors, and import glucose and xylose as energy and carbon sources. Thus, nitrogen fixation and cellulolysis are coupled within the protist's cells. This highly evolved symbiotic system probably underlies the ability of the worldwide pest termites Coptotermes to use wood as their sole food.

Summary Many reports have stated that flagellated protists in termite guts harbour ectosymbiotic spirochetes on their cell surface. In this study, we describe another bristle‐like ectosymbiont affiliated with the order Bacteroidales . The 16S rRNA phylotype Rs‐N74 predominates among Bacteroidales clones obtained from the gut of the termite Reticulitermes speratus . An Rs‐N74 phylotype‐specific probe was designed in this study and used for detection of the corresponding bacteria in the gut by fluorescence in situ hybridization (FISH) analysis. Surprisingly, the signals were detected specifically from the bristle‐like ‘appendages’ of various flagellate species belonging to the genus Dinenympha ; these ‘appendages’ had been believed to be spirochetal ectosymbionts or structures of the protists. The Rs‐N74 bacteria attached to the cell surface of the protists by a tip and coexisted with the spirochetal ectosymbionts. An electron micrograph revealed their morphology to be similar to a typical Bacteroidales bacterium. This bacterium is proposed to represent a novel genus and species, ‘ Candidatus Symbiothrix dinenymphae’, phylogenetically affiliated with a cluster consisting exclusively of uncultured strains from termite guts. A Bacteroidales ‐specific probe for FISH further revealed that this type of symbiosis exists also in various other protists, including parabasalids and oxymonads, and is widespread in termite guts.