Phylogenetic identification of symbiotic protists of five Chinese Reticulitermes species indicates a cospeciation of gut microfauna with host termites

The protist symbionts of Reticulitermes tibialis: Unexpected diversity enables a new taxonomic framework

Wood-feeding termites harbor specialized protists in their hindguts in a classic nutritional mutualism. The protists are vertically inherited, which has generated a broad-scale pattern of codiversification over ∼150 million years, but there are many incongruences due to lineage-specific loss and transfer of symbionts. Despite the evolutionary and economic importance of this symbiosis, the symbiont communities of most termite species are incompletely characterized or entirely unstudied. Here, we have investigated the protist symbiont community of Reticulitermes tibialis, using single-cell PCR to link morphology to 18S rRNA gene sequences. The protists belong to at least 41 species in 3 major lineages within Metamonada: Spirotrichonymphida, Pyrsonymphidae, and Trichonympha. The Spirotrichonymphida symbionts belong to 6 genera, including Pseudospironympha, which has not been found in Reticulitermes until now, and Dexiohelix, a new genus. Pyrsonymphidae traditionally include just Pyrsonympha and Dinenympha, but our morphology-linked 18S phylogeny indicates that both genera are polyphyletic. We accordingly restrict the definitions of Pyrsonympha and Dinenympha to the clades that include their type species, and we propose 5 new genera to accommodate the remaining clades. Short-read 18S amplicon sequencing revealed considerable variation in community composition across R. tibialis colonies in Arizona, suggestive of a symbiont metacommunity. Symbiont species varied in their prevalence across colonies, with a core set of about 12 highly prevalent symbiont species, 11 species with intermediate prevalence, and 18 rare species. This pattern contrasts with the traditional paradigm of consistent symbiont community composition across colonies of a termite species.

Updated classification of the phylum Parabasalia

The phylum Parabasalia includes very diverse single-cell organisms that nevertheless share a distinctive set of morphological traits. Most are harmless or beneficial gut symbionts of animals, but some have turned into parasites in other body compartments, the most notorious example being Trichomonas vaginalis in humans. Parabasalians have garnered attention for their nutritional symbioses with termites, their modified anaerobic mitochondria (hydrogenosomes), their character evolution, and the wholly unique features of some species. The molecular revolution confirmed the monophyly of Parabasalia, but considerably changed our view of their internal relationships, prompting a comprehensive reclassification 14 years ago. This classification has remained authoritative for many subgroups despite a greatly expanded pool of available data, but the large number of species and sequences that have since come out allow for taxonomic refinements in certain lineages, which we undertake here. We aimed to introduce as little disruption as possible but at the same time ensure that most taxa are truly monophyletic, and that the larger clades are subdivided into meaningful units. In doing so, we also highlighted correlations between the phylogeny of parabasalians and that of their hosts.

Genomics and Geographic Diversity of Bacteriophages Associated With Endosymbionts in the Guts of Workers and Alates of Coptotermes Species (Blattodea: Rhinotermitidae)

Subterranean termites depend nutritionally on their gut microbiota, which includes protozoa as well as taxonomically and functionally diverse bacteria. Our previous metavirome study revealed a high diversity and novel families of bacteriophages in the guts of Coptotermes formosanus workers from New Orleans, Louisiana, United States. Two assembled bacteriophage genomes (Phages TG-crAlp-04 and 06, family Podoviridae) existed in all colonies and showed similarity to a prophage (ProJPt-Bp1) previously sequenced from a bacterial endosymbiont (Candidatus Azobacteroides pseudotrichonymphae, CAP) of protozoa in the gut of a termite species of the genus Prorhinotermes from Taiwan. In this study the genomes of Phage TG-crAlp-04 and 06 were subjected to detailed functional annotation. Both phage genomes contained conserved genes for DNA packaging, head and tail morphogenesis, and phage replication. Approximately 30% of the amino acid sequences derived from genes in both genomes matched to those of ProJPt-Bp1 phage or other phages from the crAss-like phage group. No integrase was identified; the lack of a lysogeny module is a characteristic of crAss-like phages. Primers were designed to sequence conserved genes of the two phages and their putative host bacterium (CAP) to detect their presence in different termite species from native and introduced distribution ranges. Related strains of the host bacterium were found across different termite genera and geographic regions. Different termite species had separate CAP strains, but intraspecific geographical variation was low. These results together with the fact that CAP is an important intracellular symbiont of obligate cellulose-digesting protozoa, suggest that CAP is a core gut bacterium and co-evolved across several subterranean termite species. Variants of both crAss-like phages were detected in different Coptotermes species from the native and introduced range, but they did not differentiate by species or geographic region. Since similar phages were detected in different termite species, we propose the existence of a core virome associated with core bacterial endosymbionts of protozoa in the guts of subterranean termites. This work provides a strong basis for further study of the quadripartite relationship of termites, protozoa, bacteria, and bacteriophages.