Complex host/symbiont integration of a multi-partner symbiotic system in the eusocial aphid Ceratovacuna japonica.

Some hemipteran insects rely on multiple endosymbionts for essential nutrients. However, the evolution of multi-partner symbiotic systems is not well-established. Here, we report a co-obligate symbiosis in the eusocial aphid, Ceratovacuna japonica. 16S rRNA amplicon sequencing unveiled co-infection with a novel Arsenophonus sp. symbiont and Buchnera aphidicola, a common obligate endosymbiont in aphids. Both symbionts were housed within distinct bacteriocytes and were maternally transmitted. The Buchnera and Arsenophonus symbionts had streamlined genomes of 432,286 bp and 853,149 bp, respectively, and exhibited metabolic complementarity in riboflavin and peptidoglycan synthesis pathways. These anatomical and genomic properties were similar to those of independently evolved multi-partner symbiotic systems, such as Buchnera-Serratia in Lachninae and Periphyllus aphids, representing remarkable parallelism. Furthermore, symbiont populations and bacteriome morphology differed between reproductive and soldier castes. Our study provides the first example of co-obligate symbiosis in Hormaphidinae and gives insight into the evolutionary genetics of this complex system.

Aphid hologenomics: current status and future challenges.

Aphids are important model organisms in ecological, developmental, and evolutionary studies of, for example, symbiosis, insect-plant interactions, pest management, and developmental polyphenism. Here, we review the recent progress made in the genomics of aphids and their symbionts: hologenomics. The reference genome of Acyrthosiphon pisum has been greatly improved, and chromosome-level assembly is now available. The genomes of over 20 aphid species have been sequenced, and comparative genomic analyses have revealed pervasive gene duplication and dynamic chromosomal rearrangements. Over 120 symbiont genomes (both obligate and facultative) have been sequenced, and modern deep-sequencing technologies have identified novel symbionts. The advances in hologenomics have helped to elucidate the dynamic evolution of facultative and co-obligate symbionts with the ancient obligate symbiont Buchnera.

Author Correction: Transcriptomic analysis reveals differences in the regulation of amino acid metabolism in asexual and sexual planarians.

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

Transcriptomic analysis reveals differences in the regulation of amino acid metabolism in asexual and sexual planarians.

Many flatworms can alternate between asexual and sexual reproduction. This is a powerful reproductive strategy enabling them to benefit from the features of the two reproductive modes, namely, rapid multiplication and genetic shuffling. The two reproductive modes are enabled by the presence of pluripotent adult stem cells (neoblasts), by generating any type of tissue in the asexual mode, and producing and maintaining germ cells in the sexual mode. In the current study, RNA sequencing (RNA-seq) was used to compare the transcriptomes of two phenotypes of the planarian Dugesia ryukyuensis: an asexual OH strain and an experimentally sexualized OH strain. Pathway enrichment analysis revealed striking differences in amino acid metabolism in the two worm types. Further, the analysis identified serotonin as a new bioactive substance that induced the planarian ovary de novo in a postembryonic manner. These findings suggest that different metabolic states and physiological conditions evoked by sex-inducing substances likely modulate stem cell behavior, depending on their different function in the asexual and sexual reproductive modes. The combination of RNA-seq and a feeding assay in D. ryukyuensis is a powerful tool for studying the alternation of reproductive modes, disentangling the relationship between gene expression and chemical signaling molecules.