Abstract
Many animals are dependent on microbial partners that provide essential nutrients lacking from their diet. Ticks, whose diet consists exclusively on vertebrate blood, rely on maternally inherited bacterial symbionts to supply B vitamins. While previously studied tick species consistently harbor a single lineage of those nutritional symbionts, we evidence here that the invasive tick Hyalomma marginatum harbors a unique dual-partner nutritional system between an ancestral symbiont, Francisella, and a more recently acquired symbiont, Midichloria. Using metagenomics, we show that Francisella exhibits extensive genome erosion that endangers the nutritional symbiotic interactions. Its genome includes folate and riboflavin biosynthesis pathways but deprived functional biotin biosynthesis on account of massive pseudogenization. Co-symbiosis compensates this deficiency since the Midichloria genome encompasses an intact biotin operon, which was primarily acquired via lateral gene transfer from unrelated intracellular bacteria commonly infecting arthropods. Thus, in H. marginatum, a mosaic of co-evolved symbionts incorporating gene combinations of distant phylogenetic origins emerged to prevent the collapse of an ancestral nutritional symbiosis. Such dual endosymbiosis was never reported in other blood feeders but was recently documented in agricultural pests feeding on plant sap, suggesting that it may be a key mechanism for advanced adaptation of arthropods to specialized diets.
Highlights
Ticks evolved to hematophagy through the acquisition of key genomic adaptations (Gulia-Nuss, 2016; Jia et al, 2020) and the evolution of mutualistic interactions with microbial symbionts (Buysse and Duron, 2021; Duron and Gottlieb, 2020)
Phylogenomic analysis based on 436 single-c opy orthologs (SCOs) Francisella genes showed that Franscisella-like endosymbiont (FLE)-Hmar-ES, FLE-Hmar-IT, and FLE-Hmar-IL cluster together in a robust clade within other FLE of ticks (Figure 2A)
We show that the tick H. marginatum is a complex symbiotic system, combining genes of diverse phylogenetic origins to generate nutritional adaptations to obligate hematophagy
Summary
Ticks evolved to hematophagy through the acquisition of key genomic adaptations (Gulia-Nuss, 2016; Jia et al, 2020) and the evolution of mutualistic interactions with microbial symbionts (Buysse and Duron, 2021; Duron and Gottlieb, 2020). Tick genomes do not contain genes for synthesis of some essential vitamins, vitamin-p rovisioning pathways have indirectly arisen from symbiotic associations with transovarially transmitted intracellular bacteria (Ben-Yosef et al, 2020; Duron et al, 2018; Duron and Gottlieb, 2020; Gerhart et al, 2016; Gottlieb et al, 2015; Guizzo et al, 2017; Smith et al, 2015) This partnership allowed the long-term acquisition of heritable biochemical functions by ticks and favored their radiation into the nearly 900 tick species that currently exist (Duron and Gottlieb, 2020). This co-e volutionary process is reflected by microbial communities dominated by tick nutritional symbionts (Bonnet and Pollet, 2021; Narasimhan and Fikrig, 2015)
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