Ghosts of symbionts past: The hidden history of the dynamic association between filarial nematodes and their Wolbachia endosymbionts: Supplementary Data files

Supplementary data, Figures and Tables for manuscript "Ghosts of symbionts past: The hidden history of the dynamic association between filarial nematodes and their Wolbachia endosymbionts" Emmelien Vancaester, Guy R. Oldrieve, Alex Reid, Georgios Koutsovoulos, Dominik R. Laetsch, Benjamin L. Makepeace, Vincent Tanya, Sven Poppert, Jürgen Krücken, Adrian Wolstenholme, Mark Blaxter Many, but not all, parasitic filarial nematodes (Onchocercidae) carry intracellular, maternally-transmitted Wolbachia symbionts, and these alphaproteobacteria are targets for anti-filarial chemotherapeutic interventions for human disease. The symbionts of Onchocercidae derive from four of the major supergroups (C, D, F and J) defined within the genus Wolbachia. Using twenty-two whole genome sequences of filarial nematodes and genome sequences of their Wolbachia partners, we have explored the evolutionary history of the nematode-Wolbachia symbiosis. We screened the nuclear genome sequences of all the nematodes for nuclear Wolbachia transfers (NUWTs), fragments of the Wolbachia genome that have been integrated into the nuclear genome.  Six species have no current Wolbachia infection. Setaria labiatopapillosa had no validated NUWTs and we interpret this to mean that this species was never infected with Wolbachia. In the other five species (Acanthocheilonema viteae, Cercopithifilaria (Ce.) johnstoni, Elaeophora elaphi, Loa (Lo.) loa and Onchocerca flexuosa) we found NUWTs, implying they have previously had and have now lost Wolbachia infections. For each NUWT locus, we identified the supergroup membership of the Wolbachia from which it originated, and found that the five Wolbachia-free species carried NUWTs derived from multiple supergroups, including a high shared rate of sequences derived from supergroup C. In Dirofilaria repens we identified a sample that carried two Wolbachia symbionts, one from supergroup C and one from supergroup F. In Dirofilaria immitis where live infection with a supergroup C Wolbachia is found, we identified NUWTs derived from an F Wolbachia, confirming that the F association predated the divergence of these Dirofilaria species. The supergroup D lineage of Wolbachia, as present in the human parasites Wuchereria bancrofti and Brugia malayi, derives from a replacement event. Madathamugadia (Md.) hiepei shows signs of multiple recent repeated endosymbiont replacement. From these data we infer that the history of Wolbachia in onchocercid nematodes includes not only cospeciation (as present in the Onchocerca-Dirofilaria group in association with supergroup C Wolbachia) and loss (in the five Wolbachia-free species), but also frequent symbiont replacement and dual infection. This dynamic pattern is challenging to models that assume host-symbiont mutualism. The zip archive contains: Scripts Python scripts written for data processing. FetchRegionSeq.py.gz Reduce_alignment.py.gz Reroot_rename_tree.py.gz SelectMatches.py.gz Data Directories containing intermediate data files generated for the analyses presented. 1_WolbachiaAnnotation - the prokka annotation of each Wolbachia genome analysed 2_WolbachiaOrthoFinder - the orthoFinder results for the clustering of the proteomes of the 165 selected Wolbachia proteomes 3_WolbachiaPhylogeny - the phylogeny of Wolbachia inferred using Astral  4_WolbachiaOrthoAlignments - protein alignments of orthogroups from the orthoFinder analysis of 165 selected Wolbachia peoteomes 5_WolbachiaHMM - nucleotide hidden Markov models generated from the nucleotide alignments of orthogroups from the orthoFinder analysis of 165 selected Wolbachia proteomes 6_NUWTtrees - phylogenies inferred using Astral of the Wolbachia orthogroups for which NUWT sequences were identified in the filarial nematode genomes. The NUWT sequences were profile aligned to the orthogroup nucleotide alignments. 7_NUWTmatches - files giving the nucleotide coordinates and scores of each orthogroup HMM in the filarial genomes Supplementary Tables For completeness, the supplementary tables are replicated here. Table S1: Wolbachia genome data Table S2: Dereplicated Wolbachia genomes Table S3: Contigs removed from filarial nematode genomes as likely contaminants. Table S4: Numbers and classification of NUWTs detected in each filarial nematode species Supplementary Figures in a separate file Figure S1: BlobTools plot of initial Dirofilaria repens assemblyFigure S2: Genome phylogeny of WolbachiaFigure S3: Wolbachia proteome clusteringFigure S4: Phylogenetic tree of orthologous family OG0000236 and NUWTsFigure S5: Phylogenetic tree of orthologous family OG0000277 and NUWTsFigure S6: Phylogenetic tree of orthologous family OG0000301 and NUWTsFigure S7: Phylogenetic tree of orthologous family OG0000453 and NUWTsFigure S8: Phylogenetic tree of orthologous family OG0000206 and NUWTs