Sampling

Gordiids were sampled over a span of 14 years, from 2007 to 2021 (Fig. 1: Sup. Table 1). Chordodes formosanus, the most common species in Taiwan (Chiu, Reference Chiu2017), was sampled country-wide, while specimens of Acutogordius taiwanensis and Gordius chiashanus were collected from fewer localities (Fig. 1; Sup. Table 1). Specimens were collected either by hand in bodies of water (i.e. streams and man-made ponds), by sampling the hosts and then immersing them until the adult worm came out, or by collecting the dead gordiids on the ground, which is the most common method for finding them in Taiwan (Chiu, Reference Chiu2017). The samples were fixed in 95% alcohol and stored at −20°C. Species recognition was based on DNA barcoding, given that the majority of the samples were too ruined for morphological identification. A total of 38 C. formosanus specimens, 10 A. taiwanensis and 3 G. chiashanus were collected (see SRA BioProject PRJNA914055); however, DNA extraction and sequencing was not successful on all of them (Sup. Table 1), probably due to the low quality of some of the specimens.

Figure 1. Sampling localities for Chordodes formosanus (black), Acutogordius taiwanensis (purple) and Gordius chiashanus (red), with a map showing elevation and river network in Taiwan. Localities from previous studies have been included. The purple dot with black borders shows an area of sympatry between C. formosanus and A. taiwanensis. The legend on the right shows elevation in metres.

DNA extraction, COXI amplification and ddRADseq protocol

For DNA extraction, we used a modified version of the Qiagen DNeasy Animal Tissue Protocol (Qiagen, Hilden, Germany). We modified the original protocol by using double-distilled water (ddH₂O) instead of elution buffer for dilution, and we eluted 60 μL of DNA, given the low concentration of DNA. Additionally, we left the tissue to incubate overnight at 60°C.

The amplification of the COXI sequences through polymerase chain reaction (PCR) was done using the universal primer set LCO1490 and HC02198 (Folmer et al., Reference Folmer, Black, Hoeh, Lutz and Vrijenhoek1994) and was performed in a total volume of 25 μL using PuReTaq Ready-To-Go PCR Beads (Cytiva, formerly GE Healthcare, Marlborough, United States). The PCR was initiated at 95°C for 5 min, followed by 40 cycles at 95°C for 1 min, 50°C for 1 min and 72°C for 1 min, with a final extension at 72°C for 10 min. The PCR products were purified following the NautiaZ Gel/PCR DNA Purification Mini Kit protocol (Nautia Gene, Taipei, Taiwan). Sanger Sequencing was done by the DNA Sequencing Core Facility of the Institute of Biomedical Sciences, Academia Sinica, Taipei, Taiwan.

An edited version of the Peterson et al. (Reference Peterson, Weber, Kay, Fisher and Hoekstra2012) protocol was used for generating the ddRADseq library. We modified the original method by using between 100 and 140 ng of genomic DNA per sample, 4 μL of ddH₂O for bead clean-up and 60 μL of ddH₂O for elution before measuring DNA concentration with Qubit. Single-end sequencing of 100-nucleotide base pair (bp) lengths were carried out using an Illumina HiSeq2500 system.

COXI analyses

The COXI forward and reversed sequences from each individual were visualized with MEGA X (ver. 10.1.8; Kumar et al., Reference Kumar, Stecher, Li, Knyaz and Tamura2018). The alignments were done with MAFFT 7.471 (Katoh and Standley, Reference Katoh and Standley2013) using the L-INS-i algorithm. The sequences were trimmed manually and consensus sequences were saved from the alignments.

COXI sequences at least 400 bp long for each taxon from previous studies (Chiu et al. Reference Chiu, Huang, Wu and Shiao2011, Reference Chiu, Huang, Wu and Shiao2016, Reference Chiu, Huang, Wu and Shiao2017, Reference Chiu, Huang, Wu, Lin, Chen and Shiao2020; Sup. Table 2) were downloaded from GenBank (Clark et al., Reference Clark, Karsch-Mizrachi, Lipman, Ostell and Sayers2016: last assessed 4th November 2022), aligned with the newly generated sequences using MAFFT 7.471 with the L-INS-i algorithm and manually trimmed while being visualized with MEGA X. In the case of A. taiwanensis, an additional sequence of a hairworm from Myanmar (MF983649) was included for population genetic structure analyses; said sequence has been shown to fall inside the known COXI variability of A. taiwanensis in previous studies (Chiu et al., Reference Chiu, Huang, Wu, Lin, Chen and Shiao2020) and therefore it should represent a sequence from the said species. In total, 433 bp were recovered for 85 specimens of C. formosanus (36 newly generated), 414 bp for 31 A. taiwanensis (3 newly generated) and 382 bp for 26 individual of G. chiashanus (1 newly generated). The newly generated sequences are available in GenBank (OQ121045-OQ121047 for A. taiwanensis, OQ121048-OQ121083 for C. formosanus, OQ121084 for G. chiashanus).

Possible population genetic structure, hypothetical haplotypes (i.e. unsampled sequences) and genetic diversity indices [nucleotide diversity (pi) and Tajima's D: Nei and Li, Reference Nei and Li1979; Tajima, Reference Tajima1989] were inferred by a haplotype network in PopArt (Leigh and Bryant, Reference Leigh and Bryant2015), generated with the TCS 1.21 algorithm (Clement et al., Reference Clement, Posada and Crandall2000). Estimation of Ne trends was calculated by running Coalescent Bayesian Skyline plot analyses on BEAST2 (version 2.6.3: Bouckaert et al., Reference Bouckaert, Vaughan, Barido-Sottani, Duchêne, Fourment, Gavryushkina, Heled, Jones, Kühnert, De Maio, Matschiner, Mendes, Müller, Ogilvie, du Plessis, Popinga, Rambaut, Rasmussen, Siveroni, Suchard, Wu, Xie, Zhang, Stadler and Drummond2019). Such analyses allow the estimation of trends from mitochondrial data, even if only one locus is available, and recover well with Pleistocene trends (Ho and Shapiro, Reference Ho and Shapiro2011). Furthermore, previous studies were able to recover demographic trends with less than 300 bp of mitochondrial sequences (Ho and Shapiro, Reference Ho and Shapiro2011 and references therein); therefore, the alignments should be long enough for allowing trends' estimations. The most likely nucleotide substitution model for each species was inferred using ModelTest, implemented in raxmlGUI (Edler et al., Reference Edler, Klein, Antonelli and Silvestro2021) according to Akaike information criterion (AIC; Akaike, Reference Akaike, Parzen, Tanabe and Kitigawa1998). A Relaxed Clock Log model, with a clock rate of roughly 0.0013 per million years, was set. We estimated this clock rate by aligning full COXI sequences from the only available Chordodes and Gordius mitogenomes from GenBank (MG257764 and MG257767), dividing the number of variable sites by the total number of sites and then dividing again by 2 before dividing by 110, which represents the estimated age in million years of the oldest known gordiid fossil (Poinar and Buckley, Reference Poinar and Buckley2006). Note that estimates for the appearance of crown group Nematomorpha range from around the mid-Cambrian to the mid-Cretaceous (Howard et al., Reference Howard, Giacomelli, Lozano-Fernandez, Edgecombe, Fleming, Kristensen, Ma, Olesen, Sørensen, Thomsen, Wills, Donoghue and Pisani2022), but that these estimates include the possible divergence time of the Nectonema lineage from gordiids too. Therefore, we prefer to refer to the fossil datum, since it is the earliest possible divergence point for the Chordodidae/Gordiidae lineage. Additionally, the C. formosanus Japanese and Taiwanese samples were split for estimations, while the Myanmar sequence was removed for A. taiwanensis.

ddRADseq analyses

Two different pipelines for processing the ddRAD data were used for C. formosanus: ipyrad (version 0.9.84: Eaton and Overcast, Reference Eaton and Overcast2020) and Stacks (version 2.62: Rochette et al., Reference Rochette, Rivera-Colón and Catchen2019). For the ipyrad pipeline, we performed de-novo assembly with a Phred Qscore offset of 43, 90% clust threshold, 0.5 maximum of heterozygotes in consensus, and minimum sample locus at 80% of all the samples, while keeping other settings at their default values. Samples with less than 300 loci were discarded for further analyses. For Stacks, the protocol listed in Rivera-Colón and Catchen (Reference Rivera-Colón, Catchen, Verde and Giordano2022) was followed and all the sites (variant and invariant) were outputted in the Variant Call Format (VCF) file. In total, 27 individuals were retained for C. formosanus from both pipelines. In the case of A. taiwanensis and G. chiashanus, only 2 individuals per species had at least 200,000 reads after trimming and therefore we only used Stacks for their assemblies, with the ‘r’ flag set at 1 instead of 0.8.

To check the genetic population genetic structure of C. formosanus, tools from ipyrad and R were used with both the ipyrad and Stacks output. The Stacks VCF file was filtered to remove the loci without SNPs and the SNPs with more than 20% missing data, using an edited version of previously released R scripts (Dalapicolla et al., Reference Dalapicolla, do Prado, Percequillo and Knowles2021). Additionally, the filtered VCF file was converted to a HDF5 database using the converter inside the ipyrad-analysis toolkit (Eaton and Overcast, Reference Eaton and Overcast2020) to make it compatible with the tools implemented inside ipyrad. After this, k-means principal component analyses (PCA) were run 100 times in the ipyrad-analysis tools suite. Moreover, the snapclust clustering method implemented into the ‘adegenet’ R package (Beugin et al., Reference Beugin, Gayet, Pontier, Devillard and Jombart2018) was used. The best number of clusters (k) was calculated by computing the AIC and the Bayesian information criterion (BIC; Schwarz, Reference Schwarz1978), while picking the value for which both criteria were lower. The snapclust analyses were run with both the ipyrad full output STRUCTURE file and a STRUCTURE file generated from the filtered Stacks VCF thanks to PGDSpider (Lischer and Excoffier, Reference Lischer and Excoffier2012). Furthermore, for analysing possible admixture between geographically separated C. formosanus individuals, RADpainter and fineRADstructure (Malinsky et al., Reference Malinsky, Trucchi, Lawson and Falush2018) were used and the results were plotted with R. The RADpainter file from the Stacks output was used for such software, while the ‘hapsFromVCF’ command generated an input file with the ipyrad-outputted VCF.

For population demographic analyses of all the taxa, a site-frequency spectra (SFS) file was generated using the easySFS script (https://github.com/isaacovercast/easySFS) by converting the Stacks VCF file with the invariant sites, choosing the number of individuals that maximize the number of segregating sites. Note that easySFS takes into consideration the fact that missing data are present, and therefore we used the full Stacks VCF output for SFS conversion. After that, Stairway Plot 2 (version 2.1.1: Liu and Fu, Reference Liu and Fu2020) was used per species following the software's manual. Given the current knowledge on Taiwanese horsehair worms (Chiu, Reference Chiu2017; Chiu et al., Reference Chiu, Huang, Wu, Lin, Chen and Shiao2020), generation time was set at 1 per year. As for the mutation rate, given the lack of whole-genome data for horsehair worms, a spontaneous mutation of rate of 2 × 10⁻⁹ per site per generation, which is one of the nematode Pristionchus pacificus (Weller et al., Reference Weller, Rödelsperger, Eberhardt, Molnar and Sommer2014), was set. We argue that, even if nematodes and hairworms have been split for hundreds of millions of years (Howard et al., Reference Howard, Giacomelli, Lozano-Fernandez, Edgecombe, Fleming, Kristensen, Ma, Olesen, Sørensen, Thomsen, Wills, Donoghue and Pisani2022), mutation rates in invertebrates tend to be around the same order of magnitude (10⁻⁹; e.g. Konrad et al., Reference Konrad, Brady, Bergthorsson and Katju2019) and therefore should not influence the results in a significant way.