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Phylogeny and morphology of some European cyathocotylid digeneans (Trematoda: Diplostomoidea)

Published online by Cambridge University Press:  31 May 2024

S.G. Sokolov Open the ORCID record for S.G. Sokolov [Opens in a new window] ,
S.A. Vlasenkov Open the ORCID record for S.A. Vlasenkov [Opens in a new window] ,
S.V. Bugmyrin Open the ORCID record for S.V. Bugmyrin [Opens in a new window] ,
A.P. Kalmykov Open the ORCID record for A.P. Kalmykov [Opens in a new window]  and
D.I. Lebedeva Open the ORCID record for D.I. Lebedeva [Opens in a new window]
S.G. Sokolov
Affiliation:
A.N. Severtsov Institute of Ecology and Evolution, Moscow 119071, Russia
S.A. Vlasenkov
Affiliation:
Institute of Biology, Karelian Research Centre, RAS, Petrozavodsk 185000, Russia
S.V. Bugmyrin
Affiliation:
Institute of Biology, Karelian Research Centre, RAS, Petrozavodsk 185000, Russia
A.P. Kalmykov
Affiliation:
Astrakhan State Natural Biosphere Reserve, Astrakhan 414021, Russia Astrakhan Museum-Reserve, Astrakhan 414000, Russia
D.I. Lebedeva*
Affiliation:
Institute of Biology, Karelian Research Centre, RAS, Petrozavodsk 185000, Russia
*
Corresponding author: D.I. Lebedeva; Email: daryal78@gmail.com
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Abstract

The Cyathocotylidae Mühling, 1898 is a family of primitive diplostomoid trematodes important for understanding the evolution of the superfamily Diplostomoidea. However, cyathocotylids remain poorly studied with the use of molecular techniques. In this study we sequenced the 5.8S + ITS2 region, 28S rRNA, and cox1 genes of two cyathocotylid species and obtained new morphological data on them. We propose Georduboisia nom. nov. instead of the preoccupied name Duboisia Szidat, 1936 (junior homonym of Duboisia Stremme, 1911). Adults of Georduboisia cf. teganuma (Ishii, 1935) and Paracoenogonimus ovatus Katsurada, 1914 were collected from fish-eating birds in the south of the European part of Russia. Georduboisia cf. teganuma was very similar to G. teganuma but differed from it in the shape of the testes. The 28S rRNA gene dataset provided the best-resolved phylogeny of the Cyathocotylidae to date. In the phylogram based on partial sequences of this gene, P. ovatus was close to members of Holostephanoides Dubois, 1983, Neogogatea Chandler & Rausch, 1947 and Gogatea Szidat, 1936. Georduboisia cf. teganuma clustered with members of Cyathocotyle Mühling, 1896 and Holostephanus Szidat, 1936. Phylogenetic analysis based on the 5.8S + ITS2 dataset showed that adults of P. ovatus examined in our study were conspecific with the metacercariae from the musculature of fish collected in Hungary and Italy. It also revealed probable misidentifications of larvae and adults of cyathocotylids whose sequences are deposited in GenBank NCBI.

Keywords

Duboisia teganumaParacoenogonimus ovatusCircus aeruginosusPodiceps cristatusspecies identification
Type
Research Paper
Information
Journal of Helminthology , Volume 98 , 2024 , e44
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

The family Cyathocotylidae Mühling, Reference Mühling1898 is a compact group of the Diplostomoidea with a complex of plesiomorphic characters such as an undivided or indistinctly divided body and the presence of a true cirrus sac (Niewiadomska Reference Niewiadomska, Gibson, Jones and Bray2002). This family has a tumultuous taxonomic history (e.g., Mühling Reference Mühling1896, Reference Mühling1898; Poche Reference Poche1925; La Rue Reference La Rue1926; Lutz Reference Lutz1935; Szidat Reference Szidat1936; Dubois Reference Dubois1936, Reference Dubois1970, Reference Dubois1987; Sudarikov Reference Sudarikov and Skrjabin1961; Yamaguti Reference Yamaguti1971). According to the current conceptualisation, the Cyathocotylidae is the senior synonym for the Brauninidae Wolf, 1903 and the Prohemistomidae Lutz, Reference Lutz1935 (Niewiadomska Reference Niewiadomska, Gibson, Jones and Bray2002; Achatz et al. Reference Achatz, Pulis, Junker, Binh, Snyder and Tkach2019). Adult cyathocotylids parasitise the intestines of mammals, birds, reptilians, and, exceptionally, fish (Yamaguti Reference Yamaguti1971).

A recent publication by Achatz et al. (Reference Achatz, Pulis, Junker, Binh, Snyder and Tkach2019) is the only modern study deciphering the phylogenetic relationships of the cyathocotylids. Its results indicate that the current system of the Cyathocotylidae based on morphological data (Niewiadomska Reference Niewiadomska, Gibson, Jones and Bray2002) should be re-evaluated. However, changes to the system of the Cyathocotylidae cannot be fully implemented due to the lack of molecular data on many cyathocotylid genera, including Duboisia Szidat, Reference Szidat1936 and Paracoenogonimus Katsurada, 1914.

Duboisia Szidat, Reference Szidat1936 is characterised by a pouch-like body with a large holdfast organ enclosed in a deep ventral concavity and a massive vaginal sphincter (Sudarikov Reference Sudarikov and Skrjabin1961; Dubois Reference Dubois1984; Niewiadomska Reference Niewiadomska, Gibson, Jones and Bray2002). This genus contains only three species parasitising as adult in Palearctic and African birds – Duboisia syriaca Dubois, 1934 (type), Duboisia skrjabini Sudarikov & Oshmarin, 1954, and Duboisia teganuma (Ishii, Reference Ishii1935) (Dubois Reference Dubois1984). However, the name Duboisia Szidat, Reference Szidat1936 is in fact a junior homonym of Duboisia Stremme, Reference Stremme, SELENKA and BLANCKENHORN1911, the name of a genus of fossil antelopes (Stremme Reference Stremme, SELENKA and BLANCKENHORN1911). The life cycle has been studied only for D. teganuma, and only partially. Its first intermediate host remains unknown; the role of the second intermediate host is played by fish (Bayanov & Islamov Reference Bayanov, Islamov and Ershov1977).

The taxonomic boundaries of Paracoenogonimus Katsurada, 1914 are assessed differently in the systems of different authors, depending on whether they recognise (e.g., Niewiadomska Reference Niewiadomska, Gibson, Jones and Bray2002) or abolish (e.g., Dubois Reference Dubois1983) the genus Linstowiella Szidat, 1933. Here we consider Linstowiella as a distinct genus following Mishchenko (Reference Mishchenko1974) and Niewiadomska (Reference Niewiadomska, Gibson, Jones and Bray2002). Paracoenogonimus sensu stricto is characterised by an oval to elongate-oval flattened body with shallow ventral concavity and a ventral sucker with absence of the vaginal sphincter (Niewiadomska Reference Niewiadomska, Gibson, Jones and Bray2002). This genus contains two species parasitising as adults various Palearctic fish-eating birds and mammals: Paracoenogonimus ovatus Katsurada, 1914 (type) and Paracoenogonimus ussuriensis Besprozvannykh & Ermolenko, Reference Besprozvannykh and Ermolenko2009 (Dubois Reference Dubois1983 with amendments by Niewiadomska Reference Niewiadomska, Gibson, Jones and Bray2002 and Besprozvannykh & Ermolenko Reference Besprozvannykh and Ermolenko2009). The life cycle, which has been studied in both members of the genus, involves gastropods of the Viviparoidea as the first intermediate hosts and various fishes as the second intermediate hosts (e.g., Komiya Reference Komiya1938; Ginetsinskaya & Koscheva Reference Ginetsinskaya and Koscheva1959; Besprozvannykh & Ermolenko Reference Besprozvannykh and Ermolenko2009).

We collected specimens of cyathocotylids during a parasitological survey of fish-eating birds in the south of the European part of Russia. Based on morphological features they were identified as representatives of Duboisia and Paracoenogonimus. This study aimed to describe the morphology of these cyathocotylids, obtain molecular data on them, and evaluate their phylogenetic relationships.

Materials and methods

Sampling and morphological study

Adult digeneans were collected from the intestines of Podiceps cristatus (Linnaeus, 1758) and Circus aeruginosus (Linnaeus, 1758). Two individuals of P. cristatus were shot by licensed hunters near Kalinino Village, Astrakhan Region, Russia (46°20′9″ N; 48°53′29″ E), in September–November 2017. In addition, two individuals of P. cristatus were found dead in fishing nets in the River Mokraya Chuburka near Leninsky Leskhoz Village, Rostov Region, Russia (46°45′38″N; 39°8′1″ E) in September 2023. One specimen of C. aeruginosus was found dead under power lines near the above-mentioned Kalinino Village in September 2017. Digenean specimens were relaxed in fresh water, fixed with 70% ethanol, and after a few minutes transferred to 96% ethanol.

Adult parasites were studied by morphological and molecular techniques. For the morphological study, the specimens were stained with acetocarmine, dehydrated in a graded ethanol series, cleared with dimethyl phthalate, and finally mounted in Canada balsam. The slides were then observed through a light microscope Olympus BX-53 (Nagano, Japan) equipped with the differential interference contrast (DIC) at the Core Facility of the Karelian Research Centre of the Russian Academy of Sciences, Petrozavodsk, Russia. All the measurements are given in micrometers (μm). In morphological descriptions, the terms prosoma and opisthosoma are used following Achatz et al. (Reference Achatz, Martens, Kostadinova, Pulis, Orlofske, Bell, Fecchio, Oyarzún-Ruiz, Syrota and Tkach2022), and the term forebody is used following Manter (Reference Manter, Singh, Tandan and Srivastava1970). The drawings were made with the help of the camera lucida. Paragenophores were deposited in the Museum of Helminthological Collections of the Center of Parasitology of the Severtsov Institute of Ecology and Evolution (IPEE RAS; Moscow, Russia).

DNA amplification, sequencing, and phylogenetic analysis

Genomic DNA was isolated individually from nine ethanol-fixed digenean specimens using DNA-Extran kits (Synthol, Moscow, Russia). Partial 28S rRNA gene sequences were amplified with digl2 (5′-AAGCATATCACTAAGCGG-3′) (Tkach et al. Reference Tkach, Pawlowski and Mariaux2000) and 1500R (5′-GCTATCCTGAGGGAAACTTCG-3′) (Tkach et al. Reference Tkach, Littlewood, Olson, Kinsella and Swiderski2003) primers. A fragment including the 5.8S + ITS2 region was amplified with the primers 3S (5′-GGTACCGGTTCACGTGGCTAGTG-3′) and ITS2.2 (5′-CCTGGTTAGTTTCTTTTCCTCCGC-3′) (Bowles et al. Reference Bowles, Blair and McManus1992). The following protocol was used for amplification of both above-mentioned regions: initial denaturation for 1 min at 95°C; 35 cycles for 1 min at 95°C, 1 min at 55°C, and 2 min at 72°C. Partial 28S rRNA gene PCR products were sequenced in both directions with dig12 and 1500R primers, alongside inner primers 300F (5′-CAAGTACCGTGAGGGAAAGTTG-3′) and ECD2 (5′-CCTTGGTCCGTGTTTCAAGACGGG-3′) [Littlewood et al. Reference Littlewood, Curini-Galletti and Herniou2000]. Sequencing of the 5.8S + ITS2 region was performed with the same primers as amplification.

Fragments of cox1 mtDNA was amplified using forward primer JB3 (5’-TTTTTTGGGCATCCTGAGGTTTAT-3’) and reverse primer JB4.5 (5’-TAAAGAAAGAACATAATGAAAATG-3’) under the following conditions: 1 min denaturation hold at 94°C, 30 cycles of 15 s at 94°C, 30 s at 50°C, 2 min at 72°C, and a 7 min extension hold at 72°C (Morgan & Blair Reference Morgan and Blair1998). Sequencing of these fragments of mtDNA was performed with the same primers as amplification.

Consensus sequences were assembled in MEGA v. 10 (Kumar et al. Reference Kumar, Stecher, Li, Knyaz and Tamura2018). The newly generated sequences were matched with those of other cyathocotylids in the Basic Local Alignment Search Tool (BLASTn) (www.ncbi.nih.gov/BLAST/). To assess the phylogenetic position of the species under study, Bayesian inference analyses were performed for the newly obtained sequences and the previously published Cyathocotylidae sequences of the 28S rRNA gene, 5.8S + ITS2 region, and a fragment of the mtDNA cox1 gene (the full list of the sequences is provided in Supplementary Table 1). The alignments were constructed using the MUSCLE algorithm implemented in MEGA v.10 (Kumar et al. Reference Kumar, Stecher, Li, Knyaz and Tamura2018). The alignment of 28S rRNA gene with a length of 1037 bp included four novel sequences and 21 other sequences of cyathocotylid digeneans available in GenBank NCBI, with a member of the Liolopidae, Liolope copulans Cohn, 1902, as the outgroup. According to Pérez-Ponce de León & Hernández-Mena (Reference Pérez-Ponce de León and Hernández-Mena2019), the Liolopidae is a sister group to the Diplostomoidea. The alignment of the cox1 gene with a length of 433 bp included five novel sequences and 18 other sequences of cyathocotylid digeneans available in GenBank NCBI, with a member of the Clinostomidae, Clinostomum tataxumui Sereno-Uribe, Pinacho-Pinacho, García-Varela & Pérez-Ponce de León, 2013, as the outgroup. The Clinostomidae is one of the most closely related groups to the Diplostomoidea (Pérez-Ponce de León & Hernández-Mena 2019). The use of a member of this family as the outgroup in this alignment is due to the lack of the cox1 gene sequence data for liolopids. The alignment of the 5.8 S + ITS2 region with a length of 386 bp included four novel sequences and 29 other sequences of cyathocotylid digeneans available in GenBank NCBI, with Paraharmotrema karinganiense Dutton & Bullard, 2022 (Liolopidae) and Clinostomum heluans Braun, 1899 (Clinostomidae) as the outgroup. The use of only one species as the outgroup did not provide a good resolution.

Prior to the analyses, the best fitting GTR + G + I model for the alignment of the 28S rRNA and cox1 gene sequences and TVM + G + I model for the alignment of the 5.8S + ITS2 region set were identified with the help of jModelTest v2.1.2 (Darriba et al. Reference Darriba, Taboada, Doallo and Posada2012). Bayesian inference analyses were conducted using MrBayes (v3.2.3) (Ronquist et al. Reference Ronquist, Teslenko, Van Der Mark, Ayres, Darling, Höhna and Huelsenbeck2012). Markov chain Monte Carlo simulations were run for 10,000,000 generations, log-likelihood scores were plotted, and only the final 75% of trees were used to produce the consensus trees. FigTree v1.4 (Rambaut Reference Rambaut2012) was used to visualize the trees. Genetic distances were estimated with MEGA v. 10 (Kumar et al. Reference Kumar, Stecher, Li, Knyaz and Tamura2018).

Results

Taxonomy

Genus Georduboisia nom. nov.

Zoobank number for genus. urn:lsid:zoobank.org:act:3E7FB9AF-F0D1-406F-A0E9-F868A3F9D177

Remarks

We changed the name Duboisia Szidat, Reference Szidat1936 to Georduboisia nom. nov. in accordance with the rules of handling homonyms (ICZN 1999, Articles 52–54, 56). Similarly to the name coined by Szidat (Reference Szidat1936), Georduboisia nom. nov. is an eponym of Georges Dubois (1902–1993), a Swiss parasitologist. The diagnosis of Georduboisia nom. nov. corresponds to that of Duboisia Szidat, Reference Szidat1936 (see Niewiadomska Reference Niewiadomska, Gibson, Jones and Bray2002). Type species: Georduboisia syriaca (Dubois, 1934) comb. nov. Other species: Georduboisia skrjabini (Sudarikov & Oshmarin, 1954) comb. nov. and Georduboisia teganuma (Ishii, Reference Ishii1935) comb. nov.

Georduboisia cf. teganuma (Ishii, Reference Ishii1935) [Figures 12]

Figure 1. Paragenophore of Georduboisia cf. teganuma from intestine of Podiceps cristatus, Astrakhan Region, Russia. (A) whole mount, ventral view; (B) body fragment with elements of female and male (only testes) reproductive systems (cirrus sac, vitellarium, and cecum removed from figure), ventral view. Scale bars: A, B = 300 μm.

Figure 2. Terminal genitalia of Georduboisia cf. teganuma. (А) cirrus sac, entire dorsal view; (B) vaginal sphincter, invaginated cirrus and common genital atrium, sinistro-lateral view; Abbreviations: c, invaginated cirrus; cc, fragment of cirrus sac; ej, ejaculatory duct; ga, genital atrium; isv, internal seminal vesicle; pp, pars prostatica with field of prostatic cells; s, sphincter of genital atrium; td, terminal depression; u, uterus; v, vaginal sphincter. Scale bars: A = 50 μm; B = 100 μm.

Description

Body unipartite, pouch-like, with deep ventral concavity, 1018–1412 × 692–817, with terminal depression on posterior extremity. Tegument with small spines. Oral sucker 93–120 × 103–138, opening terminally or subterminally. Ventral sucker usually with axis inclined anteriorly, 79–103 wide. Sucker-width ratio 1:0.66–0.86. Forebody 13.5–27.4% of body length. Prepharynx absent. Pharynx 79–103 × 83–114. Ratio of oral sucker to pharynx based on mean diameter 1:0.59–0.84. Esophagus very short, 21–28. Ceca terminating blindly in posterior quarter of body, not approaching posterior end of body. Holdfast organ sucker-like, large, with large central cavity, 464–665 × 346–519, posterior to ventral sucker. Two testes, opposite or oblique, very elongate, convoluted or folded on themselves; occasionally oval (one testis in one specimen), entire to variously lobed, contiguous; left testis 692–817 × 138–180, right testis 450–720 × 138–201. Cirrus sac elongate, massive, entirely within posterior half of body or encroaching into anterior half of body, length 369–720 (31.2–53.6% of body length), maximum width 97–125, containing internal seminal vesicle, pars prostatica, ejaculatory duct, and invaginated cirrus. Internal seminal vesicle bipartite; distal reservoir larger than proximal reservoir, tubular, rectilinear, voluminous. Pars prostatica vesicular, with extensive field of prostatic cells. Ejaculatory duct short. Invaginated cirrus massive. Genital atrium tubular, terminates with small sphincter, opens into terminal depression on posterior end of body. Ovary suboval, 111–152 × 104–138, dextro- or sinistro-submedian, pre-equatorial to post-equatorial, at level of proximal end of cirrus sac. Laurer’s canal opens dorsally to ovary (visible only in one specimen). Mehlis’ gland well developed, lateral or postero-lateral to ovary. Proximal part of uterus acts as uterine seminal vesicle; distal part terminates with massive vaginal sphincter, opens into genital atrium ventrally to male genital pore. Eggs numerous (10–16), 93–96 × 52–55. Vitelline follicles large, in two broad sublateral fields; fields running smoothly from dorsal to ventral side of body, not extending behind ventral sucker anteriorly and testes posteriorly, separate anteriorly, and confluent or separate posteriorly.

Host. Podiceps cristatus (Linnaeus, 1758) (Podicipedidae).

Site of infection. Intestine.

Material examined. Five adult specimens (paragenophores), Kalinino Village, Astrakhan Region, Russia (46°20′9″ N; 48°53′29″ E); IPEE 14345–14349. Two adult specimens (paragenophores), Leninsky Leskhoz Village, Rostov Region, Russia (46°45′38″N; 39°8′1″ E); IPEE 14350, 14351.

Sequences deposited. PP093046 (28S rRNA gene), PP093047–PP093048 (5.8S + ITS2 region), P092969–PP092970 (cox1 gene).

Remarks

The specimens examined in our study should undoubtedly be assigned to Georduboisia nom. nov. on the basis of their body shape (pouch-like with a large holdfast organ inside), position of the ventral sucker close to the pharynx, presence of a massive vaginal sphincter, and other morphological characters (Sudarikov Reference Sudarikov and Skrjabin1961; Dubois Reference Dubois1984; Niewiadomska Reference Niewiadomska, Gibson, Jones and Bray2002). Only two of the three nominal species of this genus have been recorded in Europe, G. syriaca and G. teganuma (Dubois Reference Dubois1984). According to Dubois (Reference Dubois1984), these digenean species most clearly differ by the taxonomic groups of their definitive hosts (Ciconiidae vs. Podicipedidae). Morphological differences between them are weakly expressed and concern only the width of holdfast organ and the length of the cirrus sac. The minimum values of holdfast organ width and cirrus sac length in G. syriaca usually are greater than the corresponding maximum values in G. teganuma (Table 1).

Table 1. Comparative characterisation of Georduboisia syriaca, Georduboisia teganuma, and Georduboisia cf. teganuma based on some metric traits (in μm)

* diameter

Taxonomic affiliation of the hosts, the holdfast organ width, and the cirrus sac length indicate that the digeneans examined in our study are probably conspecific with G. teganuma. However, this parasite species is characterised by oval testes (Ishii Reference Ishii1935; Sudarikov et al. Reference Sudarikov, Shigin and Zhatkanbaeva1973), whereas in our specimens the testes are usually very elongate and strongly convoluted or folded on themselves.

Genus Paracoenogonimus Katsurada, 1914

Paracoenogonimus ovatus Katsurada, 1914 (Figure 3)

Figure 3. Paragenophore of Paracoenogonimus ovatus, from intestine of Circus aeruginosus, Astrakhan Region, Russia. (A) whole mount, ventral view; (B) body fragment with elements of female and male (only testes) reproductive systems (cirrus sac, vitellarium, and cecum removed from figure), ventral view; (C) terminal genitalia, dextro-lateral view. Abbreviations: с, partly evaginated cirrus; ej, ejaculatory duct; ga, genital atrium; isv, internal seminal vesicle; mt, metraterm; pp, presumptive pars prostatica; s, sphincter of genital atrium; td, terminal depression. Scale bars: A, B = 300 μm; С = 50 μm.

Description. Body divided into oval or ovoid concave prosoma and small subtriangular opisthosoma with terminal depression on posterior extremity; total body length 758–824, prosoma length 696–789, prosoma maximum width 464–575, opisthosoma length 35–62. Tegument with small spines. Oral sucker 55–58 × 58–65, opening subterminally. Ventral sucker usually with axis inclined anteriorly, 34–41 wide. Sucker-width ratio 1:0.53–0.71. Forebody 34.5–45.4% of total body length and 36.7–47.6% of prosoma length. Prepharynx absent. Pharynx 41–52 × 34–40. Ratio of oral sucker to pharynx based on mean diameter 1:0.41–0.60. Esophagus 48–69 long. Ceca terminating blindly near posterior extremity of prosoma. Holdfast organ usually everted, 215–284 × 172–242, posterior to ventral sucker. Two testes, slightly oblique, rarely tandem, contiguous, postacetabular; anterior testis oval, 208–228 × 138–166, sinistro-submedian; posterior testis transverse-oval to almost semicircular, 138–208 × 208–277, median, rarely sinistro-submedian. Cirrus sac elongate, in posterior third of body, length 203–258 (26.4–32.1% of total body length), maximum width 34–45, containing internal seminal vesicle, pars prostatica (presumably, as not clearly discernible), ejaculatory duct and cirrus. Internal seminal vesicle saccular over most of length and tubular distally, tubular part forms distinct loop. Presumptive pars prostatica vesicular, with muscular wall of uneven thickness (thickest wall on side facing proximal end of cirrus sac); prostatic cells indistinguishable. Cirrus invaginated or partly evaginated, poorly differentiated from ejaculatory duct. Genital atrium small, terminates with small sphincter, opens into terminal depression on posterior end of body. Ovary rounded, 76–104 × 76–104, strongly dextro-submedian, at level of anterior testis or intertesticular, partly overlapped by anterior or both testes dorsally. Ovarian complex indistinguishable. Distal part of uterus forms metraterm, 89–113 long; wall of metraterm with distinct circular and longitudinal musculature. Eggs few (1–2), 103–114 × 72–86. Vitelline follicles in two broad sublateral fields surrounding holdfast organ; fields separate posteriorly and confluent or separate anteriorly.

Host. Circus aeruginosus (Linnaeus, 1758) (Accipitridae).

Site of infection. Intestine.

Material examined. Five adult specimens (paragenophores), Kalinino Village, Astrakhan Region, Russia (46°20′9″ N; 48°53′29″ E); IPEE 14352.

Sequences deposited. PP093043–PP093045 (5.8 + ITS2 region), PP093049–PP093050 (28S rRNA gene), PP092971–PP092973 (cox1 gene).

Remarks

The specimens examined in our study can be assigned to the genus Paracoenogonimus based on morphological characters such as the body divided into the oval or ovoid concave prosoma and the small subtriangular opisthosoma, the presence of the ventral sucker, the absence of the vaginal sphincter, the position of the relatively small holdfast organ in the posterior half of the prosoma, a non-massive cirrus sac and the vitellarium surrounding holdfast organ and gonads (Komiya Reference Komiya1938; Niewiadomska Reference Niewiadomska, Gibson, Jones and Bray2002).

Comparison of morphological data on the two known species of this genus, P. ovatus and P. ussuriensis, shows that they are differentiated from each other only by the size of the ventral sucker: 24–50 × 28–50 vs. 52 × 55 (Table 2). According to Besprozvannykh & Ermolenko (Reference Besprozvannykh and Ermolenko2009), adults of P. ovatus differ from those of P. ussuriensis also in the distribution of vitelline follicles: the follicles form two sublateral groups clearly separated from each other at the level of the anterior and posterior testes in the former species and are assembled in a semicircle with a gap at the level of the posterior testis in the latter species. However, these authors did not take into account the data of Golovin (Reference Golovin1958) on the distribution of vitelline follicles in specimens of P. ovatus ex Haliaeetus albicilla (Linnaeus, 1758) from European part of Russia. The follicles in these specimens were arranged in a semicircle with a gap at the level of the posterior testis. The measurements of the ventral sucker of the specimens in our study correspond to those of P. ovatus.

Table 2. Comparative characterization of Paracoegonimus spp. based on some metric traits (in µm)

* diameter

Phylogeny

We obtained partial sequences of the cox1 gene from two adult specimens of Georduboisia cf. teganuma (one from the Astrakhan Region and one from the Rostov Region) and three adult specimens of P. ovatus (Astrakhan Region). The sequences of Georduboisia cf. teganuma were very similar to each other, differing by only one nucleotide. The sequences of P. ovatus were also similar to each other (p-distance 1.6–2.1%). Partial sequences of the 5.8S + ITS2 region were obtained from one adult specimen of Georduboisia cf. teganuma collected in the Astrakhan Region and from three adult specimens of P. ovatus from the same region. The three newly obtained sequences of this fragment of rDNA from adults of P. ovatus from the Astrakhan Region were similar to each other (p-distance 0.1–0.3%). Partial sequences of the 28S rRNA gene were obtained from two adult specimens of Georduboisia cf. teganuma and two adult specimens of P. ovatus, all collected in the Astrakhan Region. These two sequences of Georduboisia cf. teganuma were identical, and so were the two sequences of P. ovatus.

Phylogenetic analysis based on partial cox1 gene sequences (Figure 4) placed Georduboisia cf. teganuma as a poorly supported sister to the clade of metacercariae of Holostephanus sp. from Carassius auratus (Linnaeus, 1758) from China, whereas P. ovatus was a poor sister to the clade of metacercariae of Cyathocotyle prussica Mühling, Reference Mühling1896. In turn, the Georduboisia cf. teganuma + Holostephanus sp. appeared to be a strongly supported sister to the P. ovatus + C. prussica clade. The group containing all these species had a poorly supported sister relationship with the clade including Mesostephanus spp. and unidentified cyathocotylids. The other cyathocotylid digeneans involved in this analysis, namely Braunina spp., occupied a basal position to all the species mentioned above.

Figure 4. Phylogenetic relationships of Georduboisia cf. teganuma and Paracoenogonimus ovatus based on Bayesian inference analysis of partial cox1 gene sequences. Posterior probability values lower than 0.6 are not shown. Development stages and biogeographical sampling places are indicated for the members of the Cyathocotylidae only. New sequences obtained in this study are highlighted by grey color frames. Abbreviations: с, cercaria; mtc, metacercaria; ad, adult; Arg, Argentina; Can, Canada; Ch, China; E, Egypt; G, Germany; M, Mexico; Rus, Russia; USA, United States of America.

Phylogenetic analysis based on the sequences of the partial 5.8S + ITS2 region of nuclear DNA (Figure 5) placed Georduboisia cf. teganuma into the strongly supported polytomic clade that also contained the clade of metacercaria of Holostephanus spp. ex C. auratus (China) and Cyprinus carpio Linnaeus, 1758 (Hungary) and the clade formed by the adult specimen and metacercaria of Holostephanus dubinini Vojtek & Vojtkova, 1968, metacercaria of C. prussica, and cyathocotylid cercariae from molluscs of Europe, China, and Vietnam, unidentified with respect to genus or species. The above-mentioned metacercariae of Holostephanus sp. ex C. auratus of China were conspecific with those in the cox1-tree. The clade containing Georduboisia cf. teganuma, H. dubinini, C. prussica, and unidentified cyathocotylid cercariae appeared as a poorly supported sister to the also poorly supported group of cercariae obtained from the Thailand mollusk Filopaludina polygramma (von Martens, 1860) and identified as Prohemistomum vivax (Sonsino, 1892). The clade containing all above-mentioned species was a moderately supported sister to the poorly supported clade including Mesostephanus spp., specimens originally identified as H. dubinini and P. vivax, and some unidentified cyathocotylid cercariae and metacercariae. Adult specimens of P. ovatus examined in our study clustered in one strongly supported clade with the metacercariae from Hungarian and Italian fishes originally classified by Cech et al. (Reference Cech, Sándor, Molnár, Varga, Caffara, Fioravanti, Buchmann and Székely2021) as Cyathocotylidae gen. sp. (available in GenBank NCBI as Holostephanus sp.). P-distance between adults of P. ovatus and the metacercariae from Hungarian and Italian fishes are 0.4–0.5%. Therefore, we consider these metacercariae from Hungary and Italy as probably conspecific with P. ovatus. In turn, the clade of adult specimens of P. ovatus and metacercariae probably conspecific with them had a sister relationship with the large clade represented by all cyathocotylids mentioned above.

Figure 5. Phylogenetic relationships of Georduboisia cf. teganuma and Paracoenogonimus ovatus based on Bayesian inference analysis of partial 5.8S+ITS2 region sequences. Posterior probability values lower than 0.6 are not shown. Development stages and biogeographical sampling places are indicated for the members of the Cyathocotylidae only. New sequences obtained in this study are highlighted by grey color frames. Abbreviations: с, cercaria; mtc, metacercaria; ad, adult; Au, Australia; Ch, China; E, Egypt; G, Germany; Hun, Hungary; Is, Israel; It, Italy; Rus, Russia; Th, Thailand; V, Vietnam.

Phylogenetic analyses based on the partial 28S rRNA gene sequences (Figure 6) revealed Georduboisia cf. teganuma to be a strongly supported sister to the H. dubinini + Cyathocotyle spp. clade. Cyathocotyle spp. within the H. dubinini + Cyathocotyle spp. clade appeared as a paraphyletic assemblage, as one of the groups of Cyathocotyle spp. (metacercaria of C. prussica and two unidentified cercariae Cyathocotyle sp.) appeared to be sister to H. dubinini and not to the other congeners; however, this sister relationship was poorly supported. This analysis supported P. ovatus as sister to unidentified specimens of Neogogatea Chandler & Rausch, 1947. The P. ovatus + Neogogatea group was nested into the strongly supported clade also containing Gogatea spp. and Holostephanoides ictaluri Vernberg, 1952. This clade had a moderately supported sister relationship with the Georduboisia cf. teganuma + (H. dubinini + Cyathocothyle spp.) clade. The group of Mesostephanus spp., Braunina spp., and unidentified cyathocotylid cercariae from Australia appeared as a strongly supported sister to the large clade including all the above-mentioned cyathocotylids. In turn, the entire set of the species just mentioned was a sister to the Suchocyathocotyle spp. clade.

Figure 6. Phylogenetic relationships of Georduboisia cf. teganuma and Paracoenogonimus ovatus based on Bayesian inference analysis of partial 28S rRNA gene sequences. Posterior probability values lower than 0.6 are not shown. Development stages and biogeographical sampling places are indicated for the members of the Cyathocotylidae only. New sequences obtained in this study are highlighted by grey color frames. Abbreviations: с, cercaria; mtc, metacercaria; ad, adult; Arg, Argentina; Au, Australia; G, Germany; M, Mexico; Rus, Russia; SA, South Africa; Th, Thailand; Ukr, Ukraine; USA, United States of America; V, Vietnam.

Discussion

In this study, we provided morphological descriptions of adults of Georduboisia cf. teganuma and P. ovatus. Georduboisia cf. teganuma differed from G. teganuma studied by Ishii (Reference Ishii1935) and Sudarikov et al. (Reference Sudarikov, Shigin and Zhatkanbaeva1973) in the shape of the testes. Unfortunately, the collection material of these authors has not been preserved. We assume that Ishii (Reference Ishii1935) and Sudarikov et al. (Reference Sudarikov, Shigin and Zhatkanbaeva1973) examined strongly pressured specimens, whose very elongate, convoluted testes could be perceived as oval. Our assumption that the testes of the specimens of G. teganuma studied by V. Sudarikov with coauthors could indeed be elongate and at the same time folded on itself or convoluted is supported by the following words of these authors: ‘Forms with hypertrophied testes are sometimes found among normally developed specimens. In such forms large, rounded areas of the same histological structure as the testes themselves become separated from the body of the testes. In these cases, a regular symmetric arrangement of the testes is broken and one of them descends closer to the posterior end of the body’ (Sudarikov et al. Reference Sudarikov, Shigin and Zhatkanbaeva1973, p. 59). However, due to this discrepancy in the testes morphology, we cannot be entirely sure about the species of the digeneans examined in our study. Therefore, we identify them as Georduboisia cf. teganuma. In addition, we re-examined the worms found in P. cristatus from the Novosibirsk Region (Russia) and identified as G. teganuma (IPEE 951/Tr) by Filimonova & Shalyapina (Reference Filimonova, Shalyapina, Ryzhikov and Folitarek1975). The shape of the testes in them was the same as in our specimens.

We demonstrated the presence of a muscular metraterm in P. ovatus, the type species of Paracoenogonimus. This is the first report of a metraterm in this genus.

The results of our phylogenetic analyses based on the three genetic markers were apparently different, the differences being associated both with the sets of species involved in them and with the strength of the phylogenetic signal for deep or external nodules. The best-resolved phylogenetic relationships of Georduboisia cf. teganuma and P. ovatus were obtained using the 28S rRNA gene sequences. According to the latest variants of the system of cyathocotylid digeneans based on morphological data, Georduboisia nom. nov. (=Duboisia Szidat, Reference Szidat1936) is a member of the Prosostephaninae, which also includes Prosostephanus Lutz, Reference Lutz1935 and either Neogagatea (see Dubois Reference Dubois1987) or Serpentostephanus Sudarikov, Reference Sudarikov and Skrjabin1961 (see Niewiadomska Reference Niewiadomska, Gibson, Jones and Bray2002). The absence of molecular data on Prosostephanus does not allow us to test the hypothesis about the proximity of Georduboisia nom. nov. to this genus. At the same time, our data do not support the conclusion of Dubois (Reference Dubois1987) regarding the affinity of Georduboisia nom. nov. to Neogogatea. However, it should be emphasised that our recent conclusion about the absence of a close relationship between Georduboisia nom. nov. and Neogogatea is largely conditional because the genus affiliation of the specimens deposited in GenBank as Neogogatea sp. (MK650447, MK650448) was not confirmed morphologically. On the other hand, our data agree with the hypothesis of Sudarikov (Reference Sudarikov and Skrjabin1961) that Cyathocotyle Mühling, Reference Mühling1896 and Holostephanus Szidat, Reference Szidat1936 are related to Georduboisia nom. nov. Morphological evidence substantiating the phylogenetic position of Georduboisia nom. nov. based on molecular data is the undoubted similarity between its adult specimens and Holostephanus in body shape (e.g., Sudarikov Reference Sudarikov and Skrjabin1961). The paraphyly of Cyathocotyle spp. revealed in the present study cannot yet be discussed in detail. This issue requires accumulation of molecular data on adult specimens of Cyathocotyle and Holostephanus.

Our data did not support the traditional hypotheses about the phylogenetic affinity of Paracoenogonimus to Mesostephanus (e.g., Dubois Reference Dubois1938, Reference Dubois1953, Reference Dubois1987; Sudarikov Reference Sudarikov and Skrjabin1961; Niewiadomska Reference Niewiadomska, Gibson, Jones and Bray2002). Paracoenogonimus appeared in our 28S-tree within a strongly supported clade together with Holostephanoides Dubois, Reference Dubois1983 and the members of the Szidatiinae (sensu Niewiadomska Reference Niewiadomska, Gibson, Jones and Bray2002), Neogogatea (but see above), and Gogatea Lutz, Reference Lutz1935. Previously Achatz et al. (Reference Achatz, Pulis, Junker, Binh, Snyder and Tkach2019) demonstrated the clustering of Holostephanoides with these two szidatiine genera. Paracoenogonimus and Holostephanoides are similar to Neogogatea and Gogatea only in general features characteristic of all cyathocotylids. This means that the phylogenetic position revealed in our study has no obvious morphological confirmation. In general, it can be noted that the current classification of the Cyathocotylidae at the subfamily level is inadequate for describing the phylogenetic relationships of its genera. In addition, it should be noted that our phylogenetic analyses revealed a number of controversial points in the identification of cyathocotylids (in particular H. dubinini and P. vivax) whose sequences are represented in GenBank NCBI (Figure 5).

This is a new report of Georduboisia nom. nov. (=Duboisia Szidat, Reference Szidat1936) from podicipedid birds. Specimens of Georduboisia cf. teganuma described in this study have been found in the Rostov, Astrakhan, and Novosibirsk regions of Russia. Georduboisia teganuma (=Cyathocotyle teganuma), to which these digeneans are very similar, has been recorded in podicepedids in Japan, Kazakhstan, Buryatia, Bashkiria, and the Astrakhan Region (Sudarikov et al. Reference Sudarikov, Shigin and Zhatkanbaeva1973; Bayanov & Islamov Reference Bayanov, Islamov and Ershov1977; Dorzhiev et al. Reference Dorzhiev, Badmaeva and Dugarov2021). Zhatkanbaeva (Reference Zhatkanbaeva1964) found specimens of Georduboisia nom. nov. in Podiceps grisegena (Boddaert, 1783) and Podiceps nigricollis (Brehm, 1831) from Turgay lakes (Kazakhstan), identifying them as G. syriaca. These specimens are indeed similar to G. syriaca at least in cirrus sac length (785 according to the drawing of Zhatkanbaeva Reference Zhatkanbaeva1964). A rather high morphological similarity between G. syriaca, G. teganuma, and Georduboisia cf. teganuma raises the question of their possible synonymy. However, to address this question, it is necessary to involve molecular data on Georduboisia nom. nov. isolates from other localities and hosts, particularly from storks (Ciconiidae).

Paracoenogonimus ovatus has been repeatedly recorded in Western and Central Europe (e.g., Komiya Reference Komiya1938; Edelényi Reference Edelényi1974; Niewiadomska Reference Niewiadomska2010) and Eastern Europe, including the Astrakhan Region (e.g., Golovin Reference Golovin1958; Ginetsinskaya & Koscheva Reference Ginetsinskaya and Koscheva1959). In most locations only metacercariae of this parasite were recorded, which can be explained by limited data on the parasite fauna of fish-eating birds in these regions. Our phylogenetic analysis based on the 5.8S + ITS2 dataset showed that the metacercariae from the musculature of fish from Hungary and Italy were probably conspecific with adults of P. ovatus. Metacercariae of P. ovatus exhibit a weak specificity to fish hosts (Ostrowska et al. Reference Ostrowska, Wiśniewski and Piasecki2019). Wierzbicka & Einszporn-Orecka (Reference Wierzbicka and Einszporn-Orecka1972) observed strong emaciation in A. brama when the density of these metacercariae reached 95 ind.·g-1 of host muscle. However, Ostrowska et al. (Reference Ostrowska, Wiśniewski and Piasecki2019) did not detect any pathological changes in R. rutilus even when the density of infection with metacercariae of this digenean species was very high (66 ind.·g-1).

It has been suggested that metacercariae of P. ovatus may potentially be harmful to humans (Sudarikov Reference Sudarikov and Skrjabin1961). This suggestion was based on reports that mammals could be experimentally infected with P. ovatus (e.g., Komiya Reference Komiya1938; Ginetsinskaya & Koscheva Reference Ginetsinskaya and Koscheva1959). Interestingly, however, the zoonotic potential of metacercariae of P. ovatus (incorrectly identified as Holostephanus sp.) was not confirmed in the experiments of Sándor et al. (Reference Sándor, Gyöngy, Nyeste, Czeglédi, Székely, Buchmann and Cech2020). A possible explanation of these results is that the parasites from birds and from mammals identified as P. ovatus belong, in fact, to different species, as has been demonstrated to be the case with the Apophallus donicus Skrjabin & Lindtrop, 1919 species complex (Sokolov et al. Reference Sokolov, Khrustalev, Greenwood, Gray, Robbins, Jones, Voropaeva, Kalmykov, Dzhamirzoev and Atopkin2023).

Supplementary material

The supplementary material for this article can be found at http://doi.org/10.1017/S0022149X24000348.

Financial support

This study was partly funded by the Russian Ministry of Science and Education: FFER-2021-0005 (SGS, SAV) and FMEN-2022-0005 (DIL, SVB).

Competing interest

The authors declare there are no competing interests.

Ethical standard

This article does not include any studies involving animal experiments. The birds were shot by licensed hunters during the hunting seasons under permission of Department of Environmental Management and Environmental Protection of Astrakhan Oblast (#000003 dated 20 February 2017).

Footnotes

ZooBank publication registration: urn:lsid:zoobank.org:pub:C4C90D05-15C5-4922-9950-2E128A635CCD

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Figure 0

Figure 1. Paragenophore of Georduboisia cf. teganuma from intestine of Podiceps cristatus, Astrakhan Region, Russia. (A) whole mount, ventral view; (B) body fragment with elements of female and male (only testes) reproductive systems (cirrus sac, vitellarium, and cecum removed from figure), ventral view. Scale bars: A, B = 300 μm.

Figure 1

Figure 2. Terminal genitalia of Georduboisia cf. teganuma. (А) cirrus sac, entire dorsal view; (B) vaginal sphincter, invaginated cirrus and common genital atrium, sinistro-lateral view; Abbreviations: c, invaginated cirrus; cc, fragment of cirrus sac; ej, ejaculatory duct; ga, genital atrium; isv, internal seminal vesicle; pp, pars prostatica with field of prostatic cells; s, sphincter of genital atrium; td, terminal depression; u, uterus; v, vaginal sphincter. Scale bars: A = 50 μm; B = 100 μm.

Figure 2

Table 1. Comparative characterisation of Georduboisia syriaca, Georduboisia teganuma, and Georduboisia cf. teganuma based on some metric traits (in μm)

Figure 3

Figure 3. Paragenophore of Paracoenogonimus ovatus, from intestine of Circus aeruginosus, Astrakhan Region, Russia. (A) whole mount, ventral view; (B) body fragment with elements of female and male (only testes) reproductive systems (cirrus sac, vitellarium, and cecum removed from figure), ventral view; (C) terminal genitalia, dextro-lateral view. Abbreviations: с, partly evaginated cirrus; ej, ejaculatory duct; ga, genital atrium; isv, internal seminal vesicle; mt, metraterm; pp, presumptive pars prostatica; s, sphincter of genital atrium; td, terminal depression. Scale bars: A, B = 300 μm; С = 50 μm.

Figure 4

Table 2. Comparative characterization of Paracoegonimus spp. based on some metric traits (in µm)

Figure 5

Figure 4. Phylogenetic relationships of Georduboisia cf. teganuma and Paracoenogonimus ovatus based on Bayesian inference analysis of partial cox1 gene sequences. Posterior probability values lower than 0.6 are not shown. Development stages and biogeographical sampling places are indicated for the members of the Cyathocotylidae only. New sequences obtained in this study are highlighted by grey color frames. Abbreviations: с, cercaria; mtc, metacercaria; ad, adult; Arg, Argentina; Can, Canada; Ch, China; E, Egypt; G, Germany; M, Mexico; Rus, Russia; USA, United States of America.

Figure 6

Figure 5. Phylogenetic relationships of Georduboisia cf. teganuma and Paracoenogonimus ovatus based on Bayesian inference analysis of partial 5.8S+ITS2 region sequences. Posterior probability values lower than 0.6 are not shown. Development stages and biogeographical sampling places are indicated for the members of the Cyathocotylidae only. New sequences obtained in this study are highlighted by grey color frames. Abbreviations: с, cercaria; mtc, metacercaria; ad, adult; Au, Australia; Ch, China; E, Egypt; G, Germany; Hun, Hungary; Is, Israel; It, Italy; Rus, Russia; Th, Thailand; V, Vietnam.

Figure 7

Figure 6. Phylogenetic relationships of Georduboisia cf. teganuma and Paracoenogonimus ovatus based on Bayesian inference analysis of partial 28S rRNA gene sequences. Posterior probability values lower than 0.6 are not shown. Development stages and biogeographical sampling places are indicated for the members of the Cyathocotylidae only. New sequences obtained in this study are highlighted by grey color frames. Abbreviations: с, cercaria; mtc, metacercaria; ad, adult; Arg, Argentina; Au, Australia; G, Germany; M, Mexico; Rus, Russia; SA, South Africa; Th, Thailand; Ukr, Ukraine; USA, United States of America; V, Vietnam.

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