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. 2017 May 12;10:235. doi: 10.1186/s13071-017-2176-7

Parasite fauna of the Antarctic dragonfish Parachaenichthys charcoti (Perciformes: Bathydraconidae) and closely related Bathydraconidae from the Antarctic Peninsula, Southern Ocean

Julian Münster 1,, Judith Kochmann 1, Juline Grigat 1, Sven Klimpel 1, Thomas Kuhn 1
PMCID: PMC5427613  PMID: 28499435

Abstract

Background

As members of the Notothenioidei - the dominant fish taxon in Antarctic waters - the family Bathydraconidae includes 12 genera and 17 species. The knowledge of these species inhabiting an isolated environment is rather fragmentary, including their parasite fauna. Studies on fish hosts and their associated parasites can help gain insights into even remote ecosystems and be used to infer ecological roles in food webs; however, ecological studies on the Bathydraconidae are scarce.

Results

In this study, stomach contents and parasite fauna of the Antarctic dragonfish species Parachaenichthys charcoti (n = 47 specimens) as well as of Gerlachea australis (n = 5), Gymnodraco acuticeps (n = 9) and Racovitzia glacialis (n = 6) were examined. The parasite fauna of P. charcoti consisted of eight genera represented by 11 species, with three of them being new host records. Overall, 24 parasite genera and 26 species were found in the sampled fish, including eleven new host records.

Conclusion

Analyses revealed that the majority of the parasite species found in the different fish hosts are endemic to Antarctic waters and are characterized by a broad host range. These findings are evidence for the current lack of knowledge and the need for further parasitological studies of fish species in this unique habitat.

Electronic supplementary material

The online version of this article (doi:10.1186/s13071-017-2176-7) contains supplementary material, which is available to authorized users.

Keywords: Antarctica, Feeding behavior, Bathydraconinae, Parachaenichthys charcoti, Gerlachea australis, Gymnodraco acuticeps, Racovitzia glacialis, Parasites, Host specificity

Background

Occurring in an isolated, extreme environment, the fauna inside the Antarctic Convergence is usually dominated by a high number of endemic species. These are typically embedded in food webs that consist of relatively low species numbers. This restricted species diversity is reflected in a narrow, highly specialized system of primary producers (phytoplankton, ice algae), primary consumers (zooplankton), predators (e.g. fish, whales, seals, seabirds) and detritivores [1, 2].

To date, 283 fish species are known to inhabit Antarctic waters, most of them belonging to the suborder Notothenioidei [35]. While economic valuable members of the family Notothenioidae where targets of a variety of studies (e.g. Dissostichus eleginoides [6]; Dissostichus mawsoni [7]), unexploited families have so far been rarely a focus of research. One example are members of the family of Antarctic dragonfishes, the Bathydraconidae. The Bathydraconidae typically occur in the demersal zone within the Antarctic Convergence, and consist of 12 genera and 17 species with a depth distribution that stretches from 5 to 1,250 m. [5].

Field observations of species occurring in the geographically isolated Antarctic are usually difficult and expensive due to a limited seasonal accessibility. In this context, parasites can help gain a better understanding of the particular fish species as they are directly linked to trophic and habitat-dependent aspects of host ecology [812]. Despite many studies on the parasite fauna of Antarctic fishes, most focused on the description of new species or single parasite taxa (e.g. Digenea [13]; Cestoda [14]; Nematoda [15]; Acanthocephala [16]). These studies revealed a mainly endemic parasite ensemble (e.g. [1719]). With more than 40 known species, Digenea are the most diverse helminth parasite group [18, 20, 21]. Most of them are endemic, with benthic fish species used as intermediate host [18, 21]. In general, Antarctic fishes seem to be infected with a wide variety of parasite species, most of them with low host specificity. Nevertheless, the knowledge of the parasite fauna of members of the family Bathydraconidae remains only fragmentary [18], due to the remote sampling areas and therefore, often low sample sizes in the respective studies.

In this study, Parachaenichthys charcoti (Vaillant, 1906) was parasitologically examined in combination with stomach content analysis. In order to evaluate the findings, the parasite fauna of fish samples of the closely related species Gymnodraco acuticeps (Boulenger, 1902), Racovitzia glacialis (Dollo, 1900) and Gerlachea australis (Dollo, 1900) were assessed. The aim of this study was to extend the knowledge on the ecology of the fish species studied, their parasite fauna and parasite life-cycles and compare the findings with literature data for other members of the family Bathydraconidae.

Methods

Sample collection

Parachaenichthys charcoti were caught during the research cruise ANT-XXVIII/4 in 2012 of the RV Polarstern in waters off the tip of Antarctic Peninsula and off South Shetland Islands (Fig. 1; Additional file 1: Table S1). The fishing was conducted with a commercially-sized 140' bottom trawl at depths between 100 and 300 m, following the standard procedure of the CCAMLR (Convention on the Conservation of Antarctic Marine Living Resources) surveys. Each haul had a towing time of 30 min with a speed of 2.6–4.4 Kn (nautical miles/h). Overall, 67 specimens of the family Bathydraconidae were caught and stored at -20 °C for examination at the Institute of Ecology, Evolution and Diversity at the Goethe University, Frankfurt/Main. Specimen identification was performed using Gon & Heemstra [22].

Fig. 1.

Fig. 1

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Sampling locations of the fish species studied in Antarctic waters. Coordinates of the sampling points are given in Additional file 1: Table S1

Morphological and parasitological examination

As part of the morphological examination, total length (TL), preanal length (PAL), total weight (TW), and carcass weight (CW) were measured to the nearest 0.1 cm and 0.1 g. Subsequently, the body surface including skin, fins, eyes, gills as well as the nasal, buccal and branchial cavities were checked for ectoparasites. Then, the body cavity was opened and the inner organs were removed and separated. Stomach, pyloric caeca, gonads, liver and intestines were checked for endoparasites using a stereomicroscope (Olympus SZ 61, magnification × 6.7–45). For stomach content analyses, the stomach content was removed. Detected parasites were isolated and all remaining host tissues were removed carefully. For the morphological identification of the parasites, existing keys and original descriptions were used [16, 20, 23, 24]. Nematode specimens were preserved in absolute ethanol and the protocol by Münster et al. [19] was followed for molecular identification.

Stomach content analyses

The isolated food items were separated and identified to the lowest possible taxonomic level and grouped into categories (e.g. subphylum, family, genus, species). The dry weight of the different food items as well as the empty stomach was measured and recorded to the nearest 0.001 g. For the dry weight, the food items were pat-dried with absorbent paper. Frequency of occurrence (F in %), numerical percentage of prey (N), the weight percentage of prey (W) and the index of relative importance (IRI) were calculated in accordance to Pinkaset et al. and Hyslop [25, 26].

Data analyses

The ecological and parasitological terminology in this study followed Bush et al. [27]: prevalence (P in %) defined as the relative number of fish infected with a specific parasite; intensity (I) as the number of parasites of a particular parasite species infecting a host individual (given as a range); and mean intensity (MI) as the average intensity of a parasite species in all examined infected fish individuals. To determine the host specificity of the parasite species, the host specificity index (HSs) was calculated, using the program Specificity v1.0, following Palm & Caira [28].

In order to compare the findings of the species studied with closely related species from the family Bathydraconidae, data were collected by a broad search on Google Scholar and Web of Knowledge. Therefore, the names of the fish genera, together with the keywords “parasite”, “Digenea”, “Monogenea”, “Cestoda”, “Nematoda”, “Acanthocephala”, and “Crustacea”, were used. In addition to original publications, Klimpel et al. [29] and Oguz et al. [30] were taken into consideration. The World Register of Marine Species (www.marinespecies.org) was used for checking the validity of species names. Only unambiguous records were included.

Results

Host biometric and parasite infection data

In this study, 47 specimens of Parachaenichthys charcoti, 9 specimens of Gymnodraco acuticeps, 6 specimens of Racovitzia glacialis and 5 specimens of Gerlachea australis were examined for their parasite fauna and stomach content. Biometric data for the species samples are shown in Table 1. The TL for P. charcoti was 19.3 ± 4.7 cm (mean ± standard deviation, SD; normality test: P = 0.12), TW was 34.1 ± 33.9 g (normality test: P < 0.001) and CW was 26.8 ± 28.0 g (normality test: P < 0.001). Thirty-five of the 47 examined specimens of P. charcoti were infected with 226 metazoan parasite specimens from 8 genera and 11 species (Table 2). The most diverse and abundant group were the Nematoda (4 species), followed by Acanthocephala (3 species), Digenea (2 species), Crustacea (1 species) and Cestoda (1 species.). Nematodes were abundant with an overall prevalence of 68.1%. Pseudoterranova decipiens (s.l.) occurred in 57.5% (MI = 3.5) of the fish, followed by Contracaecum osculatum (s.l.) (P = 25.5%, MI = 3.8) and Ascarophis nototheniae (P = 2.1%, MI = 1). Cestodes were found in 27.6% (MI = 3.0) of the fish; all of the isolated specimens were classified as Tetraphyllidea indet. All isolated nematodes and cestodes were larval stages. Digeneans, represented by Gonocerca phycidis (P = 2.1%, MI = 2.0), Lecithaster macrocotyle (P = 2.1%, MI = 1.0), and Lecithaster sp. (P = 2.1%, MI = 1.0), were present in 6.4% of the examined fish. The crustacean Eubrachiella antarctica was only found in 2.1% (MI = 1.0). A correlation test (Spearman correlation) revealed a positive correlation for P. charcoti between parasite infection and TL (r = 0.69, P < 0.001) as well as TW (r = 0.68, P < 0.001). The parasite infection data for Gymnodraco acuticeps, Racovitzia glacialis and Gerlachea australis are listed in Tables 3, 4 and 5.

Table 1.

Host biometric data of the fish species studied from Antarctic waters. Data are given as the mean ± standard deviation (first row), followed by the median (second row) and the range (third row)

Species TL (cm) TW (g) CW (g) LW (g) M F nd
G. acuticeps (n = 9) 26.4 ± 3.50 132.06 ± 60.96 105.62 ± 50.81 3.187 ± 2.55
25.9 122.03 92.48 2.542 5 4 0
20.1–32.3 48.18–264.60 37.64–219.35 1.163–9.631
P. charcoti (n = 47) 19.3 ± 4.71 34.93 ± 33.90 26.84 ± 27.98 0.797 ± 0.88
16.9 19.06 15.04 0.368 16 12 19
13.1–31.1 7.36–174.42 5.53–144.67 0.060–4.280
R. glacialis (n = 6) 25.4 ± 5.67 84.96 ± 43.62 67.48 ± 33.70 2.083 ± 1.43
27.6 93.9 75.825 1.945 0 5 1
15.1–30.0 14.14–128.49 10.98–98.40 0.294–4.140
G. australis (n = 5) 22.2 ± 2.69 39.00 ± 18.04 32.78 ± 14.35 0.745 ± 0.52
22.0 34.93 30.67 0.539 4 0 1
18.0–24.9 14.86–57.40 12.83–48.28 0.236–1.368
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Abbreviations: TL host total length, TW host total weight, CW host carcass weight, LW host liver weight, M number of male fish, F number of female fish, nd number of fish with undetermined sex

Table 2.

Parasite fauna of Parachaenichthys charcoti (n = 47) sampled in Antarctica

Parasite Organ n P (%) MI I MA
Digenea St, I 4 6.4 1.3 1–2 0.09
Gonocerca phycidis a St 2 2.1 2.0 1–2 0.04
Lecithaster macrocotyle I 1 2.1 1.0 1 0.02
Lecithaster sp. I 1 2.1 1.0 1 0.02
Cestoda Bc, St, I 39 27.6 3.0 1–9 0.83
Tetraphyllidea indet. Bc, St, I 39 27.6 3.0 1–9 0.83
Nematoda Bc, L, P, St, I 166 68.1 5.2 1–20 3.50
Ascarophis nototheniae St 1 2.1 1.0 1 0.02
Contracaecum osculatum (s.l.) Bc, L, P, I 45 25.5 3.8 1–15 0.96
Contracaecum radiatum Bc 1 2.1 1.0 1 0.02
Contracaecum sp. P 1 2.1 1.0 1 0.02
Pseudoterranova decipiens (s.l.) Bc, L, St, I 94 57.5 3.5 1–14 2.00
Nematoda indet. Bc, L, P, St, I 24 34.0 1.5 1–4 0.51
Acanthocephala Bc, L, P, St, I 16 21.3 1.6 1–3 0.34
Corynosoma cf australe a L 1 2.1 1.0 1 0.02
Corynosoma bullosum Bc, St 4 8.5 1.0 1 0.09
Corynosoma sp. P 1 2.1 1.0 1 0.02
Metacanthocephalus dalmori G 4 8.5 1.0 1 0.09
Acanthocephala indet. St, I 6 8.5 1.5 1–3 0.13
Crustacea Bs 1 2.1 1.0 1 0.02
Eubrachiella antarctica a Bs 1 2.1 1.0 1 0.02
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aNew host record

Abbreviations: P (%), prevalence, MI mean intensity, I range for intensity, MA mean abundance, St stomach, I intestine, Bc body cavity, L liver, P pyloric caeca

Table 3.

Parasite fauna of Gymnodraco acuticeps (n = 9) sampled in Antarctica

Parasite Organ n P (%) MI I MA
Digenea I 2 11.1 2.0 2 0.22
Neolebouria antarctica a I 1 11.1 1.0 1 0.11
Digenea indet. I 1 11.1 1.0 1 0.11
Cestoda I 1 11.1 1.0 1 0.11
Tetraphyllidea indet. I 1 11.1 1.0 1 0.11
Nematoda Bc, L, P, St, I 115 88.9 14.4 1–66 12.78
Contracaecum osculatum (s.l.)a Bc, L, P, St, I 103 88.9 12.9 1–56 11.44
Pseudoterranova decipiens (s.l.)a Bc 4 11.1 4.0 4 0.44
Nematoda indet. Bc, L, St 8 33.3 2.7 1–6 0.89
Acanthocephala P, I 2 22.2 1.0 1 0.22
Corynosoma bullosum a P 1 11.1 1.0 1 0.11
Acanthocephala indet. I 1 11.1 1.0 1 0.11
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aNew host record

Abbreviations: P (%), prevalence, MI mean intensity, I range for intensity, MA mean abundance, St stomach, I intestine, Bc body cavity, L liver, P pyloric caeca

Table 4.

Parasite fauna of Racovitzia glacialis (n = 6) sampled in Antarctica

Parasite Organ n P (%) MI I MA
Nematoda Bc, L, P, St, I 70 83.3 14.0 1–34 11.67
Ascarophis nototheniae St 2 16.7 2.0 2 0.33
Anisakis simplex (s.l.) St 4 16.7 4.0 4 0.67
Contracaecum osculatum (s.l.) L, I 4 33.3 2.0 1–3 0.67
Contracaecum radiatum a L, P 3 33.3 1.5 1–2 0.50
Contracaecum sp. L, P 42 50.0 14.0 2–24 7.00
Pseudoterranova decipiens (s.l.)a L 8 33.3 4.0 1–7 1.33
Nematoda indet. Bc, L, P, I 7 50.0 2.3 1–3 1.17
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aNew host record

Abbreviations: P (%), prevalence, MI mean intensity, I range for intensity, MA mean abundance, St stomach, I intestine, Bc body cavity, L liver, P pyloric caeca

Table 5.

Parasite fauna of Gerlachea australis (n = 5) sampled in Antarctica

Parasite Organ n P (%) MI I MA
Digenea I 2 20.0 2.0 2 0.40
Neolebouria antarctica a I 1 20.0 1.0 1 0.20
Digenea indet. I 1 20.0 1.0 1 0.20
Nematoda Bc, L, P, I 10 80.0 2.5 1–5 2.00
Contracaecum osculatum (s.l.) Bc, L 3 40.0 1.5 1–2 0.60
Contracaecum radiatum P 1 20.0 1.0 1 0.20
Contracaecum sp. P, L 4 40.0 4.0 2 0.80
Nematoda indet. I 2 40.0 1.0 1 0.40
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aNew host record

Abbreviations: P (%), prevalence, MI mean intensity, I range for intensity, MA mean abundance, I intestine, Bc body cavity, L liver, P pyloric caeca

Stomach content analyses

The analyses of the stomach content revealed that 91.5% stomachs contained food items, mostly Crustacea (IRI = 14,091.5) and far less frequent Teleostei (IRI = 934.1) (Table 3). The Crustacea consisted predominantly of Euphausiacea (IRI = 1753.4) and Gammaridae (IRI = 126.46). Isopods (IRI = 3.4) were less common. Due to the advanced stage of digestion, identification to lower taxonomic level was not possible. Data of the other examined species are listed in Table 6.

Table 6.

Stomach content of the examined fish species

Fish species Food item F (%) N (%) W (%) IRI
Gymnodraco acuticeps Crustacea 60.00 87.50 24.49 6719.33
Euphausiacea 40.00 50.00 22.03 2881.35
Euphausia sp. 20.00 25.00 16.09 821.78
Crustacea indet. 20.00 37.50 2.46 799.10
Teleostei 40.00 12.50 75.51 3520.45
Parachaenichthys charcoti Crustacea 90.70 93.43 61.94 14091.53
Euphausiacea 32.56 22.63 31.23 1753.44
Euphausia superba 13.95 11.68 17.43 406.18
Gammaridae 4.65 25.55 1.64 126.46
Isopoda 2.33 0.73 0.72 3.37
Ceratoserolis sp. 2.33 0.73 0.72 3.37
Crustacea indet. 48.84 44.53 28.35 3559.03
Teleostei 20.93 6.57 38.06 934.15
Racovitzia glacialis Crustacea 100 100 100 20000.00
Euphausiacea 50.00 53.33 67,42 6037.53
Euphausia sp. 50.00 53.33 67,42 6037.53
Crustacea indet. 50.00 46.67 32,58 3962.47
Gerlachea australis Crustacea 100 100 100 20000.00
Crustacea indet. 100 100 100 20000.00
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Abbreviations: F frequency of occurrence, F numerical percentage, W weight percentage, IRI index of relative importance of the different prey groups

Literature data analyses

Species of the family Bathydraconidae were rarely targeted in parasitological studies. Parasites of only ten members of the Bathydraconidae have been recorded in the Antarctic Convergence [30]. Overall, 36 species of metazoan parasites are known to infect specimens of the Bathydraconidae within these waters (Additional file 2: Table S2). The most abundant taxa were the Nematoda. Seven parasitic nematode species were found parasitizing all listed bathydraconid species, followed by the Digenea, found in eight species but being the most diverse group (14 species). For seven species of fish cestode parasites have been reported. Solely recorded from four fish species, Acanthocephala showed a similar to Digenea diversity (12 species). Crustacea and Hirudinea were far less abundant and diverse. The most abundant parasite species was the nematode Ascarophis nototheniae, occurring in five host species (Racovitzia glacialis, Gymnodraco acuticeps, Parachaenichthys charcoti, P. georgianus and Cygnodraco mawsoni), followed by Contracaecum osculatum (s.l.) (4 hosts), Corynosoma bullosum (4 hosts), Elytrophalloides oatesi (4 hosts) and Neolebouria antarctica (4 hosts). Generally, most of the known parasites show a wide fish host spectrum. For all parasite species, infecting the sampled four fish species, the host specificity index (HSs) showed a value between 5.5743 and 9.4542 (Table 7), indicating that all parasite species are euryxenous [28].

Table 7.

Host specificity index for the isolated parasite species and their fish hosts. For Class, Order, Family, Genus and Species the number of taxa, parasitizing the specific host, are given

Parasite species Class Order Family Genus Species HS Rank
Neolebouria antarctica 1 2 5 12 21 7.6701 46790515
Elytrophalloides oatesi 1 3 11 24 35 7.9727 93923274
Genolinea bowersi 1 2 6 15 31 7.6736 47163746
Glomericirrus macrouri 1 3 7 13 23 7.9659 92445330
Gonocerca phycidis 2 7 14 32 56 9.4273 26715068657
Lecithaster macrocotyle 1 2 4 14 19 7.6667 46421232
Lepidapedon garrardi 1 1 4 15 30 6.0544 1133679
Lepocreadium trullaforme 1 1 2 2 3 5.5743 375252
Macvicaria georgiana 1 1 3 9 22 5.8782 755487
Otodistomum cestoides 2 4 4 4 5 9.4048 2539978652
Anisakis simplex (s.l.) 2 11 17 26 39 9.4542 2846169314
Ascarophis nototheniae 1 3 6 12 16 7.9641 92075070
Caudotestis glacialis 1 1 2 2 2 5.5743 375251
Contracaecum osculatum (s.l.) 1 3 9 22 27 7.9693 93189730
Contracaecum radiatum 1 3 5 13 18 7.9624 91705800
Pseudoterranova decipiens (s.l.) 1 5 12 27 45 8.2624 183000359
Aspersentis megarhynchus 1 2 4 8 11 7.6666 46415287
Corynosoma arctocephali 1 2 4 10 16 7.6666 46417275
Corynosoma australe 1 2 3 3 3 7.6631 46038051
Corynosoma bullosum 1 3 10 21 30 7.9710 93555040
Corynosoma hamanni 1 1 3 11 23 5.8793 757469
Corynosoma pseudohamanni 1 1 4 13 25 6.0537 1131701
Corynosoma shackletoni 1 1 3 3 6 5.8747 749504
Hypoechinorhynchus magellanicus 1 1 3 4 5 5.8753 750500
Metacanthocephalus dalmori 1 2 5 11 17 7.6701 46789522
Metacanthocephalus johnstoni 1 1 3 5 10 5.8759 751496
Eubrachiella antarctica 1 1 4 4 5 6.0503 1122753
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Abbreviation: HS host specificity index

Discussion

The parasitological examination of Parachaenichthys charcoti revealed, compared to other members of the Nototheniodei [29], a medium diverse parasite fauna. In addition to the 19 known parasite species infecting P. charcoti [30], three new host records were detected within this study (Table 2). The parasite fauna of P. charcoti was composed of Digenea (2 species), Nematoda (4 species), Cestoda (1 species), Acanthocephala (3 species) and Crustacea (1 species). Nematoda, the most abundant group, was dominated by Pseudoterranova decipiens (s.l.). Like most nematodes within the Antarctic Convergence, P. decipiens (s.l.) shows a generalist host range for fish [31]. Its distribution in Antarctic waters is linked to the distribution and population sizes of Pinnipedia, which are very abundant final hosts and consequently maintain a constant (high) level of nematodes within the Antarctic convergence [32, 33]. Nematode specimens belonging to the complex of sibling species Contracaecum osculatum (s.l.) were the second most abundant group. Like Pseudoterranova decipiens (s.l.), C. osculatum (s.l.) uses mainly Pinnipedia as final hosts and shows a benthic life-cycle [34]. The free-living larval stages of Contracaecum radiatum on the other hand, that are able to stay in the water column, usually integrate pelagic hosts in their life-cycle [35]. However, C. radiatum (P = 2.1%) was only found once in the sampled specimens of P. charcoti, whereas the high infection numbers of nematodes with a benthic life-cycle, i.e. C. osculatum (P = 25.1%) and P. decipiens E (P = 57.7%), indicate demersal life-cycle for P. charcoti, which corresponds with former literature findings [36, 37].

In terms of diversity, Nematoda were followed by the phylum Acanthocephala. Of the three identified species, two belonged to the genus Corynosoma, C. australe and C. bullosum. Corynosoma australe uses marine mammals (e.g. Hydrurga leptonyx) as final hosts. So far, an intermediate fish host was not known from Antarctic waters, leading to the assumption that the life-cycle usually takes place outside of the Antarctic Convergence [16]; therefore, it is listed in the results as C. cf. australe. Like C. australe, C. bullosum includes pinnipeds (e.g. Mirounga leonina) as final host [16]. Both Corynosoma spp. are distributed circumpolar in Antarctic waters and beyond [16].

Interestingly, only four specimens of the usually most diverse metazoan parasite group in Antarctic waters, Digenea [18], were detected in the fish sample of P. charcoti. Of those three could be identified to species level within this study (Gonocerca phycidis: 2 specimens, Lecithaster macrocotyle: 1, Lecithaster sp.: 1). Gonocerca phycidis and L. macrocotyle are both linked to the benthic host communities in fjord and continental shelf regions within the Antarctic, with typically high infection numbers in larger predatory fish (e.g. Notothenia rossii) [16]. As P. charcoti is a rather small predatory fish, preying primarily on Crustacea with mostly very low prevalences [38], infection numbers were low (Table 2).

Overall, together with the closely related Bathydraconidae, Gerlachea australis, Gymnodraco acuticeps and Racovitzia glacialis, parasite infection patterns revealed the highest diversity for Nematoda in all four examined species (Tables 2, 3, 4 and 5). This pattern is different from the parasite diversity in Antarctica, where digeneans are usually known to be the most diverse parasite group, predominantly using teleosts as definitive hosts [18]. While the nematode fauna is relatively uniform, with Contracaecum osculatum (s.l.) and Pseudoterranova decipiens E occurring in all species studied, the composition of the digenean fauna varied between species, especially when compared with literature findings (e.g. [13, 20, 39]. For example, Neolebouria antarctica, a typical representative in demersal fish species from shelf and fjord systems [20], was also isolated from G. australis, G. acuticeps, and P. charcoti, with relatively high abundance. However, this parasite was absent from R. glacialis, which might be explained by the very low sample size.

The parasite diversity of the fish sampled (Gerlachea australis: 4 parasite species; Gymnodraco acuticeps: 9 spp; Parachaenichthys charcoti: 23 spp.; Racovitzia glacialis: 11 spp.) can be considered as low to medium when compared to other fish species inhabiting the same waters, e.g. Dissostichus elegionoides (Nototheniidae): 47 parasite species [29]; Macrourus whitsoni (Macrouridae): 25 spp. [19]; Muraneonlepis marmorata (Muraenolepididae): 29 spp. [40]; Notothenia coriiceps (Nototheniidae): 37 spp. [41]). One reason might be the position of these different fish species in the food web, with larger predators (e.g. Dissostichus spp.), often being heavily and more diversely parasitized, than smaller species (e.g. Bathydraconidae), feeding mostly on small crustaceans (this study). The same applies to infection patterns within one species; size-dependent differences in parasite infection rates as well as parasite fauna composition can be observed [11, 42]. However, another reason is that the known parasite fauna is most often directly linked to sampling effort [19]; therefore a more diverse parasite fauna is common for intensively studied fish species such as many of the economically important fishes (e.g. Gadus morhua from the North Atlantic, as one of the most intensive studied marine species with more than 130 known parasite species) [11, 43]. On the scale of individual studies, sample size has a similar effect, which probably explains the relatively low number of parasites found in the samples G. australis, G. acuticeps and R. glacialis compared to P. charcoti, although their position in the food web is similar. Overall, 24 parasite genera and 26 species were found in the sampled fish, including eleven new host records (P. charcoti: 3 new host records; G. australis: 1; R. glacialis: 3; G. acuticeps: 4 (Tables 2, 3, 4 and 5). The majority of these parasite species are endemic to Antarctic waters; nevertheless exceptions such as the cosmopolitan Gonocerca phycidis can occur [13, 20]. Although endemic to the region, all of the species that were found to infect the four fish species in this study, are euryxenous, thus, they have a wide host spectrum (e.g. Gonocerca phycidis, Anisakis simplex (s.l.), Contracaecum radiatum, Corynosoma bullosum) [6, 16, 17, 29, 44]. Only Stenakron glacialis has a narrow known host range [13, 20, 45]. According to the results of the literature data analyses, this pattern of a mostly euryxenous host spectrum holds true for the majority of parasites infecting species of Bathydraconidae in Antarctic waters.

Parasite host specificity can have various forms and way of developments [46]. One way is the coevolution between the parasite and its host. A high host specificity is often caused by a close coevolution between the host and the parasite, i.e. one parasite taxon is associated to one host taxon. On the other hand, a broad host range often originates from a lack of coevolution and multiple host switches [47]. Therefore, species belonging to a host group with a variety of different genera and species, often exhibit a larger parasite diversity, while host species with only few related species tend to show a poorer parasite fauna. Macrourus whitsoni, a member of the family Macrouridae, with only a single related species, M. caml, within the Antarctic Convergence, shows a very host-specific parasite fauna [19]. In contrast, the 17 species of Bathydraconidae are members of the Notothenioidei, the most dominant component of the recent Antarctic fish fauna [3]. This group is suspected to have gone through a strong diversification [48]. The pronounced diversification, as well as the co-occurrence of several closely related species may have favored host switches of the associated parasites and therefore caused the wide host range of the latter.

Conclusion

Eleven new host records were found in this study of parasites of four different species of the Bathydraconidae. All parasite species found can be characterized by a broad host range. The high number of new host records highlights the need for further work in the Antarctic Convergence in order to better understand this unique ecosystem and the food web structures within it.

Additional files

Additional file 1: Table S1. (19.3KB, docx)

Catch data of the examined species from Antarctic waters. Abbreviations: G.a, Gerlachea australis; G.ac, Gymnodraco acuticeps; P.c, Parachaenichthys charcoti, R.g, Racovitzia glacialis. (DOCX 19 kb)

Additional file 2: Table S2. (48KB, docx)

Parasite taxa of bathydraconid species, based on literature data and own studies. Species occurring outside of the Antarctic Convergence (e.g. South Georgia Island) are included. Records marked with an asterisk (*) were taken from Oguz et al. [30]. Abbreviations: D, Digenea; C, Cestoda; N, Nematoda; A, Acanthocephala; Cr, Crustacea; H, Hirudinea; P%, prevalence; MI, mean intensity; I, intensity range. (DOCX 48 kb)

Acknowledgment

We would like to thank Birgit Nagel and Gabriele Elter for technical assistance during the study.

Funding

The present study was financially supported by the Institute for Integrative Parasitology and Zoophysiology, Goethe-University, Frankfurt/Main.

Availability of data and materials

The dataset supporting the conclusions of this article is included within the article and its additional files.

Authors’ contributions

JM, JK, SK and TK designed the study. JM, JK and JG conducted the analyses. JM, JK, JG, SK and TK wrote the manuscript. All authors read and approved the final manuscript.

Competing interests

The authors declare that they have no competing interests.

Consent for publication

Not applicable.

Ethics approval and consent to participate

Approval of our present study by a review board institution or ethics committee was not necessary because all fish were caught during a regular research cruise on board of the RV Polarstern. No living animals were used. All fish were expertly killed according to the German Animal Protection Law (§4) and the ordinance of slaughter and killing of animals (Tierschlachtverordnung § 13).

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Footnotes

Electronic supplementary material

The online version of this article (doi:10.1186/s13071-017-2176-7) contains supplementary material, which is available to authorized users.

Contributor Information

Julian Münster, Email: Muenster@em.uni-frankfurt.de.

Judith Kochmann, Email: Judith.Kochmann@senckenberg.de.

Juline Grigat, Email: Juline.Grigat@gmx.de.

Sven Klimpel, Email: Klimpel@bio.uni-frankfurt.de.

Thomas Kuhn, Email: T.Kuhn@bio.uni-frankfurt.de.

References

  • 1.El-Sayed SZ. Productivity of the Southern Ocean: a closer look. Comp Biochem Physiol B Comp Biochem. 1988;90:489–498. doi: 10.1016/0305-0491(88)90287-8. [DOI] [Google Scholar]
  • 2.Griffiths HJ. Antarctic marine biodiversity - what do we know about the distribution of life in the Southern Ocean? PLoS ONE. 2010;5:e11683. doi: 10.1371/journal.pone.0011683. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 3.Eastman JT. Evolution and diversification of Antarctic notothenioid fishes. Am Zool. 1991;31:93–110. doi: 10.1093/icb/31.1.93. [DOI] [Google Scholar]
  • 4.Eastman JT, Clarke A. A comparison of adaptive radiations of Antarctic fish with those of non-Antarctic fish. In: Di Prisco G, Pisano E, Clarke A, editors. Fishes of Antarctica. Milano: Springer; 1998. pp. 3–26. [Google Scholar]
  • 5.Froese R, Pauly D. FishBase. World Wide Web Electron Publ. 2016. www.fishbase.org.
  • 6.Brickle P, MacKenzie K, Pike A. Parasites of the Patagonian toothfish, Dissostichus eleginoides Smitt 1898, in different parts of the Subantarctic. Polar Biol. 2005;28:663–671. doi: 10.1007/s00300-005-0737-2. [DOI] [Google Scholar]
  • 7.Gordeev II, Sokolov SG. Parasites of the Antarctic toothfish (Dissostichus mawsoni Norman, 1937) (Perciformes, Nototheniidae) in the Pacific sector of the Antarctic. Polar Res. 2016;35.
  • 8.Platt NE. Codworm - a possible biological indicator of the degree of mixing of Greenland and Iceland cod stocks. J Cons. 1976;37:41–45. doi: 10.1093/icesjms/37.1.41. [DOI] [Google Scholar]
  • 9.Williams HH, MacKenzie K, McCarthy AM. Parasites as biological indicators of the population biology, migrations, diet, and phylogenetics of fish. Rev Fish Biol Fish. 1992;2:144–176. doi: 10.1007/BF00042882. [DOI] [Google Scholar]
  • 10.Oliva ME, González M, Acuña E. Metazoan parasite fauna as a biological tag for the habitat of the flounder Hippoglossina macrops from northern Chile, in a depth gradient. J Parasitol. 2004;90:1374–1377. doi: 10.1645/GE-317R. [DOI] [PubMed] [Google Scholar]
  • 11.Münster J, Klimpel S, Fock HO, MacKenzie K, Kuhn T. Parasites as biological tags to track an ontogenetic shift in the feeding behaviour of Gadus morhua off West and East Greenland. Parasitol Res. 2015;114:2723–2733. doi: 10.1007/s00436-015-4479-y. [DOI] [PubMed] [Google Scholar]
  • 12.MacKenzie K, Hemmingsen W. Parasites as biological tags in marine fisheries research: European Atlantic waters. Parasitology. 2015;142:54–67. doi: 10.1017/S0031182014000341. [DOI] [PubMed] [Google Scholar]
  • 13.Zdzitowiecki K. Occurrence of digeneans in open sea fishes off the South Shetland Islands and South Georgia, and a list of fish digeneans in the Antarctic. Pol Polar Res. 1991;12:55–72. [Google Scholar]
  • 14.Rocka A, Zdzitowiecki K. Cestodes in fishes of the Weddell Sea. Acta Parasitol. 1998;43:64–70. [Google Scholar]
  • 15.Palm H, Andersen K, Klöser H, Plötz J. Occurrence of Pseudoterranova decipiens (Nematoda) in fish from the southeastern Weddell Sea (Antarctic) Polar Biol. 1994;14:539–544. doi: 10.1007/BF00238223. [DOI] [Google Scholar]
  • 16.Zdzitowiecki K. Antarctic Acanthocephala. In: Wägele J-W, Sieg J, editors. Synopsis of the Antarctic benthos. Koenigstein: Koeltz Scientific Books; 1991. [Google Scholar]
  • 17.Walter T, Palm H, Piepiorka S, Rückert S. Parasites of the Antarctic rattail Macrourus whitsoni (Regan, 1913) (Macrouridae, Gadiformes) Polar Biol. 2002;25:633–640. [Google Scholar]
  • 18.Rocka A. Helminths of Antarctic fishes: Life cycle biology, specificity and geographical distribution. Acta Parasitol. 2006;51:26–35. doi: 10.2478/s11686-006-0003-y. [DOI] [Google Scholar]
  • 19.Münster J, Kochmann J, Klimpel S, Klapper R, Kuhn T. Parasite fauna of Antarctic Macrourus whitsoni (Gadiformes: Macrouridae) in comparison with closely related macrourids. Parasit Vectors. 2016;9:403. doi: 10.1186/s13071-016-1688-x. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 20.Zdzitowiecki K. Antarctic Digenea, parasites of fishes. Koenigstein: Koeltz Scientific Books; 1997. [Google Scholar]
  • 21.Zdzitowiecki K. Diversity of Digenea, parasites of fishes in various areas of the Antarctic. In: Di Prisco G, Pisano E, Clarke A, editors. Fishes of Antarctica. Milano: Springer; 1998. pp. 87–94. [Google Scholar]
  • 22.Gon O, Heemstra PC. Fishes of the Southern Ocean. Grahamstown: JLB Smith Institute of Ichthyology; 1990. [Google Scholar]
  • 23.Byrd MA. Helminth parasites of Antarctic vertebrates. Part I. Digenetic trematodes of marine fishes. Proc Helminthol Soc Wash. 1963;30:129–148. [Google Scholar]
  • 24.Laskowski Z, Jeżewski W, Zdzitowiecki K. New data on the occurrence of Acanthocephala in Antarctic Amphipoda. Acta Parasitol. 2010;55:161–166. doi: 10.2478/s11686-010-0022-6. [DOI] [Google Scholar]
  • 25.Pinkas L, Oliphant MS, Iverson ILK. Food habits study. Fish Bull. 1971;152:5–10. [Google Scholar]
  • 26.Hyslop EJ. Stomach contents analysis - a review of methods and their application. J Fish Biol. 1980;17:411–429. doi: 10.1111/j.1095-8649.1980.tb02775.x. [DOI] [Google Scholar]
  • 27.Bush AO, Lafferty KD, Lotz JM, Shostak AW. Parasitology meets ecology on its own terms: Margolis et al. revisited. J Parasitol. 1997;1:575–583. doi: 10.2307/3284227. [DOI] [PubMed] [Google Scholar]
  • 28.Palm HW, Caira JN. Host specificity of adult versus larval cestodes of the elasmobranch tapeworm order Trypanorhyncha. Int J Parasitol. 2008;38:381–388. doi: 10.1016/j.ijpara.2007.08.011. [DOI] [PubMed] [Google Scholar]
  • 29.Klimpel S, Busch MW, Kellermanns E, Kleinertz S, Palm HW. Metazoan deep sea fish parasites. Solingen: Verlag Natur & Wissenschaft; 2009. [Google Scholar]
  • 30.Oguz MC, Tepe Y, Belk MC, Heckmann RA, Aslan B, Gurgen M, et al. Metazoan parasites of Antarctic fishes. Turk J Parasitol. 2015;39:174–178. doi: 10.5152/tpd.2015.3661. [DOI] [PubMed] [Google Scholar]
  • 31.Rokicki J, Rodjuk G, Zdzitowiecki K, Laskowski Z. Larval ascaridoid nematodes (Anisakidae) in fish from the South Shetland Islands (Southern Ocean) Pol Polar Res. 2009;30:49–58. [Google Scholar]
  • 32.Des Clers S, Andersen K. Sealworm (Pseudoterranova decipiens) transmission to fish trawled from Hvaler, Oslofjord, Norway. J Fish Biol. 1995;46:8–17. doi: 10.1111/j.1095-8649.1995.tb05943.x. [DOI] [Google Scholar]
  • 33.Palm HW. Ecology of Pseudoterranova decipiens (Krabbe, 1878) (Nematoda: Anisakidae) from Antarctic waters. Parasitol Res. 1999;85:638–646. doi: 10.1007/s004360050608. [DOI] [PubMed] [Google Scholar]
  • 34.Bullini L, Nascetti G, Paggi L, Orecchia P, Mattiucci S, Berland B. Genetic variation of ascaridoid worms with different life cycles. Evolution. 1986;40:437. doi: 10.2307/2408826. [DOI] [PubMed] [Google Scholar]
  • 35.Klöser H, Plötz J, Palm H, Bartsch A, Hubold G. Adjustment of anisakid nematode life cycles to the high Antarctic food web as shown by Contracaecum radiatum and C. osculatum in the Weddell Sea. Antarct Sci. 1992;4:171–178. doi: 10.1017/S0954102092000269. [DOI] [Google Scholar]
  • 36.Kock K-H. Antarctic fish and fisheries. Cambridge: Cambridge University Press; 1992. [Google Scholar]
  • 37.La Mesa M, Caputo V, Eastman JT. Gametogenesis in the dragonfishes Akarotaxis nudiceps and Bathydraco marri (Pisces, Notothenioidei: Bathydraconidae) from the Ross Sea. Antarct Sci. 2007;19:64–70. [Google Scholar]
  • 38.Busch MW, Kuhn T, Münster J, Klimpel S. Marine crustaceans as potential hosts and vectors for metazoan parasites. In: Mehlhorn H, editor. Arthropods as vectors of emerging diseases. Berlin, Heidelberg: Springer; 2012. pp. 329–360. [Google Scholar]
  • 39.Laskowski Z, Rocka A, Zdzitowiecki K, Ghigliotti L, Pisano E. New data on the occurrence of internal parasitic worms in the Gymnodraco acuticeps and Cygnodraco mawsoni (Bathydraconidae) fish in the Ross Sea. Antarctica Pol Polar Res. 2005;26:37–40. [Google Scholar]
  • 40.Gordeev II, Sokolov SG. Helminths and the feeding habits of the marbled moray cod Muraenolepis marmorata Günther, 1880 (Gadiformes, Muraenolepididae) in the Ross Sea (Southern Ocean). Polar Biol. 2016;1–8.
  • 41.Palm HW, Reimann N, Spindler M, Plötz J. The role of the rock cod Notothenia coriiceps Richardson, 1844 in the life-cycle of Antarctic parasites. Polar Biol. 1998;19:399–406. doi: 10.1007/s003000050265. [DOI] [Google Scholar]
  • 42.Poulin R. Variation in the intraspecific relationship between fish length and intensity of parasitic infection: biological and statistical causes. J Fish Biol. 2000;56:123–137. doi: 10.1111/j.1095-8649.2000.tb02090.x. [DOI] [Google Scholar]
  • 43.Hemmingsen W, MacKenzie K. The parasite fauna of the Atlantic cod, Gadus morhua L. Adv Mar Biol. 2001;40:1–80. doi: 10.1016/S0065-2881(01)40002-2. [DOI] [Google Scholar]
  • 44.Palm HW, Klimpel S, Walter T. Demersal fish parasite fauna around the South Shetland Islands: high species richness and low host specificity in deep Antarctic waters. Polar Biol. 2007;30:1513–1522. doi: 10.1007/s00300-007-0312-0. [DOI] [Google Scholar]
  • 45.Zdzitowiecki K, Ozouf-Costaz C. Contribution to the knowledge of the parasitic fauna of fish off Adelie Land, Antarctica. Pol Polar Res. 2013;34:429–435. [Google Scholar]
  • 46.Hoberg EP, Brooks DR. A macroevolutionary mosaic: episodic host-switching, geographical colonization and diversification in complex host-parasite systems. J Biogeogr. 2008;35:1533–1550. doi: 10.1111/j.1365-2699.2008.01951.x. [DOI] [Google Scholar]
  • 47.Barker SC. Evolution of host-parasite associations among species of lice and rock-wallabies: Coevolution? Int J Parasitol. 1991;21:497–501. doi: 10.1016/0020-7519(91)90053-A. [DOI] [PubMed] [Google Scholar]
  • 48.Derome N, Chen W-J, Dettaı A, Bonillo C, Lecointre G. Phylogeny of Antarctic dragonfishes (Bathydraconidae, Notothenioidei, Teleostei) and related families based on their anatomy and two mitochondrial genes. Mol Phylogenet Evol. 2002;24:139–152. doi: 10.1016/S1055-7903(02)00223-3. [DOI] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Additional file 1: Table S1. (19.3KB, docx)

Catch data of the examined species from Antarctic waters. Abbreviations: G.a, Gerlachea australis; G.ac, Gymnodraco acuticeps; P.c, Parachaenichthys charcoti, R.g, Racovitzia glacialis. (DOCX 19 kb)

Additional file 2: Table S2. (48KB, docx)

Parasite taxa of bathydraconid species, based on literature data and own studies. Species occurring outside of the Antarctic Convergence (e.g. South Georgia Island) are included. Records marked with an asterisk (*) were taken from Oguz et al. [30]. Abbreviations: D, Digenea; C, Cestoda; N, Nematoda; A, Acanthocephala; Cr, Crustacea; H, Hirudinea; P%, prevalence; MI, mean intensity; I, intensity range. (DOCX 48 kb)

Data Availability Statement

The dataset supporting the conclusions of this article is included within the article and its additional files.

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