Hostname: page-component-78c5997874-mlc7c Total loading time: 0 Render date: 2024-11-17T10:14:32.930Z Has data issue: false hasContentIssue false

Metal accumulation in ecto- and endoparasites from the anadromous fish, the Pontic shad (Alosa immaculata)

Published online by Cambridge University Press:  13 December 2021

M. Nachev*
Affiliation:
Department of Aquatic Ecology and Centre for Water and Environmental Research (ZWU), University of Duisburg-Essen, Essen, Germany
D. Rozdina
Affiliation:
Department of General and Applied Hydrobiology, Sofia University, Sofia, Bulgaria
D. N. Michler-Kozma
Affiliation:
Institute for Landscape Ecology, University of Muenster, Muenster, Germany
G. Raikova
Affiliation:
Department of General and Applied Hydrobiology, Sofia University, Sofia, Bulgaria
B. Sures
Affiliation:
Department of Aquatic Ecology and Centre for Water and Environmental Research (ZWU), University of Duisburg-Essen, Essen, Germany Department of Zoology, University of Johannesburg, Johannesburg, South Africa
*
Author for correspondence: M. Nachev, E-mail: [email protected]

Abstract

Among the parasitic taxa studied for their metal accumulation properties, especially Acanthocephala and Cestoda proved to be promising sentinels for metal pollution. However, studies on metal accumulation are still sparse for other parasite groups, mainly due to their small body size. In the present study, we collected the relatively large-sized monogenean Mazocraes alosae Hermann, 1782 from the gills of Pontic Shad (Alosa immaculata Bennet 1835) from its spawning region – the Danube River. The host tissues gills, muscle, intestine and liver, the monogeneans as well as the nematode Hysterothylacium aduncum (Rudolphi, 1802), in the cases of coinfected fish, were analysed for the elements As, Cd, Co, Cu, Fe, Mn, Pb, Se and Zn. All elements (except of As) were found in higher concentrations in monogeneans and nematodes compared to host muscle tissue. High bioconcentration factors were obtained for toxic elements such as Cd and Pb with concentrations being approximately 12 and 251 times higher in monogeneans and 773 and 33 in nematodes, respectively, as compared to host muscle tissue. In comparison to other host organs, however, some elements were found in similar or even lower concentrations in the parasites. Thus, monogeneans do not exhibit the high accumulation potential reported for other parasitic taxa. Physiological adaptations of the migratory host fish between freshwater and marine habitats with differences in uptake pathways and biological availability of elements can be discussed as a possible explanation for this divergent accumulation pattern.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2021. Published by Cambridge University Press

Introduction

Different biological indicators can be applied for the assessment of metal pollution in aquatic habitats. Usually, these are free-living organisms, which are able to concentrate pollutants in their tissues and can simultaneously resist extended pollution levels (e.g. Phillips, Reference Phillips1977; Beeby, Reference Beeby2001; Gupta and Singh, Reference Gupta and Singh2011; Amoozadeh et al., Reference Amoozadeh, Malek, Rashidinejad, Nabavi, Karbassi, Ghayoumi, Ghorbanzadeh-Zafarani, Salehi and Sures2014; Golestaninasab et al., Reference Golestaninasab, Malek, Roohi, Karbassi, Amoozadeh, Rashidinejad, Ghayoumi and Sures2014). Due to their high accumulation potential, pollutants occurring in very low concentrations in the environment can be detected by using such sentinel species, which would not be possible with conventional analyses of water, suspended particulate matter or sediments. Furthermore, bioindicators deliver valuable information about the biological availability of substances (Sures et al., Reference Sures, Nachev, Selbach and Marcogliese2017). Beside all well-established free-living biological indicators (e.g. different species of molluscs, crustaceans, annelids, fish), helminths of fish were also found to be very promising organisms to indicate metal pollution (summarized in Sures et al., Reference Sures, Nachev, Selbach and Marcogliese2017). Various species of acanthocephalans, cestodes as well as some parasitic nematodes were found to accumulate metals to extents, which exceeded those found in their host tissues (e.g. Sures et al., Reference Sures, Taraschewski and Jackwerth1994a; Tenora et al., Reference Tenora, Baruš, Kráčmar and Dvořáček2000; Baruš et al., Reference Baruš, Jarkovský and Prokeš2007; Filipović Marijić et al., Reference Filipović Marijić, Vardić Smrzlić and Raspor2013, Reference Filipović Marijić, Vardić Smrzlić and Raspor2014; Brázová et al., Reference Brázová, Hanzelová, Miklisová, Šalamún and Vidal-Martínez2015; reviewed also in Sures et al., Reference Sures, Nachev, Selbach and Marcogliese2017) and other free-living sentinels several folds (Sures et al., Reference Sures, Steiner, Rydlo and Taraschewski1999a; Golestaninasab et al., Reference Golestaninasab, Malek, Roohi, Karbassi, Amoozadeh, Rashidinejad, Ghayoumi and Sures2014). However, until now mainly endoparasitic helminths were investigated with respect to their metal accumulation capacity. Information regarding monogeneans and other ectoparasites such as crustaceans is scarce or still missing (Pérez-del-Olmo et al., Reference Pérez-del-Olmo, Nachev, Zimmermann, Fernández and Sures2019). As ectoparasites are in direct contact with the surrounding environment, changes in aqueous metal levels may be rapidly reflected in accumulated metal levels in the parasites. Additionally, monogeneans can also take up metals from the mucous and tissues on which they feed.

The Pontic shad (Alosa immaculata Bennet 1835) belongs to the family Clupeidae. It is an anadromous migratory fish species, which typically inhabits the Black Sea and the Azov Sea. Since 2001 it was also reported in the Sea of Marmara (Eryilmaz, Reference Eryilmaz2001). For spawning, the Pontic shad enters big rivers connected to the sea. It is an economically important fish species, whose annual catches in the Bulgarian sector of the Black Sea and the Danube River have dropped on average 3.5 times between 2003 and 2011 (Bulgarian Ministry of Agriculture and Food, personal communication). A. immaculatа was classified as a vulnerable species according to the IUCN red list of threatened species (IUSN, 2018) and the Bulgarian Red Book (Golemansky et al., Reference Golemansky, Beron, Popov, Popov, Beshkov, Zhivkov, Spasov, Michev, Delchev, Stoev and Dobrev2015), included also in Annex 2 and 4 of the Bulgarian Biodiversity Act and Annex 2 of the Habitats Directive 92/43ЕЕС.

The parasite fauna of A. immaculata has been studied in different regions of the Ponto–Caspian area (Nizova and Syrovatka, Reference Nizova, Syrovatka and AzNIIRKH2000; Gaevskaya and Kornyychuk, Reference Gaevskaya, Kornyychuk, Eremeev and Gaevskaya2003; Popjuk, Reference Popjuk2009, Reference Popjuk2011; Akmirza, Reference Akmirza2013; Özer et al., Reference Özer, Öztürk and Kornyychuk2013). The monogenean Mazocraes alosae Hermann, 1782 has been reported frequently from Pontic shad and other clupeids. This parasite exhibits a marine life cycle, however, it can resist the osmotic changes during the spawning migrations of it host (Aprahamian, Reference Aprahamian1985; Gérard et al., Reference Gérard, Hervé, Réveillac and Acou2016). In contrast to many monogeneans of fish, M. alosae is characterized by large body size and therefore can provide sufficient sample material required for metal analyses. Accordingly, this species fulfils most of the basic criteria for parasites as bioindicators suggested by Sures (Reference Sures2003). Metal accumulation in tissues of Pontic shad (muscle, liver and gills) collected from the Danube River has been already studied by Visnjic-Jeftic et al. (Reference Visnjic-Jeftic, Jaric, Jovanovic, Skoric, Smederevac-Lalic, Nikcevic and Lenhardt2010). However, studies based on metal uptake in its helminth parasites are still missing. Changes in osmotic conditions and salinity, respectively, lead to various physiological adaptations in migratory fishes and influence the bioavailability of hydrophilic pollutants such as metals (Merian, Reference Merian2004).

The aim of the study was to provide first data on the accumulation potential of monogeneans of fish. Therefore, a parasitological survey was carried out on Pontic Shad, which is known to harbour high infection rates of the relatively large-sized monogenean M. alosae. In order to evaluate its accumulation potential, the concentrations of different elements (As, Cd, Co, Cu, Fe, Mn, Pb, Se, Zn) in M. alosae were compared with those of host tissues (gills, muscle, intestine and liver) and with the nematode Hysterothylacium aduncum (Rudolphi, 1802), in case of co-infected fish hosts.

Materials and methods

Sample collection

Fish were collected by professional fishermen in April 2010 (n = 18) and 2011 (n = 22) during the spawning migration of the species. Sampling was performed along the Danube River in Bulgaria between the towns Lom and Vidin (river km 834–741) using gill nets with the size of the eye ranging between 32 and 88 mm. Prior to the parasitological investigation, each fish was measured for total length (TL) and standard length (SL) to the nearest mm and weighed with respect to the total weight (W) to the nearest g. The Fulton's condition factor (K) was calculated as follows K = 100 × W × TL−3 (see Nash et al., Reference Nash, Valencia and Geffen2006). Parasitological analysis was performed using standard parasitological techniques with the aid of a stereomicroscope at a magnification ×40. The skin, fins, gills and internal organs as well as the body cavity were examined for parasite infestation. After dissection the prevalence and mean intensity of parasites were calculated according to Bush et al. (Reference Bush, Lafferty, Lotz and Shostak1997). Subsequently, the parasites, as well as samples of gills, liver, gonads, intestine, muscle and kidney, were collected and kept frozen at −20°C until metal analyses.

Metal analyses

After defrosting, tissue samples and parasites were weighed and placed in 30 mL Teflon® vessels (MarsXpress; CEM GmbH, Kamp-Lintfort Germany). Some of the parasite samples from different fish of the same year were pooled together in order to reach a wet weight of at least 10 mg. Subsequently, a mixture of 1.3 mL 65% nitric acid (HNO3 sub boiled) and 2.5 mL 30% hydrogen peroxide (H2O2 suprapure Merck, Germany) was added and vessels were heated up to 170°C for 40 min using a MARS 6 digestion system (CEM GmbH, Kamp-Linfort Germany). After digestion, the clear sample solution was brought to a volume of 5 mL using Mili-Q water.

Concentrations of nine elements (As, Cd, Co, Cu, Fe, Mn, Pb, Se, Zn) were measured using a quadrupole ICP-MS system (Elan 6000, Perkin Elmer, USA). Instrument calibration was performed using a dilution series (in range 0.1–100 ppb) from standard solutions (Merck, Germany, for details see Nachev et al., Reference Nachev, Schertzinger and Sures2013). In order to prove the quality of our analytical procedure, fish tissue reference materials (IAEA-407, DORM3 and DOLT3) were analysed and accuracy rates were calculated.

Data analyses and statistical treatment

To evaluate the metal accumulation capacity of fish helminths, bioconcentration factors were calculated according to Sures et al. (Reference Sures, Siddall and Taraschewski1999b), and concentration factors were calculated with respect to metal concentrations in the water. The necessary aqueous metal levels were obtained from the database of the International Commission for Protection of Danube River (ICPDR, 2016; see Table 1). The Mann–Whitney U-test was applied to compare the morphological data of fish collected in the years 2010 and 2011. For comparisons of metal levels in host tissues and parasites, the Wilcoxon matched-pair test was applied. Additionally, correlation analyses using Spearman rank correlations were performed in order to evaluate possible relationships between element concentrations of host tissues and parasites as well as the relationship between parasite fauna composition and fish morphology data.

Table 1. Concentrations (μg/L) of selected elements in the river Daube at 834 km according to ICPDR (2016)

n.d., values below the detection limit (provided as 0 in the database); n.a., no data available.

Results

Fish data

Morphological data on Pontic shad is given in Table 2. The fish from 2010 were significantly longer and heavier than those collected in 2011 (P < 0.001). However, the mean condition factor was similar for the fish from both years.

Table 2. Morphological data of Pontic shad

TL, total length; SL, standard length; H, height; W, weight; k, condition factor.

Parasitological data

Only the monogenean M. alosae and the nematode H. aduncum were recovered during the parasitological investigations. The nematodes were found in the stomach and intestine of the dissected fish, while the monogeneans were extracted from the gills. The prevalence and mean intensity of the monogeneans did not differ significantly between the fish collected in 2010 and 2011. However, there were clear differences in the prevalence of H. aduncum between the years (see Table 3) with the nematodes being more prevalent in the year 2010 than 2011. Significant correlations were detected between the presence of nematodes and fish weight (rs = 0.73), length (rs = 0.789) and height (rs = 0.64) considering data from both years, while the correlation between the nematodes and the condition factor of the fish was negative (rs = −0.649). There was no significant correlation between the monogeneans and fish morphological data and the parasites.

Table 3. Prevalence and intensity of infection of Pontic shad with the monogenean Mazocraes alosae and the nematode Hysterothylacium aduncum

P, prevalence; MI, mean intensity; MA, mean abundance.

Element concentrations in the host and its parasites

The certified elements of the reference materials showed recovery rates in the range of 100 ± 20% (see Table 4), which assured the required quality of the applied analytical procedure to quantify the elements. Comparison of element concentrations in the host–parasite systems revealed higher levels in the parasites than in host muscle (Fig. 1; Tables 5 and 6) with the exception of As, whose concentrations in both parasite species were below the detection limit. Interestingly, relatively high bioconcentration factors were obtained for Cd and Pb, with concentrations of Pb being approximately 251 and 33 times higher in the monogeneans and nematodes, respectively, compared to the host muscle. Cadmium showed a different pattern with a higher bioconcentration factor for nematodes (773) compared to monogeneans (12) with respect to host muscle. Both parasites also accumulated essential elements to a higher degree, particularly Co (nematodes) and Fe (monogeneans). The comparison of element concentrations between parasites and other fish organs showed less clear patterns. Generally, the order of element levels in host tissues was as follows: muscle < intestine < liver < gills (for details see Fig. 1 and Table 5). The element composition in gill tissue showed similar trends and concentrations as the monogeneans. With exception of Co, the element concentrations in nematodes were comparable to the tissues from their microhabitat (liver, intestine). Direct comparisons between both parasites revealed significantly higher concentrations for Fe, Pb, Se and Zn in monogeneans, whereas the nematodes accumulated Cd, Co and Mn to a significantly higher degree (see Fig. 1, Table 6). No significant temporal concentration differences between the years were observed in the host–parasite system, which corresponds with the aqueous element concentrations provided for the years 2010 and 2011 (see Table 1).

Fig. 1. (A–C) Mean element concentrations (±s.d.) in the host–parasite system (n = 40). *Concentration below detection limit.

Table 4. Element concentrations in standard reference materials as well as accuracy and detection limits (DL) determined by ICP-MS analyses

a Fish homogenate.

b Dogfish muscle.

c Dogfish liver.

Table 5. Mean (±s.d.) bioconcentration factors for metal accumulation in parasites compared to different host tissues

Table 6. Differences between element concentrations in fish organs and parasites, and between M. alosae and H. aduncuum

M, muscle; I, intestine; L, liver; G, gills; M.a., M. alosae; H.a., H.aduncum; n.s., not significantly different.

a Not statistically tested as concentrations in parasites were below the detection limit.

In case of significant difference, the site for higher concentration is given in each cell.

*Significant at P ⩽ 0.05.

**Significant at P ⩽ 0.01.

Discussion

In this paper, we studied the metal accumulation potential of the monogenean M. alosae and compared it with that of the nematode H. aduncum from the same fish host and different tissues of the host. In general, both parasite species had higher levels of all elements than muscle tissue of the host with the exception of As, whose concentrations were below the detection limit in the parasite samples. The non-essential elements Cd and Pb were found in much higher levels in the parasites than in the host muscle tissues similar to already published data for other fish helminths such as acanthocephalans, cestodes and nematodes (Sures et al., Reference Sures, Taraschewski and Jackwerth1994a, Reference Sures, Taraschewski and Jackwerth1994b; Tenora et al., Reference Tenora, Baruš, Kráčmar and Dvořáček2000; Schludermann et al., Reference Schludermann, Konecny, Laimgruber, Lewis, Schiemer, Chovanec and Sures2003; Baruš et al., Reference Baruš, Jarkovský and Prokeš2007; Nachev et al., Reference Nachev, Schertzinger and Sures2013; Brázová et al., Reference Brázová, Hanzelová, Miklisová, Šalamún and Vidal-Martínez2015). Currently, there is not much information available on monogeneans. A study on the fresh-water monogenean Ancyrocephalus mogurndae (Yamaguti, 1940) provided evidence that it can also accumulate toxic elements such as Pb to a higher extent than its host tissues (Qian and Pin, Reference Qian and Pin2000). However, the authors did not provide the exact levels of Pb in the host–parasite system and did not calculate bioconcentration factors of monogeneans with respect to host tissues or to water. Regarding systematically related taxa such as digeneans, Sures et al. (Reference Sures, Jürges and Taraschewski1998) reported concentrations of Pb in the digenean Fasciola hepatica Linnaeus, 1758 from cattle, which were up to 170 times higher than its host tissues. In the study of Lotfy et al. (Reference Lotfy, Ezz and Hassan2013) Pb concentrations in F. hepatica and F. gigantica Cobbold, 1855 were about 2.5 times higher than in host liver tissue, in contrast to Cd that showed comparable or lower concentrations in the parasites compared to host tissues. Tellez and Merchant (Reference Tellez and Merchant2015) also provided evidence that other digeneans can accumulate various essential and non-essential elements at concentrations more than 1000 times higher than their alligator host tissues. However, almost all data on trematodes refer to terrestrial host–parasite associations (see Sures et al. (Reference Sures, Nachev, Selbach and Marcogliese2017) and there are only a few studies, which focused on marine (Torres et al., Reference Torres, Kacem, Eira, Neifar and Miquel2014) or limnetic ones (Akinsanya and Kuton, Reference Akinsanya and Kuton2016).

Previous studies on the accumulation potential of some species of the genus Hysterothylacium demonstrated the ability of this nematode to accumulate different metals. Among the elements, Cd and Pb were almost always reported at higher concentrations in the parasite than in the host (Dural et al., Reference Dural, Genc, Yemenicioǧlu and Kemal Sangun2010, Reference Dural, Genc, Sangun and Güner2011; Abdel-Ghaffar et al., Reference Abdel-Ghaffar, Abdel-Gaber, Bashtar, Morsy, Mehlhorn, Al Quraishy and Saleh2014; Mazhar et al., Reference Mazhar, Shazili and Harrison2014), with occasional reports of more than 1000 times higher concentrations in the nematode (Dural et al., Reference Dural, Genc, Yemenicioǧlu and Kemal Sangun2010). In our study, H. aduncum was also found to show high accumulation rates for Cd with respect to the host muscle tissue (see Table 5). However, Pb showed an opposite pattern being much higher accumulated in tissues of M. aloesae than in nematodes.

Generally, the biological availability of metal ions is much higher in limnetic than in marine habitats, as the concentration of hydrated ions increases with decreasing salinity (Merian, Reference Merian2004). As anadromous fish, A. imaculata experiences physiological adaptations during its migration activities. Changes in the salinity trigger adaptations in the host (Kültz, Reference Kültz and Farrell2011), which on the other hand alter the uptake mechanisms/routes of metals by the fish (Merian, Reference Merian2004). Thus, the uptake of metals in the marine environment occurs mainly over the ingested water and food. In freshwater, the uptake largely occurs through the gills, as the osmotic differences between body fluids of fish and freshwater cause water and dissolved elements to pass through the gill membrane. Thereafter, metal ions enter the blood system of fish where they might become available for blood-sucking parasites. With the aid of metal excretion into the intestine and the subsequent enterohepatic circulation, metal ions can also be taken up by endohelminths (Sures and Siddall, Reference Sures and Siddall1999).

Ectoparasites and monogeneans, in particular, can take up metals most probably via two routes. The first one represents the direct uptake from the water through the body surface similar to other platyheminthes dwelling in the intestinal lumen. The second one represents the dietary uptake. M. alosae is a haematophagous ectoparasite (Gérard et al., Reference Gérard, Hervé, Réveillac and Acou2016) and therefore it can accumulate metals available in the circulation system of the host. This was evident from the relatively high iron levels obtained for the monogeneans in comparison to the host's tissues, as haemoglobin in blood contains iron (Merian, Reference Merian2004). Thus, the accumulation of metals in monogeneans is mediated by the biological availability of metals in the water and/or by the physiology of the host. Although the concentrations of Cd and Pb in the water were below the limits of detection (see Table 1), the monogeneans accumulated up to 12 times more Cd and up to 250 times more Pb than the host's muscle. However, the concentrations of both elements were in a similar range with those in the gills tissues assuming that non-essential elements in the monogeneans reach equilibrium with respect to the tissue of the parasites microhabitat. Accordingly, the uptake routes and their importance for metal accumulation in ectoparasites cannot be clearly described.

An almost similar trend was observed for the element Pb in H. adunculum with respect to its microhabitat (intestine). The patterns for Cd were not that clear due to the high deviation of the concentrations in the intestine. As previously described, the most important accumulation pathway for fish and gut parasites in freshwater habitats represents the enterohepatic circulation (Nachev and Sures, Reference Nachev and Sures2016). Thus, the metal accumulation process is constrained mainly by the physiology of the host with osmotic adaptations during the spawning migration being a significant factor.

Here, we provide the first detailed information about the element accumulation of a monogenean species infecting a migratory (anadromous) fish. In general, the monogeneans are expected to resemble the accumulation capacity of homologues taxa e.g. from the phylum Plathyhelminthes. However, M. alosae does not exhibit such a high accumulation potential, with some elements being found in higher concentrations even in host tissues. This could be a result from the migratory behaviour of the fish host and the fact that M. alosae as an ectoparasite needs to adapt to its physiological adaptations and to osmotic changes. M. alosae can survive during the migration, however, the differences between freshwater and marine habitats and in particular the differences in the biological availability of metals, the uptake and elimination rates as well as different pollution patterns along the Danube River can shape the accumulation patterns within ectoparasites. Therefore, surveys in marine habitats can provide more representative information about the pollution levels, as the host–parasite system is exposed for a longer period to similar conditions in comparison to the short time during the spawning migration. In general, species with similar traits as M. alosae could be the subject of future research aiming to study the sentinel properties of monogeneans. M. alosae is highly abundant in different clupeid species (Gérard et al., Reference Gérard, Hervé, Réveillac and Acou2016) and with its large body size, it fulfils most of the important criteria for bioindicators as suggested by Sures (Reference Sures2003). Moreover, during the survey in 2010 and 2011 the prevalence and the intensity of monogeneans did not change in contrast to the nematodes that have been less prevalent in the fish collected in 2011. Latter differences could be attributed to the size of the fish and a different diet of larger and smaller individuals, respectively. In contrast to smaller A. immaculata specimens, the larger ones become piscivorous and feed on small fish, which serve as the second intermediate or paratenic host for H. aduncum and harbour/accumulate the larval nematodes, respectively (Hoestlandt, Reference Hoestlandt1991; Koie, Reference Koie1993). Accordingly, there was a positive correlation between infrapopulation size of H. aduncum with fish size and weight that help to explain much higher infection levels in the larger fish individuals collected in 2010 (see Tables 2 and 3). In contrast, host size and diet played no significant role in the distribution and abundance of monoxenous parasites and monogeneans in particular. Although the infestation with a high number of blood-feeding monogeneans anchored in the gill tissue can result in severe anaemia of the fish host (Buchmann and Bresciani, Reference Buchmann, Bresciani and Woo2006; Gérard et al., Reference Gérard, Hervé, Réveillac and Acou2016) our study did not exhibit any obvious effect of M. alosae on the health status (i.e. condition factor) of the fish. There was no significant relationship between infection levels and fish condition factors, as previously reported by Gérard et al. (Reference Gérard, Hervé, Réveillac and Acou2016) for M. alosae on A. alosa and Alosa fallax.

Acknowledgements

The authors would like to thank Dako Dakov for providing fish material.

Author contributions

BS, DR, GR, MN conceived and designed the study. DR and GR conducted the primary processing of the fish and parasitological investigations. DR, DM-K and MN performed the metal analysis. MN, BS, DR wrote the first draft of the article. All authors contributed to data analysis and interpretation as well as finalizing the ms.

Financial support

The study was partly funded by the Operational Programme ‘Human Resources Development’ by a schema ‘Science and education’, Project № BG051PO001-3.3-05/0001.

Conflict of interest

The authors declare there are no conflicts of interest.

Ethical standards

The catchment and processing of the fish were done according to the principles of the Bulgarian Fisheries and Aquaculture Law as well as the Directive 2010/63/EU on the protection of animals used for scientific purposes.

References

Abdel-Ghaffar, F, Abdel-Gaber, R, Bashtar, AR, Morsy, K, Mehlhorn, H, Al Quraishy, S and Saleh, R (2014) Hysterothylacium aduncum (Nematoda, Anisakidae) with a new host record from the common sole Solea solea (Soleidae) and its role as a biological indicator of pollution. Parasitology Research 114, 513522.CrossRefGoogle ScholarPubMed
Akinsanya, B and Kuton, MP (2016) Bioaccumulation of heavy metals and parasitic fauna in Synodontis clarias (Linnaeus, 1758) and Chrysichthys nigrodigitatus (Lacepede, 1803) from Lekki Lagoon, Lagos, Nigeria. Asian Pacific Journal of Tropical Disease 6, 615621.CrossRefGoogle Scholar
Akmirza, A (2013) Monogeneans of fish near Gökçeada, Turkey. Turkish Journal of Zoology 37, 441448. doi: 10.3906/zoo-1205-4Google Scholar
Amoozadeh, E, Malek, M, Rashidinejad, R, Nabavi, S, Karbassi, M, Ghayoumi, R, Ghorbanzadeh-Zafarani, G, Salehi, H and Sures, B (2014) Marine organisms as heavy metal bioindicators in the Persian Gulf and the Gulf of Oman. Environmental Science and Pollution Research 21, 23862395. doi: 10.1007/s11356-013-1890-8CrossRefGoogle ScholarPubMed
Aprahamian, MW (1985) The effect of the migration of Alosa fallax fallax (Laécpède) into freshwater, on branchial and gut parasites. Journal of Fish Biology 27, 521532.CrossRefGoogle Scholar
Baruš, V, Jarkovský, J and Prokeš, M (2007) Philometra ovata (Nematoda: Philometroidea): a potential sentinel species of heavy metal accumulation. Parasitology Research 100, 929933. doi: 10.1007/s00436-006-0384-8CrossRefGoogle ScholarPubMed
Beeby, A (2001) What do sentinels stand for? Environmental Pollution 112, 285298.CrossRefGoogle Scholar
Brázová, T, Hanzelová, V, Miklisová, D, Šalamún, P and Vidal-Martínez, VM (2015) Host–parasite relationships as determinants of heavy metal concentrations in perch (Perca fluviatilis) and its intestinal parasite infection. Ecotoxicology and Environmental Safety 122, 551556. doi: 10.1016/j.ecoenv.2015.09.032CrossRefGoogle ScholarPubMed
Buchmann, K and Bresciani, J (2006) Monogenea (Phylum Platyhelminthes). In Woo, PTK (ed.), Fish Diseases and Disorders, Vol. 1., Protozoan and Metazoan Infections. Wallingford: CABI Publishing, pp. 297344.CrossRefGoogle Scholar
Bush, AO, Lafferty, KD, Lotz, JM and Shostak, AW (1997) Parasitology meets ecology on its own terms: Margolis et al. revisited. Journal of Parasitology 83, 575583.CrossRefGoogle Scholar
Dural, M, Genc, E, Yemenicioǧlu, S and Kemal Sangun, M (2010) Accumulation of some heavy metals seasonally in Hysterothylacium aduncum (Nematoda) and its host Red Sea Bream, Pagellus erythrinus (Sparidae) from Gulf of Iskenderun (North-eastern Mediterranean). Bulletin of Environmental Contamination and Toxicology 84, 125131.CrossRefGoogle Scholar
Dural, M, Genc, E, Sangun, MK and Güner, Ö (2011) Accumulation of some heavy metals in Hysterothylacium aduncum (Nematoda) and its host sea bream, Sparus aurata (Sparidae) from North-eastern Mediterranean Sea (Iskenderun Bay). Environmental Monitoring and Assessment 174, 147155.CrossRefGoogle Scholar
Eryilmaz, LS (2001) A study on the bony fishes caught in the South of the sea of Marmara by bottom trawling and their morphologies. Turkish Journal of Zoology 25, 323342.Google Scholar
Filipović Marijić, V, Vardić Smrzlić, I and Raspor, B (2013) Effect of acanthocephalan infection on metal, total protein and metallothionein concentrations in European chub from a Sava River section with low metal contamination. Science of the Total Environment 463–464, 772780.CrossRefGoogle ScholarPubMed
Filipović Marijić, V, Vardić Smrzlić, I and Raspor, B (2014) Does fish reproduction and metabolic activity influence metal levels in fish intestinal parasites, acanthocephalans, during fish spawning and post-spawning period? Chemosphere 112, 449455.CrossRefGoogle ScholarPubMed
Gaevskaya, AV and Kornyychuk, YM (2003) Parasitic organisms as a component of ecosystems of the Black Sea near-shore zone of Crimea. In Eremeev, VN and Gaevskaya, AV (eds), Modern Condition of Biological Diversity in Near-Shore Zone of Crimea (the Black sea sector). Sevastopol: NAS Ukraine, Institute of Biology of the Southern Seas, pp. 425490.Google Scholar
Gérard, C, Hervé, M, Réveillac, E and Acou, A (2016) Spatial distribution and impact of the gill-parasitic Mazocraes alosae (Monogenea Polyopisthocotylea) on Alosa alosa and A. fallax (Actinopterygii, Clupeidae). Hydrobiologia 763, 371379.CrossRefGoogle Scholar
Golemansky, V, Beron, P, Popov, A, Popov, V, Beshkov, V, Zhivkov, M, Spasov, N, Michev, T, Delchev, H, Stoev, P and Dobrev, D (2015) Red Data Book of the Republic of Bulgaria Volume 2 – Animals. Sofia: Bulgarian Academy of Sciences (BAS) and Ministry of Environment and Water (MEW).Google Scholar
Golestaninasab, M, Malek, M, Roohi, A, Karbassi, AR, Amoozadeh, E, Rashidinejad, R, Ghayoumi, R and Sures, B (2014) A survey on bioconcentration capacities of some marine parasitic and free-living organisms in the Gulf of Oman. Ecological Indicators 37, 99104. doi: 10.1016/j.ecolind.2013.09.039CrossRefGoogle Scholar
Gupta, SK and Singh, J (2011) Evaluation of mollusc as sensitive indicator of heavy metal pollution in aquatic system: a review. IIOAB Journal 2, 4957.Google Scholar
Hoestlandt, H (1991) The Freshwater Fishes of Europe – Vol. 2: Clupeidae, Anguillidae. Wiesbaden: AULA-Verlag, pp. 337368.Google Scholar
ICPDR (2016) TransNational Monitoring Network Databese (TNMN). Available at http://www.icpdr.org/wq-db/ (Accessed 15 Februar 2016).Google Scholar
Koie, M (1993) Aspects of the life cycle and morphology of Hysterothylacium aduncum (Rudolphi, 1802) (Nematoda, Ascaridoidea, Anisakidae). Canadian Journal of Zoology 71, 12891296. doi: 10.1139/z93-178CrossRefGoogle Scholar
Kültz, D (2011) Osmosensing. In Farrell, AP (ed.), Encyclopedia of Fish Physiology: From Genome to Environment, Vol. 2. San Diego: Academic Press, pp. 13731380.CrossRefGoogle Scholar
Lotfy, WM, Ezz, AM and Hassan, AAM (2013) Bioaccumulation of some heavy metals in the liver flukes Fasciola hepatica and F. gigantica. Iranian Journal of Parasitology 8, 552558.Google ScholarPubMed
Mazhar, R, Shazili, NA and Harrison, FS (2014) Comparative study of the metal accumulation in Hysterothalycium reliquens (nematode) and Paraphilometroides nemipteri (nematode) as compared with their doubly infected host, Nemipterus peronii (Notched threadfin bream). Parasitology Research 113, 37373743. doi: 10.1007/s00436-014-4039-xCrossRefGoogle Scholar
Merian, E (2004) Elements and Their Compounds in the Environment: Occurrence, Analysis and Biological Relevance. Weinheim: Wiley-VCH Verlag GmbH & Co. KGaA.CrossRefGoogle Scholar
Nachev, M and Sures, B (2016) Environmental parasitology: parasites as accumulation bioindicators in the marine environment. Journal of Sea Research 113, 4550. doi: 10.1016/j.seares.2015.06.005CrossRefGoogle Scholar
Nachev, M, Schertzinger, G and Sures, B (2013) Comparison of the metal accumulation capacity between the acanthocephalan Pomphorhynchus laevis and larval nematodes of the genus Eustrongylides sp. infecting barbel (Barbus barbus). Parasites & Vectors 6, 21. doi: 10.1186/1756-3305-6-21CrossRefGoogle Scholar
Nash, RDM, Valencia, AH and Geffen, AJ (2006) The origin of Fulton's condition factor – setting the record straight. Fisheries 31, 236238.Google Scholar
Nizova, GA and Syrovatka, NI (2000) Helminthes of commercial fishes of Azov Sea basin, their epizootological and epidemiological importance. In AzNIIRKH, (ed.), Main Problems of Fishery in Black Sea and Azov Sea Basins. Collection of research papers of AzNIIRKH (1998–1999). Rostov-on-Don: AzNIIRKH Publ., pp. 176183.Google Scholar
Özer, A, Öztürk, T and Kornyychuk, Y (2013) First report of Mazocraes alosae (Herman, 1782), Pronoprymna ventricosa (Rudolphi, 1891) and Lecithaster confusus Odhner, 1905 in Pontic shad Alosa immaculata Bennet, 1835 near Turkish coasts of the Black sea. Lucrări Ştiinţifice-Seria Zootehnie 59, 311314.Google Scholar
Pérez-del-Olmo, A, Nachev, M, Zimmermann, S, Fernández, M and Sures, B (2019) Medium-term dynamics of element concentrations in a sparid fish and its isopod parasite after the Prestige oil-spill: shifting baselines? Science of the Total Environment 686, 648656.CrossRefGoogle Scholar
Phillips, DJH (1977) The use of biological indicator organisms to monitor trace metal pollution in marine and estuarine environments-a review. Environmental Pollution (1970) 13, 281317.CrossRefGoogle Scholar
Popjuk, MP (2009) Helminth fauna of pelagic fishes off Crimea (The Black Sea). Ecologia Morya 78, 7580.Google Scholar
Popjuk, MP (2011) Parasite fauna of three species of mass pelagic fish during migration through the Kerch Strait. Ecologia Morya 18, 7380.Google Scholar
Qian, G and Pin, N (2000) Lead content in the monogenean, Ancyrocephalus mogurndae and in different organs of its host, the mandarin fish, Siniperca chuatsi. China Environmental Science 20, 233236.Google Scholar
Schludermann, C, Konecny, R, Laimgruber, S, Lewis, JW, Schiemer, F, Chovanec, A and Sures, B (2003) Fish macroparasites as indicators of heavy metal pollution in river sites in Austria. Parasitology 126, 6169. doi: 10.1017/S0031182003003743CrossRefGoogle ScholarPubMed
Sures, B (2003) Accumulation of heavy metals by intestinal helminths in fish: an overview and perspective. Parasitology 126, 5360. doi: 10.1017/S003118200300372XCrossRefGoogle ScholarPubMed
Sures, B and Siddall, R (1999) Pomphorhynchus laevis: the intestinal acanthocephalan as a lead sink for its fish host, chub (Leuciscus cephalus). Experimental Parasitology 93, 6672. doi: 10.1006/expr.1999.4437CrossRefGoogle Scholar
Sures, B, Taraschewski, H and Jackwerth, E (1994 a) Comparative study of lead accumulation in different organs of perch (Perca fluviatilis) and its intestinal parasite Acanthocephalus lucii. Bulletin of Environmental Contamination and Toxicology 52, 269273.CrossRefGoogle ScholarPubMed
Sures, B, Taraschewski, H and Jackwerth, E (1994 b) Lead accumulation in Pomphorhynchus laevis and its host. Journal of Parasitology 80, 355357.CrossRefGoogle ScholarPubMed
Sures, B, Jürges, G and Taraschewski, H (1998) Relative concentrations of heavy metels in the parasites Ascaris suum (Nematoda) and Fasciola hepatica (Digenea) and their respective porcine and bovine definitive hosts. International Journal for Parasitology 28, 11731178.CrossRefGoogle ScholarPubMed
Sures, B, Steiner, W, Rydlo, M and Taraschewski, H (1999 a) Concentrations of 17 elements in the zebra mussel (Dreissena polymorpha), in different tissues of perch (Perca fluviatilis), and in perch intestinal parasites (Acanthocephalus lucii) from the subalpine Lake Mondsee, Austria. Environmental Toxicology and Chemistry 18, 25742579.CrossRefGoogle Scholar
Sures, B, Siddall, R and Taraschewski, H (1999 b) Parasites as accumulation indicators of heavy metal pollution. Parasitology Today 15, 1621.CrossRefGoogle ScholarPubMed
Sures, B, Nachev, M, Selbach, C and Marcogliese, DJ (2017) Parasite responses to pollution: what we know and where we go in ‘Environmental Parasitology’. Parasites and Vectors 10, 119.CrossRefGoogle ScholarPubMed
Tellez, M and Merchant, M (2015) Biomonitoring heavy metal pollution using an aquatic apex predator, the American Alligator, and its Parasites. PLoS One 10, e0142522. doi: 10.1371/journal.pone.0142522CrossRefGoogle ScholarPubMed
Tenora, F, Baruš, V, Kráčmar, S and Dvořáček, J (2000) Concentrations of some heavy metals in Ligula intestinalis plerocercoids (Cestoda) and Philometra ovata (Nematoda) compared to some their hosts (Osteichthyes). Helminthologia 37, 1518.Google Scholar
Torres, J, Kacem, H, Eira, C, Neifar, L and Miquel, J (2014) Total mercury and selenium concentrations in Sarpa salpa and Balistes capriscus and in their respective Digenean endoparasites Robphildollfusium fractum and Neoapocreadium chabaudi from Tunisia. Acta Parasitologica 59, 580585. doi: 10.2478/s11686-014-0293-4CrossRefGoogle ScholarPubMed
Visnjic-Jeftic, Z, Jaric, I, Jovanovic, L, Skoric, S, Smederevac-Lalic, M, Nikcevic, M and Lenhardt, M (2010) Heavy metal and trace element accumulation in muscle, liver and gills of the Pontic shad (Alosa immaculata Bennet 1835) from the Danube River (Serbia). Microchemical Journal 95, 341344. doi: 10.1016/j.microc.2010.02.004CrossRefGoogle Scholar
Figure 0

Table 1. Concentrations (μg/L) of selected elements in the river Daube at 834 km according to ICPDR (2016)

Figure 1

Table 2. Morphological data of Pontic shad

Figure 2

Table 3. Prevalence and intensity of infection of Pontic shad with the monogenean Mazocraes alosae and the nematode Hysterothylacium aduncum

Figure 3

Fig. 1. (A–C) Mean element concentrations (±s.d.) in the host–parasite system (n = 40). *Concentration below detection limit.

Figure 4

Table 4. Element concentrations in standard reference materials as well as accuracy and detection limits (DL) determined by ICP-MS analyses

Figure 5

Table 5. Mean (±s.d.) bioconcentration factors for metal accumulation in parasites compared to different host tissues

Figure 6

Table 6. Differences between element concentrations in fish organs and parasites, and between M. alosae and H. aduncuum