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Feeding habits of three Batoids in the Levantine Sea (north-eastern Mediterranean Sea) based on stomach content and isotopic data

Published online by Cambridge University Press:  26 May 2017

Emre Yemışken*
Affiliation:
Department of Biology, Section of Hydrobiology, Faculty of Science, Istanbul University, Turkey
Manuela G. Forero
Affiliation:
Department of Conservation Biology, Estación Biológica de Doñana (EBD-CSIC), Avda. Américo Vespucio s/n, Sevilla 41092, Spain
Persefoni Megalofonou
Affiliation:
Department of Biology, Section of Zoology Marine Biology, National and Kapodıstrıan University of Athens, Greece
Lütfıye Eryilmaz
Affiliation:
Department of Biology, Section of Hydrobiology, Faculty of Science, Istanbul University, Turkey
Joan Navarro
Affiliation:
Department of Conservation Biology, Estación Biológica de Doñana (EBD-CSIC), Avda. Américo Vespucio s/n, Sevilla 41092, Spain
*
Correspondence should be addressed to: E. Yemişken, Department of Biology, Section of Hydrobiology, Faculty of Science, Istanbul University, Turkey email: [email protected]
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Abstract

Understanding the diet of marine predators is essential to defining their trophic role in an ecosystem. Elasmobranchs (sharks and batoids) are considered pivotal components of marine food webs, and are often included in the top predator or mesopredator groups. However, in comparison with other Mediterranean areas, research focusing on marine predators inhabiting the Levantine Sea (eastern Mediterranean Sea) is very limited. Here, we examined the feeding habits (diet, trophic width and trophic position) of three endangered batoids (Gymnura altavela (Linnaeus, 1758), Raja asterias Delaroche, 1809 and Raja clavata, Linnaeus, 1758) coexisting in Iskenderun Bay (north-eastern Levantine Sea, Mediterranean Basin) by combining stomach content and stable isotope analyses. The results revealed clear differences in the trophic habits between them. Stomach contents showed differences in the diet between species, showing a clear feeding preference for teleosts in the case of G. altavela and a diet composed of fish and crustaceans in the case of R. asterias and R. clavata. In line with stomach content results, interspecific differences in the isotopic values and trophic levels were found. In particular, G. altavela was isotopically segregated from R. asterias and R. clavata, showing lower isotopic trophic width and higher trophic level. The results of this study provide new insights into the ecological role of these three endangered batoid species in the Levantine Sea and are of crucial importance for management and conservation of these species.

Type
Research Article
Copyright
Copyright © Marine Biological Association of the United Kingdom 2017 

INTRODUCTION

Understanding the trophic ecology of a particular species is essential to determining its ecological role in marine ecosystems (Coll et al., Reference Coll, Navarro and Palomera2013; Ferretti et al., Reference Ferretti, Osio, Jenkins, Rosenberg and Lotze2013). Sharks and batoids are considered important components of marine food webs, often included in the top predator or mesopredator groups, although there are important differences in the diets among species (Cortés, Reference Cortés1999; Young et al., Reference Young, Olson, Ménard, Kuhnert, Duffy, Allain, Logan, Lorrain, Somes, Graham, Goñi, Pethybridge, Simier, Potier, Romanov, Pagendam, Hannides and Choy2015). In fact, the high diversity of feeding strategies makes the ecology of this entire marine group particularly complex to understand (Cortés, Reference Cortés1999). For this reason, the trophic role of these species is often unclear. To unravel this limitation, more trophic studies are essential, as they can help inform conservation strategies for threatened species (Ferretti et al., Reference Ferretti, Osio, Jenkins, Rosenberg and Lotze2013).

The Mediterranean Sea is considered a global hotspot of elasmobranch diversity, hosting ~7% of all elasmobranchs worldwide (Cavanagh et al., Reference Cavanagh and Gibson2007; Dulvy et al., Reference Dulvy, Fowler, Musick, Cavanagh, Kyne, Harrison, Carlson, Davidson, Fordham, Francis, Pollock, Simpfendorfer, Burgess, Carpenter, Compagno, Ebert, Gibson, Heupel, Livingstone, Sanciangco, Stevens, Valenti and White2014). However, most of the batoids and shark species in the Mediterranean Sea have declined in abundance and distribution, mainly due to human impacts (Ferretti et al., Reference Ferretti, Worm, Britten, Heithaus and Lotze2010; Coll et al., Reference Coll, Navarro and Palomera2013). In fact, around 40% of the elasmobranchs are considered threatened in the Mediterranean Sea by regional assessments of the International Union for Conservation of Nature (IUCN) (Abdul Malak et al., Reference Abdul Malak, Livingstone, Pollard, Polidoro, Cuttelod, Bariche, Bilecenoglu, Carpenter, Collette, Francour, Goren, Kara, Enric, Papaconstantinou and Tunesi2011; Bradai et al., Reference Bradai, Saidi and Enajjar2012).

In comparison with other Mediterranean areas, research focusing on elasmobranchs inhabiting the Levantine Sea (eastern Mediterranean Sea) is very limited (Cavanagh et al., Reference Cavanagh and Gibson2007), even though these waters host endemic, threatened and rare elasmobranchs. This is the case of the threatened batoids Gymnura altavela (spiny butterfly ray), with a vulnerable status, and the Mediterranean endemic Raja asterias (Mediterranean starry ray) and Raja clavata (thornback ray), both with a near threatened status based on the IUCN Red List (Vooren et al., Reference Vooren, Piercy, Snelson, Grubbs, Notarbartolo di Sciara and Serena2007; Serena et al., Reference Serena, Abella, Walls and Dulvy2015; Ellis et al., Reference Ellis, Dulvy and Serena2016). In the Levantine Sea, these three batoid fishes are highly impacted by the demersal fisheries operating in coastal and deep-sea waters (Dalyan, Reference Dalyan2012; Yeldan et al., Reference Yeldan, Avşar, Mavruk and Manaşırlı2013; Yemisken et al., Reference Yemisken, Dalyan and Eryilmaz2014).

Regarding their trophic habits, previous studies based on stomach contents conducted in the western and central Mediterranean Sea indicated that these three batoids act as mesopredators in the ecosystem, exploiting a wide variety of resources including crustaceans, demersal fish and cephalopods (Cuoco et al., Reference Cuoco, Mancusi and Serena2005; Romanelli et al., Reference Romanelli, Colasante, Scacco, Consalvo, Finoia and Vacchi2007; Valls et al., Reference Valls, Quetglas, Ordines and Moranta2011; Santic et al., Reference Santic, Rada and Pallaoro2012; Navarro et al., Reference Navarro, Coll, Preminger and Palomera2013). Although stomach content methodology permits a high level of taxonomic resolution in the identification of prey, batoids and sharks show a high frequency of empty stomachs. Moreover, the prey species that are often found in the stomachs are those of slower digestion rates, which could cause biases in the diet estimation (Hyslop, Reference Hyslop1980). In addition, this conventional method requires a large number of stomachs to quantify diet. This can be difficult to obtain, especially for endangered species. The use of stable isotopes of nitrogen (δ15N) and carbon (δ13C) has been used as a complement to stomach content analysis to study the trophic ecology of elasmobranch species (e.g. Shiffman et al., Reference Shiffman, Gallagher, Boyle, Hammerschlag-Peyer and Hammerschlag2012). This approach is based on the fact that δ15N and δ13C values are transformed from dietary sources to consumers in a predictable manner (Shiffman et al., Reference Shiffman, Gallagher, Boyle, Hammerschlag-Peyer and Hammerschlag2012). δ15N values show a predictable increase from one trophic level to the next (Jennings et al., Reference Jennings, Reñones, Morales-Nin, Polunin, Moranta and Coll1997; Layman et al., Reference Layman, Araujo, Boucek, Hammerschlag-Peyer, Harrison, Jud, Matich, Rosenblatt, Vaudo, Yeager, Post and Bearhop2012). δ13C values show little change due to trophic transfer, but are useful indicators of dietary sources of carbon (Layman et al., Reference Layman, Araujo, Boucek, Hammerschlag-Peyer, Harrison, Jud, Matich, Rosenblatt, Vaudo, Yeager, Post and Bearhop2012).

In this study, we investigated the feeding ecology (diet, trophic width and trophic position) of three batoids (G. altavela, R. asterias and R. clavata) coexisting in Iskenderun Bay (north-eastern Levantine Sea, Mediterranean Basin) by combining stomach contents and stable isotope analyses. Our study provides new insights into the ecological role of these three endangered batoid species in the Levantine Sea.

MATERIALS AND METHODS

Study area and sampling procedure

The north-east Levantine Sea (Figure 1) has a wide continental shelf and shows high marine productivity influenced by local wind effects, upwelling movements and rich terrestrial nutrient inputs from the Asi River (Polat & Piner, Reference Polat and Piner2002). The area includes a high richness of marine species within the eastern Mediterranean Sea (Bilecenoğlu, Reference Bilecenoğlu2016). The oceanographic conditions, such as the environmental conditions similar to tropical and sub-tropical regions, has promoted the colonization by invasive species from the Red Sea (Bilecenoğlu, Reference Bilecenoğlu2016).

Fig. 1. Study area (North-eastern Levantine Sea, eastern Mediterranean Sea), indicating the sampling locations (black points).

A total of 13 G. altavela, 46 R. asterias and 26 R. clavata individuals were collected between September 2014 and April 2016 at a depth ranging from 33 to 450 m, by commercial trawl vessels in the Iskenderun Bay (Figure 1). All individuals were accidentally captured as by-catch of the fishing fleet. Individuals were taken to the lab in a freezer where body size (disc width length; DW, to the nearest mm) and weight (nearest g) were recorded.

Stomach content analysis

All prey items presented in the stomachs were identified at the lowest taxonomic levels (copepods, decapods, cephalopods and teleosts). Per cent of number (%N), weight (%W) and frequency of occurrence (%F) of prey items were calculated and these values were utilized for calculating the Index of Relative Importance (IRI) of each prey item (IRI = %F(%N + %W)). The IRI was standardized using the formula: %IRI = (IRI/ΣIRI) × 100 (Cortés, Reference Cortés1997). The vacuity index (v; the percentage of empty stomachs) and the percentage of fullness of stomachs (Fullness %) were also calculated. Levin's and Pianka's measures were used to determine niche breadth (Bi) with the standardized niche breath (BA), and niche overlap between the three batoid fishes (Colwell & Futuyma, Reference Colwell and Futuyma1971). Prey-specific abundance was calculated according to the following: P i  = (ΣS i S t) × 100, where P i is the prey-specific abundance of prey i, S i is the stomach contents (number) including prey i, and S t is the total stomach contents among those individuals with prey in their stomach (Amundsen et al., Reference Amundsen, Gabler and Staldvik1996).

Stable isotope analysis

We obtained a muscle sample from the pectoral fin of seven spiny butterfly rays, seven Mediterranean starry rays and nine thornback skates. Before stable isotope analysis, we extracted lipid from muscle samples using a chloroform-methanol solution (Kim & Koch, Reference Kim and Koch2011). Samples were subsequently freeze-dried and powdered and 0.28–0.4 mg of each sample was packed into tin capsules. Isotopic analyses were performed at the Stable Isotopes Laboratory at the Estación Biológica de Doñana CSIC (Seville, Spain). Samples were combusted at 1020°C using a continuous flow isotope ratio mass spectrometry system (Thermo Electron) by means of a Flash HT Plus elemental analyser coupled to a Delta-V Advantage isotope ratio mass spectrometer. Stable isotope ratios were expressed in the standard δ-notation (‰) relative to Vienna Pee Dee Belemnite (δ13C) and atmospheric N215N). Based on laboratory standards, the measurement error was ±0.1 and ±0.3 for δ13C and δ15N, respectively (Cabana & Rasmussen, Reference Cabana and Rasmussen1996).

As a measure of trophic width, for each species a Bayesian isotopic ellipse area (SEA) was calculated from the stable isotope values (Jackson et al., Reference Jackson, Inger, Parnell and Bearhop2011). This metric represents a measure of the total amount of the isotopic niche exploited by a particular predator and is thus a proxy for the extent of trophic diversity (or trophic width) exploited by the species (high values of isotopic standard ellipse areas indicate high trophic width). This metric uses multivariate ellipse-based Bayesian metrics. Bayesian inference techniques allow for robust statistical comparisons between datasets with different sample sizes. Isotopic standard ellipse areas were calculated using the routine Stable Isotope Bayesian Ellipses incorporated in the SIAR library (SIBER, Jackson et al., Reference Jackson, Inger, Parnell and Bearhop2011).

Trophic position

The trophic position (TP) of each species was estimated by using isotopic values (TPSIA) and stomach content analysis (TPstomach). TPSIA was performed according to Zanden & Rasmussen (Reference Zanden and Rasmussen2001):

$$\hbox{TP}_{{\rm consumer}} = \hbox{TP}_{{\rm basal}} + ({\rm \delta}^{15} \hbox{N}_{{\rm consumer}} -{\rm \delta} ^{15} \hbox{N}_{{\rm basal}} )/\Delta {\rm \delta} ^{15} \hbox{N},$$

where δ15 N consumer is the value for each batoid species and δ15 N basal is that of the crab, Monodaeus couchii (7.1‰) sampled from the north-eastern Levantine Sea. We used 1.95 for Δ15 N values (Hussey et al., Reference Hussey, Brush, McCarthy and Fisk2010), defined as the trophic enrichment factor between organism and diet.

TPstomach was calculated using the following equation: TL j  = 1 + Σn j –1 IRI% * TP i , where j is the predator of prey i, IRI% is the fraction of prey i in the diet of predator j, and TL i is the trophic position of prey i (Cortés, Reference Cortés1999). Trophic positions of prey categories were based on Ebert & Bizzarro (Reference Ebert and Bizzarro2007).

Statistical analysis of stomach content data

Data analysis was performed with multivariate techniques (PERMANOVA). The diets of the three batoid species were analysed using the Bray–Curtis resemblance matrix of log(x + 1) transformed, with prey abundance data. The comparison similarities of prey groups among the three batoids were determined by SIMPER and appeared as vector overlay on the principal coordinates analysis (PCO) plot by PRIMER v6 (Clarke & Warwick, Reference Clarke and Warwick2001). One-way analysis of covariance (ANCOVA) was used to reveal relationships between body size and the fullness index in stomach contents with SPSS 21 software.

RESULTS

Stomach content analysis

A total of 85 individual stomachs were analysed belonging to three batoids. We found that 71 of these individuals had food in their stomachs (coefficient of vacuity: 32% for R. asterias, 15% for R. clavata and 31% for G. altavela). We identified 15 different prey species belonging to three different taxonomic groups (Table 1). The minimum average of percentage of fullness was estimated at 14% for the spiny butterfly ray and 43% for the thornback skate and Mediterranean starry ray. There were no significant differences between the fullness index and body size in any of the three batoids (P > 0.05).

Table 1. Diet composition of Gymnura altavela, Raja asterias and Raja clavata in the Iskenderun Bay (DW, disc width; TL, trophic level estimated from stomach contents; N, number of stomach; %FO, frequency of occurrence; %N, percentage in number; %W, percentage in mass; %IRI, index of relative importance of prey).

Although teleosts were the main prey group for all three batoids, we found significant differences in the diet composition (PERMANOVA tests, Pseudo-F 2,20 = 28.01; P < 0.001). In particular, pairwise tests indicated that stomach contents differed between G. altavela and both R. asterias and R. clavata. The PCO analysis showed that the horizontal axes explain separation with 57.7% total variation because of the contribution of cephalopods and decapods to the diet of the batoids. The vertical axes explained separation with 29.8% total variation in accordance with the contribution of the teleost species to the diets (Figure 2). While the teleost group was common in all batoids, the main differences among the batoid species were found in decapod and cephalopod groups.

Fig. 2. Principal coordinates analysis of stomach contents from G. altavela, R. asterias and R. clavata from the north-eastern Levantine Sea (Mediterranean Sea).

Champsodon sp. was a common prey fish species in the stomach of G. altavela and R. clavata, whereas Equulites klunzingeri (IRI = 21.13%) was only found in the stomach of G. altavela (Table 2). In addition, Chlorophthalmus agassizi was found in the stomachs of both R. asterias and R. clavata. Argentina sphyraena (IRI = 0.2%), Bregmaceros atlaticus (IRI = 0.4%) and Trachurus sp. (IRI = 0.5%) were identified only in the stomach contents of R. asterias. Decapoda was the second main prey group for R. asterias and R. clavata (IRI = 18.68% and IRI = 44.40%, respectively). Copepods were only found in the stomach of R. asterias (IRI = 1.7%). Although it was somewhat common to find cephalopods in the batoid stomachs, they were not represented in a high percentage of the stomach contents (IRI % between 2.15 and 10.64).

Table 2. Sample size (N) and mean and standard deviation of isotopic values and trophic level estimated with δ15N values (TLSIA) of three batoids in the Iskenderun Bay (north-eastern Mediterranean Sea).

Regarding the niche width, G. altavela showed lower values (B i : 1.1, BA: 0.1), followed by R. asterias (B i : 3.32, BA: 0.8) and R. clavata (B i : 3.25, BA: 0.8). Diet overlap was lowest between G. altavela and R. clavata (0.46), and highest between R. asterias and R. clavata (0.98). The relationship between prey specific abundance and prey occurrence confirms a specialist feeding strategy on teleosts for G. altavela (Figure 3). In contrast, R. asterias and R. clavata displayed generalist feeding strategies.

Fig. 3. Graphical representation of the feeding strategy of G. altavela (A), R. asterias (B) and R. clavata (C) from the north-eastern Levantine Sea (Mediterranean Sea): prey-specific abundance (Pi %) plotted against mean frequency of occurrence (%FO) of the different prey groups.

Stable isotope results

Combined values of stable nitrogen and carbon differed among batoid species (δ15N, F 2,21 = 73.22, P < 0.001; δ13C, F 2,21 = 24.38, P < 0.001). Specifically, R. asterias and R. clavata did not differ in their stable nitrogen and carbon values (Tukey post hoc tests, all P > 0.05; Table 2, Figure 4) but showed lower values of stable isotopes than G. altavela (post hoc test, P < 0.05; Table 3, Figure 4). The isotopic niche width based on the Standard Ellipse Area (SEA) clearly differed between batoid species (Figure 4), with the highest values for the thornback skate (SEA = 0.91‰), followed by G. altavela (SEA = 0.91‰) and R. asterias (SEA = 0.41‰) (Figure 4).

Fig. 4. Mean and standard deviation of δ13C, δ15N and trophic level values of G. altavela, R. asterias and R. clavata from the north-eastern Levantine Sea (Mediterranean Sea). The Bayesian standard ellipse areas are also indicated.

Table 3. Main prey groups in the diet of Gymnura altavela, Raja asterias and Raja clavata from the Mediterranean Sea. NW, north-western; SC, south-central; C, central; W, western; SE, south-east.

Trophic level

The trophic position estimated from stomach contents (TPstomach) varied between 3.88 and 4.24 among the three batoids, with G. altavela having a higher value than R. asterias and R. clavata, which occupied a very similar trophic position. When we estimated the trophic level from nitrogen isotope values, we found that absolute values differed from those estimated by stomach contents, but the relative position of the three studied species remained similar (Table 2).

DISCUSSION

In this study, the trophic ecology of three batoids (G. altavela, R. asterias and R. clavata) inhabiting the Levantine Sea (East Mediterranean Sea) was studied by combining stomach contents and isotope analyses. Stomach content results provide a snapshot of the diet of each species, and isotopic values identify the trophic width and trophic level integrating a long-term view (Peterson & Fry, Reference Peterson and Fry1987; Kim & Koch, Reference Kim and Koch2011; Navarro et al., Reference Navarro, López, Coll, Barría and Sáez-Liante2014). Based on the results of both stomach contents and stable isotopes, we found clear differences in the trophic habits among these three demersal predators.

Stomach contents revealed that the diet of G. altavela was mainly composed of fish prey, a result that agrees with the very few studies conducted previously in this species in Mediterranean waters (Table 3; Neifar et al., Reference Neifar, Euzet and Ben Hassine2002; Psomadakis et al., Reference Psomadakis, Dalù, Scacco and Vacchi2008; Barría et al., Reference Barría, Coll and Navarro2015). This indicates that this species is a predator with clear preferences for fish. Although R. asterias and R. clavata also included fish in their diet, crustaceans were important prey as well for these species, contributing to the diet in the same proportion as fish. These results contrast with those from other locations in the Mediterranean, where the diet of these two rajidae species were composed mainly by crustaceans (Kabasakal, Reference Kabasakal2001; Vannucci et al., Reference Vannucci, Mancusi, Serena, Cuoco and Volani2006; Valls et al., Reference Valls, Quetglas, Ordines and Moranta2011; Navarro et al., Reference Navarro, Coll, Preminger and Palomera2013; Eronat & Özaydın, Reference Eronat and Özaydın2015; Fatimetou & Younes, Reference Fatimetou and Younes2016). For example, Navarro et al. (Reference Navarro, Coll, Preminger and Palomera2013) found that crabs were the dominant prey for R. asterias in the western Mediterranean Sea. In the Ligurian Sea and Tyrrhenian Sea, similar results were found with R. asterias. Goneplax rhomboides and Liocarcinus sp. were reported mostly in stomach content of R. asterias from shallow water (Cuoco et al., Reference Cuoco, Mancusi and Serena2005; Romanelli et al., Reference Romanelli, Colasante, Scacco, Consalvo, Finoia and Vacchi2007). Yeldan (Reference Yeldan2005) showed that crustacean species were the main prey in the diet of R. asterias along the east coast of the Iskenderun Bay (North Levantine Sea). The current study differs from Yeldan (Reference Yeldan2005) in its sampling area. Yeldan (Reference Yeldan2005) sampled the individuals in coastal waters, where the availability of crustaceans is high. Our samples of Raja spp. were captured mostly from deeper waters. Discrepancies in the diet of R. clavata between our study and those carried out previously are probably due to geographic and depth differences reported for this batoid (Kabasakal, Reference Kabasakal2001; Vannucci, Reference Vannucci, Mancusi, Serena, Cuoco and Volani2006; Valls et al., Reference Valls, Quetglas, Ordines and Moranta2011; Eronat & Özaydın, Reference Eronat and Özaydın2015). For instance, Eronat & Özaydın (Reference Eronat and Özaydın2015) indicated the dominant occurrence of crustaceans in the diet of R. clavata between 120 and 350 m in the Aegean Sea, while Valls et al. (Reference Valls, Quetglas, Ordines and Moranta2011) showed that the contribution of teleosts was much more relevant for this species in deeper waters. In our study, the relative contribution of crustaceans and teleosts was nearly the same.

The existence of interspecific differences in teeth morphology could explain differences in the diet (McEachran & Capapé, Reference McEachran, Capapé, Whitehead, Bauchot, Hureau, Nielsen and Tortonese1984; Jacobsen & Bennett, Reference Jacobsen and Bennett2013). The presence of crushing teeth plates in the two Raja spp. probably confers a greater capacity to crush the carapace of crustaceans, whereas the cuspidate teeth of G. altavela facilitate the capture of fish (Vannucci et al., Reference Vannucci, Mancusi, Serena, Cuoco and Volani2006; Motta & Huber, Reference Motta, Huber, Carrier, Musick and Heithaus2012; Ellis et al., Reference Ellis, Dulvy and Serena2016). Based on the principle of competitive exclusion, we expect that competing predators coexisting in the same waters segregate their exploitation of trophic resources (e.g. Papastamatiou et al., Reference Papastamatiou, Wetherbee, Lowe and Crow2006; Follesa et al., Reference Follesa, Mulas, Cabiddu, Porcu, Deiana and Cau2010; Albo-Puigserver et al., Reference Albo-Puigserver, Navarro, Coll, Aguzzi, Cardona and Sáez-Liante2015). For this reason, the three batoids partially segregate their main trophic resources as a mechanism that allows coexistence in the demersal habitat.

As expected from the stomach content results, interspecific differences in the isotopic values and trophic levels were found. In particular, G. altavela was isotopically segregated from R. asterias and R. clavata, showing a lower isotopic trophic width and higher trophic level. The trophic width estimated from SEAs was larger for G. altavela and R. clavata in comparison to R. asterias. Distribution of R. clavata shows variety from shallow to deep water in the area. This could be a result of the more generalized feeding strategy of R. clavata. On the other hand, previous studies on the feeding ecology of R. asterias show its specialized feeding strategy on crustacean species (Barría et al., Reference Barría, Coll and Navarro2015). The diversity richness of the coastal area in which G. altavela is mainly distributed (Emre Yemisken, unpublished data) probably explains the high trophic width of this species. Based on the trophic position of the species, both methodologies (stomach contents and isotopic values) revealed that G. altavela was at a higher position than the other two species. This pattern was previously found within demersal food webs in the western Mediterranean Sea where G. altavela shows a higher trophic position than coexisting batoids (Valls et al., Reference Valls, Quetglas, Ordines and Moranta2011; Barría et al., Reference Barría, Coll and Navarro2015), probably related to its large body size.

Although we expected a similar estimation of trophic position using stable isotope analysis (SIA) and stomach contents, we found differences between the methods in both Rajidae species. The estimation of trophic level from stable isotopes was lower than from stomach contents. Differences between TPsia and TPstomach would be expected considering that the estimated trophic levels from isotopic data are vulnerable to the basic assumption of which basal sources are used (Olin et al., Reference Olin, Hussey, Grgicak-Mannion, Fritts, Wintner and Fisk2013). Discrepancies between the methodologies (TPsia and TPstomach) revealed the need for caution when values of trophic levels are compared (Albo-Puigserver et al., Reference Albo-Puigserver, Navarro, Coll, Aguzzi, Cardona and Sáez-Liante2015). However, differences observed in the trophic position between the two methods in this study might be explained by long-term and short-term prey preference differences of Rajidae species in the region. When resources are restricted in the ecosystem, sometimes species may adapt and change their feeding behaviour after a while in the area. Although stomach content results have shown teleost and shrimp preferences in feeding behaviour, prey availability may not be sustainable on the same prey.

In conclusion, this study presents new information regarding the feeding ecology of three endangered batoids (G. altavela, R. asterias and R. clavata) in the Levantine Sea. The results indicate differences in the diet between species, showing a clear feeding preference for teleosts in the case of G. altavela and a diet composed of fish and crustaceans in the case of R. asterias and R. clavata. These results can be used by managers to conduct an appropriate assessment and inform conservation strategies for these species.

ACKNOWLEDGEMENTS

We thank Suna Tüzün, Onur Gonual and Mert Kesiktas for their help during the sampling and laboratory process and special thanks to Susana Carrasco during the stable isotope analysis at Laboratory of Estación Biológica de Doñana CSIC (Seville, Spain).

FINANCIAL SUPPORT

This study was partially funded by Istanbul University (project no: 42822) and TUBITAK 2214A (PhD student international scholarships programme).

References

REFERENCES

Abdul Malak, D., Livingstone, S.R., Pollard, D., Polidoro, B.A., Cuttelod, A., Bariche, M., Bilecenoglu, M., Carpenter, K.E., Collette, B.B., Francour, P., Goren, M., Kara, M.H., Enric, M., Papaconstantinou, C. and Tunesi, L. (2011) Overview of the conservation status of the marine fishes of the Mediterranean Sea. Gland, Switzerland and Malaga, Spain: IUCN. vii + 61 pp.Google Scholar
Albo-Puigserver, M., Navarro, J., Coll, M., Aguzzi, J., Cardona, L. and Sáez-Liante, R. (2015) Feeding ecology and trophic position of three sympatric demersal chondrichthyans in the northwestern Mediterranean. Marine Ecology Progress Series 524, 255268.Google Scholar
Amundsen, P.A., Gabler, H.M. and Staldvik, F.J. (1996) A new approach to graphical analysis of feeding strategy from stomach contents data – modification of the Costello (1990) method. Journal of Fish Biology 48, 607614.Google Scholar
Azouz, A. and Capape, C. (1971) Les relations alimentaires entre les Sélaciens et le zoobenthos des côtes nord de la Tunisie. Le Bulletin de l'Institut National Scientifique et Technique d'Océanographie et de Pêche 2, 121130.Google Scholar
Barría, C., Coll, M. and Navarro, J. (2015) Unravelling the ecological role and trophic relationships of uncommon and threatened elasmobranchs in the western Mediterranean Sea. Marine Ecology Progress Series 539, 225240.Google Scholar
Bello, G. (1997) Cephalopods from the stomach contents of demersal chondrichthyans caught in the Adriatic Sea. Vie Milieu 47, 221227.Google Scholar
Bilecenoğlu, M. (2016) Demersal Lessepsian fish assemblage structure in the northern Levant and Aegean Seas. Journal of the Black Sea/Mediterranean Environment 22, 4659.Google Scholar
Bradai, M.N., Saidi, B. and Enajjar, S. (2012) Elasmobranchs of the Mediterranean and Black Sea. Status, ecology and biology: a bibliographic analysis. Food and Agriculture Organisation of the United Nations, Rome. General Fisheries Commission for the Mediterranean 91, 1116.Google Scholar
Cabana, G. and Rasmussen, J.B. (1996) Comparison of aquatic food chains using nitrogen isotopes. Ecology 93, 1084410847.Google Scholar
Capapé, C. (1975) Contribution a la biologie des Rajidae des cotes tunisiennes. 4. Raja clavata (Linne 1758): regime alimentaire. Annales de l'Institut Michel Pacha 8, 1632.Google Scholar
Capapé, C. and Quignard, J. (1977) Contribution à la biologie des Rajidae des cotes tunisiennes. 6. Raja asterias Delaroche, 1809. Régime alimentarie. Le Bulletin de l'Institut National Scientifique et Technique d'Océanographie et de Pêche Solammbò 4, 319332.Google Scholar
Cavanagh, R.D. and Gibson, C. (2007) Overview of the conservation status of cartilaginous fishes (Chondrichthyans) in the Mediterranean Sea. Gland, Switzerland and Malaga, Spain: IUCN. vi + 42 pp.Google Scholar
Clarke, K.R. and Warwick, R.M. (2001) Change in marine communities, an approach to statistical analysis and interpretation, 2nd edition. Plymouth: PRIMER-E.Google Scholar
Coll, M., Navarro, J. and Palomera, I. (2013) Ecological role, fishing impact, and management options for the recovery of a Mediterranean endemic skate by means of food web models. Biological Conservation 157, 108120.CrossRefGoogle Scholar
Colwell, R.K. and Futuyma, D.J. (1971) On the measurement of niche breadth and overlap. Ecology 52, 567576.CrossRefGoogle ScholarPubMed
Cortés, E. (1997) A critical review of methods of studying fish feeding based on analysis of stomach contents: application to elasmobranch fishes. Canadian Journal of Fisheries and Aquatic Sciences 54, 726738.CrossRefGoogle Scholar
Cortés, E. (1999) Standardized diet compositions and trophic levels of sharks. ICES Journal of Marine Science 56, 707717.CrossRefGoogle Scholar
Cuoco, C., Mancusi, C. and Serena, F. (2005) Studio sulle abitudini alimentari di Raja asterias Delaroche, 1809 (Chondrichthyes, Rajidae). Biologia Marina Mediterranea 12, 504508.Google Scholar
Dalyan, C. (2012) Levant denizi (Doğu Akdeniz) kuzeydoğusunun üst kıta yamacı balıklarının dağılımları. PhD thesis, Istanbul University. [In Turkish]Google Scholar
Dulvy, N.K., Fowler, S.L., Musick, J.A., Cavanagh, R.D., Kyne, P.M., Harrison, L.R., Carlson, J.K., Davidson, L.N.K., Fordham, S.V. Francis, M.P., Pollock, C.M., Simpfendorfer, C.A., Burgess, G.H., Carpenter, K.E., Compagno, L.J.V., Ebert, D.A., Gibson, C., Heupel, M.R., Livingstone, S.R., Sanciangco, J.C., Stevens, J.D., Valenti, S. and White, W.T. (2014) Extinction risk and conservation of the world's sharks and rays. eLife 3, 183.Google Scholar
Ebert, D.A. and Bizzarro, J.J. (2007) Standardized diet compositions and trophic positions of skates (Chondrichthyes: Rajiformes: Rajoidei). Environmental Biology of Fishes 80, 221237.Google Scholar
Ellis, J.R., Dulvy, N.K. and Serena, F. (2016) Malacoraja clavata. The IUCN red list of threatened species 2016: e.T39399A81164303. Downloaded on 28 October 2016.Google Scholar
Eronat, E.G.T. and Özaydın, O. (2015) Diet composition of the thornback ray, Raja clavata Linnaeus, 1758 (Elasmobranchii: Rajidae) in the Turkish Aegean Sea. Zoology in the Middle East 61, 3844.Google Scholar
Fatimetou, M.K. and Younes, S. (2016) Diet of Raja asterias (Delaroche, 1809) caught along the Mediterranean part of the Moroccan coast (Northern Morocco). Journal of the Black Sea/Mediterranean Environment 22, 182189.Google Scholar
Ferretti, F., Osio, G.C., Jenkins, C.J., Rosenberg, A.A. and Lotze, H.K. (2013) Long-term change in a meso-predator community in response to prolonged and heterogeneous human impact. Scientific Reports 3, 1057 pp.CrossRefGoogle Scholar
Ferretti, F., Worm, B., Britten, G.L., Heithaus, M.R. and Lotze, H.K. (2010) Patterns and ecosystem consequences of shark declines in the ocean. Ecology Letters 13, 10551071.Google Scholar
Follesa, M.C., Mulas, A., Cabiddu, S., Porcu, C., Deiana, A.M. and Cau, A. (2010) Diet and feeding habits of two skate species, Raja brachyura and Raja miraletus (Chondrichthyes, Rajidae) in Sardinian waters (central-western Mediterranean). Italian Journal of Zoology 77, 5360.Google Scholar
Hussey, N.E., Brush, J., McCarthy, I.D. and Fisk, A.T. (2010) δ15N and δ13C diet discrimination factors for large sharks under semi-controlled conditions. Comparative Biochemistry and Physiology Part A 155, 445453.Google Scholar
Hyslop, E.J. (1980) Stomach contents analysis – a review of methods and their application. Journal of Fish Biology 17, 411429.Google Scholar
Jackson, A.L., Inger, R., Parnell, A.C. and Bearhop, S. (2011) Comparing isotopic niche widths among and within communities: SIBER-Stable isotope Bayesian ellipses in R. Journal of Animal Ecology 80, 595602.Google Scholar
Jacobsen, I.P. and Bennett, M.B. (2013) A comparative analysis of feeding and trophic level ecology in stingrays (Rajiformes; Myliobatoidei) and electric rays (Rajiformes: Torpedinoidei). PLoS ONE 8, e71348.Google Scholar
Jardas, I. (1972) Supplement to the knowledge of ecology of some Adriatic cartilaginous fishes (Chondrichthyes) with special reference to their nutrition. Acta Adriatica 14, 360.Google Scholar
Jennings, S., Reñones, O., Morales-Nin, B., Polunin, N.V.C., Moranta, J. and Coll, J. (1997) Spatial variation in the 15N and 13C stable isotope composition of plants, invertebrates and fishes on Mediterranean reefs: implications for the study of trophic pathways. Marine Ecology Progress Series 146, 109116.Google Scholar
Kabasakal, H. (2001) Preliminary data on the feeding ecology of some selachians from North-Eastern Aegean Sea. Acta Adriatica 42, 1524.Google Scholar
Kabasakal, H. (2002) Cephalopods in the stomach contents of four Elasmobranch species from the northern Aegean Sea. Acta Adriatica 43, 1724.Google Scholar
Kim, S.L. and Koch, P.L. (2011) Methods to collect, preserve, and prepare elasmobranch tissues for stable isotope analysis. Environmental Biology Fishes 95, 5363. doi: 10.1007/s10641-011-9860-9.CrossRefGoogle Scholar
Layman, C.A., Araujo, M.S., Boucek, R., Hammerschlag-Peyer, C.M., Harrison, E., Jud, Z.R., Matich, P., Rosenblatt, A.E., Vaudo, J.J., Yeager, L.A., Post, D.M. and Bearhop, S. (2012) Applying stable isotopes to examine food-web structure: an overview of analytical tools. Biological Review of Cambridge Philosophy Society 87, 545562.Google Scholar
McEachran, J.D. and Capapé, C. (1984) Dasyatidae. In Whitehead, P.J.P., Bauchot, M.-L., Hureau, J.-C., Nielsen, J. and Tortonese, E. (eds) Fishes of the North-eastern Atlantic and Mediterranean, Volume 1. Paris: UNESCO, pp. 197202.Google Scholar
Motta, P.J. and Huber, D.R. (2012) Prey capture behavior and feeding mechanics of elasmobranchs In Carrier, J.C.., Musick, J.A. and Heithaus, M.R.. (eds) Biology of sharks and their relatives, Volume 1. 2nd edn. Boca Raton, FL: CRC Press, pp. 153209.Google Scholar
Navarro, J., Coll, M., Preminger, M. and Palomera, I. (2013) Feeding ecology and trophic position of a Mediterranean endemic ray: consistency between sexes, maturity stages and seasons. Environmental Biology of Fishes 96, 13151328.Google Scholar
Navarro, J., López, L., Coll, M., Barría, C. and Sáez-Liante, R. (2014) Short-and long-term importance of small sharks in the diet of the rare deep-sea shark Dalatias licha . Journal of Marine Biology 161, 16971707.Google Scholar
Neifar, L., Euzet, L. and Ben Hassine, O. (2002) Anthobothrium altavelae sp. n. (Cestoda: Tetraphyllidea) from the spiny butterfly ray Gymnura altavela (Elasmobranchii: Gymnuridae) in Tunisia. Folia Parasitologica 49, 295298.Google Scholar
Olin, J.A., Hussey, N.E., Grgicak-Mannion, A., Fritts, M.W., Wintner, S.P. and Fisk, A.T. (2013) Variable δ 15 N diet-tissue discrimination factors among sharks: implications for trophic position, diet and food web models. PLoS ONE 8(10), e77567.Google Scholar
Papastamatiou, Y.P., Wetherbee, B.M., Lowe, C.G. and Crow, G.L. (2006) Distribution and diet of four species of carcharhinid shark in the Hawaiian Islands: evidence for resource partitioning and competitive exclusion. Marine Ecology Progress Series 320, 239251.Google Scholar
Peterson, B.J. and Fry, B. (1987) Stable isotopes in ecosystem studies. Annual Reviews in Ecological Systems 18, 293320.Google Scholar
Polat, S. and Piner, P.M. (2002) Seasonal variations in biomass, abundance and species diversity of phytoplankton in the Iskenderun Bay (Northeastern Mediterranean). Pakistan Journal of Botany 34, 101112.Google Scholar
Psomadakis, P., Dalù, M., Scacco, U. and Vacchi, M. (2008) A rare batoid fish Gymnura altavela (Chondrichthyes, Gymnuridae) captured in the Tyrrhenian Sea. Marine Biodiversity Records 1(e6), 14.Google Scholar
Romanelli, M., Colasante, A., Scacco, U., Consalvo, I., Finoia, M.G. and Vacchi, M. (2007) Commercial catches, reproduction and feeding habits of Raja asterias (Chondrichthyes: Rajidae) in a coastal area of the Tyrrhenian Sea (Italy, northern Mediterranean). Acta Adriatica 48, 5757.Google Scholar
Santic, M., Rada, B. and Pallaoro, A. (2012) Diet and feeding strategy of thornback ray Raja clavata . Journal of Fish Biology 81, 10701084.Google Scholar
Serena, F., Abella, A., Walls, R. and Dulvy, N. (2015) Raja asterias. The IUCN red list of threatened species 2015: e.T63120A48913317. Downloaded on 28 October 2016.Google Scholar
Serena, F., Barone, M., Mancusi, C. and Abella, A.J. (2005) Reproductive biology, growth and feeding habits of Raja asterias (Delaroche, 1809), from the North Tyrrhenian and South Ligurian Sea (Italy), with some notes on trends in landing. Theme Session on Elasmobranch Fisheries Science CM2005/N:12. 2005 ICES Annual Science Conference 20–24 September 2005.Google Scholar
Shiffman, D., Gallagher, A., Boyle, M., Hammerschlag-Peyer, C. and Hammerschlag, N. (2012) Stable isotope analysis as a tool for elasmobranch conservation research: a primer for non-specialists. Marine and Freshwater Research 63, 635643.Google Scholar
Valls, M., Quetglas, A., Ordines, F. and Moranta, J. (2011) Feeding ecology of demersal elasmobranchs from the shelf and slope off the Balearic Sea (western Mediterranean). Scientia Marina 75, 633639.Google Scholar
Vannucci, S., Mancusi, C., Serena, F., Cuoco, C. and Volani, A. (2006) Feeding ecology of rays in the southern Ligurian Sea. Biologia Marina Mediterranea 13, 296297.Google Scholar
Vooren, C.M., Piercy, A.N., Snelson, F.F. Jr., Grubbs, R.D., Notarbartolo di Sciara, G. and Serena, S. (2007) Gymnura altavela. The IUCN red list of threatened species 2007: e.T63153A12624290. Downloaded on 28 October 2016.Google Scholar
Yeldan, H. (2005) İskenderun ve Mersin Körfez'lerinden Avlanan Vatozların (Raja clavata (Linnaeus, 1758), Raja asterias (Delaroche, 1809), Raja radula (Delaroche, 1809), Dasyatis pastinaca (Linnaeus, 1758), Gymnura altavela (Linnaeus, 1758) Biyoekolojik Özelliklerinin Belirlenmesi. MSc. thesis. Çukurova Üniversitesi Fen Bilimleri Entitüsü. [In Turkish].Google Scholar
Yeldan, H., Avşar, D. and Manaşırlı, M. (2008) Kuzeydoğu Akdeniz'deki Deniz Tilkisi Raja clavata (Linnaeus, 1758)’nın Bazı Biyolojik Özellikleri. Su Ürünleri Dergisi 25, 221228.Google Scholar
Yeldan, H., Avşar, D., Mavruk, S. and Manaşırlı, M. (2013) Temporal changes in some Rajiformes species of cartilaginous fish (Chondrichthyes) from the west coast of İskenderun Bay (Northeastern Mediterranean). Turkish Journal of Zoology 37, 693698.Google Scholar
Yemisken, E., Dalyan, C. and Eryilmaz, L. (2014) Catch and discard fish species of trawl fisheries in the Iskenderun Bay (Northeastern Mediterranean) with emphasis on lessepsian and chondricthyan species. Mediterranean Marine Science 15, 380389.Google Scholar
Yığın, Ç. and İşmen, A. (2010) Diet of thornback ray (Raja clavata Linnaeus, 1758) in Saros Bay (the North Aegean Sea). Rapport Commission Internationale Mer Méditerranée (CIESM), 39, 700.Google Scholar
Young, J.W., Olson, R.J., Ménard, F., Kuhnert, P.M., Duffy, L.M., Allain, V., Logan, J.M., Lorrain, A., Somes, C.J., Graham, B., Goñi, N., Pethybridge, H., Simier, M., Potier, M., Romanov, E., Pagendam, D., Hannides, C. and Choy, C.A. (2015) Setting the stage for a global-scale trophic analysis of marine top predators: a multi-workshop review. Reviews in Fish Biology and Fisheries 25, 261272.Google Scholar
Zanden, M. and Rasmussen, J.B. (2001) Variation in δ15N and δ13C trophic fractionation: implications for aquatic food web studies. Limnology and Oceanography 46, 20612066.Google Scholar
Figure 0

Fig. 1. Study area (North-eastern Levantine Sea, eastern Mediterranean Sea), indicating the sampling locations (black points).

Figure 1

Table 1. Diet composition of Gymnura altavela, Raja asterias and Raja clavata in the Iskenderun Bay (DW, disc width; TL, trophic level estimated from stomach contents; N, number of stomach; %FO, frequency of occurrence; %N, percentage in number; %W, percentage in mass; %IRI, index of relative importance of prey).

Figure 2

Fig. 2. Principal coordinates analysis of stomach contents from G. altavela, R. asterias and R. clavata from the north-eastern Levantine Sea (Mediterranean Sea).

Figure 3

Table 2. Sample size (N) and mean and standard deviation of isotopic values and trophic level estimated with δ15N values (TLSIA) of three batoids in the Iskenderun Bay (north-eastern Mediterranean Sea).

Figure 4

Fig. 3. Graphical representation of the feeding strategy of G. altavela (A), R. asterias (B) and R. clavata (C) from the north-eastern Levantine Sea (Mediterranean Sea): prey-specific abundance (Pi %) plotted against mean frequency of occurrence (%FO) of the different prey groups.

Figure 5

Fig. 4. Mean and standard deviation of δ13C, δ15N and trophic level values of G. altavela, R. asterias and R. clavata from the north-eastern Levantine Sea (Mediterranean Sea). The Bayesian standard ellipse areas are also indicated.

Figure 6

Table 3. Main prey groups in the diet of Gymnura altavela, Raja asterias and Raja clavata from the Mediterranean Sea. NW, north-western; SC, south-central; C, central; W, western; SE, south-east.