Open-access Trophic niche comparison between two predators in northern Rio de Janeiro State, Brazil: a stable isotopes approach

Comparação do nicho trófico entre dois predadores no norte do estado do Rio de Janeiro, Brasil: uma abordagem de isótopos estáveis

Abstracts

The trophic niche of the sympatric predators Pontoporia blainvillei(franciscana dolphin) and Trichiurus lepturus (ribbonfish) was compared by stable isotope (δ15N and δ13C) ratios in hepatic and muscular tissues to understand how they co-exist in the northern Rio de Janeiro State (21°30′S-22°15′S), south-eastern Brazil. Dolphin specimens were incidentally captured through commercial gillnet fisheries, while fish specimens were the target of these fisheries. The predators had similar δ15N values in the liver (P. blainvillei: 14.6 ± 1.0‰; T. lepturus: 14.4 ± 0.6‰), which indicates similar trophic position in the recent food intake. However,P. blainvillei showed lighter δ15N values in muscle (13.8 ± 1.0‰) than T. lepturus (15.0 ± 0.4‰), revealing differences in the long term diet that could be related with the prey size ingested. The δ13C signatures showed a preferential inshore and benthic food chain for P. blainvillei (liver: −15.2 ± 0.6‰; muscle: −16.0 ± 0.5‰) and a more offshore and pelagic food chain for T. lepturus(liver: −17.2 ± 0.6‰; muscle: −16.8 ± 0.3‰). The isotopic variances of liver and muscle revealed a broader niche width to P. blainvillei in relation to T. lepturus, with a greater use of available food resources in coastal waters. In the area of study, the differences in habitat use and exploitation of food resources are favoring the predators' coexistence.

trophic niche; marine vertebrates; stable isotopes; Rio de Janeiro; Southwest Atlantic


O nicho trófico dos predadores simpátricos Pontoporia blainvillei (golfinho franciscana) e Trichiurus lepturus(peixe-espada) foi comparado através de razões de isótopos estáveis (δ15N and δ13C) nos tecidos hepático e muscular para compreender como eles coexistem no norte do Estado do Rio de Janeiro (21°30′S-22°15′S), sudeste do Brasil. Os espécimes do golfinho foram capturados acidentalmente em pescarias comerciais com rede de espera, enquanto os espécimes do peixe foram alvo dessas pescarias. Os predadores apresentaram valores similares de δ15N no fígado (P. blainvillei: 14.6 ± 1.0;T. lepturus: 14.4 ± 0.6), o que indica posição trófica semelhante quanto à ingestão alimentar recente. No entanto, P. blainvillei apresentou valores mais leves de δ15N no músculo (13.8 ± 1.0) em relação a T. lepturus (15.0 ± 0.4), revelando diferenças na dieta de longo prazo que podem estar relacionadas ao tamanho das presas ingeridas. As assinaturas de δ13C indicaram uma cadeia alimentar preferencialmente costeira e bentônica para P. blainvillei(fígado: −15.2 ± 0.6; músculo: −16.0 ± 0.5) e uma cadeia alimentar mais oceânica e pelágica para T. lepturus(fígado: −17.2 ± 0.6; músculo: −16.8 ± 0.3). As variâncias isotópicas do fígado e do músculo revelaram uma maior amplitude de nicho para P. blainvillei em relação a T. lepturus, com maior aproveitamento dos recursos alimentares disponíveis em águas costeiras. Na área de estudo, as diferenças no uso do habitat e na exploração de recursos alimentares estão favorecendo a coexistência dos predadores.

nicho trófico; vertebrados marinhos; isótopos estáveis; Rio de Janeiro; Atlântico Sul Ocidental


Introduction

Species that require similar feeding resources and co-exist in the same habitat tend to minimize food competition by using different physical areas or preying on different species (Pimm 2002). The target species of this study are two predators that co-exist in coastal waters of the Southwest Atlantic Ocean: franciscana dolphinPontoporia blainvillei (Gervais & D'Orbigny 1844) and ribbonfishTrichuirus lepturus (Linnaeus 1758). The species P. blainvillei is the most vulnerable dolphin along the southwest Atlantic Ocean due to their encounters with gillnet fisheries, and their populations are considered to be decreasing (International… 2012). Its distribution is restricted to waters up to 30 m depth, between 19 °S to 38 °S (Crespo et al. 1998,Di Beneditto 2003). The species T. lepturus may be found along tropical and sub-tropical latitudes and it is an important fishery resource worldwide. Juvenile and subadult specimens are related to estuarine and coastal waters, while adult specimens move along the continental shelf widely, reaching the continental slope and oceanic waters (Martins et al. 2005, Froese & Pauly 2012).

Studies on stomach content analysis indicated that P. blainvilleifeeds preferentially on fishes and squids up to 10 cm length (Di Beneditto & Ramos 2001, Danilewicz et al. 2002). In contrast, the feeding habit of T. lepturus changes during its ontogeny, being zooplanktivorous at juvenile stage (5-30 cm length) and becoming a carnivore when adult (>100 cm length), feeding mainly on fishes (Martins et al. 2005). A previous comparison about the food preference of these predators in northern Rio de Janeiro State, south-eastern Brazil, through stomach content analysis, showed a feeding overlap in which 60% of total food resources consumed were shared between them (Bittar & Di Beneditto 2009).

The stomach content analysis of dead vertebrates is commonly used to identify the preferential prey and their quantitative contribution to diet (e.g. Ohizumi et al. 2003, Di Beneditto & Ramos 2001, Bittar et al. 2008). Indeed, this is the more efficient method for the taxonomic recognition and size estimates of prey ingested by aquatic predators. However, stomach content analysis usually indicates the last food intake, but not the dietary input over time (food assimilation). Thus, complementary analysis with other diet markers such as stable isotopes can provide additional information about feeding preference and trophic niche in the ecosystem (Di Beneditto et al. 2011).

Stable isotope measurements have provided useful data on marine vertebrates' trophic ecology, indicating the food assimilated from feeding activities and food sources (e.g.Das et al. 2000, Hobson et al. 2002; Di Beneditto et al. 2011, 2012). In general, stable isotope ratios of a consumer are related to those of their prey and consumers that occupy the same trophic position have similar isotopic measurements (Renaud et al. 2011, Di Beneditto et al. 2011). In trophic ecology approaches, stable isotope of nitrogen (δ15N) has been mainly used to recognize different trophic levels and food assimilation over time, while carbon (δ13C) indicates different dietary-based carbon sources (e.g. inshore vs. offshore, pelagic vs. benthic or aquatic vs. terrestrial) (DeNiro & Epstein 1978, Peterson & Fry 1987, Fry 2008). Additionally, the concept of isotopic niche, gathering δ15N and δ13C measurements, has been used to better understand species' trophic niche width and competition or coexistence among species (Bearhop et al. 2004, Newsome et al. 2007, Franco-Trecu et al. 2012).

The aim of this study is to describe the trophic niche of P. blainvillei and T. lepturus in the coastal waters of northern Rio de Janeiro State using stable isotope analyses in hepatic and muscular tissues to understand how they co-exist in the study area.

Material and methods

1.
Sampling

The area of study is the northern Rio de Janeiro State (21°30′S-22°15′S) (Figure 1). Dolphin specimens were incidentally captured through commercial gillnet fisheries while fish specimens were the target of these fisheries. In this area the gillnet fisheries are conducted along the continental shelf, whose slope is located around 100 m depth. The specimens were captured in waters from 2 to 56 km from the coastline, in depths varying from 10 to 50 m. Only adult fish (>100 cm length) were considered for this study due to their potential to be a trophic competitor of P. blainvillei (Bittar & Di Beneditto 2009). A sub-sample from the back dorso-lateral muscle and the liver (entire for T. lepturus and final portion of the largest lobe for P. blainvillei) were removed. All tissue samples were freeze-dried and homogenized with a mortar and pestle for stable isotope analyses.

Figure 1.
Northern Rio de Janeiro State, south-eastern Brazil, where Pontoporia blainvillei and Trichiurus lepturus specimens were captured (dotted area).

2.
Stable isotope analysis

Stable isotope ratios were determined in dry hepatic and muscular tissue samples, without lipid-extraction, using a Thermo Quest-Finnigan Delta Plus isotope ratio mass spectrometer (Finnigan-MAT) interfaced with an Elemental Analyzer (Carlo Erba). Pee Dee beleminite carbonate and atmospheric nitrogen were used as standard values for carbon and nitrogen analyses, respectively. The analytical precision was ±0.1 for δ13C and ±0.2 for δ15N (triplicate samples of every fifth sample).

The tissues samples were not lipid-extracted, which could have influenced δ13C results. Kiljunen et al. (2006)and Post et al. (2007) stated that a C:N ratio less than 3.5 indicates that the tissue contains zero extractable lipid. The mean C:N ratios of the muscle samples, by weight from elemental composition, were less than 3.5 and indicated a low lipid content. In this sense, the lipid-extraction was not considered a restriction on muscle δ13C values interpretation. Meanwhile, hepatic tissue usually has high lipid content and should be lipid-corrected (Sweeting et al. 2006). We applied the lipid-normalizing δ13C to liver samples, as proposed by Logan et al. (2008): δ13C′ = 0.967 × δ13C + 0.861.

3.
Data analysis

The assumptions of normality and homoscedasticity were assessed through Shapiro-Wilk and Levene tests, respectively. The data fit a normal distribution, but the homoscedasticity was not verified in all cases. In this sense, Welch t-test for non-homogeneous samples was applied to verify the diet and feeding ground overlaps between P. blainvillei andT. lepturus considering stable isotopes measurements in hepatic and muscular tissues. The trophic niche width of predators was compared through the isotopic variance of liver and muscle, using a simple variance ratio test (F-test), as described inBearhop et al. (2004). The statistical analysis was performed using Statistica 10.0 for Windows (StatSoft, Inc 1984-2011, USA) and R 2.12.2 for Windows (R Development Core Team 2011). A p value equal or less than 0.05 was chosen to indicate statistical significance.

Results and Discussion

The δ15N values in the liver ranged from 13.3 to 16.9‰ toP. blainvillei (mean: 14.6±1.0‰), and 13.7 to 15.5‰ to T. lepturus (mean: 14.4 ± 0.6‰) (Figure 2). No significant difference was detected between predators (t= −1.097; p = 0.279). However, the δ15N values in muscular tissue of P. blainvillei(11.2 to 15.6‰; mean: 13.8 ± 1.0‰) were significantly lighter (t= 3.986; p < 0.001) than in T. lepturus (14.0 to 15.5‰; mean: 15.0 ± 0.4‰) (Figure 2).

Figure 2.
Stable isotopes (δ15N and δ13C) values in the liver (A) and muscle (B) of Pontoporia blainvillei andTrichiurus lepturus specimens.

Comparisons of δ15N signatures in different tissues allow food ingestion evaluation in different periods of time, as days, weeks or months (Hobson et al. 1996, Das et al. 2000, Fry 2008). Considering hepatic and muscular tissues, the turnover rate is faster in the former due to differences in metabolic activity (Tieszen et al. 1983, Hesslein et al. 1993). From this perspective, it is possible to suggest that δ15N signatures in the liver are normally derived by more recent food ingestion (e.g., days or weeks) than in the muscle (e.g. months).

The feeding ground (and diet) overlap between these predators in the area of study should occur when adult specimens of T. lepturus move along shallower waters. At this time, P. blainvillei (with a restrict area of distribution in the inner continental shelf) and T. lepturus (with a wide area of distribution along the entire continental shelf) share the available food resources, that can include the same prey species with similar size. Since the analyzed specimens were captured in the inner continental shelf (see Material and Methods), the recent feeding events (measured by δ15N signatures in the liver) were probably similar, as well as the predators' trophic level in this feeding ground. This could explain the similar results of hepatic δ15N for T. lepturus and P. blainvilleispecimens.

On the other hand, the δ15N ratios in muscle ofP. blainvillei specimens were lighter than in T. lepturusspecimens, showing differences between predators when considering the trophic level in a long-term diet. According to Bittar & Di Beneditto (2009), the predators are sharing 60% of the total food resources ingested, but the average prey size consumed by T. lepturus is twice greater than P. blainvillei's. In general, small size specimens of a given species are lessδ15N enriched than the large ones (Jennings et al. 2002), and this condition could explain the muscleδ15N differences between predators.

Stable carbon isotope was specifically grouped in both tissues (Figure 2). In P. blainvillei specimens the values ranged from −15.6 to −13.4‰ (mean: −15.2 ± 0.6‰) in hepatic tissue and −17.1 to −14.9‰ (mean: −16.0 ± 0.5‰) in muscular tissue, while in T. lepturus specimens the values ranged from −18.4 to −16.5‰ (mean: −17.2 ± 0.6‰) and −17.8 to −16.3‰ (mean: −16.8 ± 0.3‰) in liver and muscle, respectively (Figure 2). In both tissues, the values of δ13C for T. lepturuswere significantly lighter than in P. blainvillei (liver:t= −11,01; p < 0.001; muscle:t= −5,692; p < 0.001).

Differences in δ13C signatures reflect differences in habitat use between these predators. The δ13C signatures are usually applied to distinguish different dietary-based carbon sources: benthic and inshore trophic chains are usually enriched in δ13C compared to pelagic and offshore ones (DeNiro & Epstein 1978, Hobson 1999, Lesage et al. 2001, Fry 2008). Thus, δ13C signatures showed a preferential inshore and benthic food chain for P. blainvillei and a more offshore and pelagic food chain forT. lepturus.

In P. blainvillei, the variances in δ15N values (liver: 1.02; muscle: 1.10) were significantly greater (F = 3.01; p = 0.026) than in T. lepturus (liver: 0.34; muscle: 0.17), reflecting a broader niche width to the dolphin. Considering the pool of ingested prey species by each predator, this result indicates that the number of prey species that have importance in the diet of P. blainvillei is greater than in T. lepturus, corroborating the prey's index of relative importance analysis done in Bittar & Di Beneditto (2009).

The variances in δ13C values in hepatic tissue were similar between predators (P. blainvillei: 0.38; T. lepturus: 0.35;F = 1.06; p = 0.884). This can indicate similar trend regarding feeding grounds used by both predators in recent feeding events, when they are sharing the coastal waters along the inner continental shelf and probably the food resources, as discussed above. The variances in muscle δ13C of P. blainvillei(0.30) was greater than T. lepturus (0.12), but with no significant difference (F = 2.50; p = 0.061). Although demersal feeding ground seems to be more important to P. blainvillei than pelagic ones, as shown by δ13C values (Figure 2), this predator explores both sites to capture its preferred prey (Di Beneditto & Ramos 2001). On the other hand, T. lepturus is a typical pelagic predator (Bittar et al. 2008). These characteristics would lead to differences in the variances considering the muscular δ13C values.

In the area of study, some previous investigations described in details the feeding habits of both predators through stomach content analysis. Both pelagic (e.g.,Doryteuthis spp, Anchoa filifera, Pellona harroweri and Chirocentrodon bleekerianus) and demersal species (Stellifer spp, Isopisthus parvipinnis and Cynoscion jameicensis) were identified as preferential prey of P. blainvillei(Di Beneditto & Ramos 2001). RegardingT. lepturus, only pelagic species were among the most consumed prey (e.g.,T. lepturus – juvenile specimens, P. harroweri, C. bleekerianus and Lycengraulis grossidens and Doryteuthisspp) (Bittar et al. 2008, 2012). Comparing the previous stomach content analysis with the stable carbon isotope signatures measured in the present study, we can argue that demersal prey species are more important for P. blainvillei than previously thought. This feeding strategy can reduce the trophic competition between P. blainvillei and T. lepturus (and other pelagic predators) in coastal areas. Additionally, the trophic niche width of P. blainvillei indicates its great ability in using the available food resources, compensating its limits regarding the distributional area and allowing the coexistence with trophic competitors, as T. lepturus.

We thank fishermen from Atafona Harbour and Silvana Ribeiro Gomes, who provided us with franciscana dolphin and ribbonfish specimens. APM Di Beneditto was supported by Conselho Nacional de Desenvolvimento Científico e Tecnológico - CNPq (Proc. 300241/2009-7 and 403735/2012-2) and Fundação Carlos Chagas Filho de Amparo a Pesquisa do Estado do Rio de Janeiro - FAPERJ (Proc. E-26/102.915/2011). CE Rezende was supported by CNPq (Proc. 304615/2010-2) and FAPERJ (Proc. E-26/102.945/2011). This work was partially supported by CNPq INCT Material Transference from the Continent to the Ocean (Proc. 573.601/2008-9). Franciscana dolphin's research permit was provided by the Brazilian Government/Instituto Brasileiro do Meio Ambiente e dos Recursos Naturais Renováveis (Permit n° 012-02/CMA/IBAMA).

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Publication Dates

  • Publication in this collection
    Sept 2013

History

  • Received
    11 June 2012
  • Reviewed
    5 June 2013
  • Accepted
    7 Oct 2013
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Instituto Virtual da Biodiversidade | BIOTA - FAPESP Departamento de Biologia Vegetal - Instituto de Biologia, UNICAMP CP 6109, 13083-970 - Campinas/SP, Tel.: (+55 19) 3521-6166, Fax: (+55 19) 3521-6168 - Campinas - SP - Brazil
E-mail: contato@biotaneotropica.org.br
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