Isotopic signatures (δ 13C and δ15N) of muscle, carapace and claw in Phrynops geoffroanus (Testudines: Chelidae)

Marques, Thiago S.; Tassoni-Filho, Maurício; Ferronato, Bruno O.; Guardia, Isabela; Verdade, Luciano M.; Camargo, Plínio B. de

doi:10.1590/S1984-46702011000300016

Abstract

The isotopic composition ( δ13C and δ 15N) of muscle, carapace and claw was determined from six wild individuals of Phrynops geoffroanus (Schweigger, 1812) in order to verify the variation between those tissues. The mean values of δ13C e δ 15N were, respectively, -19.48 ± 0.81‰ (-20.8 - -18.64‰) and 7.23 ± 0.67‰ (6.49 - 8.3‰) for muscle, -16.52 ± 0.98‰ (-17.88 - -15.43‰) and 7.29 ± 0.54‰ (6.74 - 7.97‰) for carapace and -18.57 ± 0.97‰ (-19.97 - -17.26‰) and 4.36 ± 0.33‰ (3.93 - 4.79‰) for claw. We found a significant difference for the tissues evaluated for both δ13C and δ15N. Muscle and claw were statistically similar and more depleted in 13C than the carapace. Nonetheless, claw was more depleted in 15N than muscle and carapace tissues. These results are likely related to differences in metabolic processes involved on each tissue formation. The description of the isotopic signatures variation in P. geoffroanus tissues provides a baseline for future investigations on the diet reconstruction of this species when more than one tissue is involved.

Diet; freshwater turtles; Geoffroy's side-necked-turtle; metabolic processes; stable isotope

SHORT COMMUNICATION

Isotopic signatures (δ ¹³C and δ¹⁵N) of muscle, carapace and claw in Phrynops geoffroanus (Testudines: Chelidae)

Thiago S. Marques^* * Corresponding author ; Maurício Tassoni-Filho; Bruno O. Ferronato; Isabela Guardia; Luciano M. Verdade; Plínio B. de Camargo

Laboratório de Ecologia Isotópica, CENA, Universidade de São Paulo, Caixa Postal 96, 13416-000 Piracicaba, SP, Brasil, E-mail: thiagomq@yahoo.com.br; mtassonifilho@yahoo.com.br; brunoferronato@hotmail.com; isabela.guardia@gmail.com; lmverdade@usp.br; pcamargo@cena.usp.br

ABSTRACT

The isotopic composition ( δ¹³C and δ ¹⁵N) of muscle, carapace and claw was determined from six wild individuals of Phrynops geoffroanus (Schweigger, 1812) in order to verify the variation between those tissues. The mean values of δ¹³C e δ ¹⁵N were, respectively, -19.48 ± 0.81 (-20.8 - -18.64) and 7.23 ± 0.67 (6.49 - 8.3) for muscle, -16.52 ± 0.98 (-17.88 - -15.43) and 7.29 ± 0.54 (6.74 - 7.97) for carapace and -18.57 ± 0.97 (-19.97 - -17.26) and 4.36 ± 0.33 (3.93 - 4.79) for claw. We found a significant difference for the tissues evaluated for both δ¹³C and δ¹⁵N. Muscle and claw were statistically similar and more depleted in ¹³C than the carapace. Nonetheless, claw was more depleted in ¹⁵N than muscle and carapace tissues. These results are likely related to differences in metabolic processes involved on each tissue formation. The description of the isotopic signatures variation in P. geoffroanus tissues provides a baseline for future investigations on the diet reconstruction of this species when more than one tissue is involved.

Key words: Diet; freshwater turtles; Geoffroy's side-necked-turtle; metabolic processes; stable isotope.

doi: 10.1590/S1984-46702011000300016

Stable isotope analyses present a great potential to be explored in animal ecology studies (GANNES et al. 1997). This technique can provide information on animals' movement patterns, diet reconstruction, trophic level, protein balance, turnover of nutrients, and nutrient allocation (GANNES et al. 1997, 1998, HOBSON 1999). However, investigations based on this technique for Neotropical chelonians are scarce.

The use of stable isotopic technique on chelonians is generally concentrated in marine turtles (e.g., GODLEY et al. 1998, HATASE et al. 2002, BIASATTI 2004, WALLACE et al. 2006, REICH et al. 2007). However, some information on freshwater turtle's species is also available (ARESCO & JAMES 2005, SEMINOFF et al. 2007, BULTÉ et al. 2008). The Geoffroy's side-necked turtle, Phrynops geoffroanus (Schweigger, 1812), is widely distributed in South America, ranging from Venezuela and Colombia to southern Brazil, Paraguay, northern Argentina and Uruguay (PRITCHARD & TREBBAU 1984, ERNST & BARBOUR 1989). It is a common inhabitant of urban polluted rivers (SOUZA & ABE 2000, MARQUES et al. 2008, FERRONATO et al. 2009a, c, PIÑA et al. 2009), where it can coexist with the invasive exotic species Trachemys scripta elegans (Wied, 1838) (FERRONATO et al. 2009b).

The goal of this study was to describe the variation in isotopic signatures ( δ¹³C and δ ¹⁵N) found in muscle, carapace and claw tissues of Geoffroy's side-necked turtle and to provide a better understanding of the isotopic relationships of its different tissues.

In this investigation, we used turtles from two polluted watercourses in southeastern Brazil, the Piracicaba river and its tributary, the Piracicamirim stream, Piracicaba Municipality, state of São Paulo (22º42'52.18"S, 47º37'38.95"W). The Piracicaba river basin has suffered an intense change in land use, which altered the original landscape and water quality (DEL GRANDE et al. 2003). For further information on the study sites see MARQUES et al. (2008), FERRONATO et al. (2009a), and PIÑA et al. (2009). Muscle samples from different body regions (abdomen, arm, leg and neck), as well as carapace and claw samples were collected from six Geoffroy's side-necked turtles (three from each watercourse). Claw samples represented the terminal 8 mm of the claw. Despite the relatively small sample-size, this study generates valuable data considering the ethical difficulty in sacrificing a larger number of animals.

All samples were dried at 50ºC in an oven device until they reached a constant mass (MAGNUSSON et al. 1999). The carapace and claw samples were manually cleaned to remove contaminants from both the environment and the turtle itself, and fragmented into very small pieces, while the muscle samples were ground to a fine powder. The resultant material was weighted (claw: 1.2-1.5 mg; carapace: 1-1.2 mg; muscle: 1-1.2 mg) and put inside small tin capsules. The isotopic composition of carbon and nitrogen were determined by "online" combustion of the samples by CF-IRMS (Continuous Flow - Isotope Ratio Mass Spectrometers), using an elemental analyzer Carlo Erba (CHN-1110) interfaced to an isotope ratio mass spectrometer Delta Plus, in the Isotopic Ecology Laboratory/CENA/University of São Paulo. Carbon and nitrogen isotopic composition were calculated according to JESPEN & WINEMILLER (2002). The results are defined in delta notation ( ) and reported in parts per thousand () relative to international standards (see CRAIG 1957). The results are represented in delta (δ) notation in . Routine measurements were precise to within 0.3 for δ ¹³C and 0.5 for δ¹⁵N.

Data normality was tested using the Anderson-Darling test. To verify any difference in the isotopic signatures (δ¹⁵C and δ¹³C) of muscle samples from the abdomen, arm, leg and neck, we used the Kruskal-Wallis test as the data were not normally distributed. In addition, we used the same test to check for any differences between muscle, carapace and claw. If a difference was detected, we used the Mann-Whitney Test between the treatments. We used Minitab 16 software for the statistical analyses.

The turtles used in the present study had a mean straight line carapace length of 284 ± 22 mm (243-307 mm) and mean body mass of 2038 ± 434 g (1300-2450 g). There was no significant difference in isotopic signatures among muscle samples collected from different body regions (Fig. 1; δ¹³C: df = 3, h = 0.8, p = 0.84; δ¹⁵N: df = 3, h = 2.65, p = 0.44); consequently we could use a general mean of muscle from each individual, when comparing the data with other tissues (carapace and claw). The isotope ratios of muscle, claw, and carapace are shown in figure 2 and table I.

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There was a significant difference between the tissues sampled (muscle, carapace, and claw) for δ¹³C and δ¹⁵N ( δ¹³C: df = 2, h = 11.56, p = 0.003; δ¹⁵N: df = 2, h = 11.47, p = 0.003). There was no difference between claw and muscle samples for ¹³C (w = 29, p = 0.12). However, there was a significant difference between carapace and muscle/claw (carapace/muscle: w = 57, p = 0.005; carapace/claw: w = 55, p = 0.01). In addition, in the case of δ¹⁵N there was a significant difference for claw and the other tissues (claw/muscle: w = 57, p = 0.005; claw/carapace: w = 21, p = 0.005), which did not differ from each other (Tab. I; w = 36, p = 0.68).

ARESCO & JAMES (2005) found no difference in the values of δ¹⁵N and δ¹³C when comparing muscle and claw tissues in two north American freshwater turtles, Trachemys scripta scripta (Schoepff, 1792) and Pseudemys floridana (LeConte, 1829). REVELLES et al. (2007) did not find differences in δ¹³C composition between muscle and carapace of loggerhead sea turtle, Caretta caretta, however they found differences for δ¹⁵N values. In the present study, we found the same pattern only for the δ¹³C in muscle and claw samples. Apparently, it is not clear if there is a relation for chelonians muscle and carapace samples when analysing δ¹³C and δ¹³N composition.

The tissues of consumers are synthesised by nutrients present in the diet, so they usually reflect the isotopic composition of their food (DENIRO & EPSTEIN 1978, HOBSON & CLARK 1992a, CRAWFORD et al. 2008). The differences found in the isotopic signatures of the tissues can result from different metabolic processes involved in the formation of different tissues. TIESZEN et al. (1983) suggested such a mechanism in their study of the rodent Meriones unguienlatus (Milne-Edwards, 1867) under controlled conditions.

When the animal's diet changes, the isotopic signature of the tissues does not change homogeneously in time (REICH et al. 2008). Tissues with high metabolic rate reflect the recent diet of the animal, while tissues with low metabolic rates reflect the diet from a longer period (HOBSON & CLARK 1992b). This is why using different tissues with distinct metabolic rates could help in reconstructing the animal's diet, as well as detecting seasonal differences and migratory trends (DALERUM & ANGERBJÖN 2005). However, in the present study our claw samples probably represent a mix of old and new tissues due to the length of claw material that was sampled (see ETHIER 2010).

Investigations on tissues turnover patterns in freshwater turtles are scarce. SEMINOFF et al. (2007) estimated for pond sliders (Trachemys scripta) a turnover period for blood plasma, whole blood and liver of 142, 155 and 210 days, respectively. The isotopic signatures of ¹³C and ¹⁵N of the claw of pond sliders took, respectively, twelve and six months to reflect changes in the turtle's diet (ARESCO & JAMES 2005). This information could also be relevant to our results because the turtles were captured in the wild and there is no information on possible temporal changes in their diet.

Most dietary studies on chelonians use stomach flushing techniques (LEGLER 1977) and faeces analysis (BURKE et al. 1993, WITZELL & SCHMID 2005, CAPUTO & VOGT 2008) These methods impose some limitations, such as the overestimation of the items with hard digestion structures, and the underestimation of the food items that are completely digested and absorbed (BULTÉ et al. 2008). In addition, they could include non-dietary items incidentally ingested. The isotopic analysis applied for dietary studies using different tissues is a powerful tool in the diet reconstruction, since they provide measurements of food assimilation for different periods of time (MARTINELLI et al. 2009).

In addition, if the proportionality of δ¹³C and δ¹⁵N in claw and muscle of Phrynops geoffroanus demonstrated in the present study is confirmed, there will be no need to sacrifice or harm animals in order to get muscle samples in this species. This technique could also be applied in other freshwater turtles that show the same similarity for δ¹³C and δ¹⁵N. Besides helping investigating long-term dietary trends, stable isotopes also provide an alternative to traditional diet studies which allows for non-destructive sampling. This is the first step in order to carry out diet studies on P. geoffroanus by the use of isotopes.

Our results are original in describing the variation in the isotopic signatures of Geoffroy's side-necked turtle tissues, which can be used in future investigations of the species diet reconstruction. In complement, future studies of isotopic ecology under controlled conditions should be prioritized for the species. It could also help solving questions of temporal or spatial variation in the use of feeding resources.

ACKNOWLEDGEMENTS

This study was sponsored by FAPESP (Process 2005/002109 and 2007/50428-6) and CNPq (Process 300087/2005-5). Turtles were captured under ICMBio/RAN Capture Permit (Process 02010.000005/05-61). The manuscript benefited from helpful suggestions by A.L. Pereira, S. Oppel, and an anonymous reviewer.

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Seminoff, A.A.; K.A. Bjorndal & A.B. Bolten. 2007. Stable Carbon and Nitrogen Isotope Discrimination and Turnover in Pond Sliders Trachemys scripta: Insights for Trophic Study of Freshwater Turtles. Copeia 2007 (3): 534-542.

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Submitted: 18.XI.2010;

Accepted: 14.V.2011.

Editorial responsibility: Carolina Arruda Freire

Aresco, M.J. & F.C James. 2005. Ecological Relationships of Turtles in Northern Florida Lakes: A Study of Omnivory and the Structure of a Lake Food Web. Tallahassee, Florida Fish and Wildlife Conservation Commission, 66p.
Biasatti, D.M. 2004. Stable carbon isotopic profiles for sea turtle humeri: implications for ecology and physiology. Paleogeography, Paleoclimatology, and Paleoecology 206: 203-216.
Bulté, G.; M.A. Gravel & G. Blouin-Dermers. 2008. Intersexual niche divergence in northern map turtles (Graptemys geographica): the roles of diet and habitat. Canadian Journal of Zoology 86: 1235-1243.
Burke, V.J.; E.A. Standora & S.J. Morreale. 1993. Diet of Juvenile Kemp's Ridley and Loggerhead Sea Turtles from Long Island, New York. Copeia 1993 (4): 1176-1180.
Caputo, F.P& R.C. Vogt. 2008. Stomach Flushing Vs. Fecal Analysis: The Example of Phrynops rufipes (Testudines: Chelidae). Copeia 2008 (2): 301-305.
Craig, H. 1957. Isotopic standards for carbon and oxygen and correction factors for mass-spectrometric analysis of carbon dioxide. Geochimicha et Cosmochimica Acta 12: 133-149.
Crawford, K.; R.A. Mcdonald & S. Bearhop. 2008. Applications of stable isotope techniques to the ecology of mammals. Mammal Review 38 (1): 87-107.
Dalerum, F. & A. Angerbjörn. 2005. Resolving temporal variation in vertebrate diets using naturally occurring stable isotopes. Oecologia 144: 647-658.
Del Grande, M.; M.O.O. Rezende & O. Rocha. 2003. Distribuição de compostos organoclorados nas águas e sedimentos da bacia do rio Piracicaba/SP Brasil. Química Nova 26: 678-686.
Deniro, M.J. & S. Epstein. 1978. Influence of diet on the distribution of carbon isotopes in animals. Geochimicha et Cosmochimica Acta 42: 495-506.
Ernst, C.H. & R.W. Barbour. 1989. Turtles of the World. Washington, DC, Smithsonian Institution Press, 313p.
ETHIER, D. M.; C.J. KYLE; T.K. KYSER & J.J. NOCERA. 2010. Variability in the growth patterns of the cornified claw sheath among vertebrates: implications for using biogeochemistry to study animal movement. Canadian Journal of Zoology 88: 1043-1051.
Ferronato, B.O.; T.S. Marques; F.L. Souza; L.M. Verdade & E.R. Matushima. 2009a. Oral bacterial microbiota and traumatic injuries of free-ranging Phrynops geoffroanus (Testudines, Chelidae) in southeastern Brazil. Phyllomedusa 8: 19-25.
Ferronato, B.O.; T.S. Marques; I. Guardia; A.L.B. Longo; C.I. Piña; J. Bertoluci & L.M. Verdade. 2009b. The turtle Trachemys scripta elegans (Testudines, Emydidae) as an invasive species in a polluted stream of southeastern Brazil. Herpetological Bulletin 109: 29-34.
Ferronato, B.O.; M.E. Merchant; T.S. Marques & L.M. Verdade. 2009c. Characterization of innate immune activity in Phrynops geoffroanus (Testudines: Chelidae). Zoologia 26: 747-752.
Gannes, L.Z.; C.M. Del Rio & P. Koch. 1998. Natural abundance variations in stable isotopes and their potential uses in animal physiological ecology. Comparative Biochemistry and Physiology 119 (3): 725-737.
Gannes, L.Z.; D.M. O'Brien & C.M. Del Rio. 1997. Stables isotopes in animal ecology: assumptions, caveats, and a call for more laboratory experiments. Ecology 78 (4): 1271-1276.
Godley, B.J.; D.R. Thompson; S. Waldron & R.W. Furness. 1998. The trophic status of marine turtles as determined by stable isotope analysis. Marine Ecology Progress Series 166: 277-284.
Hatase, H.; N. Takai; Y. Matsuzawa; W. Sakamoto; K. Omuta; K. Goto; N. Arai & T. Fujiwara. 2002. Size-related differences in feeding habitat use of adult female loggerhead turtles Caretta caretta around Japan determined by stable isotope analyses and satellite telemetry. Marine Ecology Progress Series 233: 273-281.
Hobson, K.A. 1999. Tracing origins and migration of wildlife using stable isotopes: a review. Oecologia 120: 314-326.
Hobson, K.A. & R.G. Clark. 1992a. Assessing avian diets using stable isotopes II: Factors influencing diet-tissue fractionation. Condor 94: 189-197.
Hobson, K.A. & R.G. Clark. 1992b. Assessing avian diets using stable isotopes I: turnover in ¹³C in tissues. Condor 94: 181-188.
JEPSEN, D.B. & K. WINEMILLER. 2002. Structure of tropical river food webs revealed by stable isotope ratios. Oikos 96: 46-55.
Legler, J.M. 1977. Stomach flushing: a technique for chelonian dietary studies. Herpetologica 33: 281-284.
Magnusson, W.E.; M.C. Araújo; R. Cintra; A.P. Lima; L.A. Martinelli; T.M. Sanaiotti; H.L. Vasconcelos & R.L. Victoria. 1999. Contributions of C³ and C⁴ plants to higher trophic levels in an Amazonian savanna. Oecologia 119: 91-96.
Marques, T.S.; B.O. FERRONATO; I. GUARDIA; A.L.B. LONGO; S. TRIVINHO-Strixino; J. Bertoluci & L.M. Verdade. 2008. Primeiro registro de larvas de Chironomus inquinatus Correia, Trivinho-Strixino & Michailova (Diptera, Chironomidae) vivendo no casco do cágado Phrynops geoffroanus Schweigger (Testudines, Chelidae) na região Neotropical. Biota Neotropica 8 (4): 1-3.
Martinelli, L.A.; J.P.H.B. Ometto; E.S. Ferraz; R.L. Victoria; P.B. Camargo & M.Z. Moreira. 2009. Desvendando Questões Ambientais Com Isótopos Estáveis. São Paulo, Oficina de Textos, 144p.
Piña, C.I.; V.A. Lance; B.O. Ferronato; I. Guardia; T.S. Marques & L.M. Verdade. 2009. Heavy Metal Contamination in Phrynops geoffroanus (Schweigger, 1812) (Testudines: Chelidae) in a River Basin, São Paulo, Brazil. Bulletin of Environmental Contamination and Toxicology 83: 771-775.
Pritcahrd, P.C.H. & P. Trebbau. 1984. Phrynops geoffroanus (Schweigger, 1812), p. 111-117. In: P.C.H. PRITCHARD & P. TREBBAU (Eds). The turtles of Venezuela. Athens, Society for Study of Amphibians and Reptiles, 414p.
Reich, K.J.; K.A. Bjorndal & A.B. Bolten. 2007. The 'lost years' of green turtles: using stable isotopes to study cryptic lifestages. Biology Letters 3: 712-714.
Reich, K.J.; K.A. Bjorndal & C. Del Rio. 2008. Effects of growth and tissue type on the kinetics of ¹³C and ¹⁵N incorporation in a rapidly growing ectotherm. Oecologia 155: 651-663.
Revelles, M.; L. Cardona; A. Aguilar; A. Borrell; G. Fernández & M.S. Félix. 2007. Stable C and N isotope concentration in several tissues of the loggerhead sea turtle Caretta caretta from the western Mediterranean and dietary implications. Scientia Marina 71 (1): 87-93.
Seminoff, A.A.; K.A. Bjorndal & A.B. Bolten. 2007. Stable Carbon and Nitrogen Isotope Discrimination and Turnover in Pond Sliders Trachemys scripta: Insights for Trophic Study of Freshwater Turtles. Copeia 2007 (3): 534-542.
Souza, F.L. & A.S. Abe. 2000. Feeding ecology, density and biomass of the freshwater turtle, Phrynops geoffroanus, inhabiting a polluted urban river in south-eastern Brazil. Journal of Zoology 252: 437-446.
Tieszen, L.L.; T.W. Boutton; K.G. Tesdahl & N.A. Slade. 1983. Fractionation and turnover of stable carbon isotopes in animal tissues: Implication for ¹³C analysis of diet. Oecologia 57: 32-37.
Wallace, B.P.; J.A. Seminoff; S.S. Kilham; J.R. Spotila & P.H. Dutton. 2006. Leatherback turtles as oceanographic indicators: stable isotope analyses reveal a trophic dichotomy between ocean basins. Marine Biology 149: 953-960.
Witzell, W.N. & J.R. Schmid. 2005. Diet of immature kemp's ridley turtles (Lepidochelys kemp) from gullivan bay, ten thousand islands, southwest Florida. Bulletin of Marine Science 77 (2): 191-199.

*

Corresponding author

Publication Dates

Publication in this collection
25 July 2011
Date of issue
June 2011

History

Accepted
14 May 2011
Received
18 Nov 2010

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

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[37] Witzell, W.N. & J.R. Schmid. 2005. Diet of immature kemp's ridley turtles (Lepidochelys kemp) from gullivan bay, ten thousand islands, southwest Florida. Bulletin of Marine Science 77 (2): 191-199.