Publikation: Dietary availability determines metabolic conversion of long‐chain polyunsaturated fatty acids in spiders : a dual compound‐specific stable isotope approach
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Consumers feeding at the aquatic–terrestrial ecosystem interface may obtain a mixture of aquatic and terrestrial diet resources that vary in nutritional composition. However, in lake riparian spiders, the relative significance of aquatic versus terrestrial diet sources remains to be explored. We investigated the trophic transfer of lipids and polyunsaturated fatty acids (PUFA) from emergent aquatic and terrestrial insects to spiders at varying distances from the shoreline of a subalpine lake in Austria, using differences in fatty acid profiles and compound-specific stable carbon (δ13C) and hydrogen (δ2H) isotopes. The omega-3 PUFA content of emergent aquatic insects was higher than that of terrestrial insects. Emergent aquatic insects contained on average 6.6 times more eicosapentaenoic acid (EPA) and 1.2 times more α-linolenic acid (ALA) than terrestrial insects, whereas terrestrial insects contained on average 2.6 times more linoleic acid (LIN) than emergent aquatic insects. Spiders sampled directly on the lake and in upland habitats had similar EPA contents, but this EPA was derived from different diet sources, depending on the habitat. The δ13CEPA and δ2HEPA values of ‘lake spiders' revealed an aquatic diet pathway (i.e. EPA of aquatic origin). In contrast, EPA of spiders collected in terrestrial habitats was depleted in both 13C and 2H compared to any potential food sources, and their ALA isotopic values, suggesting that EPA was partly bioconverted from its dietary precursor ALA (i.e. internal pathway). The δ2H values of fatty acids clearly indicated that diet sources differed depending on the spider's habitat, which was less evident from the δ13C values of the fatty acids. Our data highlight that spiders can use two distinct pathways (trophic versus metabolic) to satisfy their physiological EPA demand, depending on habitat use and dietary availability.
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MATHIEU‐RESUGE, Margaux, Matthias PILECKY, Cornelia W. TWINING, Dominik MARTIN-CREUZBURG, Tarn Preet PARMAR, Simon VITECEK, Martin J. KAINZ, 2022. Dietary availability determines metabolic conversion of long‐chain polyunsaturated fatty acids in spiders : a dual compound‐specific stable isotope approach. In: Oikos. Wiley. 2022(7), e08513. ISSN 0030-1299. eISSN 1600-0706. Available under: doi: 10.1111/oik.08513BibTex
@article{MathieuResuge2022-07Dieta-55294, year={2022}, doi={10.1111/oik.08513}, title={Dietary availability determines metabolic conversion of long‐chain polyunsaturated fatty acids in spiders : a dual compound‐specific stable isotope approach}, number={7}, issn={0030-1299}, journal={Oikos}, author={Mathieu‐Resuge, Margaux and Pilecky, Matthias and Twining, Cornelia W. and Martin-Creuzburg, Dominik and Parmar, Tarn Preet and Vitecek, Simon and Kainz, Martin J.}, note={Article Number: e08513} }
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