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| Main Authors: | , , , , , |
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| Format: | Artículo científico |
| Language: | en |
| Published: |
PloS one
2026
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| Subjects: | |
| Online Access: | https://pubmed.ncbi.nlm.nih.gov/42139259/ |
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Table of Contents:
- Analyses of eye lens stable isotopes across ontogeny of trophically diverse freshwater salmonids. Schumacher, Glenn T Peebles, Ernst B Furey, Nathan B Kinnison, Michael T Kronisch, Gregory R Murphy, Christina A Animals Lens, Crystalline Lakes Trout Fresh Water Nitrogen Isotopes Ecosystem Bayes Theorem Ontogenetic niche shifts in fishes are nearly universal but remain poorly understood in many species despite being fundamentally important for the persistence, management, and conservation of fish populations, including those of vulnerable salmonids. Eye lens stable isotope analysis has proven useful in studying ontogeny in some marine species but has rarely been applied in freshwater fishes. We conducted among the first applications of eye lens stable isotope analysis in two salmonids, Arctic Charr (Salvelinus alpinus) and Brook Trout (Salvelinus fontinalis), in four North American lakes at the southern extent of the range of Arctic Charr (Maine, USA). Our goal was to determine if ontogenetic patterns varied between individuals and populations in ways that relate to differential vulnerability. Like studies in marine systems, we found patterns in lens isotopic values that agree with expected ontogenetic patterns to reach known adult trophic niches. Within lakes and individuals examined in this study, Arctic Charr appeared more dependent on pelagic resources than co-occurring Brook Trout through life. Using Bayesian hierarchical linear regressions, we found evidence that ontogenetic shifts in trophic position (measured by δ15N) of Arctic Charr may vary among lakes. Arctic Charr in some populations increased in trophic position through life (population lifetime δ15N posterior mean slope estimate = 1.01) while others showed no substantial changes (population lifetime δ15N posterior mean slope = 0.05), which may relate to differences in habitat and fish assemblage among our study lakes. Our study suggests that individual life stages and populations of salmonids are likely to respond to climate variability (e.g., basal resource shifts) differentially, which could warrant population and life-stage-specific management.