Using hydrogen isotopes of freshwater fish tissue as a tracer of provenance.

Hydrogen isotope (δ ² H) measurements of consumer tissues in aquatic food webs are useful tracers of diet and provenance and may be combined with δ ¹³ C and δ ¹⁵ N analyses to evaluate complex trophic relationships in aquatic systems. However, δ ² H measurements of organic tissues are complicated by analytical issues (e.g., H exchangeability, lack of matrix-equivalent calibration standards, and lipid effects) and physiological mechanisms, such as H isotopic exchange with ambient water during protein synthesis and the influence of metabolic water. In this study, δ ² H (and δ ¹⁵ N) values were obtained from fish muscle samples from Lake Winnipeg, Canada, 2007-2010, and were assessed for the effects of species, feeding habits, and ambient water δ ² H values. After lipid removal, we used comparative equilibration to calibrate muscle δ ² H values to nonexchangeable δ ² H equivalents and controlled for H isotopic exchange between sample and laboratory ambient water vapor. We then examined the data for evidence of trophic δ ² H enrichment by comparing δ ² H values with δ ¹⁵ N values. Our results showed a significant logarithmic correlation between fork length and δ ² H values, and no strong relationships between δ ¹⁵ N and δ ² H. This suggests the so-called apparent trophic compounding effect and the influence of metabolic water into tissue H were the potential mechanisms for δ ² H enrichment. We evaluated the importance of water in controlling δ ² H values of fish tissues and, consequently, the potential of H isotopes as a tracer of provenance by taking account of confounding variables such as body size and trophic effects. The δ ² H values of fish appear to be a good tracer for tracking provenance, and we present a protocol for the use of H isotopes in aquatic ecosystems, which should be applicable to a broad range of marine and freshwater fish species. We advise assessing size effects or working with fish of relatively similar mass when inferring fish movements using δ ² H measurements.