posted on 2021-10-01, 13:36authored byAlain Manceau, Romain Brossier, Sarah E. Janssen, Tylor J. Rosera, David P. Krabbenhoft, Yves Cherel, Paco Bustamante, Brett A. Poulin
A prerequisite for environmental
and toxicological applications
of mercury (Hg) stable isotopes in wildlife and humans is quantifying
the isotopic fractionation of biological reactions. Here, we measured
stable Hg isotope values of relevant tissues of giant petrels (Macronectes spp.). Isotopic data were interpreted
with published HR-XANES spectroscopic data that document a stepwise
transformation of methylmercury (MeHg) to Hg-tetraselenolate (Hg(Sec)4) and mercury selenide (HgSe) (Sec = selenocysteine). By mathematical
inversion of isotopic and spectroscopic data, identical δ202Hg values for MeHg (2.69 ± 0.04‰), Hg(Sec)4 (−1.37 ± 0.06‰), and HgSe (0.18 ±
0.02‰) were determined in 23 tissues of eight birds from the
Kerguelen Islands and Adélie Land (Antarctica). Isotopic differences
in δ202Hg between MeHg and Hg(Sec)4 (−4.1
± 0.1‰) reflect mass-dependent fractionation from a kinetic
isotope effect due to the MeHg → Hg(Sec)4 demethylation
reaction. Surprisingly, Hg(Sec)4 and HgSe differed isotopically
in δ202Hg (+1.6 ± 0.1‰) and mass-independent
anomalies (i.e., changes in Δ199Hg of ≤0.3‰),
consistent with equilibrium isotope effects of mass-dependent and
nuclear volume fractionation from Hg(Sec)4 → HgSe
biomineralization. The invariance of species-specific δ202Hg values across tissues and individual birds reflects the
kinetic lability of Hg-ligand bonds and tissue-specific redistribution
of MeHg and inorganic Hg, likely as Hg(Sec)4. These observations
provide fundamental information necessary to improve the interpretation
of stable Hg isotope data and provoke a revisitation of processes
governing isotopic fractionation in biota and toxicological risk assessment
in wildlife.