Natural abundance of stable nitrogen and oxygen isotopes are invaluable biogeochemical tracers for assessing the N transformations in the environment. To fully exploit these tracers, the N and O isotope effects (¹⁵ε and ¹⁸ε) associated with the respective nitrogen transformation processes must be known. Anaerobic ammonium oxidation (anammox) and denitrification are the two major sinks of fixed nitrogen (N). In addition, anammox bacteria contribute to re-oxidation of nitrite to nitrate, because they fix CO₂ into biomass with reducing equivalents generated from oxidation of nitrite to nitrate. Nitrate production by anammox bacteria influences the nitrite and nitrate N and O isotope effects in freshwater and marine systems. Despite the significant importance of anammox bacteria in the global N cycle, the N and O isotope effects of anammox are not well known. Especially, the oxygen isotope effect of anammox metabolism has never been determined yet. This is probably because the O isotope effect of nitrite is affected by three simultaneously occurring reactions; (1) nitrite reduction to N₂ gas, (2) nitrite oxidation to nitrate, and (3) incorporation of a water-derived O atom into nitrate during nitrite oxidation to nitrate, and thus is difficult to determine. Furthermore, the δ¹⁸O_NO2 value is affected by abiotic O isotope exchange between nitrite and water. Here we analyzed the O isotope effects and oxygen atom exchange associated with anammox metabolism by a marine anammox species “Ca. Scalindua sp.”.
The rate of abiotic oxygen atom exchange rate was measured using the medium with different δ¹⁸O values (δ¹⁸O_H2O= -12.3, 27.1, 60.0, and 114.3‰) at a temperature of 30°C and pH=7.5 which was same as the experimental condition of anammox batch incubation. The approach of δ¹⁸O_NO2 to isotope equilibrium (δ¹⁸O_{NO2, eq}) is modeled with the following formula: δ¹⁸O_NO2 = δ¹⁸O_NO2,eq + (δ¹⁸O_NO2,initial - δ¹⁸O_NO2,eq )*exp(-k_eq*Time). k_eq (in units of h^-1) represents the rate constant for abiotic equilibration of oxygen atoms (Fig. 1). The model fitting approach of δ¹⁸O_NO2 at different medium δ¹⁸O values yielded a rate constant (k_eq) of (1.13 ± 0.007) × 10^-2 (h^-1), and the equilibrium oxygen isotope effect between nitrite and water (¹⁸ε_eq) of 12.95 ± 0.16‰ (tentative result).
To determine oxygen isotope effects of (1) nitrite reduction to N₂ gas (¹⁸ε_NO2→N2) and (2) nitrite oxidation to nitrate (¹⁸ε_NO2→NO3), anammox batch experiments were conducted using the medium with different δ¹⁸O values (δ¹⁸O_H2O= -12.3, 27.1, 60.0, and 114.3‰) in triplicate. In these batch experiments, we used highly enriched (Percoll-separated) cultures (>99.9%) of “Ca. Scalindua sp.”. The stoichiometric ratios of consumed nitrite and consumed ammonium (ΔNO₂^-/ΔNH₄⁺, average 1.35) and produced nitrate and consumed ammonium (ΔNO₃^-/ΔNH₄⁺, average 0.29) agreed with previously observed stoichiometry of anammox process (Fig. 2). During the anammox reaction, δ¹⁸O of produced nitrate appeared to depend on the δ¹⁸O_H2O of medium. This observation suggested that a water-derived O atom was incorporated into nitrate during nitrite oxidation to nitrate. Rapid increase in δ¹⁸O of nitrite overtime was observed in high δ¹⁸O_H2O media as compared to abiotic exchange. A numerical model is currently being developed to estimate the oxygen isotope effect of each reaction (¹⁸ε_NO2→N2 and ¹⁸ε_NO2→NO3). The obtained O isotopic effects of a marine anammox species “Ca. Scalindua sp.” could provide significant insights into the contribution of anammox bacteria to the fixed N loss and NO₂ ^- reoxidation (N recycling) in the ocean.