Abstract

Nutrient measurements indicate that 30–50% of the total nitrogen (N) loss in the ocean occurs in oxygen minimum zones (OMZs). This pelagic N-removal takes place within only ∼0.1% of the ocean volume, hence moderate variations in the extent of OMZs due to global warming may have a large impact on the global N-cycle. We examined the effect of oxygen (O2) on anammox, NH3 oxidation and NO3 − reduction in 15N-labeling experiments with varying O2 concentrations (0–25 µmol L−1) in the Namibian and Peruvian OMZs. Our results show that O2 is a major controlling factor for anammox activity in OMZ waters. Based on our O2 assays we estimate the upper limit for anammox to be ∼20 µmol L−1. In contrast, NH3 oxidation to NO2 − and NO3 − reduction to NO2 − as the main NH4 + and NO2 − sources for anammox were only moderately affected by changing O2 concentrations. Intriguingly, aerobic NH3 oxidation was active at non-detectable concentrations of O2, while anaerobic NO3 − reduction was fully active up to at least 25 µmol L−1 O2. Hence, aerobic and anaerobic N-cycle pathways in OMZs can co-occur over a larger range of O2 concentrations than previously assumed. The zone where N-loss can occur is primarily controlled by the O2-sensitivity of anammox itself, and not by any effects of O2 on the tightly coupled pathways of aerobic NH3 oxidation and NO3 − reduction. With anammox bacteria in the marine environment being active at O2 levels ∼20 times higher than those known to inhibit their cultured counterparts, the oceanic volume potentially acting as a N-sink increases tenfold. The predicted expansion of OMZs may enlarge this volume even further. Our study provides the first robust estimates of O2 sensitivities for processes directly and indirectly connected with N-loss. These are essential to assess the effects of ocean de-oxygenation on oceanic N-cycling.

Highlights

  • Oxygen (O2) is one of the key regulatory factors of major biogeochemical cycles in the marine environment [1]

  • We present results for the Namibian and Peru/ Chile upwelling systems, two of the most productive regions in the worlds’ oceans associated with massive N-loss, where we explored the effect of O2 on anammox, NH3 oxidation and NO32 reduction throughout the oxygen minimum zones (OMZs)

  • Nitrite concentrations were fairly constant in the upper,100 m (0.1–0.5 mmol L21) and increased to,2 and,4 mmol L21 in the bottom waters at St. 206 and 252, respectively. The increase in both NO22 and NH4+ in the lower OMZ was accompanied by a sharp decrease in NO32 concentrations, with minimum concentrations of,12 mmol L21 in the lowest sampling depths at both stations

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Summary

Introduction

Oxygen (O2) is one of the key regulatory factors of major biogeochemical cycles in the marine environment [1]. Oxygen, entering the ocean interior mainly at high latitudes, is distributed throughout the global ocean via thermohaline circulation. Subsurface regions of severely reduced O2 concentrations (O2#5 mmol L21), the so-called oxygen minimum zones (OMZs), are found along the eastern boundaries of the ocean basins in the subtropics and tropics (e.g. off California, Namibia, Peru/Chile) and in the Arabian Sea. Subsurface regions of severely reduced O2 concentrations (O2#5 mmol L21), the so-called oxygen minimum zones (OMZs), are found along the eastern boundaries of the ocean basins in the subtropics and tropics (e.g. off California, Namibia, Peru/Chile) and in the Arabian Sea In these regions, wind-driven circulation results in the upwelling of nutrient-rich deep waters, fueling high primary production in the euphotic zone. Combined with the poor ventilation of these water masses [2,3], this leads to permanently O2-depleted to anoxic conditions at mid-depths [4,5,6]

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