Abstract
Abstract. The high availability of electron donors occurring in coastal upwelling ecosystems with marked oxyclines favours chemoautotrophy, in turn leading to high N2O and CH4 cycling associated with aerobic NH4+ (AAO) and CH4 oxidation (AMO). This is the case of the highly productive coastal upwelling area off central Chile (36° S), where we evaluated the importance of total chemolithoautotrophic vs. photoautotrophic production, the specific contributions of AAO and AMO to chemosynthesis and their role in gas cycling. Chemolithoautotrophy was studied at a time-series station during monthly (2007–2009) and seasonal cruises (January 2008, September 2008, January 2009) and was assessed in terms of the natural C isotopic ratio of particulate organic carbon (δ13POC), total and specific (associated with AAO and AMO) dark carbon assimilation (CA), and N2O and CH4 cycling experiments. At the oxycline, δ13POC averaged −22.2‰; this was significantly lighter compared to the surface (−19.7‰) and bottom layers (−20.7‰). Total integrated dark CA in the whole water column fluctuated between 19.4 and 2.924 mg C m−2 d−1, was higher during active upwelling, and contributed 0.7 to 49.7% of the total integrated autotrophic CA (photo plus chemoautotrophy), which ranged from 135 to 7.626 mg C m−2 d−1, and averaged 20.3% for the whole sampling period. Dark CA was reduced by 27 to 48% after adding a specific AAO inhibitor (ATU) and by 24 to 76% with GC7, a specific archaea inhibitor. This indicates that AAO and AMO microbes (most of them archaea) were performing dark CA through the oxidation of NH4+ and CH4. Net N2O cycling rates varied between 8.88 and 43 nM d−1, whereas net CH4 cycling rates ranged from −0.41 to −26.8 nM d−1. The addition of both ATU and GC7 reduced N2O accumulation and increased CH4 consumption, suggesting that AAO and AMO were responsible, in part, for the cycling of these gases. These findings show that chemically driven chemolithoautotrophy (with NH4+ and CH4 acting as electron donors) could be more important than previously thought in upwelling ecosystems, raising new questions concerning its relevance in the future ocean.
Highlights
Coastal upwelling regions, most of which are associated with eastern boundary current systems, significantly influence oceanic biogeochemistry in terms of marine productivity and atmospheric chemistry
The addition of both ATU and GC7 reduced N2O accumulation and increased CH4 consumption, suggesting that associated with aerobic NH+4 (AAO) and ammonium monooxygenase enzyme (AMO) were responsible, in part, for the cycling of these gases. These findings show that chemically driven chemolithoautotrophy could be more important than previously thought in upwelling ecosystems, raising new questions concerning its relevance in the future ocean
Our study reveals that integrated dark carbon assimilation (CA) fixation within the redoxcline and the aphotic zone of the coastal area off central Chile represents, on average, 20% of total autotrophic production
Summary
Most of which are associated with eastern boundary current systems, significantly influence oceanic biogeochemistry in terms of marine productivity and atmospheric chemistry. They represent less than 1% of the area of the ocean, these regions provide about 20% of the global fish catch (Pauly and Chistensen, 1995) and give off intense N2O and CH4 emissions (Law and Owens, 1990; Owens et al, 1991; Nevinson et al, 2004). The supply of nutrients to the surface in terms of new nitrogen (NO−3 ) results in high organic matter or “new” production (Eppley, 1989).
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