Inhibitors with 14 or 13CO2 uptake

Template:BreadcrumbsNutrients

• Page authors: PRIMO
• Responsible curator: Hagen Buck-Wiese

The chemoautotrophic CO₂ fixation attributable specifically to nitrifiers is estimated by comparing dark ¹⁴C or ¹³C-bicarbonate incorporation in paired incubations: one with nitrification inhibitors (ATU, octyne) and one without. The difference in dark carbon fixation between control and inhibited bottles is attributed to nitrifier chemoautotrophic production. This approach is based on the principle that nitrifying bacteria and archaea derive energy from NH₄⁺ or NO₂^- oxidation and fix CO₂ as their sole carbon source^[1].

Point sample; dark incubations of hours to days. Requires strict exclusion of light to prevent phytoplankton photosynthetic CO₂ fixation from contaminating the signal.

Nitrifier-specific dark carbon fixation rates in nmol C L^-1 d^-1; convertible to nitrification rates using the theoretical yield of 1 mol CO₂ fixed per ~7 mol NH₄⁺ oxidized (AOA; ratio differs for AOB).

Units are mol C L^-1 d^-1 or mol C cell^-1 d^-1. The currency is carbon.

Typical samples are ~1 L in volume.

The method assumes that nitrification is the primary driver of dark CO₂ fixation in the water column. Recent evidence suggests this assumption is increasingly questionable in some environments where other chemoautotrophs (sulphur oxidisers, hydrogen oxidisers) contribute substantially. Long incubations in the dark can alter community composition. The conversion factor between CO₂ fixation and N oxidation varies among nitrifier lineages and must be determined empirically.

• Ward (2011) Measurement and distribution of nitrification rates in the oceans ^[1]

• Nitrification rate from dark C fixation: assuming 1 mol CO₂ fixed per 7 mol NH₄⁺ oxidised, nitrification rate (nmol N L^-1 d^-1) = dark C fixation (nmol C L^-1 d^-1) × 7.