At the start of the project, it was only hypothesized that Fe limitation and metabolic plasticity in general may influence the respiratory quotient (RQ) during bacterial respiration (Fourquez et al. 2014). The work conducted thus far has confirmed this hypothesis: Fe limitation decreases the RQ. This result has significant implications, as Fe is the limiting element for growth in the Southern Ocean, which represents 40% of all oceanic uptake of anthropogenic CO2. Therefore, this discovery directly impacts estimates of net primary production in this climatically important region, which is the difference between the amount of CO2 uptake during photosynthesis and the amount of CO2 released during respiration.
Advanced technologies were combined to support the validity of this hypothesis. At the cellular level, membrane inlet mass spectrometry (MIMS) enabled continuous and simultaneous recording of CO2 and O2 levels in a controlled experiment. This, combined with pH and alkalinity measurements, allowed for the derivation of total dissolved inorganic carbon produced during cellular respiration. At the community level, the deployment of MIMS technology to measure bacterial respiration is challenging. This is due to the lower density and activity of bacteria in natural environments compared to laboratory cultures. Although the technology itself is sensitive enough to measure respiration in these environments, the experimental setup requires no exchange with the atmosphere, which can rapidly lead to anoxic conditions before any measurement can be made. During the project, I conducted numerous tests, including the use of new pCO2 sensors, to measure RQ directly in the field. I discovered a promising methodology that involved using stable isotopes (specifically 13C) to track the journey of an organic molecule, glucose, into (by NanoSIMS technology) and out (by Gasbench mass spectrometry) of the cell. This new approach to addressing the question of RQ in situ confirmed the results obtained in the lab, showing that RQ varied and was lower in areas where iron (Fe) was limited.
Overall, the results will help to implement the carbon budget at a large scale and, importantly, to reconsider the parameters used in modeling to define bacterial respiration. Nowadays, having an accurate estimate of the ocean's capacity to sequester CO2 is of fundamental importance at both the scientific and societal levels.