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Effects of O2 on N2 fixation in heterocystous cyanobacteria from the Baltic Sea
Staal, M.; te Lintel Hekkert, S.; Harren, F.J.M.; Stal, L.J. (2003). Effects of O2 on N2 fixation in heterocystous cyanobacteria from the Baltic Sea. Aquat. Microb. Ecol. 33(3): 261-270. https://dx.doi.org/10.3354/ame033261
In: Aquatic Microbial Ecology. Inter-Research: Oldendorf/Luhe. ISSN 0948-3055; e-ISSN 1616-1564, more
Peer reviewed article  

Available in  Authors 

Keywords
    Algal blooms
    Baltic Sea
    Chemical elements > Nonmetals > Atmospheric gases > Oxygen
    Chemical reactions > Nitrogen fixation
    Hydrographic features > Marine areas > Seas > Northeast atlantic > Baltic sea
    Physics > Acoustics
    Radiations > Electromagnetic radiation > Light
    ANE, Baltic [Marine Regions]
    Marine/Coastal

Authors  Top 
  • Staal, M.
  • te Lintel Hekkert, S.
  • Harren, F.J.M.
  • Stal, L.J., more

Abstract
    The effect of O2 on nitrogenase activity in natural samples of heterocystous cyanobacteria from the Baltic Sea was studied using on-line laser photo-acoustic trace-gas detection. This technique records nitrogenase activity in near real-time and allows measurements in continuously changing O2 concentrations. Our results showed that under non-steady state conditions the optimum concentration of O2 for N2 fixation differed from that at steady-state O2 levels. The optimum O2 concentration depended upon whether the O2 concentration was increasing or decreasing, with decreasing concentrations yielding higher O2 optima for dark nitrogenase activity than increasing O2 concentrations. The cyanobacteria rapidly adapt to changes in O2, and therefore measurements also reflect the history of O2 concentrations to which organisms have been exposed. Steady-state and non- steady-state O2 concentrations both decreased their optimum O2 concentration for nitrogenase activity rates with increasing irradiance. However, the optimum O2 concentration was always higher than zero, even at saturating irradiances. Hence, it appears that low levels of O2 are an obligatory requirement for maximum nitrogenase activity in the field. Low levels of respiration served as a source of additional energy, suggesting that even at light saturation, photosynthetic energy generation in the heterocyst can not saturate the demand of nitrogenase for ATP. The large changes in nitrogenase activity due to the combined effect of variations in O2 concentration and light emphasize the necessity of including these effects in models that calculate the daily integral of N2 fixation.

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