1. Non-Redfield, nutrient synergy and flexible internal elemental stoichiometry in a marine bacterium
- Author
-
Mirjam Kant, Reiner Hulsch, Annemieke Strijkstra, Bernd Blasius, Hanna S. Ruppersberg, Ralf Rabus, Kathleen Trautwein, Daniel Wünsch, Christoph Feenders, Stefan Schulz, Bernhard Michalke, Jannes Vagts, Michael Maczka, and Helmut Hillebrand
- Subjects
0301 basic medicine ,Phaeobacter inhibens DSM 17395 ,Oceans and Seas ,Heterotroph ,Applied Microbiology and Biotechnology ,Microbiology ,Phosphates ,03 medical and health sciences ,Nutrient ,Algae ,Ammonium Compounds ,Botany ,Ecological stoichiometry ,Biomass ,Growth rate ,Liebig's law of the minimum ,p Ratio ,Phaeobacter Inhibens Dsm 17395 ,Redfield [Ecological Stoichiometry ,Growth Physiology ,Liebig Limitation ,N] ,Ecosystem ,growth physiology ,ecological stoichiometry ,Ecology ,biology ,Redfield ,Liebig limitation ,Heterotrophic Processes ,Bacterioplankton ,Roseobacter ,biology.organism_classification ,030104 developmental biology ,N:P ratio ,Research Article - Abstract
The stoichiometric constraints of algal growth are well understood, whereas there is less knowledge for heterotrophic bacterioplankton. Growth of the marine bacterium Phaeobacter inhibens DSM 17395, belonging to the globally distributed Roseobacter group, was studied across a wide concentration range of NH4+ and PO43−. The unique dataset covers 415 different concentration pairs, corresponding to 207 different molar N:P ratios (from 10−2 to 105). Maximal growth (by growth rate and biomass yield) was observed within a restricted concentration range at N:P ratios (∼50−120) markedly above Redfield. Experimentally determined growth parameters deviated to a large part from model predictions based on Liebig's law of the minimum, thus implicating synergistic co-limitation due to biochemical dependence of resources. Internal elemental ratios of P. inhibens varied with external nutrient supply within physiological constraints, thus adding to the growing evidence that aquatic bacteria can be flexible in their internal elemental composition. Taken together, the findings reported here revealed that P. inhibens is well adapted to fluctuating availability of inorganic N and P, expected to occur in its natural habitat (e.g. colonized algae, coastal areas). Moreover, this study suggests that elemental variability in bacterioplankton needs to be considered in the ecological stoichiometry of the oceans., Phaeobacter inhibens DSM 17395, member of the marine Roseobacter group, grows optimally at N:P supply ratios >16, exhibits phytoplankton-like flexible internal elemental stoichiometry and different nutrients control growth synergistically.
- Published
- 2017