Journal
PLANT PHYSIOLOGY
Volume 151, Issue 4, Pages 1751-1757Publisher
AMER SOC PLANT BIOLOGISTS
DOI: 10.1104/pp.109.141499
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Funding
- Australian Research Council
- United Kingdom Natural Environmental Research Council
- European Commission
- Natural Environment Research Council [NER/G/S/2003/00008] Funding Source: researchfish
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Plant roots and microorganisms interact and compete for nutrients within the rhizosphere, which is considered one of the most biologically complex systems on Earth. Unraveling the nitrogen (N) cycle is key to understanding and managing nutrient flows in terrestrial ecosystems, yet to date it has proved impossible to analyze and image N transfer in situ within such a complex system at a scale relevant to soil-microbe-plant interactions. Linking the physical heterogeneity of soil to biological processes marks a current frontier in plant and soil sciences. Here we present a new and widely applicable approach that allows imaging of the spatial and temporal dynamics of the stable isotope N-15 assimilated within the rhizosphere. This approach allows visualization and measurement of nutrient resource capture between competing plant cells and microorganisms. For confirmation we show the correlative use of nanoscale secondary ion mass spectrometry, and transmission electron microscopy, to image differential partitioning of (NH4+)-N-15 between plant roots and native soil microbial communities at the submicron scale. It is shown that N-15 compounds can be detected and imaged in situ in individual microorganisms in the soil matrix and intracellularly within the root. Nanoscale secondary ion mass spectrometry has potential to allow the study of assimilatory processes at the submicron level in a wide range of applications involving plants, microorganisms, and animals.
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