Phloem Import and Storage Metabolism Are Highly Coordinated by the Low Oxygen Concentrations within Developing Wheat Seeds

doi:10.1104/pp.104.040980

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Phloem Import and Storage Metabolism Are Highly Coordinated by the Low Oxygen Concentrations within Developing Wheat Seeds

Joost T. van Dongen ^*, Gerhard W. Roeb , Marco Dautzenberg , Anja Froehlich , Helene Vigeolas , Peter E. H. Minchin , and Peter Geigenberger

Max Planck Institute of Molecular Plant Physiology, Am Mühlenberg 1, 14476 Golm, Germany
Institute of Chemistry and Dynamics of the Geosphere (ICG), Institute III: Phytosphere, Forschungszentrum Jülich GmbH, D-52425 Jülich, Germany

^* Corresponding author; email: dongen{at}mpimp-golm.mpg.de.

We studied the influence of the internal oxygen concentrationin seeds of wheat (Triticum aestivum) on storage metabolismand its relation to phloem import of nutrients. Wheat seedsthat were developing at ambient oxygen (21%) were found to behypoxic (2.1%). Altering the oxygen supply by decreasing orincreasing the external oxygen concentration induced parallelchanges in the internal oxygen tension. However, the decreasein internal concentration was proportionally less than the reductionin external oxygen. This indicates that decreasing the oxygensupply induces short-term adaptive responses to reduce oxygenconsumption of the seeds. When external oxygen was decreasedto 8%, internal oxygen decreased to approximately 0.5% leadingto a decrease in energy production via respiration. Conversely,increasing the external oxygen concentration above ambient levelsincreased the oxygen content as well as the energy status ofthe seeds, indicating that under normal conditions the oxygensupply is strongly limiting for energy metabolism in developingwheat seeds. The intermediate metabolites of seed storage metabolismwere not substantially affected when oxygen was either increasedor decreased. However, at subambient external oxygen concentrations(8%) the metabolic flux of carbon into starch and protein, measuredby injecting ¹⁴C-Suc into the seeds, was reduced by 17% and32%, respectively, whereas no significant effect was observedat superambient (40%) oxygen. The observed decrease in biosyntheticfluxes to storage compounds is suggested to be part of an adaptiveresponse to reduce energy consumption preventing excessive oxygenconsumption when oxygen supply is limited. Phloem transporttoward ears exposed to low (8%) oxygen was significantly reducedwithin 1 h, whereas exposing ears to elevated oxygen (40%) hadno significant effect. This contrasts with the situation wherethe distribution of assimilates has been modified by removingthe lower source leaves from the plant, resulting in less assimilatestransported to the ear in favor of transport to the lower partsof the plant. Under these conditions, with two strongly competingsinks, elevated oxygen (40%) did lead to a strong increase inphloem transport to the ear. The results show that sink metabolismis affected by the prevailing low oxygen concentrations in developingwheat seeds, determining the import rate of assimilates viathe phloem.

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