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Differential Response of Gray Poplar Leaves and Roots Underpins Stress Adaptation during Hypoxia
- Kreuzwieser, Jürgen, Hauberg, Jost, Howell, Katharine A., Carroll, Adam, Rennenberg, Heinz, Millar, A. Harvey, Whelan, James
- Plant physiology 2009 v.149 no.1 pp. 461-473
- Populus canescens, adaptation, amino acid metabolism, biochemical pathways, biosynthesis, carbon, cell walls, cellulose, energy, fermentation, hypoxia, leaves, messenger RNA, metabolome, nitrogen, nitrogen metabolism, nutrient transport, phloem, physiological response, roots, shoots, starch, sucrose
- The molecular and physiological responses of gray poplar (Populus x canescens) following root hypoxia were studied in roots and leaves using transcript and metabolite profiling. The results indicate that there were changes in metabolite levels in both organs, but changes in transcript abundance were restricted to the roots. In roots, starch and sucrose degradation were altered under hypoxia, and concurrently, the availability of carbohydrates was enhanced, concomitant with depletion of sucrose from leaves and elevation of sucrose in the phloem. Consistent with the above, glycolytic flux and ethanolic fermentation were stimulated in roots but not in leaves. Various messenger RNAs encoding components of biosynthetic pathways such as secondary cell wall formation (i.e. cellulose and lignin biosynthesis) and other energy-demanding processes such as transport of nutrients were significantly down-regulated in roots but not in leaves. The reduction of biosynthesis was unexpected, as shoot growth was not affected by root hypoxia, suggesting that the up-regulation of glycolysis yields sufficient energy to maintain growth. Besides carbon metabolism, nitrogen metabolism was severely affected in roots, as seen from numerous changes in the transcriptome and the metabolome related to nitrogen uptake, nitrogen assimilation, and amino acid metabolism. The coordinated physiological and molecular responses in leaves and roots, coupled with the transport of metabolites, reveal important stress adaptations to ensure survival during long periods of root hypoxia.