Abstract
In this study the impact of salt stress on the physiology and wood structure of the salt-sensitive Populus × canescens was investigated. Two weeks of salt stress altered wood anatomy significantly. The xylem differentiation zone was reduced and the resulting vessels exhibited reduced lumina. To understand this phenomenon, ion composition, levels of corresponding transcripts and of the stress hormone ABA were analysed. With increasing sodium and chloride concentrations, a general reduction of potassium was found in roots and shoots, but not in leaves. Consequently, the corresponding K+ channel transcripts in roots favoured K+ release. The overall osmolarity in leaves was up to fourfold higher than in roots or shoots. Therefore, adjustment of the K+/Na+ balance seemed not to be required in leaves. Sodium increased gradually from roots to shoots and then to leaves indicating that sodium storage took place first in roots, then in shoots, and finally in leaves to protect photosynthesis from salt effects as long as possible. Since leaf abscisic acid levels markedly increased, stomatal closure seemed to limit CO2 uptake. As a consequence, diminished nutrient supply to the cambium in combination with lowered shoot K+ content led to decreased vessel lumina, and a reduction of the radial cambium was observed. Thus, xylem differentiation was curtailed and the development of full size vessels was impaired.
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Abbreviations
- ABA:
-
Abscisic acid
- PCR:
-
Polymerase chain reaction
- TEM:
-
Transmission electron microscopy
- EDXA:
-
Energy-dispersive X-ray analysis
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Acknowledgments
We thank Ute Neef for technical assistance and Duncan Cameron (University of Sheffield, UK) and Lois Banta (Haverford College, PA, USA) for carefully reading of the manuscript and helpful comments. The study was supported financially by the German Science Foundation (DFG; Ache: AC97/4-2, Schnitzler: SCHN653/4, Nehls: Ne332/9-1, Fromm: Fr955/10-2, and Polle: PO362/13) within the German joint research group ‘Poplar—A model to address tree-specific questions’.
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María Escalante-Pérez and Silke Lautner contributed equally to this work.
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Escalante-Pérez, M., Lautner, S., Nehls, U. et al. Salt stress affects xylem differentiation of grey poplar (Populus × canescens). Planta 229, 299–309 (2009). https://doi.org/10.1007/s00425-008-0829-7
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DOI: https://doi.org/10.1007/s00425-008-0829-7