Physiological changes during heartwood formation young Eucalyptus bosistoana trees
Physiological changes during heartwood formation young Eucalyptus bosistoana trees
- IAWA Journal, p.1-13, 2018 .
Eucalyptus bosistoana F.Muell. is valued for its naturally durable heartwood. As part of an E. bosistoana breeding programme, we have tested the hypothesis that there is a prolonged transition from sapwood to heartwood in young trees, resulting in a wide transition zone. This needs to be considered when assessing trees for heartwood quantity and quality. Heartwood formation was investigated in radial profiles in cores from bark to bark of 6-year-old trees with conventional and confocal microscopy, and with a range of different staining techniques that visualised the physiological changes taking place in the parenchyma cells. Using immunolabelling with antibodies against histone proteins and ?-tubulin, histochemical staining using potassium iodide (I3-KI)and fluorescence emission spectral scanning, we demonstrated that in heartwood nuclei, microtubules, reserve materials (starch)and vacuoles were absent. The observations revealed that 6-year-old E. bosistoana trees contained heartwood. The loss of wáter conductivity by tyloses formation and the death of the parenchyma cells occurred in close proximity resulting in a transition zone of ~1 cm.
AMYLOPLASTS
CONFOCAL MICROSCOPY
EXTRACTIVES
JUVENILE COREWOOD
NUCLEI
PARENCHYMA CELLS
RAY CELLS
TYLOSES
WOOD
Eucalyptus bosistoana F.Muell. is valued for its naturally durable heartwood. As part of an E. bosistoana breeding programme, we have tested the hypothesis that there is a prolonged transition from sapwood to heartwood in young trees, resulting in a wide transition zone. This needs to be considered when assessing trees for heartwood quantity and quality. Heartwood formation was investigated in radial profiles in cores from bark to bark of 6-year-old trees with conventional and confocal microscopy, and with a range of different staining techniques that visualised the physiological changes taking place in the parenchyma cells. Using immunolabelling with antibodies against histone proteins and ?-tubulin, histochemical staining using potassium iodide (I3-KI)and fluorescence emission spectral scanning, we demonstrated that in heartwood nuclei, microtubules, reserve materials (starch)and vacuoles were absent. The observations revealed that 6-year-old E. bosistoana trees contained heartwood. The loss of wáter conductivity by tyloses formation and the death of the parenchyma cells occurred in close proximity resulting in a transition zone of ~1 cm.
AMYLOPLASTS
CONFOCAL MICROSCOPY
EXTRACTIVES
JUVENILE COREWOOD
NUCLEI
PARENCHYMA CELLS
RAY CELLS
TYLOSES
WOOD