Optimal conditions for visualizing water-conducting pathways in a living tree by the dye injection method

Optimal conditions for visualizing water-conducting pathways in a living tree by the dye injection method

To elucidate the water-conducting pathways in living trees by the dye injection method, suitable sample preparation procedures are needed. We evaluated quantitatively the properties and concentrations of three dyes (acid fuchsin, basic fuchsin and safranin) widely used for this purpose, and determin...

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Bibliographic Details
Published in:Tree physiology Vol. 27; no. 7; pp. 993 - 999
Main Authors: Umebayashi, T, Utsumi, Y, Koga, S, Inoue, S, Shiiba, Y, Arakawa, K, Matsumura, J, Oda, K
Format: Journal Article
Language:English
Published: Canada 01-07-2007
Subjects:
acid fuchsin
Benzenesulfonates - metabolism
Cryoelectron Microscopy
developmental stages
differential staining
Ericaceae - metabolism
Ericaceae - physiology
Ericaceae - ultrastructure
Phenazines - metabolism
Pieris
Pieris japonica
Plant Stems - metabolism
Plant Stems - physiology
Plant Stems - ultrastructure
Plant Transpiration - physiology
Rosaniline Dyes - metabolism
safranin
sap flow
stems
translocation (plant physiology)
Trees - metabolism
Trees - physiology
Trees - ultrastructure
Water - metabolism
water uptake
wood anatomy
woody plants
xylem
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Summary:To elucidate the water-conducting pathways in living trees by the dye injection method, suitable sample preparation procedures are needed. We evaluated quantitatively the properties and concentrations of three dyes (acid fuchsin, basic fuchsin and safranin) widely used for this purpose, and determined the optimal conditions required to avoid artifacts after dye injection into the sap stream of Pieris japonica D. Don. Among the dyes tested, an aqueous solution of acid fuchsin at a concentration of 0.1% or more was the most useful for delineating water movement. In non-transpiring stem segments, the vertical movement of acid fuchsin by capillarity and diffusion from the dye injection site was limited. However, acid fuchsin moved rapidly in the horizontal direction by capillarity and diffusion, and most xylem cells were stained within 2 h. A delay of more than 2 h between dye injection and examination of the tissues greatly reduces the precision of the method. Use of the dye injection method without appropriate, well-defined experimental procedures may give rise to misleading information about the functional water-conducting pathway in living trees.
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content type line 23
ISSN:0829-318X
1758-4469
DOI:10.1093/treephys/27.7.993