5.2.3  Damage control

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Transpiration operates by suction, but leaves are especially liable to damage by grazing and mechanical forces. Leaf vessels therefore need special protection against air embolisms spreading in the vessel network that would block liquid flow (Section 5.1). This is achieved at all points in the leaf distal to the node (i.e. petiole, large veins, small veins) by the vessels being very short. That is, files of vessel elements joined to make a single pipe with a terminal end-wall are much shorter in the leaf than in the rest of the plant. Water flows through vessel end-walls with little extra resistance, but an air–water interface cannot be pulled through an end-wall or pit membrane (Section 5.1). The force needed to curve the interface into a meniscus small enough to pass through the end-wall is the same force as is generated by evaporation from wet cell walls (Section 5.2.1). To pull the interface through a hole of diameter Dµm requires a pressure of 0.3/D MPa. While only 0.1MPa can pull an interface through a 3µm hole, 6MPa is required to pull air through a 0.05µm hole: cell walls have pores much smaller than 0.05µm. So an embolism formed from cavitating water fills one vessel but does not spread beyond it.


Figure 5.8 Cleared whole mount of a wheat leaf demonstrating the frequent occurrence of end-walls in leaf vessels.The leaf was fed an emulsion of green latex paint in the transpiration fluid from a cut surface 6.5 mm to the right of the picture. At the right side of the picture, two vessels in the central large vein (see Figure 5.5) are carrying paint. Halfway across the picture (at arrowhead) the upper vessel is blocked by an end-wall through which the paint particles could not pass, although water continued to flow. The paint in the lower vessel continued for another 3 mm beyond the left of the picture, where an end—wall in that vessel limited its further progress. Note that paint has not passed out of the large vein into transverse veins where water flowed because pit membranes (Section 5.1) filtered out paint particles. Bright-field optics. Scale bar = 100 µm (Photograph courtesy M. McCully and M. Canny)

Short vessels are easily demonstrated by allowing a leaf to transpire in a fine colloidal suspension that cannot pass end-walls. Latex paint, diluted 100 times with water and allowed to settle for a week or two, provides such a suspension. Leaves that have drawn up this suspension for an hour or so during transpiration can be cleared by dissolving out the chlorophyll and soaking in lactic acid. Progress of the paint is then readily seen (Figure 5.8). Very few vessels exceed 1cm in length.