Salleo Sebastiano, Gullo M Assukta Lo, DE Paoli Dorotea, Zippo Manuela
Dipartimento di Bioligia, Università di Trieste, via L. Giorgieri 10, 1-34121 Trieste, Italy.
Istituto di Botanica, Università di Messina, Casella Postale 58, 1-98166 Messina S. Agata, Italy.
New Phytol. 1996 Jan;132(1):47-56. doi: 10.1111/j.1469-8137.1996.tb04507.x.
Xylem recovery from cavitation-induced embolism was studied in l-yr-old twigs of Laurus mibilis L. Cavitation was induced by applying pre-established pressure differentials (AP ) across the pit membranes of xylem conduits. ΔP ) were 1.13, 1.75 and 2.26 MPa, corresponding to about 50, 77 und 100% of the measured leaf water potential at the rurgor loss point ΔP were obtained either by increasing xylem tensions or by applying positive pressures from outside, or by a combination of the two. The percentage loss of hydraulic conductivity (PLC) did not change, regardless of how the ΔP were obtained. This confirmed that xylem cavitation was nucleated by microbubbles from outside the vessels. Positive pressures, however, amplified (up to 75%) and sped up the xylem refilling (20 min) in comparison with that measured in unpressurized twigs (c.50% in 15 h). Twigs girdled proximally to their pressurized segment 1 nun after the desired pressure value had been reached, did not recover from embolism. The later the twigs were girdled with respect to when they were tested for PLC, the higher was their recovery from embolism, suggesting that some messenger was transported in the phloem which stimulated xylem refilling. Indol-3-acetic acid (1AA] applied to the exposed cortex of both pressurized and unpressurized twigs, induced an almost complete recovery from PLC. We hypothesize that the refilling of cavitated xylem might be a result of an auxin-induced increase in the phloem loading with solutes. This would cause radial transport of solutes to cavitated xylem conduits via the rays, thus decreasing their osmotic potential and making them refill. No positive xylem pressure potentials were measured during xylem recovery from PLC.
在月桂树1年生小枝中研究了木质部从空穴化诱导栓塞中的恢复情况。通过在木质部导管的纹孔膜上施加预先设定的压力差(ΔP)来诱导空穴化。ΔP分别为1.13、1.75和2.26兆帕,分别对应于膨压丧失点时测得的叶水势的约50%、77%和100%。ΔP可通过增加木质部张力或从外部施加正压力或两者结合来获得。无论ΔP如何获得,水力导度损失百分比(PLC)都没有变化。这证实了木质部空穴化是由来自导管外部的微气泡成核的。然而,与未加压小枝(15小时内约50%)相比,正压力使木质部再充盈放大(高达75%)并加速(20分钟)。在达到所需压力值1分钟后,在靠近其加压段处进行环剥的小枝没有从栓塞中恢复。相对于测试PLC的时间,小枝环剥得越晚,其从栓塞中的恢复就越高,这表明有一些信使在韧皮部中运输,刺激了木质部再充盈。将吲哚-3-乙酸(IAA)应用于加压和未加压小枝的暴露皮层,可使PLC几乎完全恢复。我们假设,空穴化木质部的再充盈可能是生长素诱导韧皮部溶质装载增加的结果。这将导致溶质通过射线径向运输到空穴化的木质部导管,从而降低其渗透势并使其再充盈。在木质部从PLC恢复过程中未测得正的木质部压力势。
