Systemic signaling was investigated in both a dicot (Vicia faba) and a monocot (Hordeum vulgare) plant. Stimuli were applied to one leaf (S-leaf), and apoplastic responses were monitored on a distant leaf (target; T-leaf) with microelectrodes positioned in substomatal cavities of open stomata. Leaves that had been injured by cutting and to which a variety of cations were subsequently added caused voltage transients at the T-leaf, which are neither action potentials nor variation potentials: with respect to the cell interior, the initial polarity of these voltage transients is hyperpolarizing; they do not obey the all-or-none rule but depend on both the concentration and the type of substance added and propagate at 5 to 10 cm min−1. This response is thought to be due to the stimulation of the plasma membrane H+-ATPase, a notion supported by the action of fusicoccin, which also causes such voltage transients to appear on the T-leaf, whereas orthovanadate prevents their propagation. Moreover, apoplastic ion flux analysis reveals that, in contrast to action or variation potentials, all of the investigated ion movements (Ca2+, K+, H+, and Cl−) occur after the voltage change begins. We suggest that these wound-induced “system potentials” represent a new type of electrical long-distance signaling in higher plants.
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机译:在双子叶植物(Vicia faba)和单子叶植物(大麦(Hordeum vulgare))中都研究了系统信号传导。将刺激物施加到一片叶子(S叶片)上,并在远处的叶子(目标; T叶片)上用微电极监测开放性气孔下气孔中的质外体反应。被割伤的叶子随后添加了多种阳离子,在T形叶上引起了电压瞬变,既不是动作电位也不是变化电位:就细胞内部而言,这些电压瞬变的初始极性为超极化它们不遵循全有或全无的规则,而是取决于浓度和所添加物质的类型,并以5至10 cm min -1 传播。这种反应被认为是由于质膜H + -ATPase的刺激而引起的,这是由fusicoccin的作用所支持的,它也导致此类电压瞬变出现在T叶片上,而原钒酸盐阻止其扩散。此外,质外塑性离子通量分析表明,与作用或变异势相反,所有研究的离子运动(Ca 2 + ,K + ,H + 和Cl -)在电压变化开始之后发生。我们建议这些伤口诱导的“系统电位”代表了高等植物中新型的电子长途信号传递。
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