Chlorophyll fluorescence and water relations of salt-stressed plants

W.J.S. Downton, Jeny Millhouse
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引用次数: 19

Abstract

The yield of chlorophyll a variable fluorescence from leaves of grapevine, bean, barley, spinach, citrus (Citrus myrtifolia) and mangrove (Avicennia marina) remained unaffected by salt treatment declining only when excessive ion accumulation led to losses of cell turgor pressure. Salt treatment was found to accelerate the rate of fluorescence quenching after maximal fluorescence yield was attained in barley, spinach, citrus and mangrove, species which accumulate both sodium and chloride into their leaves, but not in grapevine or bean, species which accumulate chloride but exclude sodium from their leaves. Stimulation of fluorescence quenching in intact chloroplasts and thylakoids isolated from spinach was induced upon addition of sodium chloride, but not sorbitol. Energy-dependent fluorescence quenching associated with establishment of a pH gradient appears to be stimulated by sodium ion in isolated chloroplasts and thylakoids. In intact leaves stimulation of fluorescence quenching is more likely a consequence of accelerated photochemical reoxidation of Q, the stable electron acceptor of photosystem II.

盐胁迫植物叶绿素荧光与水分的关系
葡萄、豆类、大麦、菠菜、柑橘(citrus myrtifolia)和红树林(Avicennia marina)叶片叶绿素a可变荧光的产量不受盐处理的影响,只有当过量离子积累导致细胞膨胀压力损失时才会下降。在大麦、菠菜、柑橘和红树林中,钠和氯化物均在其叶片中积累,盐处理加速了荧光猝灭的速度,而在葡萄和豆类中,钠和氯化物均在其叶片中积累,但不从其叶片中积累。添加氯化钠可诱导菠菜完整叶绿体和类囊体的荧光猝灭,而山梨醇则不能。与pH梯度的建立相关的能量依赖性荧光猝灭似乎是由钠离子在分离的叶绿体和类囊体中刺激的。在完整的叶片中,刺激荧光猝灭更可能是光系统II的稳定电子受体Q加速光化学再氧化的结果。
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