具有异戊二烯排放能力的植物中叶粒体膜的稳定减少了活性氧的形成。
Stabilization of thylakoid membranes in isoprene-emitting plants reduces formation of reactive oxygen species.
机构信息
Institute of Plant Physiology and Genetics, Bulgarian Academy of Sciences, Sofia, Bulgaria.
出版信息
Plant Signal Behav. 2012 Jan;7(1):139-41. doi: 10.4161/psb.7.1.18521.
Abstract
Isoprene is emitted by a significant fraction of the world's vegetation. Isoprene makes leaves more thermotolerant, yet we do not fully understand how. We have recently shown that isoprene stabilizes thylakoid membranes under heat stress. Here we show that heat-stressed, isoprene-emitting transgenic Arabidopsis plants also produce a lower pool of reactive oxygen and reactive nitrogen species, and that this was especially due to a lower accumulation of H2O2 in isoprene emitting plants. It remains difficult to disentangle whether in heat stressed plants isoprene also directly reacts with and quenches reactive oxygen species (ROS), or reduces ROS formation by stabilizing thylakoids. We present considerations that make the latter a more likely mechanism, under our experimental circumstances.
摘要
异戊二烯由世界上很大一部分植被排放。异戊二烯使叶片更能耐受高温,但我们并不完全了解其具体机制。我们最近发现,异戊二烯可在热胁迫下稳定类囊体膜。在这里,我们发现,在热胁迫下,排放异戊二烯的转基因拟南芥植物也产生了较低水平的活性氧和活性氮物种,这主要是由于异戊二烯排放植物中 H2O2 的积累较低。在热胁迫植物中,异戊二烯是否也直接与活性氧(ROS)反应并使其淬灭,或者通过稳定类囊体来减少 ROS 的形成,仍然难以区分。根据我们的实验情况,我们提出了一些考虑因素,认为后者是一种更可能的机制。
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3
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4
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5
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