多胺与 ROS 在诱导根系 Ca(2+)和 K(+)流中的协同作用。
Synergism between polyamines and ROS in the induction of Ca ( 2+) and K (+) fluxes in roots.
机构信息
Centro Universitario de Investigaciones Biomédicas, Universidad de Colima, Colima, México.
出版信息
Plant Signal Behav. 2012 Sep 1;7(9):1084-7. doi: 10.4161/psb.21185. Epub 2012 Aug 17.
Abstract
Stress conditions cause increases in ROS and polyamines levels, which are not merely collateral. There is increasing evidence for the ROS participation in signaling as well as for polyamine protective roles under stress. Polyamines and ROS, respectively, inhibit cation channels and induce novel cation conductance in the plasma membrane. Our new results indicate that polyamines and OH (•) also stimulate Ca ( 2+) pumping across the root plasma membrane. Besides, polyamines potentiate the OH (•) -induced non-selective current and respective passive K (+) and Ca ( 2+) fluxes. In roots this synergism, however, is restricted to the mature zone, whereas in the distal elongation zone only the Ca ( 2+) pump activation is observed. Remodeling the plasma membrane ion conductance by OH (•) and polyamines would impact K (+) homeostasis and Ca ( 2+) signaling under stress.
摘要
应激条件会导致 ROS 和多胺水平的增加,而这两者并非偶然。越来越多的证据表明,ROS 参与信号转导,多胺在应激下也具有保护作用。多胺和 ROS 分别抑制阳离子通道并在质膜中诱导新型阳离子电导。我们的新结果表明,多胺和 OH(•)也会刺激 Ca(2+)穿过根质膜的泵送。此外,多胺会增强 OH(•)诱导的非选择性电流以及相应的被动 K(+)和 Ca(2+)流。然而,在根中,这种协同作用仅限于成熟区,而在远轴伸长区仅观察到 Ca(2+)泵的激活。OH(•)和多胺重塑质膜离子电导会影响应激下的 K(+)稳态和 Ca(2+)信号转导。
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本文引用的文献
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