研究报告

小麦悬浮细胞应答激发子刺激的过敏性反应中Ca2+和 NO的动态变化及其相互作用

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  • 河北农业大学生命科学学院, 保定 071001

? 共同第一作者

收稿日期: 2013-10-30

  录用日期: 2014-02-23

  网络出版日期: 2015-04-09

基金资助

国家自然科学基金(No.31171472)、高等学校博士学科点专项科研基金(No.20111302130001)、河北省应用基础研究计划重点基础研究(No.08965505D)和河北省自然科学基金(No.C2007000515, No.C2010000787)

Dynamics and Interaction of Ca2+ and Nitric Oxide in Wheat Suspension Cells in the Hypersensitive Response

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  • College of Life Sciences, Agricultural University of Hebei, Baoding 071001, China

? These authors contributed equally to this paper

Received date: 2013-10-30

  Accepted date: 2014-02-23

  Online published: 2015-04-09

摘要

以感染叶锈菌的小麦(Triticum aestivum)叶片细胞间隙液IWF-260作为激发子, 刺激小麦品种洛夫林10和郑州5389的悬浮细胞, 探讨由激发子引发悬浮细胞过敏性反应中Ca2+和NO的变化及相互作用。以荧光分子探针Fluo-3AM和DAF-FM DA分别对细胞内Ca2+和NO进行标记, 利用激光共聚焦扫描显微镜对其动态变化进行实时监测, 通过药物学实验对Ca2+和NO的产生机制及其可能存在的相互关系进行探讨。结果表明, 2个小麦品种悬浮细胞的[Ca2+]cyt水平对激发子刺激的反应表现出明显的差异, 对叶锈菌小种表现不亲和的洛夫林10悬浮细胞分别在激发子刺激后330秒和700秒出现2个钙峰; 而对该小种表现亲和的郑州5389悬浮细胞在激发子刺激后[Ca2+]cyt水平稍有波动但变化不明显。药物学实验证明, [Ca2+]cyt的升高依赖于胞外钙离子内流, 钙离子与激发子刺激诱发的过敏性防卫反应紧密相关。同样, 在激发子刺激后, 洛夫林10悬浮细胞出现1个NO峰, 而郑州5389悬浮细胞胞质NO变化不明显。药物学实验初步证明, NO的产生与胞外钙离子内流密切相关。由此推测, 在小麦悬浮细胞应答激发子刺激诱发的过敏性反应中, NO可能在钙的下游发挥作用。

本文引用格式

乔妹, 孙嘉炜, 陈琰, 韩胜芳, 侯春燕, 刘刚, 王冬梅 . 小麦悬浮细胞应答激发子刺激的过敏性反应中Ca2+和 NO的动态变化及其相互作用[J]. 植物学报, 2015 , 50(1) : 1 -11 . DOI: 10.3724/SP.J.1259.2015.00001

Abstract

Suspension cells of wheat varieties Lovrin 10 and Zhengzhou 5389 were stimulated with IWF-260, a leaf intercellular washing fluid induced by leaf rust. The dynamics and interaction of Ca2+ and nitric oxide (NO) in the hypersensitive response induced by IWF-260 were analysed. The fluorescence molecular probe Fluo-3AM and DAF-FM DA were used to mark Ca2+ and NO, respectively. The two kinds of suspension cells showed differences in the concentration of Ca2+. Lovrin 10, a disease-resistant variety, showed two peaks of [Ca2+]cyt, at 330 and 700 s, on stimulation, whereas Zhengzhou 5389, a susceptible variety, showed no obvious change in [Ca2+]cyt with stimulation. The increased [Ca2+]cyt depended on Ca2+ flowing into cells, which suggests that Ca2+ may be involved in the hypersensitive response. Like Ca2+, NO showed a similar pattern after elicitor stimulation. For Lovrin 10, NO showed a peak, with no change for Zhengzhou 5389. Thus, NO production and extracellular calcium influx are closely related to wheat suspension cells’ response to stimulation; NO may play a role downstream of calcium.

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