利用锌特异性探针HL1示踪植物细胞外Zn2+的分布

doi:10.11983/CBB16196

摘要/Abstract

摘要： 以拟南芥(Arabidopsis thaliana)和谷子(Setaria italic)为研究材料, 利用锌特异性探针HL¹, 使用荧光分光光度仪、等温滴定热量测定仪(ITC200)和倒置荧光显微镜等仪器探究了该化学探针的特性以及植物细胞外游离Zn²⁺的分布。结果表明, 当HL¹与不同元素溶液混合时, 只与Zn²⁺特异性结合, 在紫外光(UV)激发下, 发射出波长为500 nm的蓝色荧光; 生成物的平衡解离常数K_D=7.02×10^-4 mol·L^-1, 具有很好的稳定性。拟南芥叶片中的Zn²⁺分布于细胞间隙及叶表皮毛的外周和表层, 且叶表皮毛的荧光强度具有明显的浓度依赖性; 谷子叶片中的Zn²⁺分布在细胞间隙以及维管组织。拟南芥根中的Zn²⁺分布于根的伸长区, 且荧光强度也明显地表现出与浓度相关。由此推断, 根伸长区与Zn²⁺运输有关, 叶的维管组织是植物细胞外运输Zn²⁺的主要途径, 细胞间隙和叶表皮毛是植物储存Zn²⁺的主要区域。HL¹适用于检测细胞外Zn²⁺的分布。

关键词: 锌, 蓝色荧光, 叶表皮毛, 维管组织, 细胞间隙

Abstract: We chose Arabidopsis thaliana and Setaria italic as material to study the character of HL¹ that can specifically combine with zinc, and the distribution of extracellular Zn²⁺ by using fluorescence spectrophotometry, isothermal titration calorimetry (ITC200) and inverted fluorescence microscopy. Fluorescence intensity for HL¹ was greatly enhanced with the addition of Zn²⁺ but not other ions. The dissociation constant (K_D=7.02×10^-4 mol·L^-1) exhibited product stability with the combined reaction of HL¹ and Zn²⁺. In A. thaliana, the distribution of extracellular free Zn²⁺was mainly located in leaf intercellular space and surface of the trichome where fluorescence intensity was corresponding to the concentration of Zn²⁺. The distribution of Zn²⁺were located in intercellular space and fibrovascular tissue in the leaf of S. italic. The root of elongation zone was existing the blue fluorescence corresponded to the presence and concentration of Zn²⁺. The root elongation zone relates to Zn²⁺ transportation, and the leaf intercellular space and trichome surface are related to Zn²⁺storage. In conclusion, Investigation of extracellular free Zn²⁺by using HL¹is efficient.

Key words: zinc, blue fluorescence, leaf trichome, vascular tissue, intercellular space

姚宏伟, 刘洋, 程宇来, 于海洋, 刘志亮, 杨菊. 利用锌特异性探针HL¹示踪植物细胞外Zn²⁺的分布. 植物学报, 2017, 52(5): 608-614.

Hongwei Yao, Yang Liu, Yulai Cheng, Haiyang Yu, Zhiliang Liu, Ju Yang. Fluorescence Imaging of the Extracellular Zinc Distribution in Plants by Using a Highly Specific Fluorescent Probe. Chinese Bulletin of Botany, 2017, 52(5): 608-614.

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链接本文: https://www.chinbullbotany.com/CN/10.11983/CBB16196

https://www.chinbullbotany.com/CN/Y2017/V52/I5/608

图/表 7

图1 HL1的结构

Figure 1 The structure of HL1

图2 HL1的特异性及对Zn2+结合的敏感性(A) 1 mmol·L-1不同元素与HL1探针结合后在500 nm处的荧光强度; (B) 不同Zn2+浓度下的荧光强度(a: 1 mmol∙L-1 Zn2+; b: 0.5 mmol∙L-1 Zn2+; c: 0.1 mmol∙L-1 Zn2+; d: 0.05 mmol∙L-1 Zn2+; e: 0.01 mmol∙L-1 Zn2+)

Figure 2 Specific and sensitivity of combination of HL1 and Zn2+(A) Fluorescence intensity of different element (1 mmol∙L-1) in presence of ligand HL1 (1 mmol∙L-1) at 500 nm; (B) Plot of fluorescence intensity against different concentration of Zn2+ at 500 nm (a: 1 mmol∙L-1 Zn2+; b: 0.5 mmol∙L-1 Zn2+; c: 0.1 mmol∙L-1 Zn2+; d: 0.05 mmol∙L-1 Zn2+; e: 0.01 mmol∙L-1 Zn2+)

图3 利用ITC200检测HL1与Zn2+的反应

Figure 3 ITC200 detection plot of combination of HL1 and Zn2+

图4 拟南芥叶细胞外Zn2+分布荧光图像(A) 用不同浓度ZnSO4溶液及HL1溶液处理成熟的拟南芥叶片, a1和a2为对照, b1和b2处理ZnSO4溶液浓度为0.3 μmol∙L-1, c1和c2处理ZnSO4溶液浓度为3 μmol∙L-1, d1和d2处理ZnSO4溶液浓度为30 μmol∙L-1, e1和e2处理ZnSO4溶液浓度为300 μmol∙L-1; (B) 不同浓度ZnSO4溶液及HL1溶液处理下的拟南芥叶表皮毛的荧光强度, 其中a为对照, b、c、d和e分别为叶表皮毛在Zn2+浓度为0.3、3、30和300 μmol∙L-1时的荧光强度。蓝色荧光代表Zn2+, 红色荧光代表叶绿素。Bar=100 μm

Figure 4 Fluorescence imaging showing the distribution of extracellular Zn2+ in Arabidopsis leaves(A) Mature Arabidopsis leaves pre-treated with different concentrations of ZnSO4 and HL1 (1 mmol∙L-1) for 4 h, a1 and a2 for control, b1 and b2 for 0.3 μmol∙L-1 ZnSO4, c1 and c2 for 3 μmol∙L-1 ZnSO4, d1 and d2 for 30 μmol∙L-1 ZnSO4, e1 and e2 for 300 μmol∙L-1 ZnSO4; (B) The fluorescence intensity of trichome in Arabidopsis leaf with different concentration of ZnSO4 and HL1 (1 mmol∙L-1) for 4 h, a for control, b for 0.3 μmol∙L-1 ZnSO4, c for 3 μmol∙L-1 ZnSO4, d for 30 μmol∙L-1 ZnSO4, and e for 300 μmol∙L-1 ZnSO4. Blue fluorescence represents Zn2+ and red fluorescence for chlorophyll. Bar=100 μm

图5 植物细胞在1 mmol∙L-1 HL1下的荧光图像蓝色荧光代表Zn2+, 红色荧光代表叶绿素。Bar=50 μm

Figure 5 Fluorescence image of plant cell in presence of 1 mmol∙L-1 HL1Blue represents Zn2+ and red for chlorophyll. Bar=50 μm

图6 拟南芥根细胞外Zn2+分布荧光图像(A) 分别用不同浓度的ZnSO4溶液与HL1溶液共处理2 cm左右的拟南芥根, 处理时间为4小时, 其中A1为对照, A2和A3中Zn2+浓度分别为30和300 μmol∙L-1 (Bar=100 μm); (B) A1、A2和A3分别对应处理液Zn2+浓度0、30和300 μmol∙L-1下的荧光强度。蓝色荧光代表Zn2+。

Figure 6 Fluorescence images showing the distribution of extracellular Zn2+ in Arabidopsis roots(A) Two-centimeter-long Arabidopsis root pre-treated with different concentrations of ZnSO4 and HL1 (1 mmol∙L-1) for 4 h, A1, A2, and A3 for control, 30 μmol∙L-1 ZnSO4 and 300 μmol∙L-1 ZnSO4, respectively (Bar=100 μm); (B) A1, A2, and A3 corresponding to the fluorescence intensity of Arabidopsis root treated with different concentrations of ZnSO4 for 0, 30, and 300 μmol∙L-1. Blue fluorescence represents Zn2+.

图7 谷子叶片细胞外Zn2+分布荧光图像(A) 叶中央; (B) 叶边缘; (C) 叶尖。蓝色荧光代表Zn2+, 红色荧光代表叶绿素。Bar=100 μm

Figure 7 Fluorescence images showing the distribution of extracellular Zn2+ in Setaria italic leaves(A) The center of leaf; (B) The margin of leaf; (C) The apex of leaf. Blue fluorescence represents Zn2+ and red fluorescence for chlorophyll. Bar=100 μm

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利用锌特异性探针HL¹示踪植物细胞外Zn²⁺的分布

Fluorescence Imaging of the Extracellular Zinc Distribution in Plants by Using a Highly Specific Fluorescent Probe

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