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高压纳秒脉冲电场的细胞器生物电效应综述

郭雨怡 石富坤 王群 季振宇 庄杰

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高压纳秒脉冲电场的细胞器生物电效应综述

郭雨怡, 石富坤, 王群, 季振宇, 庄杰

A review on bioelectrical effects of cellular organelles by high voltage nanosecond pulsed electric fields

Guo Yu-Yi, Shi Fu-Kun, Wang Qun, Ji Zhen-Yu, Zhuang Jie
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  • 纳秒级高压脉冲电场的生物医学应用是近年来新兴的交叉学科研究领域, 相比于微秒和毫秒级脉冲电场, 高压纳秒脉冲电场不仅能够导致细胞膜结构极化和介电击穿, 产生膜电穿孔, 还可以穿透至细胞内部, 引发诸如细胞骨架解聚、胞内钙离子释放及线粒体膜电位耗散等细胞器生物电效应, 吸引了学术界的广泛关注. 本文首先介绍高压纳秒脉冲电场及其细胞器生物电作用的物理模型; 然后对高压纳秒脉冲电场与细胞骨架、线粒体、内质网、细胞核等亚细胞结构的相互作用研究进行综述和总结; 强调高压纳秒脉冲电场的细胞器作用与细胞死亡、细胞间通信等生物效应之间的联系; 最后, 凝练当前高压纳秒脉冲电场在生物医学研究中的关键技术问题, 并对未来潜在的研究方向进行展望.
    The biomedical application of high-voltage nanosecond pulsed electric fields (nsPEFs) has become an emerging interdisciplinary research field in recent years. Compared with microsecond and millisecond pulsed electric fields, high-voltage nsPEFs can not only lead the cell membrane structure to polarize and dielectric break down the cell membrane structure, i.e. membrane electroporation, but also penetrate into the cell, triggering off organelle bioelectrical effects such as cytoskeleton depolymerization, intracellular calcium ion release, and mitochondrial membrane potential dissipation. Extensive attention has been attracted from related academic communities. In this article, the following aspects are involved. First, the physical model of high-voltage nsPEFs and its bioelectrical effects on cellular organelles are introduced. Then, the existing researches of the interactions of high-voltage nsPEFs with cytoskeleton, mitochondria, endoplasmic reticulum, cell nucleus and other subcellular structure are reviewed and summarized; the relationship between the influence on cellular organelles by high-voltage nsPEFs and the biological effects such as cell death and intercellular communication is highlighted. Finally, the key technical challenges to high-voltage nsPEFs in biomedical research are condensed, followed by the prospects of future research directions.
      通信作者: 庄杰, jzhuang@sibet.ac.cn
    • 基金项目: 国家重点研发计划(批准号: 2019YFC0119102, 2019YFC0118004, 2020YFC0122301)资助的课题
      Corresponding author: Zhuang Jie, jzhuang@sibet.ac.cn
    • Funds: Project supported by the National Key R&D Program of China (Grant Nos. 2019YFC0119102, 2019YFC0118004, 2020YFC0122301) .
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  • 图 1  PEFs导致的细胞膜EP示意图

    Fig. 1.  Schematic diagram of PEF-induced membrane electroporation.

    图 2  PEFs中哺乳动物细胞等效电路模型

    Fig. 2.  Equivalent circuit model for the mammalian cells with the exposure to PEFs, where individual subcellular components are described by a combination of the resistor or capacitor.

    图 3  NsPEFs细胞器效应的文献发表情况

    Fig. 3.  Literature research about the intracellular effects for cells exposured to nsPEFs.

    图 4  NsPEFs对贴壁细胞的影响. 1, 破坏细胞与细胞间连接; 2, 细胞膜电穿孔; 3, 细胞脱落

    Fig. 4.  Effect of nsPEFs on adherent cells. 1, Disruption of the intercallular connections; 2, electroporation; 3, cell necrosis or shedding.

    图 5  NsPEFs诱导的细胞内凋亡途径

    Fig. 5.  Apoptosis pathways for cells after exposure to nsPEFs

    表 1  nsPEFs的细胞器生物电效应总结

    Table 1.  Summary of effects of nsPEFs on cell organelles.

    细胞器细胞类型脉冲宽度/ns电场强度/(kV·cm–1)主要结果概述
    细胞骨架GH3, HeLa[47]6012肌动蛋白丝变短、变细、碎片化、解聚、收缩、分离, 细胞弹性降低;
    微管屈曲、解聚、破碎;
    微管聚合速率和聚合数量发生变化;
    中间丝破坏;
    细胞通透性改变;
    细胞肿胀、起泡、细胞质颗粒化;
    细胞间通讯受抑制;
    细胞骨架的破坏受钙离子调控: 1)高钙离子浓度溶液中, nsPEFs处理会使微管解聚, 破坏肌动蛋白丝; 2) 低钙离子浓度溶液中, nsPEFs处理后微管显示正常结构
    BY-2[48]1033
    Jurkat, HeLa, SV40[49]6015, 60
    CHO-K1[50]60019.2
    Jurkat, U937, CHO-K1[51]10150
    WB-F344[52]1005—35
    U87-MG[53]10, 10044
    CHO[54]60016.2
    GUV[55]3—10
    tubulin[56]1020
    U2OS[57]
    CHO-K1[58]10, 6027.7, 150
    HepG2[59]4508
    B16-F10[60]30012, 18, 26, 40, 60
    WB-F344, WB-Ras[61]10020
    U-937[62]6010
    线粒体Jurkat[63]600—60线粒体膜通透性改变, 线粒体的通透性转换孔(MPTP)不可逆过度开放;
    线粒体膜电位损失;
    线粒体肿胀;
    线粒体膜蛋白受影响, 线粒体膜间隙蛋白 Cyt-C, AIF 释放入胞浆;
    调控线粒体凋亡途径, Caspase-3表达量增加, Bax 表达量增加;
    线粒体释放细胞色素C;
    影响线粒体信号传导途径;
    ATP消耗;
    胞内ROS水平升高
    N1-S1[36]6000—80
    Jurkat, U-937[46]1050, 150
    Jurkat[64]6000—60
    HeLa S3[65]8020
    HCT116, NCM460[66]10, 600, 8003, 4, 5
    Jurkat, B10-2[67]10—300≤ 300
    Jurkat, HL-60[68]10, 60, 300150, 60, 25
    Jurkat, HL-60[34]10—30015—60
    Hela[69]10, 20, 30, 5040, 45
    CT-26 tumor cells[70]1022
    MCA205, McA-RH7777,
    JurkatE6-1[71]
    1006—25
    4T1[72]10046—54
    内质网Jurkat[73]7, 10, 3025内质网穿孔、损伤;
    钙离子释放, 引发胞内钙离子浓度升高;
    内质网应激响应;
    免疫原性细胞死亡;
    肿瘤细胞内与内质网凋亡相关蛋白Caspase-3的释放量增加;
    内质网凋亡信号通路起作用
    Jurkat, HL-60[74]60, 30015—60
    Jurkat, HL-60[75]10, 60, 30026, 40, 60, 150, 300 (10 ns); 16, 26, 40, 60 (60 ns); 40 (300 ns)
    Newly outdated platelet[76]3000—30
    Cardiac cells from rats[77]410—80
    Jurkat[15]6025, 50, 100
    NG108-15[78]416.2
    CHO-K1[79]603.7—30
    U937, CHO-K1, BPAE[80]300
    HeLa, HEK293T, C2C12[40]7, 10, 2010—50
    HeLa, HEK293, MEF[81]1410, 20, 25, 30, 40, 50
    MG63[82]606.7, 13.3, 16.7, 20,
    26.7, 33.3
    HeLa, MEF[83]14, 7080, 100 (14 ns), 30, 50, 70, 75 (70 ns)
    Bovine chromaffin cells [84]5170
    B16 F10, EL-4[39]2007
    Hela[85]20, 500100, 20
    Murine secondary oocytes [86]104—10
    MEF[87]60—30030, 60
    CHO-K1, NG108[88]300, 6003.7, 7.4, 11, 1
    细胞核HL-60[89]10, 6065 (10 ns), 25 (60 ns)核膜穿孔;
    DNA双链破坏、DNA片段化;
    选择性降低DNA甲基化;
    核蛋白复合物改变, 抑制snRNA的生成, 改变亚核结构
    B16 F10[18,90,91]30040
    Jurkat[92]10150
    Jurkat, U-937[93]10, 3002.25, 4.5, 150, 290
    B16F10[60]3000—60
    E4 squamous cell [94]3000—60
    Jurkat[16]6010, 15, 25
    N1-S1[17]6000—80
    N1-S1[95]10050
    CHO[58]10, 60018.2, 27.7, 16.7
    HEK 293[96]30025.5
    HL-60[36]8020
    K562, CT26. WT[97]60050
    HL60, Jurkat, ALL[98]10, 60, 30026, 60, 150, 300
    B10-2, HL-60[99]10, 50, 60, 30026, 60, 75, 150
    溶酶体CHO-K1[41]1, 20, 60016.2溶酶体去膜化、溶酶体损伤;
    溶酶体运动受影响, 高钙离子浓度溶液下, 溶酶体迁移停止;
    CHO-K1[42]60016.2
    囊泡Human eosinophils [100]6036, 53囊泡穿孔;
    诱导细胞外囊泡的释放
    COS-7[101]5020—300
    下载: 导出CSV
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出版历程
  • 收稿日期:  2021-10-05
  • 修回日期:  2021-11-23
  • 上网日期:  2022-01-26
  • 刊出日期:  2022-03-20

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