用脱落酸受体PYL2修饰的微电极上的安培计实时监测单个水稻原生质体的脱落酸释放情况

IF 4.8 2区化学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Bioelectrochemistry Pub Date : 2024-05-15 DOI:10.1016/j.bioelechem.2024.108733

Yunhua Wu , Liuzhe Hu , Lvliang Wu , Yong Yang , Yong Li

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引用次数: 0

摘要

之前有报道称胁迫会诱导植物细胞产生脱落酸，但没有直接的方法可以证明这一点。本文通过自组装方法制备了一种脱落酸受体PYL2修饰碳纤维微电极的电化学微传感器，以微电极表面PYL2的组氨酸标签结合Cu2+作为检测探针，Cu+与铁氰化物的介导反应实现了放大反应，使该微传感器对脱落酸的检测灵敏度较高，检测限为0.8 nM。利用这种微传感器，可以实时监测单个水稻原生质体在硫酸盐、渗透压和盐度胁迫下细胞外赤霉酸的增加。直接测量单个植物细胞中游离的细胞外赤霉酸可为了解赤霉酸在受到非生物胁迫的植物中的作用提供重要的新见解。

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Real-time monitoring abscisic acid release from single rice protoplast by amperometry at microelectrodes modified with abscisic acid receptor PYL2

It was previously reported that stress induces a cellular production of abscisic acid in plants, but no direct method shows the evidence. Here, an electrochemical microsensor involving an abscisic acid receptor PYL2 modified carbon fiber microelectrode was fabricated by self-assembly method, where the Cu²⁺ combined with the histidine tag of PYL2 on the surface of microelectrode was used as the detection probe, the mediated reaction between Cu⁺ and ferricyanide realized the amplification responses and provided the microsensor with a high sensitivity for detection of abscisic acid with a detection limit of 0.8 nM. With use of this microsensor, an increase of extracellular abscisic acid from single rice protoplast induced by sulfate, osmotic and salinity stress was real-time monitored. Direct measurement of free extracellular abscisic acid in single plant cells might offer important new insights into its role in plants challenged by abiotic stresses.

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来源期刊

Bioelectrochemistry 生物-电化学

CiteScore

9.10

自引率

6.00%

发文量

238

审稿时长

38 days

期刊介绍： An International Journal Devoted to Electrochemical Aspects of Biology and Biological Aspects of Electrochemistry Bioelectrochemistry is an international journal devoted to electrochemical principles in biology and biological aspects of electrochemistry. It publishes experimental and theoretical papers dealing with the electrochemical aspects of: • Electrified interfaces (electric double layers, adsorption, electron transfer, protein electrochemistry, basic principles of biosensors, biosensor interfaces and bio-nanosensor design and construction. • Electric and magnetic field effects (field-dependent processes, field interactions with molecules, intramolecular field effects, sensory systems for electric and magnetic fields, molecular and cellular mechanisms) • Bioenergetics and signal transduction (energy conversion, photosynthetic and visual membranes) • Biomembranes and model membranes (thermodynamics and mechanics, membrane transport, electroporation, fusion and insertion) • Electrochemical applications in medicine and biotechnology (drug delivery and gene transfer to cells and tissues, iontophoresis, skin electroporation, injury and repair). • Organization and use of arrays in-vitro and in-vivo, including as part of feedback control. • Electrochemical interrogation of biofilms as generated by microorganisms and tissue reaction associated with medical implants.