非损伤微测技术在细胞生物学研究中的应用系列讲座(一)——技术简介

非损伤微测技术是一种选择性微电极技术,可以不损伤样品而获得进出样品的离子和分子信息,具有非损伤性,长时间、多电极、多角度测量等优势.本文介绍非损伤微测技术原理和技术特点及其在细胞生物学不同领域中的应用.     

心肌细胞内外离子活度,跨膜电位,肌张力的连续记录

细胞内普通玻璃微电极记录是心肌电生理学研究的常用方法之一。目前虽已能同时进行心肌张力的测量,但以往由于在标本制备、灌流、微电极技术、张力测量等方面因素的限制,微电极在细胞内的稳定时间仍是实验成功与否的关键。近年来利用离子选择性微电极对心肌进行研究,除遇到上述问题外,还由于     

非损伤微测技术及其在环境科学领域的应用

非损伤微测技术(NMT)主要是通过计算机控制选择性微电极,测量距被测物几微米处两点的电压,然后通过校正曲线、Nernst方程和Fick第一扩散定律公式换算出离子或者分子的移动速率。它具有保持样品完整性、时间空间分辨率高及可同时测量多个位点的优势,可用于生物体内分子或者离子流实时测量。本文概述了NMT在环境科学领域应用原理与特点,就该项技术在重金属污染土壤植物修复机理、植物抗土壤盐渍化和水环境生物监测等方面的应用进行了综述,并指出该技术在环境科学领域应用的不足与前景。     

应用离子选择性电极研究植物组织及根部的离子运转

以往研究高等植物的组织或根部的离子运转,采用化学分析方法测定植物材料或外部溶液内离子浓度的变化,来观察离子运转的情况。60年代以来,发展了离子选择性电极。Hinke(1959)用玻璃微电极测定细胞内Na~+、K~+的活度。Bowling(1971)用K~+选择性的玻璃微电极插入玉米根皮层细胞的液     

多元光学蛋白质芯片研究取得重要进展

蛋白质芯片技术是一种新型蛋白质分析技术,具有集成、并行、快速和自动化分析的优势。多元光学蛋白质芯片传感器,仅需微量生理或生物采样,即可以同时检测、识别和纯化不同的生物分子和研究分子间的相互作用。无需标记,可以直接测量像血浆、细胞裂解液等生理样品。     

Ni^2＋对心肌细胞Na^＋,K^＋活度及膜钠泵活动的影响

本实验应用离子选择性微电极方法,动态监测了Ｎｉ２＋对心肌细胞Ｎａ＋、Ｋ＋活度的影响,并以细胞内Ｎａ＋逐出速率［ｄ（ａｉＮａ）／ｄｔ］作为膜钠泵活动度的指标,观察了Ｎｉ２＋对膜钠泵活动的影响。结果显示：（１）在本实验浓度下Ｎｉ２＋对静息及活动（自律或电刺激）的细胞内Ｎａ＋、Ｋ＋活度无明显影响;（２）可使细胞外Ｋ＋活度升高;（３）便刺激停止即刻细胞内Ｎａ＋逐出速率下降;（４）减小无钠无钙液引起的细胞外Ｋ＋活度下降幅度。结果提示：Ｎｉ２＋对处于高水平活动的心肌细胞膜钠泵具有明显的抑制作用,而对处于一般活动状态的膜钠泵则未见有明显影响;在Ｎｉ２＋存在下心肌细胞膜对Ｋ＋的通透性有不同程度的提高。     

活细胞成像

活细胞成像又叫作生物成像或者录像显微镜。其特征在于研究手段和测定对象。手段是显微镜或者照相机等成像器材,对象是活细胞的活动。根据测定对象的不同,或者是器官中（in vivo）,或者是培养细胞,或者是细胞中部分的细胞器、蛋白质．分别叫作生物体水平、细胞水平、分子水平。     

非损伤微测技术在植物生理学研究中的应用及进展

非损伤微测技术(NMT)是一种选择性微电极技术,可以在不损伤活体样品的情况下获得进出样品的各种离子或分子浓度、流速及其三维运动方向的信息。该技术具有非损伤性、长时间、多电极、高分辨率、高灵敏度、多角度测量等优点,可获得其他技术难以测到的生理特征和生命活动规律,从而在理论研究和应用领域产生实质性的突破。本文综述了近年来NMT在植物营养调控、抗病性、抗盐碱、抗旱、抗冷、抗重金属毒害等方面的应用及其进展,并展望了NMT在植物生理学研究中的应用前景。     

离子选择性微电极及其在生物医学中的应用

离子选择性微电极技术及其在生物医学中的应用研究是当前多学科协同攻关的热门课题。本文择要介绍了离子选择性微电极的发展简史。研究现况与发展趋势。并概述了离子选择性微电极在神经生理与电生理研究中所显示出的独特功能。     

植物生理学研究中的压力探针技术

压力探针技术是一种用来测定微系统中压力大小和变化的新技术。其最初被设计用于直接测定巨型藻类的细胞膨压。随着操作装置的进一步微型化和精密化, 后来被应用于测定普通高等植物细胞膨压及其它水分关系参数。该技术的发展建立在一系列相应的流体物理学理论基础上。通过这些物理学公式的计算, 该技术能测定跨细胞膜或器官的水分运输速度以及它们的水力学导度; 测定溶液中水分和溶质的相对运输速度以及它们之间的相互影响; 还可以测定细胞壁的刚性等。目前压力探针技术已成为植物生理学和生态学领域研究中的多用途技术。它可以在细胞水平上原位测定水分及溶质跨膜运输及分布情况, 这对于阐明水通道功能具有极其重要的意义。此外, 木质部压力探针技术是目前唯一可以直接测定导管或管胞中负压的工具。该技术还可以用于单细胞汁液的样品采集, 结合微电极技术测定导管或其它细胞中的pH值、离子浓度以及细胞膜电位。本文重点介绍该技术使用的基本原理和相应的理论基础, 并详细地描述了操作过程中的技术和技巧。     

Measurement of Extracellular Ion Fluxes Using the Ion-selective Self-referencing Microelectrode Technique

Cells from animals, plants and single cells are enclosed by a barrier called the cell membrane that separates the cytoplasm from the outside. Cell layers such as epithelia also form a barrier that separates the inside from the outside or different compartments of multicellular organisms. A key feature of these barriers is the differential distribution of ions across cell membranes or cell layers. Two properties allow this distribution: 1) membranes and epithelia display selective permeability to specific ions; 2) ions are transported through pumps across cell membranes and cell layers. These properties play crucial roles in maintaining tissue physiology and act as signaling cues after damage, during repair, or under pathological condition. The ion-selective self-referencing microelectrode allows measurements of specific fluxes of ions such as calcium, potassium or sodium at single cell and tissue levels. The microelectrode contains an ionophore cocktail which is selectively permeable to a specific ion. The internal filling solution contains a set concentration of the ion of interest. The electric potential of the microelectrode is determined by the outside concentration of the ion. As the ion concentration varies, the potential of the microelectrode changes as a function of the log of the ion activity. When moved back and forth near a source or sink of the ion (i.e. in a concentration gradient due to ion flux) the microelectrode potential fluctuates at an amplitude proportional to the ion flux/gradient. The amplifier amplifies the microelectrode signal and the output is recorded on computer. The ion flux can then be calculated by Fick’s law of diffusion using the electrode potential fluctuation, the excursion of microelectrode, and other parameters such as the specific ion mobility. In this paper, we describe in detail the methodology to measure extracellular ion fluxes using the ion-selective self-referencing microelectrode and present some representative results.     

Procedures for manufacturing double-barrelled ion-sensitive microelectrodes employing liquid sensors

Liquid ion-sensitive/selective sensors are available for most inorganic ions of physiological and biochemical importance. In order to measure intracellular ionic activities in relatively small cells, it is advisable to manufacture and use double-barrelled microelectrodes. Procedures for making two types of double-barrelled ion-sensitive microelectrode are described in detail. Such microelectrodes have been used successfully to measure intracellular K+, Cl- and Na+ activities in retinal horizontal cells of fish and body-wall muscles of insect larvae.     

Iontophoretic release of cyclic AMP and dispersion of melanosomes within a single melanophore

Selective dispersion of melanosomes was often observed after iontophoretic injection of cyclic adenosine monophosphate (AMP) from a glass microelectrode positioned in a target melanophore in frog skin (as viewed from above through a microscope), with other melanophores in the field serving as controls. Because the skin has orderly arrays of several types of closely spaced cells, it is probable that at times the microelectrode also impales cells other than melanophores. When cyclic AMP injection inside a cell resulted in dispersion of melanosomes from a perinuclear position into dendritic processes, the onset of dispersion was relatively rapid, in many cases less than 4 min (mean time of onset, 5.3 +/- 2.9 [SD] min). A much slower dispersion (mean time of onset, 19.0 +/- 5.0 min) of melanosomes was observed when the microelectrode was positioned adjacent to a melanophore, and much larger quantities of cyclic AMP were released. In addition, no changes were observed for injections of 5'-AMP or cyclic guanosine monophosphate (GMP) through electrodes positioned inside or adjacent to melanophores. Potential measurements showed that after impaling a clell, a constant transmembrane potential could often be recorded over many minutes, indicating that the membrane tends to seal around the microelectrode. The results indicate that cyclic AMP acts more rapidly on the inside of a cell than when applied outside a cell and allowed to diffuse through the plasma membrane. This study introduces a model system whereby the properties of the plasma membrane and melanocyte-stimulating hormone (MSH) receptors can be studies within a single target cell.     

Application of spin-echo nuclear magnetic resonance to whole-cell systems. Membrane transport.

A new method for studying membrane transport is presented. High resolution n.m.r. is used to measure the distribution of small molecules between the intracellular and extracellular compartments. The method uses spin-echo techniques and relies on a difference in the magnetic susceptibility of the media inside and outside of cells. It also provides simultaneous information on the metabolic status of the cell. The method is illustrated by a study of alanine and lactate transport in the human erythrocyte.     

P-糖蛋白结构及作用机制

ABC (ATP-binding cassette) 转运蛋白广泛存在于各种生物体细胞中,例如细菌的内层细胞浆膜和真核生物的细胞膜和细胞器膜.其利用与ATP的结合和水解供能进行底物的跨膜转运,其中一部分ABC转运蛋白能转运多种疏水性分子.P-糖蛋白隶属于ABC转运蛋白超家族,是研究最为透彻的一员,主要功能是防止机体对外来有害物质的摄入.P-糖蛋白(P-glycoprotein)由4 个基本结构域组成,2 个跨膜区和2 个位于细胞浆内的核苷酸结合区.核苷酸结合区参与ATP的结合和水解,而各由6 个α 跨膜螺旋组成的2个跨膜区联合构成了底物跨膜转运的通道.P 糖蛋白能转运多种不同结构的底物,包括脂类、胆汁酸、多肽和外源性化学物质,这对机体的生存至关重要,但同时也存在不利的一面,包括干扰了药物的运输,从而导致了多药耐药现象的产生.本文就P-糖蛋白的分子结构和作用机制的最新研究进展进行综述.     

Monitoring of dopamine release in single cell using ultrasensitive ITO microsensors modified with carbon nanotubes

The study of single cell dynamics has been greatly adapted in biological and medical research and applications. In this work a novel microfluidic electrochemical sensor with carbon nanotubes (CNTs) modified indium tin oxide (ITO) microelectrode was developed for single cells release monitoring. The sensitivity of the electrochemical sensor after CNTs surface modification was improved by 2.5-3 orders of magnitude. The developed CNTs modified ITO sensor was successfully employed to monitor the dopamine release from single living rat pheochromocytoma (PC 12) cells. Its ultrahigh sensitivity, transparency and need for fewer agents enable this smart electrochemical sensor to become a powerful tool in recording dynamic release from various living tissues and organs optically and electrically.     

Quantitative 3-D imaging of eukaryotic cells using soft X-ray tomography

Imaging has long been one of the principal techniques used in biological and biomedical research. Indeed, the field of cell biology grew out of the first electron microscopy images of organelles in a cell. Since this landmark event, much work has been carried out to image and classify the organelles in eukaryotic cells using electron microscopy. Fluorescently labeled organelles can now be tracked in live cells, and recently, powerful light microscope techniques have pushed the limit of optical resolution to image single molecules. In this paper, we describe the use of soft X-ray tomography, a new tool for quantitative imaging of organelle structure and distribution in whole, fully hydrated eukaryotic Schizosaccharomyces pombe cells. In addition to imaging intact cells, soft X-ray tomography has the advantage of not requiring the use of any staining or fixation protocols—cells are simply transferred from their growth environment to a sample holder and immediately cryofixed. In this way the cells can be imaged in a near native state. Soft X-ray tomography is also capable of imaging relatively large numbers of cells in a short period of time, and is therefore a technique that has the potential to produce information on organelle morphology from statistically significant numbers of cells.     

Novel synthesis scheme and in vitro antimicrobial evaluation of a panel of (E)-2-aryl-1-cyano-1-nitroethenes

Drug resistance has become a major concern in the field of infection management, therefore searching for new antibacterial agents is getting more challenging. Our study presents an optimized and eco-friendly synthesis scheme for a panel of nitroalkenes bearing various functional groups in the aromatic moiety and bromine or cyano substituents in 1 position of nitrovinyl moiety. The presence of nitrolefine group outside the ring minimalizes genotoxic properties while conjugation of aryl group with nitrovinyl moiety increases stability of the compounds. Then our research focused on evaluation of biological properties of such obtained (E)-2-aryl-1-cyano-1-nitroethenes. As they exhibit strong bacteriostatic and bactericidal activities against reference bacteria and yeast species with no detectable cytotoxicity towards cultured human HepG2 and HaCaT cells, they could be promising candidates for the replacement of traditional nitrofurane-containing antibacterial drugs. Nevertheless, validation of the obtained data in an in vivo model and additional safety studies on mutagenicity are still required.     

Application of Non-invasive Microsensing System to Simultaneously Measure Both H^＋ and O2 Fluxes Around the Pollen Tube

Various Ionic and molecular activities in the extraceUular environment are vital to plant cell physiological processes. A noninvasive microsensing system （NMS） based on either the scanning ion-selective electrode technique （SIET） or the scanning polarographlc electrode technique （SPET） is able to obtain information regarding the transportation of various Ions/molecules in Intact samples under normal physiological conditions. The two-probe simultaneous test system （2STS） Is an Integrated system composed of SIET, SPET, and a Xu-Kunkel sampling protocol. In the present study, 2STS was able to simultaneously measure fluxes of H^＋ and O2 of the Uly （Lillum Iongiflorum Thunb. cv. Ace） pollen tube while avoiding interference between the two probes. The results Indicate that the proton fluxes were effluxes, whereas the oxygen fluxes were Influxes, and they were closely correlated to each other surrounding the constitutive alkaline band region. Specifically, when the proton effluxes increased, the oxygen Influxes also increased. Therefore, the hypothesis of condensed active mitochondria existing in the alkalized area of the pollen tube proposed by Hepler＇s group is supported.     

Steroid analysis in single cells by capillary electrophoresis with collinear laser-induced fluorescence detection.

Capillary electrophoresis with collinear laser-induced fluorescence detection was used for the analysis of steroids in single R2C cells. Progesterone secretion was monitored from cultured cells and subsequently detected in single cells. Mass detection limit of 10(-18) mol for dansylated steroids was achieved with the 325-nm line of a helium-cadmium laser. Dansylhydrazine proved to be an effective fluorescent tag for derivatization of steroids outside and inside the biological cell. Fluorescence microscopy indicates that a dimethyl sulfoxide-containing physiological buffer was sufficient to incorporate the tag inside the cell for subsequent steroid derivatization.