Single-cell electroporation

Electroporation is a widely used method for the introduction of polar and charged agents such as dyes, drugs, DNA, RNA, proteins, peptides, and amino acids into cells. Traditionally, electroporation is performed with large electrodes in a batch mode for treatment of a large number of cells in suspension. Recently, microelectrodes that can produce extremely localized electric fields, such as solid carbon fiber microelectrodes, electrolyte-filled capillaries and micropipettes as well as chip-based microfabricated electrode arrays, have proven useful to electroporate single cells and subcellular structures. Single-cell electroporation opens up a new window of opportunities in manipulating the genetic, metabolic, and synthetic contents of single targeted cells in tissue slices, cell cultures, in microfluidic channels or at specific loci on a chip-based device.     

电穿孔技术在转基因及动物克隆中的应用

电穿孔技术利用电场造成细胞膜的改变而将DNA导入细胞内,它还可用于细胞融合及动物克隆等。基因电转移的效率通常比化学法提高1—2个数量级,主要与脉冲波形、长度、缓冲液等有关。方波直流电脉冲应用广泛,在有关细胞核移植的多项研究报告中均指出它有重要作用。     

A nonuniform electrical field electroporation chamber design

We show an inexpensive design for an electroporation chamber which subjects electroporated cells to a nonuniform electrical field. Our design, which we call an electroporation cylinder, improved transfection efficiency over that of a uniform field design (electroporation cuvettes) by about sixfold when tested in five mouse cell lines with a transient gene expression assay. Electroporation cylinders subjected cells to electrical field strengths at least as powerful as those of electroporation cuvettes, as judged by comparing the percentages of cells killed by electroporation. Cylinder and cuvette designs were similar in their effect on the variability of transfection efficiency. Electroporation cylinders may be particularly useful when the optimal electrical field strength for a cell line is not known or is unattainable with a given power supply.     

Volume changes of isolated human K562 leukemia cells induced by electric field pulses

Electropermeabilization of immobilized human leukemia K562 cells was studied by measuring changes in cell volume. Such changes reflect mass transfer between the cell and external medium. Electropermeabilization was carried out in an isosmotic water-sorbitol medium with a range of electric field strengths from 500 to 800 V. cm(-1), corresponding to low-energy levels. Electroporation of the K562 cell membrane was found to provoke an inflow of sorbitol and a corresponding osmotic inflow of water and/or an outflow of intracellular solutes due to Fick diffusion. Such flows were found to involve the shrinkage, swelling, or rupture of K562 cells, depending on the characteristics of the electric field and of the physiological state of cells. The behavior of immobilized cells was observed during their exposure to the electric field. The response in immobilized cell volume corresponded with the theoretical pore size and pore opening time, permitting an explanation of the behavior of cell suspensions subject to electrical fields.     

Optimization of electroporation for transfection of mammalian cell lines

Electroporation can be a highly efficient method for introducing DNA molecules into cultured cells for transient expression of genes or for permanent genetic modification. However, effective transformation by electroporation requires careful optimization of electric field strength and pulse characteristics. We have used the transient expression of the firefly luciferase gene as a rapid and sensitive indicator of gene expression to describe the effects on transfection efficiency of altering electroporation field strength and shape. Using the luciferase assay, we investigated the correlation of cell viability with optimal transfection efficiency and determined the optimal parameters for a number of phenotypically distinct mammalian cell lines derived from the nervous and immune systems. The efficiency of electroporation under optimal conditions was compared with that obtained using DEAE-dextran or calcium phosphate-mediated transformation. Transfection by electroporation using square wave pulses, as opposed to exponentially decaying pulses, was found to be significantly increased by repetitive pulses. These methods improve the ability to obtain high efficiency gene transfer into many mammalian cell types.     

Efficient in situ electroporation of mammalian cells grown on microporous membranes.

Electroporation is a common technique for the introduction of DNA molecules into living cells. The method is currently limited by the necessity of applying the electrical discharge to cells in suspension. Adherent cells must therefore be removed from their substratum, which can induce unwanted physiological effects. We report here a new procedure for in situ electroporation of cells grown on microporous membranes of polyethylene terephthalate (PET) or polyester (PE). We demonstrate that this method of in situ electroporation employs only readily available materials and standard electroporation devices without any modifications, is as efficient as conventional electroporation of cells in suspension, and is applicable to a wide range of cell types. Efficient electroporation can be achieved under conditions of minimal cell killing, and can be performed with quiescent cells as well as with confluent epithelial sheets. The method is a useful extension of electroporation technology, and will allow the application of electroporation to a wider spectrum of biological systems.     

Single-cell electroporation for gene transfer in vivo

We report an electroporation technique for targeting gene transfer to individual cells in intact tissue. Electrical stimulation through a micropipette filled with DNA or other macromolecules electroporates a single cell at the tip of the micropipette. Electroporation of a plasmid encoding enhanced green fluorescent protein (GFP) into the brain of intact Xenopus tadpoles or rat hippocampal slices resulted in GFP expression in single neurons and glia. In vivo imaging showed morphologies, dendritic arbor dynamics, and growth rates characteristic of healthy cells. Coelectroporation of two plasmids resulted in expression of both proteins, while electroporation of fluorescent dextrans allowed direct visualization of transfer of molecules into cells. This technique will allow unprecedented spatial and temporal control over gene delivery and protein expression.     

Microfluidic formation of single cell array for parallel analysis of Ca release-activated Ca (CRAC) channel activation and inhibition

High-throughput single cell analysis is required for understanding and predicting the complex stochastic responses of individual cells in changing environments. We have designed a microfluidic device consisting of parallel, independent channels with cell-docking structures for the formation of an array of individual cells. The microfluidic cell array was used to quantify single cell responses and the distribution of response patterns of calcium channels among a population of individual cells. In this device, 15 cell-docking units in each channel were fabricated with each unit containing 5 sandbag structures, such that an array of individual cells was formed in 8 independent channels. Single cell responses to different treatments in different channels were monitored in parallel to study the effects of the specific activator and inhibitor of the Ca²⁺ release-activated Ca²⁺ (CRAC) channels. Multichannel detection was performed to obtain the response patterns of the population of cells within this single cell array. The results demonstrate that it is possible to acquire single cell features in multichannels simultaneously with passive structural control, which provides an opportunity for high-throughput single cell response analysis in a microfluidic chip.     

Ion channel electrophysiology via integrated planar patch-clamp chip with on-demand drug exchange

Planar patch clamp has revolutionized characterization of ion channel behavior in drug discovery primarily via advancement in high throughput. Lab use of planar technology, however, addresses different requirements and suffers from inflexibility to enable wide range of interrogation via a single cell. This work presents integration of planar patch clamp with microfluidics, achieving multiple solution exchanges for tailor-specific measurement and allowing rapid replacement of the cell-contacting aperture. Studies via endogenously expressed ion channels in HEK 293T cells were commenced to characterize the device. Results reveal the microfluidic concentration generator produces distinct solution/drug combination/concentrations on-demand. Volume-regulated chloride channel and voltage-gated potassium channels in HEK 293T cells immersed in generated solutions under various osmolarities or drug concentrations show unique channel signature under specific condition. Excitation and blockage of ion channels in a single cell was demonstrated via serial solution exchange. Robustness of the reversible bonding and ease of glass substrate replacement were proven via repeated usage of the integrated device. The present approach reveals the capability and flexibility of integrated microfluidic planar patch-clamp system for ion channel assays.     

Quantitative Proteomic Analysis of Cell Responses to Electroporation,a Classical Gene Delivery Approach

Electroporation, as an established nonviral technology for breaching cell membrane, has been accepted for the delivery of nucleic acids. Despite satisfactory delivery efficiencies have been achieved on multiple cell kinds by simply exhausting all possible electrical parameters, electroporation is still inefficient, or even invalid, for various kinds of cells. This is largely due to the lack of comprehensive understanding of cell responses to electrical stimulation at biological aspect. Moreover, a systematically investigation of protein variation of electroporated cells is also required for biosafety evaluation before clinically applying electroporation. By employing quantitative proteomic analysis, the biological mechanism of electroporation is explored from the molecular level. The results reveal that electrical stimulations widely influence many biological processes including nucleic acid stabilization, protein synthesis, cytoskeleton dynamic, inflammation, and cell apoptosis. It is found that several antivirus‐related processes appeared in the enrichment results. Moreover, SAMD9, a broad spectrum antiviral and antitumor factor, is dramatically downregulated on easy‐to‐transfect cells while electroporation can not alter SAMD9 expression on hard‐to‐transfect cells, hinting that electroporation, a pure physical treatment, can induce antivirus‐like defensive responses and the altering of SAMD9 can be used to predict the effectiveness of electroporation on transfecting specific kinds of cells.     

Loss of intracellular glycerol from Dunaliella by electroporation at constant osmotic pressure: subsequent restoration of glycerol content and associated volume changes

The effect of electroporation on Dunaliella tertiolecta at constant osmotic pressure (or water activity) was investigated. The following metabolic and physiological parameters were determined: extracellular and intracellular glycerol content, soluble protein content, photosynthetic oxygen evolution, mitochondrial oxygen uptake, cell volume and cell density. Electroporation conditions are described that released about 10% of intracellular glycerol to the external medium with minimal apparent effects on metabolism. Glycerol release originated from most cells rather than by total rupture of a small proportion of cells. Cell volume, measured on motile cells by video microscopy, reduced by 23% immediately after electroporation. Cell density did not increase. The uptake of mannitol, the major solute in the electroporation medium, was less than 20% of glycerol release. Following electroporation, the intracellular glycerol content and the cell volume both returned to pre-electroporation values after about 30min. Because the cells were maintained at constant external osmotic pressure throughout the procedure, it is concluded that the regulatory mechanism responsible for setting the intracellular glycerol content does not sense external osmotic pressure per se. These findings are consistent with a mechanism that senses a parameter linked directly to cell volume to set the intracellular glycerol content.     

Targeted electroporation in Xenopus tadpoles in vivo--from single cells to the entire brain

Electroporation is becoming more popular as a technique for transfecting neurons within intact tissues. One of the advantages of electroporation over other transfection techniques is the ability to precisely target an area for transfection. Here we highlight this advantage by describing methods to restrict transfection to either a single cell, clusters of cells, or to include large portions of the brain of the intact Xenopus tadpole. Electroporation is also an effective means of gene delivery in the retina. We have developed these techniques to examine the effects of regulated gene expression on various neuronal properties, including structural plasticity and synaptic transmission. Restriction of transfection to individual cells aids in imaging of neuronal morphology, while bulk cell transfection allows examination of the affects of gene expression on populations of cells by biochemical assays, imaging, and electrophysiological recording.     

Transfection of cells using flow-through electroporation based on constant voltage

Electroporation is a high-efficiency and low-toxicity physical gene transfer method. Classical electroporation protocols are limited by the small volume of cell samples processed (less than 10(7) cells per reaction) and low DNA uptake due to partial permeabilization of the cell membrane. Here we describe a flow-through electroporation protocol for continuous transfection of cells, using disposable devices, a syringe pump and a low-cost power supply that provides a constant voltage. We show transfection of cell samples with rates ranging from 40 μl min(-1) to 20 ml min(-1) with high efficiency. By inducing complex migrations of cells during the flow, we also show permeabilization of the entire cell membrane and markedly increased DNA uptake. The fabrication of the devices takes 1 d and the flow-through electroporation typically takes 1-2 h.     

In situ bipolar electroporation for localized cell loading with reporter dyes and investigating gap junctional coupling

Electroporation is generally used to transfect cells in suspension, but the technique can also be applied to load a defined zone of adherent cells with substances that normally do not permeate the plasma membrane. In this case a pulsed high-frequency oscillating electric field is applied over a small two-wire electrode positioned close to the cells. We compared unipolar with bipolar electroporation pulse protocols and found that the latter were ideally suited to efficiently load a narrow longitudinal strip of cells in monolayer cultures. We further explored this property to determine whether electroporation loading was useful to investigate the extent of dye spread between cells coupled by gap junctions, using wild-type and stably transfected C6 glioma cells expressing connexin 32 or 43. Our investigations show that the spatial spread of electroporation-loaded 6-carboxyfluorescein, as quantified by the standard deviation of Gaussian dye spread or the spatial constant of exponential dye spread, was a reliable approach to investigate the degree of cell-cell coupling. The spread of reporter dye between coupled cells was significantly larger with electroporation loading than with scrape loading, a widely used method for dye-coupling studies. We conclude that electroporation loading and dye transfer is a robust technique to investigate gap-junctional coupling that combines minimal cell damage with accurate probing of the degree of cell-cell communication.     

Electroporation and expression of the broad host-range plasmid pRK2501 in Azotobacter vinelandii.

Azotobacter vinelandii cells were transformed via high-voltage electroporation, with the broad host-range plasmid pRK2501. The number of transformants was dependent on the applied voltage, capacitance, and recovery procedure after electroporation. For example, Log, 4.44 transformants microgram-1 DNA were recovered in the A. vinelandii cell suspension electroporated at 1500 V and 25 microF capacitance (time constant 29.0 ms) and recovered on LB agar amended with 0.5 microgram/ml-1 kanamycin (pRK2501 encodes for both kanamycin and tetracycline resistance). Electroporation at 2500 V and capacitance settings of 25 and 3 microF did not produce any transformants. Cell survival was also poor at high voltages. A. vinelandii transformants were not recovered on N-free agar medium. In addition, no viable cells were recovered on N-free agar after electroporation at 2500 V, 25 microF; 2500 V, 3 microF; and 1500 V, 25 microF. Electroporation may be a useful method to genetically transform Azotobacter species for use in physiological and/or genetic studies.     

Simultaneous quantitative determination of electroporative molecular uptake and subsequent cell survival using gel microdrops and flow cytometry

BACKGROUND: Electroporation is widely used to introduce molecules into cells, but conditions yielding maximal molecular uptake often result in low cell survival. We describe a high throughput method for analyzing populations of culturable cells simultaneously for molecular uptake and cell growth. METHODS: Cells are microencapsulated within agarose gel microdrops (GMDs), exposed to a polar tracer fluorescent molecule, electrically pulsed at various field strengths, and cultured. The GMDs are then analyzed at about 100,000 occupied GMDs per hour by flow cytometry for both uptake and microcolony formation. RESULTS: We demonstrate how the method can be used to optimize a parameter of interest (e.g., the applied field strength) with respect to both uptake and cell survival. Here, the optimal field strength is determined to be 1.7 kV/cm. Below this, there is lower molecular uptake. As the field strength is increased, the cell survival rate goes down. CONCLUSIONS: This method may be applicable to optimization of other electroporation parameters and alternative physical and chemical methods for cell loading.     

Electroporation efficiency in mammalian cells is increased by dimethyl sulfoxide (DMSO).

Electroporation is one of the most common methods used transform mammalian cells with plasmids. This method is versatile and can be adapted to meet the requirements of many cell lines. However, sometimes the efficiency of this method is low. We demonstrate that dimethyl sulfoxide (DMSO) facilitated a better DNA uptake in four different cell lines (HL60, TR146, Cos-7 and L132). The cells were electroporated with a beta-Gal expression plasmid in a medium containing DMSO (1.25%) during, and for 24 h after the pulse. In all these cells a dramatic (up to 8-fold) increase in transfection efficiency occurred after this treatment. This method opens up the possibility of using electroporation even in cells which are difficult to transfect.     

Instantaneous gene transfer from donor to recipient microorganisms via electroporation

Simplified electroporation methodologies have been developed that reliably yield transformants with only minutes of effort. Neither DNA purification, cells in specific phase of growth, cell washing nor chilled cuvettes are required to obtain transformants. Electroporation can be used to transfer plasmid or chromosomal DNA directly from donor to recipient cells. This simplified direct method of electroporation has been demonstrated to work for both intra- as well as interspecies transformations using a variety of microorganisms. The use of electroporation to purify plasmid DNA was also investigated and found to be inferior to conventional plasmid isolation procedures.