Electroporation of lymphoid cells: factors affecting the efficiency of transfection

We have increased the efficiency of electroporation of lymphoid cells over fifty fold by optimising several biological and electrical parameters. Under optimised conditions, the electroporation efficiency was comparable to that reported for other cell types. Actively dividing cells were crucial for high transient transfection signal. The two most important electrical parameters were high capacitance (960 microF) and moderate decay constants in the range of 10-15 ms. The optimal field strength depended on the cell line, but was in the range 0.6-1 kV/cm. Administering the pulse in medium lacking serum gave higher efficiency than when isotonic salt solution was used and the transfection signal was depressed if cells and DNA were allowed to incubate for several minutes either before or after the pulse. Electroporation was carried out at room temperature and there was no advantage in using low temperatures (0-4 degrees C). When electroporated cells were grown in conditioned medium, the signal was enhanced about two fold depending on the source of the conditioned medium.     

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.     

Optimizing Electroporation Conditions in Primary and Other Difficult-to-Transfect Cells

Electroporation is a valuable tool for nucleic acid delivery because it can be used for a wide variety of cell types. Many scientists are shifting toward the use of cell types that are more relevant to in vivo applications, including primary cells, which are considered difficult to transfect. The ability to electroporate these cell types with nucleic acid molecules of interest at a relatively high efficiency while maintaining cell viability is essential for elucidating the pathway(s) in which a gene product is involved. We present data demonstrating that by optimizing electroporation parameters, nucleic acid molecules can be delivered in a highly efficient manner. We display transfection results for primary and difficult-to-transfect cell types including human primary fibroblasts, human umbilical vein endothelial cells, Jurkat cells, and two neuroblastoma cell lines [SK-N-SH (human) and Neuro-2A (mouse)] with plasmid DNAs and siRNAs. Our data demonstrate that by determining proper electroporation conditions, glyceraldehyde phosphate dehydrogenase mRNA was silenced in Jurkat cells when compared with negative control siRNA electroporations as early as 4 h post-transfection. Other experiments demonstrated that optimized electroporation conditions using a fluorescently labeled transfection control siRNA resulted in 75% transfection efficiency for Neuro-2A, 93% for human primary fibroblasts, and 94% for HUVEC cells, as analyzed by flow cytometry.     

Strategy for increased efficiency of transfection in human cell lines using radio frequency electroporation

Traditional electroporation devices use direct current electric fields to stimulate the uptake of oligonucleotides, plasmids, short peptides, and proteins into a variety of cell types. A variation of this widely used technique is now available which relies on radio frequency (RF) electrical pulses. This oscillating type of electrical field reportedly elicits greater uptake of plasmid DNA across the plasma membrane. We evaluated a protocol for RF electroporation of the a human embryonic kidney cell line and a Burkitt's lymphoma (BL) cell line for effeciency of transfection by RF electroporation. The plasmid EGFP, which codes for the widely used fusion protein, enhanced green fluorescent protein (EGFP), was used as a reporter of plasmid uptake after transfections. Transfection efficiency consistently increased approximately 30% from that typically obtained with conventional DC type electroporation and was accompanied by greater survivability of cells. Additionally, in some instances, percent transfection efficiency increased to over 70%. Thus, RF electroporation represents an improved methodology for transfection of human cell lines. Moreover, the RF protocol is simple to incorporate in laboratories already utilizing conventional electroporation devices and techniques.     

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.     

Electroporation optimization to deliver plasmid DNA into dental follicle cells

Electroporation is a simple and versatile approach for DNA transfer but needs to be optimized for specific cells. We conducted square wave electroporation experiments for rat dental follicle cells under various conditions. These experiments indicated that the optimal electroporation electric field strength was 375 V/cm, and that plasmid concentrations greater than 0.18 μg/μL were required to achieve high transfection efficiency. BSA or fetal bovine serum in the pulsing buffer significantly improved cell survival and increased the number of transfected cells. The optimal pulsing duration was in the range of 45–120 ms at 375 V/cm. This electroporation protocol can be used to deliver DNA into dental follicle cells to study the roles of candidate genes in regulating tooth eruption. This is the first report showing the transfection of dental follicle cells using electroporation. The parameters determined in this study are likely to be applied to transfection of other fibroblast cells.     

Optimization of an electroporation protocol using the K562 cell line as a model: role of cell cycle phase and cytoplasmic DNAses

The improvement of gene therapy protocols is intimately related to the establishment of efficient gene transfer methods. Electroporation has been increasingly employed in in vitro and in vivo protocols, and much attention has been given to increasing its transfection potential. The method is based on the application of an electric field of short duration and high voltage to the cells, forming reversible pores through which molecules can enter the cell. In this work, we describe the optimization of a protocol for the electroporation of K562 cells involving the combination of electric field, resistance and capacitance values. Using RPMI 1640 as pulsing buffer and 30 μg of pEGFP-N1 plasmid, 875 V cm⁻¹, 500 μF and infinite resistance, we achieved transfection rates of 82.41 ± 3.03%, with 62.89 ± 2.93% cell viability, values higher than those reported in the literature. Analyzing cell cycle after electroporation, with three different electric field conditions, we observed that in a heterogeneous population of cells, viability of G₁ cells is less affected by electroporation than that of cells in late S and G₂/M phases. We also observed that efficiency of electroporation can be improved using the DNAse inhibitor Zn, immediately after the pulse. These results can represent a significant improvement of current methods of electroporation of animal and plant cells.     

Efficiency of cellular delivery of antisense peptide nucleic acid by electroporation depends on charge and electroporation geometry

Electroporation is potentially a very powerful technique for both in vitro cellular and in vivo drug delivery, particularly relating to oligonucleotides and their analogs for genetic therapy. Using a sensitive and quantitative HeLa cell luciferase RNA interference mRNA splice correction assay with a functional luciferase readout, we demonstrate that parameters such as peptide nucleic acid (PNA) charge and the method of electroporation have dramatic influence on the efficiency of productive delivery. In a suspended cell electroporation system (cuvettes), a positively charged PNA (+8) was most efficiently transferred, whereas charge neutral PNA was more effective in a microtiter plate electrotransfer system for monolayer cells. Surprisingly, a negatively charged (-23) PNA did not show appreciable activity in either system. Findings from the functional assay were corroborated by pulse parameter variations, polymerase chain reaction, and confocal microscopy. In conclusion, we have found that the charge of PNA and electroporation system combination greatly influences the transfer efficiency, thereby illustrating the complexity of the electroporation mechanism.     

DNA transfection of Escherichia coli by electroporation

Electroporation was applied to transfection and transformation of Escherichia coli. Efficient transfer of DNA was achieved by a single voltage pulse at 2.5 kV (initial electric field strength = 6.25 kV/cm), with a 25 microF capacitor. As the recipient for transfecting DNA in the electroporation, spheroplasts, EDTA-treated cells and osmotically shocked bacteria were inferior to intact E. coli. Various parameters affecting the transfection efficiency were defined including growth phase of recipient cells, concentrations of DNA and cells, temperature and additions. In most strains tested, electroporation was far more efficient than Ca2+-dependent transfection (transformation). Various aspects of the electroporation-mediated DNA uptake are discussed.     

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.     

Novel Parallelized Electroporation by Electrostatic Manipulation of a Water-in-Oil Droplet as a Microreactor

Electroporation is the most widely used transfection method for delivery of cell-impermeable molecules into cells. We developed a novel gene transfection method, water-in-oil (W/O) droplet electroporation, using dielectric oil and an aqueous droplet containing mammalian cells and transgene DNA. When a liquid droplet suspended between a pair of electrodes in dielectric oil is exposed to a DC electric field, the droplet moves between the pair of electrodes periodically and droplet deformation occurs under the intense DC electric field. During electrostatic manipulation of the droplet, the local intense electric field and instantaneous short circuit via the droplet due to droplet deformation facilitate gene transfection. This method has several advantages over conventional transfection techniques, including co-transfection of multiple transgene DNAs into even as few as 10³ cells, transfection into differentiated neural cells, and the capable establishment of stable cell lines. In addition, there have been improvements in W/O droplet electroporation electrodes for disposable 96-well plates making them suitable for concurrent performance without thermal loading by a DC electric field. This technique will lead to the development of cell transfection methods for novel regenerative medicine and gene therapy.     

A novel electroporation method using a capillary and wire-type electrode

Electroporation is widely used to achieve gene transfection. A common problem in electroporation is that it has a lower viability than any other transfection method. In this study, we developed a novel electroporation device using a capillary tip and a pipette that was effective on a wide range of mammalian cells, including cell lines, primary cells, and stem cells. The capillary electroporation system considerably reduced cell death during electroporation because of its wire-type electrode, which has a small surface area. The experimental results also indicated that the cell viability was dependent on the change in pH induced by electrolysis during electroporation. Additionally, the use of a long and narrow capillary tube combined with simple pipetting shortened the overall time of the electroporation process by up to 15 min, even under different conditions with 24 samples. These results were supported by comparison with a conventional electroporation system. The transfection rate and the cell viability were enhanced by the use of the capillary system, which had a high transfection rate of more than 80% in general cell lines such as HeLa and COS-7, and more than 50% in hard-to-transfect cells such as stem or primary cells. The viability was approximately 70-80% in all cell types used in this study.     

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.     

Nucleofection-based gene targeting in human pre-B cells

Electroporation is a powerful and convenient means for transfection of nonviral vectors into mammalian cells, providing an essential tool for numerous applications including gene targeting via homologous recombination. Recent evidence clearly suggests that high-efficiency gene transfer can be achieved in most cell lines by nucleofection, an electroporation-based transfection method that allows transfected vectors to directly enter the nucleus. In this paper, we analyze the effectiveness of nucleofection for gene targeting using human pre-B cells. For this, we tested 93 different transfection conditions, and found several conditions that gave high (~ 80%) transfection efficiency with low cytotoxicity (~ 70% survival rate). Remarkably, under the optimal nucleofection conditions, the gene-targeting efficiency was ~ 2-5-fold higher than that achieved with conventional electroporation methods. We also found that nucleofection conditions with high transfection efficiency and low cytotoxicity tend to provide high gene-targeting efficiency. Our results provide significant implications for gene targeting, and suggest that nucleofection-based nonviral gene transfer is useful for systematic generation of human gene-knockout cell lines.     

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.     

Optimization of transfection methods for Huh-7 and Vero cells: A comparative study

Availability of an efficient transfection protocol is the first determinant in success of gene transferring studies in mammalian cells which is accomplished experimentally for every single cell type. Herein, we provide data of a comparative study on optimization of transfection condition by electroporation and chemical methods for Huh-7 and Vero cells. Different cell confluencies, DNA/reagent ratios and total transfection volumes were optimized for two chemical reagents including jetPEI? and Lipofectamine? 2000. Besides, the effects of electric field strength and pulse length were investigated to improve electroporation efficiency. Transfection of cells by pEGFP-N1 vector and tracking the expression of GFP by FACS and Fluorescence Microscopy analysis were the employed methods to evaluate transfection efficiencies. Optimized electroporation protocols yielded 63.73 ± 2.36 and 73.9 ± 1.6% of transfection in Huh-7 and Vero cells respectively, while maximum achieved level of transfection by jetPEI? was 14.2 ± 0.69 and 28 ± 1.11% Huh-7 and Vero cells, respectively. Post transfectional chilling of the cells did not improve electrotransfection efficiency of Huh-7 cells. Compared to chemical based reagents, electroporation showed superior levels of transfection in both cell lines. The presented protocols should satisfy most of the experimental applications requiring high transfection efficiencies of these two cell lines.     

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.     

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。     

Introduction of antibody into viable cells using electroporation

Conditions for labelling an intracellular antigen, p21ras, using electroporation to introduce a fluorescent antibody, are described. Following labelling, cells were evaluated for p21ras associated fluorescence by flow cytometry. Electroporation, sorting, and cell handling parameters were varied to determine optimal conditions for cell viability. Cells were best held in serum containing growth medium both before and after electroporation, while antibody introduction during the electroporation phase was most efficient when carried out in a balanced saline solution. For maximum efficiency of antibody internalization, the antibody needed to be present during electroporation, and medium needed to be replaced several times in the first few hours after electroporation to ensure good cell survival.     

Electroporation by nucleofector is the best nonviral transfection technique in human endothelial and smooth muscle cells

BACKGROUND: The aim of this study was to determine the optimal non-viral transfection method for use in human smooth muscle cells (SMC) and endothelial cells (EC). METHODS: Coronary Artery (CoA) and Aortic (Ao) SMC and EC were transfected with a reporter plasmid, encoding chloramphenicol acetyltransferase type 1 (CAT), with seven different transfection reagents, two electroporation methods and a photochemical internalization (PCI) method. CAT determination provided information regarding transfection efficiency and total protein measurement was used to reflect the toxicity of each method. RESULTS: Electroporation via the nucleofector machine was the most effective method tested. It exhibited a 10 to 20 fold (for SMC and EC, respectively) increase in transfection efficiency in comparison to the lipofection method combined with acceptable toxicity. FuGene 6 and Lipofectamine PLUS were the preferred transfection reagents tested and resulted in 2 to 60 fold higher transfection efficiency in comparison to the PCI which was the least effective method. CONCLUSION: This study indicates that electroporation via the nucleofector machine is the preferred non-viral method for in vitro transfection of both human aortic and coronary artery SMC and EC. It may be very useful in gene expression studies in the field of vascular biology. Through improved gene transfer, non-viral transfer techniques may also play an increasingly important role in delivering genes to SMC and EC in relevant disease states.