Effect of actin cytoskeleton disruption on electric pulse‐induced apoptosis and electroporation in tumour cells

Electric pulses are known to affect the outer membrane and intracellular structures of tumour cells. By applying electrical pulses of 450 ns duration with electric field intensity of 8 kV/cm to HepG2 cells for 30 s, electric pulse‐induced changes in the integrity of the plasma membrane, apoptosis, viability and mitochondrial transmembrane potential were investigated. Results demonstrated that electric pulses induced cell apoptosis and necrosis accompanied with the decrease of mitochondrial transmembrane potential and the formation of pores in the membrane. The role of cytoskeleton in cellular response to electric pulses was investigated. We found that the apoptotic and necrosis percentages of cells in response to electric pulses decreased after cytoskeletal disruption. The electroporation of cell was not affected by cytoskeletal disruption. The results suggest that the disruption of actin skeleton is positive in protecting cells from killing by electric pulses, and the skeleton is not involved in the electroporation directly.     

Effect of high-voltage pulses on the viability of human leucocytes in vitro

Human leucocytes were exposed to high-voltage pulses (transient currents) produced by discharging a capacitor through a test chamber containing the cell suspension then tested for viability using trypan blue. With the pulse discharge times of 1 and 3 μs increases in the number of dyeloaded cells were seen for field strengths above 2.6 kV/cm in the sample. For 0.2-μs pulses the critical field strength was about 5 kV/cm.     

Microdosimetry for conventional and supra-electroporation in cells with organelles

Conventional electroporation (EP) by 0.1 to 1 kV/cm pulses longer than 100 micros, and supra-electroporation by 10 to 300 kV/cm pulses shorter than 1 micros cause different cellular effects. Conventional EP delivers DNA, proteins, small drugs, and fluorescent indicators across the plasma membrane (PM) and causes moderate levels of phosphatidylserine (PS) translocation at the PM. We hypothesize that supra-EP is central to intracellular effects such as apoptosis induction and higher levels of PS translocation. Our cell system model has 20,000 interconnected local models for small areas of the PM and organelle membranes, small regions of aqueous media, appropriate resting potentials, and the asymptotic EP model. Conventional EP primarily affects the PM, but with a hint of endoplasmic reticulum involvement. Supra-EP can involve all of a cell's membrane at the largest fields. Conventional EP fields tend to go around cells, but supra-EP fields go through cells, extensively penetrating organelles.     

Quantitative study of electroporation-mediated molecular uptake and cell viability

Electroporation's use for laboratory transfection and clinical chemotherapy is limited by an incomplete understanding of the effects of electroporation parameters on molecular uptake and cell viability. To address this need, uptake of calcein and viability of DU 145 prostate cancer cells were quantified using flow cytometry for more than 200 different combinations of experimental conditions. The experimental parameters included field strength (0.1-3.3 kV/cm), pulse length (0.05-20 ms), number of pulses (1-10), calcein concentration (10-100 microM), and cell concentration (0.6-23% by volume). These data indicate that neither electrical charge nor energy was a good predictor of electroporation's effects. Instead, both uptake and viability showed a complex dependence on field strength, pulse length, and number of pulses. The effect of cell concentration was explained quantitatively by electric field perturbations caused by neighboring cells. Uptake was shown to vary linearly with external calcein concentration. This large quantitative data set may be used to optimize electroporation protocols, test theoretical models, and guide mechanistic interpretations.     

The effects of intense submicrosecond electrical pulses on cells

A simple electrical model for living cells predicts an increasing probability for electric field interactions with intracellular substructures of both prokaryotic and eukaryotic cells when the electric pulse duration is reduced into the sub-microsecond range. The validity of this hypothesis was verified experimentally by applying electrical pulses (durations 100 micros-60 ns, electric field intensities 3-150 kV/cm) to Jurkat cells suspended in physiologic buffer containing propidium iodide. Effects on Jurkat cells were assessed by means of temporally resolved fluorescence and light microscopy. For the longest applied pulses, immediate uptake of propidium iodide occurred consistent with electroporation as the cause of increased surface membrane permeability. For nanosecond pulses, more delayed propidium iodide uptake occurred with significantly later uptake of propidium iodide occurring after 60 ns pulses compared to 300 ns pulses. Cellular swelling occurred rapidly following 300 ns pulses, but was minimal following 60 ns pulses. These data indicate that submicrosecond pulses achieve temporally distinct effects on living cells compared to microsecond pulses. The longer pulses result in rapid permeability changes in the surface membrane that are relatively homogeneous across the cell population, consistent with electroporation, while shorter pulses cause surface membrane permeability changes that are temporally delayed and heterogeneous in their magnitude.     

DH10B菌株高效电转化条件探究

以pUC19、pECBAC1、pCLD04541DNA以及3个不同大小的BACDNA为材料,研究了E.coli DH10B菌株在5个不同脉冲电场下的转化效率。研究发现,随着DNA片段大小的增加,最高转化效率和最适场强迅速减小。利用DH10B细胞转化pUC19 DNA的最适场强是21kV/cm,而190kb BAC DNA仅为13kV/cm;在最适场强下,40kb BAC DNA的转化效率约是190kb BAC DNA的50倍。通过大量数据绘制了不同因素影响下转化效率的变化曲线,优化了E.coli DH10B菌株电转化条件,为质粒的重组转化以及大片段基因组文库的构建奠定了基础。     

Electroporation: A general phenomenon for manipulating cells and tissues

Electroporation is a fascinating cell membrane phenomenon with several existing biological applications and others likely. Although DNA introduction is the most common use, electroporation of isolated cells has also been used for (1) introduction of enzymes, antibodies, and other biochemical reagents for intracellular assays; (2) selective biochemical loading of one size cell in the presence of many smaller cells; (3) introduction of virus and other particles; (4) cell killing under nontoxic conditions; and (5) insertion of membrane macromolecules into the cell membrane. More recently, tissue electroporation has begun to be explored, with potential applications including (1) enhanced cancer tumor chemotherapy, (2) gene therapy, (3) transdermal drug delivery, and (4) noninvasive sampling for biochemical measurement. As presently understood, electroporation is an essentially universal membrane phenomenon that occurs in cell and artificial planar bilayer membranes. For short pulses (μs to ms), electroporation occurs if the transmembrane voltage, U(t), reaches 0.5–1.5 V. In the case of isolated cells, the pulse magnitude is 10³–10⁴ V/cm. These pulses cause reversible electrical breakdown (REB), accompanied by a tremendous increase molecular transport across the membrane. REB results in a rapid membrane discharge, with the elevated U(t) returning to low values within a few microseconds of the pulse. However, membrane recovery can be orders of magnitude slower. An associated cell stress commonly occurs, probably because of chemical influxes and effluxes leading to chemical imbalances, which also contribute to eventual survival or death. Basic phenomena, present understanding of mechanism, and the existing and potential applications are briefly reviewed.     

Bioactivity of electric field-pulsed human recombinant interleukin-2 and its encapsulation into erythrocyte carriers

The molecular integrity of human recombinant interleukin-2 (rIL-2), as measured by size exclusion chromatography, was not altered when exposed to high electrical field intensities. In addition, the biological activity was unaffected, as evidenced by the ability of the rIL-2 to stimulate the proliferation (by cell growth assays and tritiated thymidine uptake) and differentiation (by cytotoxicity assay) of human lymphocytes into killer cells. Electroporation conditions chosen for the loading of rIL-2, based upon those which provided for good recovery of carriers and minimal hemoglobin release, involved a lower field intensity (i.e., 6 kV/cm instead of 7 or 8 kV/cm) and multiple pulses (eight pulses, 5 microseconds) rather than a single pulse (40 microseconds). Human erythrocyte carriers consistently encapsulated 5-7.5% of the rIL-2 by electroporation (6 kV/cm, eight pulses, 5 microseconds duration). A rIL-2 concentration of 600,000 U/ml surrounding the erythrocytes during loading resulted in ca. 245,000 U/ml carriers, which represents a therapeutically significant quantity. Thus, rIL-2 shows potential as an encapsulated agent for slow release in the erythrocyte carrier system.     

潮霉素B抗性为选择标记的整合型表达载体的构建及在米根霉中的遗传转化

为了建立适合米根霉的遗传转化体系,应用重叠延伸PCR的方法构建了以潮霉素B抗性为选择标记的单交换整合型表达载体p BS-hygro-ldh A;分别采用PEG/Ca Cl2介导的原生质体转化、原生质体电转化及萌发孢子电转化的方法将表达载体p BS-hygro-ldh A转化入米根霉AS 3.819菌株中,并研究了菌丝酶解时间、孢子萌发时间以及电转化电场强度对于转化效率的影响;通过荧光定量PCR(q PCR)对米根霉转化子基因组中质粒整合拷贝数进行了检测,并研究了其对米根霉转化子抗性稳定性的影响。实验结果表明成功获得整合了表达载体p BS-hygro-ldh A的米根霉转化子。菌丝酶解140 min产生的原生质体其再生率和转化率最高,原生质体电转化最佳电场强度为13 k V/cm,孢子萌发2.5 h转化率最高,萌发孢子电转化最佳电场强度为14 k V/cm。萌发孢子电转化方法转化率要高于原生质体转化的方法。荧光定量PCR检测结果表明,在一定范围内,高质粒整合拷贝数的米根霉转化子比较稳定。研究建立了用于工业米根霉菌株的遗传转化体系,为米根霉代谢调控研究以及菌种改造工作提供了基础与支持。     

Electroporation and electrophoretic DNA transfer into cells. The effect of DNA interaction with electropores.

It has been shown recently that electrically induced DNA transfer into cells is a fast vectorial process with the same direction as DNA electrophoresis in an external electric field (Klenchin, V. A., S. I. Sukharev, S. M. Serov, L. V. Chernomordik, and Y. A. Chizmadzhev. 1991. Biophys. J. 60:804-811). Here we describe the effect of DNA interaction with membrane electropores and provide additional evidences for the key role of DNA electrophoresis in cell electrotransfection. The assay of electrically induced uptake of fluorescent dextrans (FDs) by cells shows that the presence of DNA in the medium during electroporation leads to a sharp increase in membrane permeability to FDs of M(r) < 20,000. The permeability increases with DNA concentration and the effect is seen even if FD is added to the cell suspension a few minutes after pulse application. The longer the DNA fragment, the greater the increase in permeability. The use of a two-pulse technique allows us to separate two effects provided by a pulsed electric field: membrane electroporation and DNA electrophoresis. The first pulse (6 kV/cm, 10 microseconds) creates pores efficiently, whereas transfection efficiency (TE) is low. The second pulse of much lower amplitude, but substantially longer (0.2 kV/cm, 10 ms), does not cause poration and transfection by itself but enhances TE by about one order of magnitude. In two-pulse experiments, TE rises monotonously with the increase of the second pulse duration. By varying the delay duration between the two pulses, we estimate the lifetime of electropores (which are DNA-permeable in conditions of low electric field) as tens of seconds.(ABSTRACT TRUNCATED AT 250 WORDS)     

Simple and effective method of electroporation for introduction of plasmid and cosmid DNAs to mammalian cells

We have established a simple and efficient method of electroporation applicable to gene transfer in mammalian cells. It uses a single decaying pulse of around 1 ms at room temperature in the medium such as Saline G appropriate for repair of pulse-induced pores in the plasma membrane. Many types of cells (both floating and adherent) could be transformed efficiently by the electric field strengths between 1-2 kV/cm. For instance P3U1, mouse myeloma cell, could be transformed by a pulse at 1.2 kV/cm with the frequency of 10(-2) per viable cells and with survivals of 90%. We have applied these conditions to transform tsBN2 cell line of BHK21/13 by a cosmid clone (approximately 45 kb) carrying the human gene complementing to tsBN2 mutation. Significant levels of transformation were observed for this gene. Since this gene can only work as a whole size (approximately 30 kb), the results show that electroporation is useful to introduce cosmid or possibly genomic DNA to mammalian cells.     

Electroporation of abalone sperm enhances sperm-DNA association

The ability of sperm from the black-footed abalone Haliotis iris to take up foreign DNA in solution has been demonstrated. The efficiency of DNA uptake is related to the conditions of electroporation, including field strength (625 V cm⁻¹, 1000 V cm⁻¹), pulse length (18.6 ms, 27.4ms) and number of pulses (1, 2), and DNA concentration (20, 100 μg ml⁻¹). Sperm motility decreased with increased field strength and pulse number. At a field strength of 625 V cm⁻¹, neither the pulse length nor pulse number enhanced DNA uptake. A 40% enhancement in DNA uptake was observed when the sperm were shocked at 1000 V cm⁻¹ with two long pulses (27.4 ms each). Linear regression analysis revealed that pulse number ( p = 0.013) and field strength ( P =0.039) were the most important factors in sperm–DNA interaction. Higher DNA concentration enhanced sperm DNA uptake irrespective of field strength, pulse length and pulse number. The optimal electroporation conditions for DNA uptake were 1000 V cm', with two pulses of 27.4 ms each, and a DNA concentration of 100 μg ml⁻¹.     

Electrofusion parameters for mouse two-cell embryos

We studied electrofusion of mouse two-cell embryos in order to define parameters which would result in a high yield of fused embryos. Various cell alignment times (from <10 to >60 s) and alternating current percentages (2 to 100%) were examined. The fusion parameters tested were the number of fusion pulses (1-9), pulse length (30-90 mus) and pulse strength (0.50-1.79 kV/cm). Furthermore different combinations of these three parameters were tested. In addition the influence of several embryo culture media on the fusion rates was examined. The results show that the fusion rate of the embryos increases with shorter alignment and higher percentages of the alternating current. The highest fusion rate (95%) was obtained by use of one pulse with a duration of 70 mus and a field strength of 0.60-0.79 kV/cm. The survival rate of the embryos was best if Whitten Medium was used before and after the fusion pulses. The fusion of two-cell stages results in tetraploid embryos which can serve as models for studies in polyploid cells.     

Nanosecond Electroporation: Another Look

As the medical field moves from treatment of diseases with drugs to treatment with genes, safe and efficient gene delivery systems are needed to make this transition. One such safe, non-viral, and efficient gene delivery system is electroporation (electrogenetherapy). Exciting discoveries using electroporation could make this technique applicable to drug and vaccine delivery in addition to gene delivery. Typically milli and microsecond pulses have been used for electroporation. Recently, the use of nanosecond electrical pulses (10-300 ns) at very high magnitudes (10-300 kV/cm) has been studied for direct DNA transfer to the nucleus in vitro. This article reviews the work done using high-intensity nanosecond pulses, termed as nanosecond electroporation (nsEP), in electroporation gene delivery systems.     

In vivo electroporation of skeletal muscle: threshold, efficacy and relation to electric field distribution.

In vivo electroporation is increasingly being used to deliver small molecules as well as DNA to tissues. The aim of this study was to quantitatively investigate in vivo electroporation of skeletal muscle, and to determine the threshold for permeabilization. We designed a quantitative method to study in vivo electroporation, by measuring uptake of (51)Cr-EDTA. As electrode configuration influences electric field (E-field) distribution, we developed a method to calculate this. Electroporation of mouse muscle tissue was investigated using either external plate electrodes or internal needle electrodes placed 4 mm apart, and eight pulses of 99 micros duration at a frequency of 1 Hz. The applied voltage to electrode distance ratio was varied from 0 to 2.0 kV/cm. We found that: (1) the threshold for permeabilization of skeletal muscle tissue using short duration pulses was at an applied voltage to electrode distance ratio of 0.53 kV/cm (+/-0.03 kV/cm), corresponding to an E-field of 0.45 kV/cm; (2) there were two phases in the uptake of (51)Cr-EDTA, the first indicating increasing permeabilization and the second indicating beginning irreversible membrane damage; and (3) the calculated E-field distribution was more homogeneous for plate than for needle electrodes, which was reflected in the experimental results.     

细胞电穿孔动态过程的荧光测量

利用改进后的Ｔｈ／ＤＰＡ荧光方法及探针ＥＢ对人血影及大鼠骨髓细胞电穿孔的动态过程及其与电脉冲参数的关系进行了系统的研究．测量结果表明,在临界点以上电场作用下,血影电穿孔在电击后０．２—０．３ｓ时达最大,在约０．８ｓ时愈合;而大鼠骨髓细胞电穿孔在电击后０．４—０．９ｓ达到最大,３－５ｓ左右愈合;电穿孔大小及扩大、愈合速率与电脉冲参数有关。１０－４０ｍｍｏｌ／Ｌ乙醇和５－２０ｍｍｏｌ／Ｌ成二醛抑制血影对Ｔｂ３＋离子的电通透,相同浓度的成二醛作用强于乙醇。这些结果将为电穿孔技术的合理应用提供参考。     

Low electric field parameters required to induce death of cancer cells

Irreversible electroporation (IRE) is a novel technique that deals with killing undesirable cells, mainly cancer cells, directly without using any cytotoxic drugs. Commonly in this technique very high electric field up to 1000?V/cm is used but for very short exposure time (nanoseconds). Low electric fields (LEFs) are used before to internalize molecules and drugs inside the cells (electroendocytosis) but mainly not in killing the cells. The aim of this work is to determine the ability of using LEFs to kill cancer cells (Hela cells). The Physics idea is in making LEFs energy equivalent to IRE energy. Four IRE protocols were selected to represent very high, high, moderate and mild voltages IRE, then we make equivalent energy for each of these protocols using different LEFs’ parameters of different amplitudes (7, 10, 14 and 20?V), different pulse numbers (40, 80, 160 and 320 pulses), different frequencies from 0.5 to 106.86?Hz and different pulse widths from 9.38 to 2000?ms. Each of the calculated LEF equivalent to IRE was applied on Hela cell line. The results show complete destruction of the cancer cells for all the tested exposure protocols. This damage was not due to thermal effect because the measured temperature was not changed before and after the exposure. The possible effect mechanism is discussed. It was concluded that the lethal effect on the cancer cells can be achieved using LEFs if the same energy equivalent to IRE is used. This work will help in using low-risk drug-free techniques in cancer treatment.     

Inactivation and injury of Escherichia coli O157:H7 and Staphylococcus aureus by pulsed electric fields

Two pathogenic microorganisms Escherichia coli O157:H7 and Staphylococcus aureus, suspended in peptone solution (0.1% w/v) were treated with 12, 14, 16 and 20 kV/cm electric field strengths with different pulse numbers up to 60 pulses. Pulsed electric field (PEF) treatment at 20 kV/cm with 60 pulses provided nearly 2 log reduction in viable cell counts of E. coli O157:H7 and S. aureus. S. aureus cells were slightly more resistant than E.coli O157:H7 cells. The results related to the effect of initial cell concentration of E. coli O157:H7 on the PEF inactivation showed that more inactivation was obtained by decreasing initial cell concentration. Any possible injury by PEF was also investigated after applying 20 kV/cm electric field to the microorganisms. As a result, it was determined that there was 35.92 to 43.36% injury in E. coli O157:H7 cells, and 17.26 to 30.86% injury in S. aureus cells depending on pulse number. The inactivation results were also described by a kinetic model.     

Plasma membrane voltage changes during nanosecond pulsed electric field exposure

The change in the membrane potential of Jurkat cells in response to nanosecond pulsed electric fields was studied for pulses with a duration of 60 ns and maximum field strengths of approximately 100 kV/cm (100 V/cell diameter). Membranes of Jurkat cells were stained with a fast voltage-sensitive dye, ANNINE-6, which has a subnanosecond voltage response time. A temporal resolution of 5 ns was achieved by the excitation of this dye with a tunable laser pulse. The laser pulse was synchronized with the applied electric field to record images at times before, during, and after exposure. When exposing the Jurkat cells to a pulse, the voltage across the membrane at the anodic pole of the cell reached values of 1.6 V after 15 ns, almost twice the voltage level generally required for electroporation. Voltages across the membrane on the side facing the cathode reached values of only 0.6 V in the same time period, indicating a strong asymmetry in conduction mechanisms in the membranes of the two opposite cell hemispheres. This small voltage drop of 0.6-1.6 V across the plasma membrane demonstrates that nearly the entire imposed electric field of 10 V/mum penetrates into the interior of the cell and every organelle.     

Diverse effects of nanosecond pulsed electric fields on cells and tissues

The application of pulsed electric fields to cells is extended to include nonthermal pulses with shorter durations (10-300 ns), higher electric fields (< or =350 kV/cm), higher power (gigawatts), and distinct effects (nsPEF) compared to classical electroporation. Here we define effects and explore potential application for nsPEF in biology and medicine. As the pulse duration is decreased below the plasma membrane charging time constant, plasma membrane effects decrease and intracellular effects predominate. NsPEFs induced apoptosis and caspase activation that was calcium-dependent (Jurkat cells) and calcium-independent (HL-60 and Jurkat cells). In mouse B10-2 fibrosarcoma tumors, nsPEFs induced caspase activation and DNA fragmentation ex vivo, and reduced tumor size in vivo. With conditions below thresholds for classical electroporation and apoptosis, nsPEF induced calcium release from intracellular stores and subsequent calcium influx through store-operated channels in the plasma membrane that mimicked purinergic receptor-mediated calcium mobilization. When nsPEF were applied after classical electroporation pulses, GFP reporter gene expression was enhanced above that observed for classical electroporation. These findings indicate that nsPEF extend classical electroporation to include events that primarily affect intracellular structures and functions. Potential applications for nsPEF include inducing apoptosis in cells and tumors, probing signal transduction mechanisms that determine cell fate, and enhancing gene expression.