In vivo electroporation for genetic manipulations of whole Hydra polyps

In vivo electroporation is used to study gene regulation and gene function in the freshwater polyp Hydra. Although this approach has been used successfully by several investigators, efficacy and handling continue to present a problem. Here we show technical aspects of in vivo electroporation for introducing fluorescent dyes, plasmid DNA and double stranded RNA into Hydra polyps. We describe the fundamentals of the electroporation delivery system, discuss recent studies where this approach has been used successfully, compare it to alternative transfection methods such as lipofection, and identify future directions.     

Electroporation of the vasculature and the lung

Electroporation has proven to be a highly effective technique for the in vivo delivery of genes to a number of solid tissues. In most of the reported methods, DNA is injected into the target tissue and electrodes are placed directly on or in the tissue for application of the electric field. While this works well for solid tissues, there are many tissues and organs that are not amenable to such an approach. In this review I will focus on the development of electroporation protocols for two such tissues: the vasculature and the lung. Several methods for in vivo electroporation of the vasculature have been developed in recent years that deliver DNA to vessel segments from either the inside or outside of the vessel. The advantages and disadvantages of each are discussed, as are the applications for which they have been used. In more recent work, our laboratory has developed a novel method to deliver genes to the rodent lung that results in high level, uniform, gene expression throughout all cell types of the lung. Most importantly, this technique is safe, and causes no inflammatory response or alterations in normal physiology of the organs. Taken together, these studies demonstrate the utility of electroporation for gene transfer to non injectible tissues.     

活体电穿孔法基因导入技术

活体电穿孔法(invivoelectroporation)可将外源基因有效导入靶组织或器官,导入效率较高,并且可在多种组织器官上应用。近年来活体电穿孔法用于转基因研究的报道不断增多,在基因治疗方面的优势也日趋显著,是一种很好的活体基因导入方法 。     

Gene transfer by electroporation

Electroporation of cells in the presence of DNA is widely used for the introduction of transgenes either stably or transiently into bacterial, fungal, animal, and plant cells. A review of the literature shows that electroporation parameters are often reported in an incomplete or incorrect manner, forcing researchers to rely too much on a purely empirical trial and error approach. The goal of this article is to provide the reader with an understanding of electrical circuits used in electroporation experiments as well as physical and biological aspects of the electroporation process itself. Further, a simple paradigm is provided which unites all electroporation parameters. This article should be particularly useful to those new to the technique.     

活体电转化技术在新生小鼠视网膜中的应用

活体电转化技术是在高电压的脉冲作用下,瞬态增加细胞膜的渗透性从而将外源基因高效导入细胞的方法。与病毒载体等其他方法相比,活体电转化技术具有安全、高效、快速、稳定及应用范围广等优点,近年来在很多组织和器官中得到广泛使用,包括在眼科研究领域。文章介绍了活体电转化技术在新生小鼠视网膜中的应用,通过新生小鼠视网膜下注射的方法,经几次高电压的脉冲,将高浓度的绿色荧光蛋白表达质粒导入新生小鼠视网膜细胞内。通过冰冻切片观察绿色荧光蛋白在视网膜中的表达。结果表明绿色荧光蛋白在视网膜外核层高表达,证实了活体电转化技术可以将外源基因高效、快捷的导入视网膜,从而为研究视网膜发育及功能提供一种有效的手段。     

In vivo electroporation using an exponentially enhanced pulse: a new waveform

In vivo electroporation is currently accomplished by one of two types of common waveforms: exponential decay or square-wave pulses. The purpose of this report is to present a new electroporation waveform, the exponentially enhanced pulse (EEP). Pulsing protocols including the EEP resulted in high levels of luciferase expression in muscle and skin, equal to or greater than expression resulting from low-voltage, millisecond square-wave pulses. This high level of expression requires fewer pulses when using an EEP protocol. Therefore, similar or greater plasmid DNA expression levels are obtained using fewer pulses with the EEP protocol than with current protocols. This is the first report of this new waveform and shows the success of using protocols employing the EEP to deliver plasmid DNA to various tissue types.     

利用电磁脉冲提高抗癌药物治疗肿瘤细胞疗效的实验研究

本文采用一种新的方法——电穿孔结合化学药物进行肿瘤治疗的电化学疗法。电穿孔由于能使细胞膜出现瞬时微孔,从而能大大提高癌细胞对药物的吸收率、促进了药物等大分子进入细胞。这里利用电穿孔现象结合抗癌药物治疗昆明小鼠身上的S-180肉瘤,从实验数据可看出,这种方法取得了很好的效果。这种癌症治疗新技术具有易于控制、便于操作等优点,特别适用浅表肿瘤的治疗,为临床治疗肿瘤提供了一条新的途径。     

Mechanism of in vivo DNA transport into cells by electroporation: electrophoresis across the plasma membrane may not be involved

BACKGROUND: Recently, in vivo gene transfer with electroporation (electro-gene transfer) has emerged as a leading technology for developing nonviral gene therapies and nucleic acid vaccines. The widely hypothesized mechanism is that electroporation induces structural defects in the membrane and provides an electrophoretic force to facilitate DNA crossing the permeabilized membrane. In this study, we have designed a device and experiments to test the hypothesis. METHODS: In this study, we have designed a device that alternates the polarity of the applied electric field to elucidate the mechanism of in vivo electro-gene transfer. We also designed experiments to challenge the theory that the low-voltage (LV) pulses cannot permeabilize the membrane and are only involved in DNA electrophoresis, and answer the arguments that (1) the reversed polarity pulses can cause opposing sides of the cell membrane to become permeabilized and provide the electrophoresis for DNA entry; or (2) once DNA enters cytoplasmic/endosomal compartments after electroporation, it may bind to cellular entities and might not be reversibly extracted. Thus a gradual buildup of the DNA in the cell still seems quite possible even under the condition of the rapid reversal of polarity. RESULTS: Our results indicate that electrophoresis does not play an important role in in vivo electro-gene transfer. CONCLUSIONS: This study provides new insights into the mechanism of electro-gene transfer, and may allow the definition of newer and more efficient conditions for in vivo electroporation.     

In vivo DNA electrotransfer into muscle

Naked plasmid DNA injected into skeletal muscle is taken up by muscle cells and the genes in the plasmid are expressed. Among the non-viral techniques for gene transfer in vivo , this method is especially simple, inexpensive, and safe. However, the relatively low expression levels attained by this method have limited its applications for uses other than as a DNA vaccine. We and other groups investigated the applicability of in vivo electroporation for gene transfer into muscle, using plasmid DNA vector. The results demonstrated that gene transfer into muscle by in vivo electroporation is far more efficient than simple intramuscular DNA injection and provides a potential approach to systemically delivering cytokines, growth factors, and other serum proteins for basic research and human gene therapy.     

The feasibility of non-viral gene transfer to the diaphragm in vivo

Gene transfer using electroporation is an essential method for the study of developmental biology, especially to understand the internal control of degeneration and apoptosis of the muscle cells that occurs earlier and quicker than the usual degeneration process occurring by aging. Such experimental studies may have a role in developing new strategies for treating patients suffering from inherited primary myopathies such as Duchenne muscular dystrophy (DMD). The present study was designed to evaluate the feasibility of electroporation mediated transfer of reporter genes to the diaphragm in vivo. This is the first report of gene transfer of naked plasmid DNA into the diaphragm muscle in vivo using electroporation. Our results showed that in vivo gene transfer of naked plasmid DNA into the diaphragm muscle using electroporation is feasible.     

Ex vivo electroporation as a potent new strategy for nonviral gene transfer into autologous vein grafts

Gene transfer to vein grafts has therapeutic potential to prevent late graft failure; however, certain issues, including efficacy and safety, have hindered the clinical application of this treatment modality. Here, we report the successful and efficient gene transfer of plasmid DNA via ex vivo electroporation into veins as well as into vein grafts. Two approaches were used: one involved transluminal in situ gene transfer using a T-shaped electrode (the "Lu" method), and the other was an adventitial ex vivo approach using an electroporation cuvette followed by vein grafting (the "Ad" method). The Lu method was carried out at 10 V, with optimal gene transfer efficiency in the in situ jugular veins of rabbits, and transgene expression was observed primarily in endothelial cells. However, when these veins were grafted into the arterial circulation, no luciferase activity was detected; this effect was probably due to the elimination of the gene-transferred cells as a result of endothelial denudation. In contrast, optimal and satisfactory gene transfer was obtained with the vein grafts subjected to the Ad method at 30 V, and transgene expression was seen primarily in adventitial fibroblasts. Gene transfer of endothelial nitric oxide synthase cDNA to the vein graft via the Ad method successfully limited the extent of intimal hyperplasia, even under hyperlipidemic conditions, at 4 wk after grafting. We thus propose that the Ad method via ex vivo electroporation may provide a novel, safe, and clinically available technique for nonviral gene transfer to sufficiently prevent late graft failure.     

脉冲电场在医学中的基础研究及电穿孔的临床应用

脉冲电场利用方波直流脉冲发生器改变细胞膜的通透性,并在细胞膜上形成纳米级细孔,其被称为电穿孔是一种新型微创技术,分为可逆电穿孔(reversible electroporation)及不可逆电穿孔(irreversible electroporation)。在过去的四十年,电穿孔大量的实验研究及其自身的优点及先进性,使电穿孔相关的技术已被允许应用与临床。目前临床和实验中应用电穿孔的化疗药物已有十余种,通过电穿孔进行基因转染及DNA疫苗的研发已取得巨大成功。尤其近几年发展的非热能的不可逆电穿孔对实体肿瘤的消融作用,为肿瘤治疗提供新的思路,因其比其他局部治疗方法:具有治疗时间短,减少间接热损伤,对毗邻主要血管的肿瘤组织有消融能力等优点引起了对不可逆电穿孔巨大的临床研究兴趣。本文就电穿孔的基本理论,电化学治疗,基因电转染及不可逆电穿孔的临床应用进行探讨。     

Genetic manipulation of adult mouse neurogenic niches by in vivo electroporation

Targeted ectopic expression of genes in the adult brain is an invaluable approach for studying many biological processes. This can be accomplished by generating transgenic mice or by virally mediated gene transfer, but these methods are costly and labor intensive. We devised a rapid strategy that allows localized in vivo transfection of plasmid DNA within the adult neurogenic niches without detectable brain damage. Injection of plasmid DNA into the ventricular system or directly into the hippocampus of adult mice, followed by application of electrical current via external electrodes, resulted in transfection of neural stem or progenitor cells and mature neurons. We showed that this strategy can be used for both fate mapping and gain- or loss-of-function experiments. Using this approach, we identified an essential role for cadherins in maintaining the integrity of the lateral ventricle wall. Thus, in vivo electroporation provides a new approach to study the adult brain.     

In Vivo Muscle Electroporation Threshold Determination: Realistic Numerical Models and In Vivo Experiments

In vivo electroporation is used as an effective technique for delivery of therapeutic agents such as chemotherapeutic drugs or DNA into target tissue cells for different biomedical purposes. In order to successfully electroporate a target tissue, it is essential to know the local electric field distribution produced by an application of electroporation voltage pulses. In this study three-dimensional finite element models were built in order to analyze local electric field distribution and corresponding tissue conductivity changes in rat muscle electroporated either transcutaneously or directly (i.e., two-plate electrodes were placed either on the skin or directly on the skeletal muscle after removing the skin). Numerical calculations of electroporation thresholds and conductivity changes in skin and muscle were validated with in vivo measurements. Our model of muscle with skin also confirms the in vivo findings of previous studies that electroporation “breaks” the skin barrier when the applied voltage is above 50?V.     

Numerical modeling of in vivo plate electroporation thermal dose assessment

Electroporation is an approach used to enhance the transport of large molecules to the cell cytosol in which a targeted tissue region is exposed to a series of electric pulses. The cell membrane, which normally acts as a barrier to large molecule transport into the cell interior, is temporarily destabilized due to the development of pores in the cell membrane. Consequently, agents that are ordinarily unable enter the cell are able to pass through the cell membrane. Of possible concern when exposing biological tissue to an electric field is thermal tissue damage associated with joule heating. This paper explores the thermal effects of various geometric, biological, and electroporation pulse parameters including the blood vessel presence and size, plate electrode configuration, and pulse duration and frequency. A three-dimensional transient finite volume model of in vivo parallel plate electroporation of liver tissue is used to develop a better understanding of the underlying relationships between the physical parameters involved with tissue electroporation and resulting thermal damage potential.     

Intramuscular electroporation with the pro-opiomelanocortin gene in rat adjuvant arthritis

Endogenous opioid peptides have an essential role in the intrinsic modulation and control of inflammatory pain, which could be therapeutically useful. In this study, we established a muscular electroporation method for the gene transfer of pro-opiomelanocortin (POMC) in vivo and investigated its effect on inflammatory pain in a rat model of rheumatoid arthritis. The gene encoding human POMC was inserted into a modified pCMV plasmid, and 0-200 microg of the plasmid-POMC DNA construct was transferred into the tibialis anterior muscle of rats treated with complete Freund's adjuvant (CFA) with or without POMC gene transfer by the electroporation method. The safety and efficiency of the gene transfer was assessed with the following parameters: thermal hyperalgesia, serum adrenocorticotropic hormone (ACTH) and endorphin levels, paw swelling and muscle endorphin levels at 1, 2 and 3 weeks after electroporation. Serum ACTH and endorphin levels of the group into which the gene encoding POMC had been transferred were increased to about 13-14-fold those of the normal control. These levels peaked 1 week after electroporation and significantly decreased 2 weeks after electroporation. Rats that had received the gene encoding POMC had less thermal hypersensitivity and paw swelling than the non-gene-transferred group at days 3, 5 and 7 after injection with CFA. Our promising results showed that transfer of the gene encoding POMC by electroporation is a new and effective method for its expression in vivo, and the analgesic effects of POMC cDNA with electroporation in a rat model of rheumatoid arthritis are reversed by naloxone.     

The importance of electric field distribution for effective in vivo electroporation of tissues.

Cells exposed to short and intense electric pulses become permeable to a number of various ionic molecules. This phenomenon was termed electroporation or electropermeabilization and is widely used for in vitro drug delivery into the cells and gene transfection. Tissues can also be permeabilized. These new approaches based on electroporation are used for cancer treatment, i.e., electrochemotherapy, and in vivo gene transfection. In vivo electroporation is thus gaining even wider interest. However, electrode geometry and distribution were not yet adequately addressed. Most of the electrodes used so far were determined empirically. In our study we 1) designed two electrode sets that produce notably different distribution of electric field in tumor, 2) qualitatively evaluated current density distribution for both electrode sets by means of magnetic resonance current density imaging, 3) used three-dimensional finite element model to calculate values of electric field for both electrode sets, and 4) demonstrated the difference in electrochemotherapy effectiveness in mouse tumor model between the two electrode sets. The results of our study clearly demonstrate that numerical model is reliable and can be very useful in the additional search for electrodes that would make electrochemotherapy and in vivo electroporation in general more efficient. Our study also shows that better coverage of tumors with sufficiently high electric field is necessary for improved effectiveness of electrochemotherapy.     

Screening for gene function in chicken embryo using RNAi and electroporation

In the postgenomic era the elucidation of the physiological function of genes has become the rate-limiting step in the quest to understand the development and function of living organisms. Gene functions cannot be determined by high-throughput methods but require analysis in the context of the entire organism. This is particularly true in the developing vertebrate nervous system. Because of its easy accessibility in the egg, the chicken embryo has been the model of choice for developmental in vivo studies. However, its usefulness has been hampered by a lack of methods for genetic manipulation. Here we describe an approach that could compensate for this disadvantage. By combining gene silencing by dsRNA (through RNA interference, RNAi) with in ovo electroporation, we developed an efficient method to induce loss of gene function in vivo during the development of the chicken CNS. This method opens new possibilities for studying gene function not only by gain-of-function but also by loss-of-function approaches and therefore represents a new tool for functional genomics.     

Electroporation enhances c-myc antisense oligodeoxynucleotide efficacy.

Obtaining high transfection efficiencies and achieving appropriate intracellular concentrations and localization are two of the most important barriers to the implementation of gene targeted therapy. The efficiency of endogenous uptake of oligodeoxynucleotides (ODNs) varies from cell type to cell type and may be a limiting factor of antisense efficacy. The use of electroporation to obtain high intracellular concentrations of a synthetic ODN in essentially 100% of viable cells is described. It is also shown that the transfected ODNs initially localize to the nucleus and remain there for at least 48 hours. The cellular trafficking of electroporated ODNs is shown to be an energy dependent process. Targeting of the c-myc proto-oncogene of U937 cells by electroporation of phosphorothioate-modified ODNs results in rapid and specific suppression of this gene at ODN concentrations much lower than would otherwise be required. This technique appears to be applicable to a variety of cell types and may represent a powerful new investigate tool as well as a promising approach to the ex vivo treatment of hematologic disorders.