Introduction of deoxyribonucleoside triphosphates into intact cells by electroporation

A method for functional evaluation of caspase activation pathways in intact lymphoid cells using electroporation-mediated protein delivery and flow cytometric analysis

The purpose of the study was to develop a rapid technique for determining the functional status of caspase activation pathways in intact lymphocytes. Proteins known to activate caspase-family cell death proteases (cytochrome c; granzyme-B; caspase-8) were introduced into human leukemia and lymphoma cell lines, as well as freshly isolated lymphocytes and leukemia cells, by electroporation. Fluorochrome-labeled proteins with a wide range of molecular weights (from 15 to 150 kDa) were used to evaluate electroporation efficiency by flow cytometry and to compare the efficiency of protein delivery using various electroporation conditions. Caspase activity was monitored using a cleavable, cell-permeable fluorogenic substrate. Conditions were identified for efficient delivery of proteins of +150 kDa into lymphoid cells. Caspase activation induced by various proteins was compared in normal and leukemic lymphocytic cells, revealing impaired caspase activation pathways in some malignant cells. We conclude that electroporation of apoptotic proteins into intact lymphoid cells can be used to contrast the status of various caspase activation pathways, thereby providing insights into the pathological defects in apoptosis regulation that exist in individual patient specimens.

Genetic transformation of plants by protoplast electroporation

This article describes an optimized protocol for the electroporation of tobacco mesophyll protoplasts together with notes and data on the effects of various parameters and suggestions for work with protoplasts of other species. In this protocol, electroporation is achieved by means of electrical pulses from a high-voltage, capacitive-discharge unit. Procedures are described for measurement of protoplast viability with Evan's blue, the detection of transient expression of CAT and GUS gene plasmid constructs, and for the recovery of stable transformants based on selection for kanamycin resistance.

Cell electropermeabilization: a new tool for biochemical and pharmacological studies

Cell electropermeabilization is the transient permeabilization of the plasma membrane by means of short and intense electric pulses. Under optimized conditions, electropermeabilization is compatible with cell survival. It provides a direct access into the cytosol to ions, small molecules, exogenous drugs and macromolecules. As cells remain functional, a large variety of cell biology questions can be addressed. Such 'in situ biochemistry' opens new possibilities beside the more classical studies dealing with unpermeabilized cells or subcellular extracts. Electropermeabilization also allows pharmacological studies with cells, cultured monolayers and in vivo tissues as well as the design of drug controlled-release systems.

Electroporation of extraneous proteins into CHO cells: increased efficacy by utilizing centrifugal force and microsecond electrical pulses

A novel electroporation system employing an oscillating electric pulse and centrifugal force was used to introduce extraneous proteins into CHO cells. Following the electrical pulse, the compression and subsequent rebound induced by the centrifugal acceleration and deceleration, respectively, enhanced protein uptake, presumably by a hydrodynamic pumping of extracellular solutions through the permeabilized membrane. Protein uptake was quantitated by measuring the amount of radiolabeled, extraneous, CHO proteins introduced into unlabeled CHO cells. The amount of protein introduced into electroporated CHO cells was enhanced up to four-fold by a combination of electric pulse and centrifugal force compared to that introduced by electric pulse only. The optimum gradient of centrifugal force (GCF, temporal change of centrifugal force) was 590 and -470 g/s during acceleration and deceleration, respectively. The optimum electric field was 5 kV/cm with a 30-microsecond pulse length. At this optimum electroporation condition, approximately 5 pg of proteins (up to 200 kDa molecular weight) were introduced per CHO cell. These same settings also permitted electroporation of other membrane impermeable substances including propidium iodide and ethidium bromide. Introduction of extraneous materials into the cytoplasm during electroporation was confirmed by the ability of anti alpha-tubulin to stain the microtubules and propidium iodide and ethidium bromide to stain the nuclei. Cells electroporated with optimum device settings exhibited no significant decrease in clonogenic survival.

Introduction of exogenous DNA into Chlamydomonas reinhardtii by electroporation

The fate of exogenous DNA introduced into Chlamydomonas reinhardtii by electroporation was analyzed. With single and double electrical pulses, plasmids as large as 14 kb were introduced into cells with and without intact cell walls. Within hours after introduction, exogenous plasmid DNA was associated with nuclei isolated from cells; several weeks after introduction, exogenous DNA was stably integrated into the Chlamydomonas genome. These studies establish electroporation as a method for introducing DNA, and potentially other molecules, into C. reinhardtii.

Introduction of exogenous DNA into Chlamydomonas reinhardtii by electroporation

The fate of exogenous DNA introduced into Chlamydomonas reinhardtii by electroporation was analyzed. With single and double electrical pulses, plasmids as large as 14 kb were introduced into cells with and without intact cell walls. Within hours after introduction, exogenous plasmid DNA was associated with nuclei isolated from cells; several weeks after introduction, exogenous DNA was stably integrated into the Chlamydomonas genome. These studies establish electroporation as a method for introducing DNA, and potentially other molecules, into C. reinhardtii.

Metabolism and toxicity of electroporated 1-beta-D-arabinofuranosylcytosine triphosphate in a human leukemia cell line

The metabolism and toxicity of 1-beta-D-arabinofuranosylcytosine triphosphate (ara-CTP) directly injected into cells by electroporation was studied in human leukemia cell lines. The intracellular accumulation of ara-CTP (ara-CTP-Ep) was dependent on the cell type, extracellular ara-CTP concentration and pulse voltage on electroporation. In a promyelocytic leukemia cell line, HL-60, ara-CTP-Ep revealed a cytotoxic effect in a dose-dependent manner, although electroporation alone did not have any significant toxicity. Furthermore, simultaneous injection of dCTP, or continuous exposure to deoxycytidine, but not to other deoxyribonucleosides, immediately after electroporation rescued the cells from the toxicity of ara-CTP-Ep. The degradation of ara-CTP-Ep consisted of an early rapid phase followed by a slower phase with a half life of 1.5 h. The addition of dipyridamole (10 microM), an inhibitor of nucleoside transport, retarded this degradation process. These data indicate that transfer of ara-CTP by electroporation is a useful method for the study of ara-CTP metabolism.

Electroporation of adherent cells in situ

A simple, rapid, and reproducible procedure for the introduction of macromolecules into adherent mammalian cells by electroporation is described. Cells were growing on a glass surface coated with electrically conductive, optically transparent indium-tin oxide at the time of pulse delivery. Several factors affected the optimal voltage for permeation of a given line including the metabolic state of the cells and their degree of spreading onto the conductive growth surface. Careful control of the electric field strength resulted in almost 100% of the cells containing introduced antibodies without any detectable change in the length of their division cycle. Higher voltages were required for the stable expression of DNA than for the introduction of antibodies, resulting in a significant rate of cell death.

Stable, resealable pores formed in sea urchin eggs by electric discharge (electroporation) permit substrate loading for assay of enzymes in vivo

We describe a simple electroporation procedure for loading suspensions of unfertilized sea urchin eggs with impermeant small molecules under conditions that allow close to 90% successful fertilization and development. Poration is carried out in a low-Ca2+ medium that mimicks the intracellular milieu. The induced pores remain open for several minutes in this medium, allowing loading of the cells; resealing is achieved by adding back millimolar calcium ions to the medium. While the pores are open, an influx of exogenous molecules and efflux of endogenous metabolites takes place, and the eggs can lose up to 40% of their ATP content and still survive. Introduced metabolites are utilized by the cells, e.g., introduced 3H-thymidine is incorporated into DNA. This procedure will be useful for loading impermeant substrates into eggs, permitting in vivo assessment of metabolism, and also for introducing other interesting impermeant molecules, such as inhibitors, fluorescent indicators, etc. Though the details may differ, the principle of electroporation in an intracellular-like medium may prove to be useful for loading other cell types with minimal loss of viability.

Electric-field-induced permeabilization and fusion of embryonic amphibian cells

The technique of electropulsation has been shown to be highly efficient in promoting penetration of exogenous molecules into living cells, transfection, and cell fusion in different animal, vegetal, and bacterial cell systems. Introduction of such exogenous compounds, i.e., plasmids, into living cells is of great interest for embryological studies. Embryonic amphibian ectodermal cells from Pleurodeles waltl gastrulae, either freshly dissociated or cultured for 5 days, can be permeabilized when submitted to an external electric field of sufficient intensity: 500 V/cm for isolated spherical cells and 150-200 V/cm for plated cultured cells. Permeabilization was indicated by both the leakage of metabolites (ATP) from the cells and the uptake of exogenous compounds (pyranin) into the cells. With the use of higher field intensities (600 V/cm for freshly dissociated cells and 300 V/cm for cultured cells) cell fusion and syncytial structures could also be obtained. Isolated spherical cells had 100% viability immediately after being pulsed at intensities up to 600 V/cm. Cell lysis was observed above this value, although the nonlysed cells were observed to spread on a substrate and differentiate normally. For the cultured plated cells, cell viability fell with increasing electric-field strength, and for a given electric field value, cell viability decreased with the age of the culture after pulsing. Nevertheless, for electric-field intensities less than or equal to 300 V/cm, 100% of the cells remained attached to the substrate and differentiated normally over the following 5 days.

Induction of cervical neoplasia in the mouse by herpes simplex virus type 2 DNA

Induction of cervical neoplasia in the mouse cervix by herpes simplex virus types 1 (HSV-1) and 2 (HSV-2) has been reported. The present study was done to determine if transfection with DNA of HSV-2 can induce carcinogenesis in this animal model. Genomic HSV-2 DNA was isolated from infected HEp-2 cells and separated from host cell DNA by cesium chloride density gradient centrifugation. The DNA was applied to mouse cervix for periods of 80-100 weeks. Experimental controls were treated with uninfected genomic HEp-2 cell DNA or with calf thymus DNA. Vaginal cytological preparations from all animals were examined monthly to detect epithelial abnormalities. Animals were sacrificed and histopathology studies were done when cellular changes indicative of premalignant or malignant lesions were seen on vaginal smears. Cytologic and histologic materials were coded and evaluated without knowledge of whether they were from animals treated with virus or control DNA. Premalignant and malignant cervical lesions similar to those that occur in women were detected in 61% of the histologic specimens obtained from animals exposed to HSV-2 DNA. The yield of invasive cancers was 21% in animals treated with HSV-2 DNA. No cancers were detected in mice treated with either HEp-2 or calf thymus DNA. Dysplasia was detected in only one of these control animals.

Use of electroporation for high-molecular-weight DNA-mediated gene transfer

Electroporation was used to introduce high-molecular-weight DNA into murine hematopoietic cells and NIH3T3 cells. CCRF-CEM cells were stably transfected with SV2NEO plasmid and the genomic DNA from G-418-resistant clones (greater than 65 kb) was introduced into mouse bone marrow and NIH3T3 cells by electroporation. NEO sequences and expression were detected in the hematopoietic tissues of lethally irradiated mice, with 24% of individual spleen colonies expressing NEO. The frequency of genomic DNA transfer into NIH3T3 cells was 0.25 X 10(-3). Electroporation thus offers a powerful mode of gene transfer not only of cloned genes but also of high-molecular-weight DNA into cells.

Use of electroporation to study the cytotoxic effects of fluorodeoxyuridylate in intact cells

The introduction of 2'-deoxyuridine 5'-monophosphate and its analog, 5-fluoro-2'-deoxyuridine 5'-monophosphate, into intact CCRF-CEM and NIH3T3 cells was achieved by electroporation. Following electroporation, cells were shown to be fully functional as monitored by the incorporation of deoxyuridylate, after conversion to thymidylate, into DNA. Pretreatment of cells with fluorodeoxyuridine completely abolished this effect. In contrast, introduction of the fluoro analog into cells by electroporation markedly inhibited both DNA synthesis and cell growth in a time-dependent manner. Thus, electroporation offers a powerful tool to permeabilize cells to a variety of cellular metabolites and antimetabolites.