Electroporation Medium Research Articles

Artificial activation of porcine oocytes matured in vitro

These studies were undertaken to understand the biological basis of artificially induced activation of meiotic metaphase II oocytes and to develop a source of oocytes as recipients for cloning by nuclear transfer. In vitro matured porcine oocytes were pulsed with various voltages of electricity and evaluated for pronuclear formation. The percentage of eggs that activated was significantly greater for the higher voltages. The effect on activation of the temperature of the ovaries returning from the abattoir was evaluated and it was found that oocytes derived from ovaries returning at 29 degrees C activated at lower rates (45.5%) than those returning at 36 degrees C (78.9%). An experiment was designed to evaluate the pH of electroporation medium (EM) and the duration of exposure to EM on activation. Oocytes were placed in EM at various pHs for 5 minutes, pulsed, and immediately removed to TL-Hepes or allowed an additional 2 minutes in EM prior to rinsing in TL-Hepes. The results indicate an optimum activation rate at a pH of 7.0 and allowing the additional 2 minutes in EM. Additional glucosamine (5 mM) had no affect on development of the oocyte to metaphase but reduced the percent pronuclear formation from 61% and 47%. A final experiment evaluated the developmental competence of oocytes subjected to a optimum combination of the above treatments and illustrated that a significant portion of the activated oocytes can show limited signs of cleavage. Thus in vitro matured pig oocytes can be induced to activate at high rates.

Introduction of unlabeled proteins into living cells by electroporation and isolation of viable protein-loaded cells using dextran-fluorescein isothiocyanate as a marker for protein uptake

Commonly, microinjection has been the method of choice for introducing proteins into living cells. Viable cells containing an introduced protein can be then identified providing that the protein is fluorochrome conjugated. This approach is applicable only for adherent cells, and the number of cells that can be analyzed is small. In this study, we have established that electroporation can be used to load proteins into large numbers of cells with high efficiency. Furthermore, we have developed a method for the isolation of protein-loaded cells using fluorescein isothiocyanate—dextran (dextran—FITC) as a molecular marker for protein uptake. The essential features of this method are that dextran—FITC is included in the electroporation medium and, thus, is cointroduced with the protein of interest. Purification of cells containing dextran—FITC using fluorescence-activated cell sorting yields a population which is composed almost entirely of cells containing the protein of interest.

Transformation of Rhodococcus fascians by High-Voltage Electroporation and Development of R. fascians Cloning Vectors

The analysis of the virulence determinants of phytopathogenic Rhodococcus fascians has been hampered by the lack of a system for introducing exogenous DNA. We investigated the possibility of genetic transformation of R. fascians by high-voltage electroporation of intact bacterial cells in the presence of plasmid DNA. Electrotransformation in R. fascians D188 resulted in transformation frequencies ranging from 10/mug of DNA to 10/mug of DNA, depending on the DNA concentration. The effects of different electrical parameters and composition of electroporation medium on transformation efficiency are presented. By this transformation method, a cloning vector (pRF28) for R. fascians based on an indigenous 160-kilobase (chloramphenicol and cadmium resistance-encoding) plasmid pRF2 from strain NCPPB 1675 was developed. The origin of replication and the chloramphenicol resistance gene on pRF28 were used to construct cloning vectors that are capable of replication in R. fascians and Escherichia coli. The electroporation method presented was efficient enough to allow detection of the rare integration of replication-deficient pRF28 derivatives in the R. fascians D188 genome via either homologous or illegitimate recombination.

DNA uptake during electroporation of germinating pollen grains

Electroporation of germinating pollen grains of Nicotiana gossei (L.) Domin under a variety of conditions showed that DNA was taken up by the pollen without detrimental effects on the viability of the pollen. By optimizing both the field strength of the electroporation pulse and the DNA concentration in the electroporation medium up to 6% of the donor DNA can be taken up by the germinating pollen while maintaining a pollen viability of 90%. Field strengths as high as 9 kV/cm could be applied to germinating pollen grains without detrimental effects on viability. Southern hybridizations demonstrated that DNA encoding the marker enzyme β-glucuronidase (GUS) was incorporated into electroporated pollen. Germinating pollen, treated in this manner, is capable of producing 300–400 seeds per capsule of viable seed when applied to the stigmas of compatible flowers of N. gossei which has been emasculated 4 days earlier.

The osmolarity of the electroporation medium affects the transient expression of genes

The osmolarity of the electroporation medium affects the transient expression of genes

Properties of electroporation-mediated DNA transfer in Escherichia coli.

Efficient and reproducible DNA-transfection was attained in E. coli, by electroporation. The yield of the transfectants was affected by pretreatment of the recipient cells as well as by the composition of the electroporation medium. Using a single pulse procedure, relationships among the electrical parameters, the transfection efficiency, and the cellular viability were investigated in 10 mM Tris-HCl buffer (pH 7.5) containing 5% sucrose. Certain sodium salts (e.g., citrate, phosphate, and sulfate) were promotive, whereas Mg2+, DEAE-dextran, and polyvinylpyrrolidone were inhibitory to the transfection. Heterologous nucleic acids (native DNA, denatured DNA, and tRNA) exerted only a marginal effect on transfection with a viral replicative-form DNA. The efficiency of DNA transfer was affected by culture conditions, and bacteria grown at a higher temperature were more competent. The electroporation system was more efficient than an improved CaCl2 method, not only in transfection with viral single- and double-stranded DNAs, but also in transformation with plasmid DNAs.

Gene transfer by electroporation in betulaceae protoplasts: Alnus incana

The Escherichia coli β-glucuronidase gene (GUS) was introduced into Alnus incana (L.) Moench protoplasts by electroporation. Level of GUS transient gene expression was increased by increasing DNA concentrations of pBI 221 plasmid and was affected by the amplitude and duration of the applied electric pulse as well as by the presence of polyethylene glycol (PEG) in the electroporation medium. An optimal level of GUS activity was obtained after electroporation with a capacitive discharge of 500 V/cm and 71 ms-duration. This transformation procedure is simple and efficient. These results motivated us to investigate this method as a possible way of achieving the stable transformation of actinorhizal alder.

Genetic transformation of Streptococcus thermophilus by electroporation

A rapid and convenient electroporation procedure was developed for the genetic transformation of intact cells of Streptococcus thermophilus with various species of plasmid DNA. Transformation frequency was influenced by the capacitance and voltage selected for electric pulsing, the pH and composition of the electroporation medium and the molecular mass of the transforming DNA. Electroporation is a simple and effective technique to introduce plasmid DNA into S. thermophilus and useful in the development of recombinant DNA technology for this important industrial microorganism.

Use of a transient expression assay for the optimization of direct gene transfer into tobacco mesophyll protoplasts by electroporation

Plasmid DNA was transfected into tobacco mesophyll protoplasts by electroporation. Transfection efficiency was estimated, using a transient expression assay based on the measurement of chloramphenicol transacetylase activity or by scoring colonies expressing resistance to paromomycin, an aminoglycoside related to kanamycin. Under conditions of cell survival superior to 50% after electroporation, transient expression signals and transformation efficiencies were found to be proportional. Factors affecting the efficiency of transformation were studied. A clear-cut optimum voltage (250–300 V/cm) was detected. Among various salts tested, potassium chloride was the best electrolyte. No improvement of electroporation efficiency was obtained by a heat - shock (45°C/5 min) treatment prior to electroporation or by the presence of polyethylene glycol in the electroporation medium. The physiological state of plants used as the protoplast source significantly affected the transfection ability of the resulting protoplasts. These results are discussed and compared to previously published procedures.

Expression of genes transferred into monocot and dicot plant cells by electroporation.

We have developed a general method for electrically introducing DNA into plant cells. Gene transfer occurs when a high-voltage electric pulse is applied to a solution containing protoplasts and DNA. Carrot protoplasts were used as a model system to optimize gene-transfer efficiency, which was measured 24-48 hr after electroporation by the amount of chloramphenicol acetyltransferase activity resulting from the expression of the introduced chimeric plasmids. Gene-transfer efficiency increased with the DNA concentration and was affected by the amplitude and duration of the electric pulse as well as by the composition of the electroporation medium. Our optimized gene-transfer conditions were effective when applied to tobacco and maize protoplasts, demonstrating that the method is applicable to both monocot and dicot protoplasts.