Influence of Plasmid Concentration on DNA Electrotransfer In Vitro Using High-Voltage and Low-Voltage Pulses

DNA electrotransfer in vivo for gene therapy is a promising method. For further clinical developments, the efficiency of the method should be increased. It has been shown previously that high efficiency of gene electrotransfer in vivo can be achieved using high-voltage (HV) and low-voltage (LV) pulses. In this study we evaluated whether HV and LV pulses could be optimized in vitro for efficient DNA electrotransfer. Experiments were performed using Chinese hamster ovary (CHO) cells. To evaluate the efficiency of DNA electrotransfer, two different plasmids coding for GFP and luciferase were used. For DNA electrotransfer experiments 50 μl of CHO cell suspension containing 100, 10 or 1 μg/ml of the plasmid were placed between plate electrodes and subjected to various combinations of HV and LV pulses. The results showed that at 100 μg/ml plasmid concentration LV pulse delivered after HV pulse increased neither the percentage of transfected cells nor the total transfection efficiency (luciferase activity). The contribution of the LV pulse was evident only at reduced concentration (10 and 1 μg/ml) of the plasmid. In comparison to HV (1,200 V/cm, 100 μs) pulse, addition of LV (100 V/cm, 100 ms) pulse increased transfection efficiency severalfold at 10 μg/ml and fivefold at 1 μg/ml. At 10 μg/ml concentration of plasmid, application of four LV pulses after HV pulse increased transfection efficiency by almost 10-fold. Thus, these results show that contribution of electrophoretic forces to DNA electrotransfer can be investigated in vitro using HV and LV pulses.     

Genetic transformation of intact Lactococcus lactis subsp. lactis by high-voltage electroporation

To apply recombinant DNA techniques for genetic manipulation of the industrially important lactococci, an efficient and reliable high-frequency transformation system must be available. High-voltage electric pulses have been demonstrated to enhance uptake of DNA into protoplasts and intact cells of numerous gram-negative and gram-positive microorganisms. The objective of this study was to develop a system for electroporating intact cells of Lactococcus lactis subsp. lactis LM0230 (previously designated Streptococcus lactis LM0230) with a commercially available electroporation unit (BTX Transfector 100; BTX, Inc., San Diego, Calif.). Parameters which influenced the efficiency of transformation included growth phase and final concentration of cells, ionic strength of the suspending medium, concentration of plasmid DNA, and the amplitude and duration of the pulse. Washed suspensions of intact cells suspended in deionized distilled water were subjected to one high-voltage electric pulse varying in voltage (300 to 900 V corresponding to field strengths of 5 to 17 kV/cm) and duration (100 microseconds to 1 s). Transformation efficiencies of 10(3) transformants per microgram of DNA were obtained when dense suspensions (final concentration, 5 x 10(10) CFU/ml) of stationary-phase cells were subjected to one pulse with a peak voltage of 900 V (field strength, 17 kV/cm) and a pulse duration of 5 ms in the presence of plasmid DNA. Dilution of porated cells in broth medium followed by an expression period of 2 h at 30 degrees C was beneficial in enhancing transformation efficiencies. Plasmids ranging in size from 9.8 to 30.0 kilobase pairs could be transformed by this procedure.     

Genetic transformation of intact Lactococcus lactis subsp. lactis by high-voltage electroporation.

To apply recombinant DNA techniques for genetic manipulation of the industrially important lactococci, an efficient and reliable high-frequency transformation system must be available. High-voltage electric pulses have been demonstrated to enhance uptake of DNA into protoplasts and intact cells of numerous gram-negative and gram-positive microorganisms. The objective of this study was to develop a system for electroporating intact cells of Lactococcus lactis subsp. lactis LM0230 (previously designated Streptococcus lactis LM0230) with a commercially available electroporation unit (BTX Transfector 100; BTX, Inc., San Diego, Calif.). Parameters which influenced the efficiency of transformation included growth phase and final concentration of cells, ionic strength of the suspending medium, concentration of plasmid DNA, and the amplitude and duration of the pulse. Washed suspensions of intact cells suspended in deionized distilled water were subjected to one high-voltage electric pulse varying in voltage (300 to 900 V corresponding to field strengths of 5 to 17 kV/cm) and duration (100 microseconds to 1 s). Transformation efficiencies of 10(3) transformants per microgram of DNA were obtained when dense suspensions (final concentration, 5 x 10(10) CFU/ml) of stationary-phase cells were subjected to one pulse with a peak voltage of 900 V (field strength, 17 kV/cm) and a pulse duration of 5 ms in the presence of plasmid DNA. Dilution of porated cells in broth medium followed by an expression period of 2 h at 30 degrees C was beneficial in enhancing transformation efficiencies. Plasmids ranging in size from 9.8 to 30.0 kilobase pairs could be transformed by this procedure.     

The Role of Electrophoresis in Gene Electrotransfer

Gene electrotransfer is an established method for gene delivery which uses high-voltage pulses to increase the permeability of a cell membrane and enables transfer of genes. Poor plasmid mobility in tissues is one of the major barriers for the successful use of gene electrotransfer in gene therapy. Therefore, we analyzed the effect of electrophoresis on increasing gene electrotransfer efficiency using different combinations of high-voltage (HV) and low-voltage (LV) pulses in vitro on CHO cells. We designed a special prototype of electroporator, which enabled us to use only HV pulses or combinations of LV + HV and HV + LV pulses. We used optimal plasmid concentrations used in in vitro conditions as well as lower suboptimal concentrations in order to mimic in vivo conditions. Only for the lowest plasmid concentration did the electrophoretic force of the LV pulse added to the HV pulse increase the transfection efficiency compared to using only HV. The effect of the LV pulse was more pronounced for HV + LV, while for the reversed sequence, LV + HV, there was only a minor effect of the LV pulse. For the highest plasmid concentrations no added effect of LV pulses were observed. Our results suggest that there are different contributing effects of LV pulses: electrophoretically increased contact of DNA with the membrane and increased insertion of DNA into permeabilized cell membrane and/or translocation due to electrophoretic force, which appears to be the dominant effect.     

低压脉冲电泳介导的外源基因转化部分酶解的水稻小细胞团

开发了一类新型的低压脉冲电泳法介导外源基因进入水稻细胞的转化系统。本系统以水稻部分酶解小细胞团为受体,采用低压脉冲电泳推动质核DNA进入水稻细胞。以报告基因GUS酶活性为指标,借以测定转化了的水稻细胞。最佳的组合处理可以获得8.2％的转化频率。文中对低压脉冲电泳转移外源基因的条件亦作了讨论。     

Efficient DNA transformation of Bradyrhizobium japonicum by electroporation.

Intact cells of Bradyrhizobium japonicum USDA 110 were transformed with a 30-kilobase plasmid to efficiencies of 10(6) to 10(7) transformants per microgram by high-voltage electroporation. The technique was reliable and simple, with single colonies arising from transformed cells within 5 days of antibiotic selection. Plasmid DNA from B. japonicum transformed the Bradyrhizobium (Arachis) sp. with high efficiency, while the same plasmid extracted from Escherichia coli transformed B. japonicum at very low efficiency. The electrical conditions that resulted in the highest efficiencies were high voltage (10.5 to 12.5 kV/cm) and short pulse length (6 to 7 ms). A linear increase in the number of transformants was observed as DNA concentration was increased over 4 orders of magnitude; saturation appeared to begin between 120 ng/ml and 1.2 micrograms/ml. This novel method of transformation should enhance B. japonicum genetic research by providing a valuable alternative to conjugal mating, which is currently the only efficient, widely used means of introducing DNA into this organism.     

Efficient DNA transformation of Bradyrhizobium japonicum by electroporation

Intact cells of Bradyrhizobium japonicum USDA 110 were transformed with a 30-kilobase plasmid to efficiencies of 10(6) to 10(7) transformants per microgram by high-voltage electroporation. The technique was reliable and simple, with single colonies arising from transformed cells within 5 days of antibiotic selection. Plasmid DNA from B. japonicum transformed the Bradyrhizobium (Arachis) sp. with high efficiency, while the same plasmid extracted from Escherichia coli transformed B. japonicum at very low efficiency. The electrical conditions that resulted in the highest efficiencies were high voltage (10.5 to 12.5 kV/cm) and short pulse length (6 to 7 ms). A linear increase in the number of transformants was observed as DNA concentration was increased over 4 orders of magnitude; saturation appeared to begin between 120 ng/ml and 1.2 micrograms/ml. This novel method of transformation should enhance B. japonicum genetic research by providing a valuable alternative to conjugal mating, which is currently the only efficient, widely used means of introducing DNA into this organism.     

Transformation of Acetobacter xylinum with plasmid DNA by electroporation.

Genetic analysis of Acetobacter xylinum, a cellulose-synthesizing bacterium, has been limited by lack of a successful transformation method. Transformation of A. xylinum was attempted using two broad-host-range plasmids (pUCD2 and pRK248) and a variety of transformation methods. Methods using CaCl2, freeze/thaw treatments, and polyethylene glycol were unsuccessful. Transformation of a cellulose-negative strain of A. xylinum with plasmid DNA has been achieved with high-voltage electroporation. Electroporation conditions of 25 microF capacitance, 2.5 kV, 400 ohms resistance, and pulse lengths of 6-8 ms were applied to a cell/DNA mixture in a 0.2-cm cuvette. Plasmid pUCD2 transformed at an efficiency of 10(6)-10(7) transformants/micrograms DNA and pRK248 yielded 10(5) transformants/micrograms DNA. The frequency of transformation increased linearly with increasing DNA concentration, while transformation efficiency remained constant. pUCD2 was recovered from transformants following chloramphenicol amplification and observed by agarose gel electrophoresis. Both plasmids could be reisolated from Escherichia coli after back-transformation with alkaline lysis DNA preparations from Acetobacter transformants. Electro-transformation of A. xylinum with plasmid DNA suggests its potential use for analysis of the A. xylinum genome.     

Characterization of DNA degradation using direct current conductivity and dynamic dielectric relaxation techniques

The purpose of this study was to evaluate DNA degradation upon thermal heating using dielectric relaxation and direct current (DC) conductivity methods. Herring sperm DNA, human growth hormone (HgH) plasmid DNA, and secreted alkaline phosphatase (SEAP) plasmid DNA were used as the examples. DNA was heated at 80°C for 1 hour. The dielectric relaxation spectra as a function of the applied field frequency were measured for HgH DNA at 0.5 hours and at 1 hour. The frequency range covered was from 10 kHz to 100 kHz. The DC conductivity measurements were made for all 3 kinds of DNA at 4 time points: 0 hours, 0.5 hours, 0.75 hours, and 1 hour. At each time point the DC conductivity was measured for each sample as a function of concentration via water dilution. The results show that the dielectric relaxation method is less sensitive in characterizing heat-driven DNA degradation. Conversely, DC conductivity is very sensitive. The semiquantitative dependence of the conductivity upon heating suggests that DNA degradation involves more than plasmid DNA nicking. Double strand and single strand breaks may also occur. In addition, herring sperm DNA, HgH DNA, and SEAP DNA, though similar in their DC conductivity functional forms upon dilution, exhibit significant differences in their responses to sustained heating.     

Study of mechanisms of electric field-induced DNA transfection. I. DNA entry by surface binding and diffusion through membrane pores.

A study of mechanisms of electrotransfection using Escherichia coli (JM 105) and the plasmid DNA pBR322 as model system is reported. pBR322 DNA carries an ampicillin resistance gene: E. coli transformants are conveniently assayed by counting colonies in a selection medium containing 50 micrograms/ml ampicillin and 25 micrograms/ml streptomycin. Samples not exposed to the electric field showed no transfection. In the absence of added cations, the plasmid DNA remains in solution and the efficiency of the transfection was 2 x 10(6)/micrograms DNA for cells treated with a 8-kV/cm, 1-ms electric pulse (square wave). DNA binding to the cell membrane greatly enhanced the efficiency of the transfection and this binding was increased by milimolar concentrations of CaCl2, MgCl2, or NaCl (CaCl2 greater than MgCl2 greater than NaCl). For example, in the presence of 2.5 mM CaCl2, 55% of the DNA added bound to E. coli and the transfection efficiency was elevated by two orders of magnitude (2 x 10(8)/micrograms DNA). These ions did not cause cell aggregation. With a low ratio of DNA to cells (less than 1 copy/cell), transfection efficiency correlated with the amount of DNA bound to the cell surface irrespective of salts. When the DNA binding ratio approached zero, the transfection efficiency was reduced by two to three orders, indicating that DNA entry by diffusion through the bulk solution was less than 1%. Square pulses of up to 12 kV/cm and 1 ms were used in the electrotransfection experiments.(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetic transformation of somatic cells. I. Clone of Chinese hamster cells defective in thymidine kinase and characterized by high transformation efficiency

A characteristics is given of clone A238 of the Chinese hamster cells deficient in thymidine kinase (TK). The isolation procedure is described. Upon transformation with the aid of DNA of plasmids, containing thymidine kinase gene (tk-gene) of Herpes simplex virus type 1 (HSV1) clone A238 cells show frequency (7.10(-5) and efficiency (130 TK+ colonies per 1 microgram of plasmid DNA) compatible with those of mouse line LMtk- cells. Modified transformation and selection conditions of clone A238 cells expressing TK-gene of HSV1 are demonstrated. A simple method is described for discriminating somatic cells, expressing either their proper or a virus TK-gene according to the cloning efficiency of cells on the HAT medium containing thymidine in concentration 100 micrograms/ml. It is shown that at the fixed total DNA concentrations a complete replacement of the eukaryotic carrier DNA for the plasmid DNA, containing no tg gene of HSV1, decreases but only insignificantly the frequency and efficiency of transformation.     

Transformation of Bacillus cereus vegetative cells by electroporation

Transformation of untreated vegetative cells of Bacillus cereus 569 with plasmid pC194 (1.8 megadaltons) by high-voltage electroporation resulted in a maximum of 2 x 10(-5) transformants per viable cell. Transformation of a 130-megadalton plasmid occurred at a comparable frequency. The method was simple, rapid, and yielded transformant colonies in 14 to 24 h. Transformation was obtained with unpurified total plasmid DNA.     

Transformation of Bacillus cereus vegetative cells by electroporation.

Transformation of untreated vegetative cells of Bacillus cereus 569 with plasmid pC194 (1.8 megadaltons) by high-voltage electroporation resulted in a maximum of 2 x 10(-5) transformants per viable cell. Transformation of a 130-megadalton plasmid occurred at a comparable frequency. The method was simple, rapid, and yielded transformant colonies in 14 to 24 h. Transformation was obtained with unpurified total plasmid DNA.     

Transformation of intact yeast cells treated with alkali cations

Intact yeast cells treated with alkali cations took up plasmid DNA. Li+, Cs+, Rb+, K+, and Na+ were effective in inducing competence. Conditions for the transformation of Saccharomyces cerevisiae D13-1A with plasmid YRp7 were studied in detail with CsCl. The optimum incubation time was 1 h, and the optimum cell concentration was 5 x 10(7) cells per ml. The optimum concentration of Cs+ was 1.0 M. Transformation efficiency increased with increasing concentrations of plasmid DNA. Polyethylene glycol was absolutely required. Heat pulse and various polyamines or basic proteins stimulated the uptake of plasmid DNA. Besides circular DNA, linear plasmid DNA was also taken up by Cs+-treated yeast cells, although the uptake efficiency was considerably reduced. The transformation efficiency with Cs+ or Li+ was comparable with that of conventional protoplast methods for a plasmid containing ars1, although not for plasmids containing a 2 microns origin replication.     

Electrically induced DNA uptake by cells is a fast process involving DNA electrophoresis.

Simian Cos-1 cells were transfected electrically with the plasmid pCH110 carrying the beta-galactosidase gene. The efficiency of transfection was determined by a transient expression of this gene. When the plasmid was introduced into a cell suspension 2 s after pulse application, the transfection efficiency was shown to be less than 1% as compared with a prepulse addition of DNA. Addition of DNAase to suspension immediately after a pulse did not decrease transfection efficiency, thus the time of DNA translocation was estimated to be less than 3 s. The use of electric treatment medium, in which the postpulse colloid-osmotic cell swelling was prevented, did not affect the transfection efficiency. These results contradict both assumptions of free DNA diffusion into cell through the long-lived pores and of involvement of osmotic effects in DNA translocation. Transfection of cells in monolayer on a porous film allowed creation of the spatial asymmetry of cell-plasmid interaction along the direction of electric field applied. A pulse with a polarity inducing DNA electrophoresis toward the cells resulted in the 10-fold excess of transfection efficiency compared with a pulse with reverse polarity. Ficoll (10%) which increases medium viscosity or Mg2+ ions (10 mM) which decrease the effective charge of DNA, both reduced transfection efficiency 2-3-fold. These results prove a significant role of DNA electrophoresis in the phenomenon considered. The permeability of cell membranes for an indifferent dye was shown to increase noticeably if the cells were pulsed in the presence of DNA. This indicates a possible interaction of DNA translocated with the pores in an electric field, that results in pore expansion.     

Electrotransformation of Clostridium thermocellum

Electrotransformation of several strains of Clostridium thermocellum was achieved using plasmid pIKm1 with selection based on resistance to erythromycin and lincomycin. A custom-built pulse generator was used to apply a square 10-ms pulse to an electrotransformation cuvette consisting of a modified centrifuge tube. Transformation was verified by recovery of the shuttle plasmid pIKm1 from presumptive transformants of C. thermocellum with subsequent PCR specific to the mls gene on the plasmid, as well as by retransformation of Escherichia coli. Optimization carried out with strain DSM 1313 increased transformation efficiencies from <1 to (2.2 ± 0.5) × 10⁵ transformants per μg of plasmid DNA. Factors conducive to achieving high transformation efficiencies included optimized periods of incubation both before and after electric pulse application, chilling during cell collection and washing, subculture in the presence of isoniacin prior to electric pulse application, a custom-built cuvette embedded in an ice block during pulse application, use of a high (25-kV/cm) field strength, and induction of the mls gene before plating the cells on selective medium. The protocol and preferred conditions developed for strain DSM 1313 resulted in transformation efficiencies of (5.0 ± 1.8) × 10⁴ transformants per μg of plasmid DNA for strain ATCC 27405 and ~1 × 10³ transformants per μg of plasmid DNA for strains DSM 4150 and 7072. Cell viability under optimal conditions was ~50% of that of controls not exposed to an electrical pulse. Dam methylation had a beneficial but modest (7-fold for strain ATCC 27405; 40-fold for strain DSM 1313) effect on transformation efficiency. The effect of isoniacin was also strain specific. The results reported here provide for the first time a gene transfer method functional in C. thermocellum that is suitable for molecular manipulations involving either the introduction of genes associated with foreign gene products or knockout of native genes.     

Electrotransformation of Clostridium thermocellum

Electrotransformation of several strains of Clostridium thermocellum was achieved using plasmid pIKm1 with selection based on resistance to erythromycin and lincomycin. A custom-built pulse generator was used to apply a square 10-ms pulse to an electrotransformation cuvette consisting of a modified centrifuge tube. Transformation was verified by recovery of the shuttle plasmid pIKm1 from presumptive transformants of C. thermocellum with subsequent PCR specific to the mls gene on the plasmid, as well as by retransformation of Escherichia coli. Optimization carried out with strain DSM 1313 increased transformation efficiencies from <1 to (2.2 +/- 0.5) x 10(5) transformants per micro g of plasmid DNA. Factors conducive to achieving high transformation efficiencies included optimized periods of incubation both before and after electric pulse application, chilling during cell collection and washing, subculture in the presence of isoniacin prior to electric pulse application, a custom-built cuvette embedded in an ice block during pulse application, use of a high (25-kV/cm) field strength, and induction of the mls gene before plating the cells on selective medium. The protocol and preferred conditions developed for strain DSM 1313 resulted in transformation efficiencies of (5.0 +/- 1.8) x 10(4) transformants per micro g of plasmid DNA for strain ATCC 27405 and approximately 1 x 10(3) transformants per micro g of plasmid DNA for strains DSM 4150 and 7072. Cell viability under optimal conditions was approximately 50% of that of controls not exposed to an electrical pulse. Dam methylation had a beneficial but modest (7-fold for strain ATCC 27405; 40-fold for strain DSM 1313) effect on transformation efficiency. The effect of isoniacin was also strain specific. The results reported here provide for the first time a gene transfer method functional in C. thermocellum that is suitable for molecular manipulations involving either the introduction of genes associated with foreign gene products or knockout of native genes.     

Highly efficient transfer and stable integration of foreign DNA into partially digested rice cells using a pulsed electrophoretic drive

A new method has been developed to introduce foreign DNA into rice cells. Gene delivery occurred when an electrophoretic drive with cycles of intervallic electric field was applied to a mixture containing partially digested small cell groups (SCGs) and plasmid DNAs. Gene transfer efficiency was evaluated by the detection of -glucuronidase (GUS) activity resulting from expression of a chimaeric plasmid DNA. The optimal combination of treatment conditions (3 V/cm, 30 s pulse and 30 min electrophoretic run) produced a frequency of up to 8.2% of blue cells in transformed microcalluses 40 days after culture of treated SCGs without selection for kanamycin resistance. Southern hybridization showed that the foreign gene had integrated into the chromosomal DNA. These results demonstrate that pulsed electrophoretic drive is applicable to the transfer of foreign genes into plant cells.     

Study of mechanisms of electric field-induced DNA transfection. II. Transfection by low-amplitude, low-frequency alternating electric fields.

Electroporation for DNA transfection generally uses short intense electric pulses (direct current of kilovolts per centimeter, microseconds to milliseconds), or intense dc shifted radio-frequency oscillating fields. These methods, while remarkably effective, often cause death of certain cell populations. Previously it was shown that a completely reversible, high ionic permeation state of membranes could be induced by a low-frequency alternating electric field (ac) with a strength one-tenth, or less, of the critical breakdown voltage of the cell membrane (Teissie, J., and T. Y. Tsong. 1981. J. Physiol. (Paris). 77:1043-1053). We report the transfection of E. coli (JM105) by plasmid PUC18 DNA, which carries an ampicillin-resistance gene, using low-amplitude, low-frequency ac fields. E. coli transformants confer the ampicillin resistance and the efficiency of the transfection can be conveniently assayed by counting colonies in a selection medium containing ampicillin. For the range of ac fields employed (peak-to-peak amplitude 50-200 V/cm, frequency 0.1 Hz-1 MHz, duration 1-100 s), 100% of the E. coli survived the electric field treatment. Transfection efficiencies varied with field strength and frequency, and as high as 1 x 10(5)/micrograms DNA was obtained with a 200 V/cm square wave, 1 Hz ac field, 30 s exposure time, when the DNA/cell ratio was 50-75. Control samples gave a background transfection of much less than 10/micrograms DNA. With a square wave ac field, the transfection efficiency showed a frequency window: the optimal frequency was 1 Hz with a 200 V/cm field, and was approximately 0.1 Hz with a 50 V/cm field.(ABSTRACT TRUNCATED AT 250 WORDS)     

“Curing” of plasmid DNA in acetogen using microwave or applying an electric pulse improves cell growth and metabolite production as compared to the plasmid-harboring strain

Plasmid-free acetogen Clostridium sp. MT962 electrotransformed with a small cryptic plasmid pMT351 was used to develop time- and cost-effective methods for plasmid elimination. Elimination of pMT351 restored production of acetate and ethanol to the levels of the plasmid-free strain with no dry cell weight changes. Destabilizing cell membrane via microwave at 2.45 GHz, or exposure to a single 12 ms square electric pulse at 35 kV cm^?1, eliminated pMT351 in 42–47 % of cells. Plasmid elimination with a single square electric pulse required 10 versus 0.1 J needed to introduce the same 3,202-bp plasmid into the cells as calculated per cell sample of Clostridium sp. MT962. Microwave caused visible changes in repPCR pattern and increased ethanol production at the expense of acetate. This is the first report on microwave of microwave ovens, wireless routers, and mobile devices causing chromosomal DNA aberrations in microbes along with carbon flux change.